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tqt3/src/kernel/qapplication.cpp

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131 KiB

/****************************************************************************
**
** Implementation of TQApplication class
**
** Created : 931107
**
** Copyright (C) 1992-2008 Trolltech ASA. All rights reserved.
**
** This file is part of the kernel module of the TQt GUI Toolkit.
**
** This file may be used under the terms of the GNU General
** Public License versions 2.0 or 3.0 as published by the Free
** Software Foundation and appearing in the files LICENSE.GPL2
** and LICENSE.GPL3 included in the packaging of this file.
** Alternatively you may (at your option) use any later version
** of the GNU General Public License if such license has been
** publicly approved by Trolltech ASA (or its successors, if any)
** and the KDE Free TQt Foundation.
**
** Please review the following information to ensure GNU General
** Public Licensing requirements will be met:
** http://trolltech.com/products/qt/licenses/licensing/opensource/.
** If you are unsure which license is appropriate for your use, please
** review the following information:
** http://trolltech.com/products/qt/licenses/licensing/licensingoverview
** or contact the sales department at sales@trolltech.com.
**
** This file may be used under the terms of the Q Public License as
** defined by Trolltech ASA and appearing in the file LICENSE.TQPL
** included in the packaging of this file. Licensees holding valid TQt
** Commercial licenses may use this file in accordance with the TQt
** Commercial License Agreement provided with the Software.
**
** This file is provided "AS IS" with NO WARRANTY OF ANY KIND,
** INCLUDING THE WARRANTIES OF DESIGN, MERCHANTABILITY AND FITNESS FOR
** A PARTICULAR PURPOSE. Trolltech reserves all rights not granted
** herein.
**
**********************************************************************/
#include "ntqobjectlist.h"
#include "ntqapplication.h"
#include "ntqeventloop.h"
#include "qeventloop_p.h"
#include "ntqwidget.h"
#include "ntqwidgetlist.h"
#include "ntqwidgetintdict.h"
#include "ntqptrdict.h"
#include "ntqcleanuphandler.h"
#include "ntqtranslator.h"
#include "ntqtextcodec.h"
#include "ntqsessionmanager.h"
#include "ntqdragobject.h"
#include "ntqclipboard.h"
#include "ntqcursor.h"
#include "ntqstyle.h"
#include "ntqstylefactory.h"
#include "ntqfile.h"
#include "ntqmessagebox.h"
#include "ntqdir.h"
#include "ntqfileinfo.h"
#ifdef Q_WS_WIN
#include "qinputcontext_p.h"
#endif
#include "qfontdata_p.h"
#if defined(QT_THREAD_SUPPORT)
# include "ntqmutex.h"
# include "ntqthread.h"
# include <private/qthreadinstance_p.h>
#endif // QT_THREAD_SUPPORT
#include <stdlib.h>
#ifdef truncate
# undef truncate
#endif
/*!
\class TQApplication ntqapplication.h
\brief The TQApplication class manages the GUI application's control
flow and main settings.
\ingroup application
\mainclass
It contains the main event loop, where all events from the window
system and other sources are processed and dispatched. It also
handles the application's initialization and finalization, and
provides session management. It also handles most system-wide and
application-wide settings.
For any GUI application that uses TQt, there is precisely one
TQApplication object, no matter whether the application has 0, 1, 2
or more windows at any time.
The TQApplication object is accessible through the global pointer \c
tqApp. Its main areas of responsibility are:
\list
\i It initializes the application with the user's desktop settings
such as palette(), font() and doubleClickInterval(). It keeps track
of these properties in case the user changes the desktop globally, for
example through some kind of control panel.
\i It performs event handling, meaning that it receives events
from the underlying window system and dispatches them to the relevant
widgets. By using sendEvent() and postEvent() you can send your own
events to widgets.
\i It parses common command line arguments and sets its internal
state accordingly. See the \link TQApplication::TQApplication()
constructor documentation\endlink below for more details about this.
\i It defines the application's look and feel, which is
encapsulated in a TQStyle object. This can be changed at runtime
with setStyle().
\i It specifies how the application is to allocate colors.
See setColorSpec() for details.
\i It provides localization of strings that are visible to the user
via translate().
\i It provides some magical objects like the desktop() and the
clipboard().
\i It knows about the application's windows. You can ask which
widget is at a certain position using widgetAt(), get a list of
topLevelWidgets() and closeAllWindows(), etc.
\i It manages the application's mouse cursor handling,
see setOverrideCursor() and setGlobalMouseTracking().
\i On the X window system, it provides functions to flush and sync
the communication stream, see flushX() and syncX().
\i It provides support for sophisticated \link
session.html session management \endlink. This makes it possible
for applications to terminate gracefully when the user logs out, to
cancel a shutdown process if termination isn't possible and even to
preserve the entire application's state for a future session. See
isSessionRestored(), sessionId() and commitData() and saveState()
for details.
\endlist
The <a href="simple-application.html">Application walk-through
example</a> contains a typical complete main() that does the usual
things with TQApplication.
Since the TQApplication object does so much initialization, it
<b>must</b> be created before any other objects related to the user
interface are created.
Since it also deals with common command line arguments, it is
usually a good idea to create it \e before any interpretation or
modification of \c argv is done in the application itself. (Note
also that for X11, setMainWidget() may change the main widget
according to the \c -geometry option. To preserve this
functionality, you must set your defaults before setMainWidget() and
any overrides after.)
\table
\header \i21 Groups of functions
\row
\i System settings
\i
desktopSettingsAware(),
setDesktopSettingsAware(),
cursorFlashTime(),
setCursorFlashTime(),
doubleClickInterval(),
setDoubleClickInterval(),
wheelScrollLines(),
setWheelScrollLines(),
palette(),
setPalette(),
font(),
setFont(),
fontMetrics().
\row
\i Event handling
\i
exec(),
processEvents(),
enter_loop(),
exit_loop(),
exit(),
quit().
sendEvent(),
postEvent(),
sendPostedEvents(),
removePostedEvents(),
hasPendingEvents(),
notify(),
macEventFilter(),
qwsEventFilter(),
x11EventFilter(),
x11ProcessEvent(),
winEventFilter().
\row
\i GUI Styles
\i
style(),
setStyle(),
polish().
\row
\i Color usage
\i
colorSpec(),
setColorSpec(),
qwsSetCustomColors().
\row
\i Text handling
\i
installTranslator(),
removeTranslator()
translate().
\row
\i Widgets
\i
mainWidget(),
setMainWidget(),
allWidgets(),
topLevelWidgets(),
desktop(),
activePopupWidget(),
activeModalWidget(),
clipboard(),
focusWidget(),
winFocus(),
activeWindow(),
widgetAt().
\row
\i Advanced cursor handling
\i
hasGlobalMouseTracking(),
setGlobalMouseTracking(),
overrideCursor(),
setOverrideCursor(),
restoreOverrideCursor().
\row
\i X Window System synchronization
\i
flushX(),
syncX().
\row
\i Session management
\i
isSessionRestored(),
sessionId(),
commitData(),
saveState().
\row
\i Threading
\i
lock(), unlock(), locked(), tryLock(),
wakeUpGuiThread()
\row
\i Miscellaneous
\i
closeAllWindows(),
startingUp(),
closingDown(),
type().
\endtable
\e {Non-GUI programs:} While TQt is not optimized or
designed for writing non-GUI programs, it's possible to use
\link tools.html some of its classes \endlink without creating a
TQApplication. This can be useful if you wish to share code between
a non-GUI server and a GUI client.
\headerfile ntqnamespace.h
\headerfile ntqwindowdefs.h
\headerfile ntqglobal.h
*/
/*! \enum TQt::HANDLE
\internal
*/
/*!
\enum TQApplication::Type
\value Tty a console application
\value GuiClient a GUI client application
\value GuiServer a GUI server application
*/
/*!
\enum TQApplication::ColorSpec
\value NormalColor the default color allocation policy
\value CustomColor the same as NormalColor for X11; allocates colors
to a palette on demand under Windows
\value ManyColor the right choice for applications that use thousands of
colors
See setColorSpec() for full details.
*/
/*
The tqt_init() and tqt_cleanup() functions are implemented in the
qapplication_xyz.cpp file.
*/
void tqt_init( int *, char **, TQApplication::Type );
void tqt_cleanup();
#if defined(Q_WS_X11)
void tqt_init( Display* dpy, TQt::HANDLE, TQt::HANDLE );
void tqt_init( int *, char **, Display* dpy, TQt::HANDLE, TQt::HANDLE );
#endif
Q_EXPORT bool tqt_tryModalHelper( TQWidget *widget, TQWidget **rettop );
TQApplication *tqApp = 0; // global application object
TQStyle *TQApplication::app_style = 0; // default application style
bool tqt_explicit_app_style = FALSE; // style explicitly set by programmer
int TQApplication::app_cspec = TQApplication::NormalColor;
#ifndef QT_NO_PALETTE
TQPalette *TQApplication::app_pal = 0; // default application palette
#endif
TQFont *TQApplication::app_font = 0; // default application font
bool tqt_app_has_font = FALSE;
#ifndef QT_NO_CURSOR
TQCursor *TQApplication::app_cursor = 0; // default application cursor
#endif
int TQApplication::app_tracking = 0; // global mouse tracking
bool TQApplication::is_app_running = FALSE; // app starting up if FALSE
bool TQApplication::is_app_closing = FALSE; // app closing down if TRUE
int TQApplication::loop_level = 0; // event loop level
TQWidget *TQApplication::main_widget = 0; // main application widget
TQWidget *TQApplication::focus_widget = 0; // has keyboard input focus
TQWidget *TQApplication::active_window = 0; // toplevel with keyboard focus
bool TQApplication::obey_desktop_settings = TRUE; // use winsys resources
int TQApplication::cursor_flash_time = 1000; // text caret flash time
int TQApplication::mouse_double_click_time = 400; // mouse dbl click limit
#ifndef QT_NO_WHEELEVENT
int TQApplication::wheel_scroll_lines = 3; // number of lines to scroll
#endif
bool tqt_is_gui_used;
bool Q_EXPORT tqt_resolve_symlinks = TRUE;
bool Q_EXPORT tqt_tab_all_widgets = TRUE;
TQRect tqt_maxWindowRect;
static int drag_time = 500;
static int drag_distance = 4;
static bool reverse_layout = FALSE;
TQSize TQApplication::app_strut = TQSize( 0,0 ); // no default application strut
bool TQApplication::animate_ui = TRUE;
bool TQApplication::animate_menu = FALSE;
bool TQApplication::fade_menu = FALSE;
bool TQApplication::animate_combo = FALSE;
bool TQApplication::animate_tooltip = FALSE;
bool TQApplication::fade_tooltip = FALSE;
bool TQApplication::animate_toolbox = FALSE;
bool TQApplication::widgetCount = FALSE;
TQApplication::Type tqt_appType=TQApplication::Tty;
#ifndef QT_NO_COMPONENT
TQStringList *TQApplication::app_libpaths = 0;
#endif
bool TQApplication::metaComposeUnicode = FALSE;
int TQApplication::composedUnicode = 0;
#ifdef QT_THREAD_SUPPORT
TQMutex *TQApplication::tqt_mutex = 0;
static TQMutex *postevent_mutex = 0;
static TQt::HANDLE tqt_application_thread_id = 0;
Q_EXPORT TQt::HANDLE tqt_get_application_thread_id()
{
return tqt_application_thread_id;
}
#endif // QT_THREAD_SUPPORT
#ifndef QT_THREAD_SUPPORT
TQEventLoop *TQApplication::eventloop = 0; // application event loop
#endif
#ifdef QT_THREAD_SUPPORT
TQEventLoop* TQApplication::currentEventLoop() {
TQThread* thread = TQThread::currentThreadObject();
if (thread) {
if (thread->d) {
return thread->d->eventLoop;
}
}
return NULL;
}
#else
TQEventLoop* TQApplication::currentEventLoop() {
return TQApplication::eventloop;
}
#endif
#ifndef QT_NO_ACCEL
extern bool tqt_dispatchAccelEvent( TQWidget*, TQKeyEvent* ); // def in qaccel.cpp
extern bool tqt_tryComposeUnicode( TQWidget*, TQKeyEvent* ); // def in qaccel.cpp
#endif
#if defined(QT_TABLET_SUPPORT)
bool chokeMouse = FALSE;
#endif
void tqt_setMaxWindowRect(const TQRect& r)
{
tqt_maxWindowRect = r;
// Re-resize any maximized windows
TQWidgetList* l = TQApplication::topLevelWidgets();
if ( l ) {
TQWidget *w = l->first();
while ( w ) {
if ( w->isVisible() && w->isMaximized() )
{
w->showNormal(); //#### flicker
w->showMaximized();
}
w = l->next();
}
delete l;
}
}
typedef void (*VFPTR)();
typedef TQValueList<VFPTR> TQVFuncList;
static TQVFuncList *postRList = 0; // list of post routines
/*!
\relates TQApplication
Adds a global routine that will be called from the TQApplication
destructor. This function is normally used to add cleanup routines
for program-wide functionality.
The function given by \a p should take no arguments and return
nothing, like this:
\code
static int *global_ptr = 0;
static void cleanup_ptr()
{
delete [] global_ptr;
global_ptr = 0;
}
void init_ptr()
{
global_ptr = new int[100]; // allocate data
tqAddPostRoutine( cleanup_ptr ); // delete later
}
\endcode
Note that for an application- or module-wide cleanup,
tqAddPostRoutine() is often not suitable. People have a tendency to
make such modules dynamically loaded, and then unload those modules
long before the TQApplication destructor is called, for example.
For modules and libraries, using a reference-counted initialization
manager or TQt' parent-child delete mechanism may be better. Here is
an example of a private class which uses the parent-child mechanism
to call a cleanup function at the right time:
\code
class MyPrivateInitStuff: public TQObject {
private:
MyPrivateInitStuff( TQObject * parent ): TQObject( parent) {
// initialization goes here
}
MyPrivateInitStuff * p;
public:
static MyPrivateInitStuff * initStuff( TQObject * parent ) {
if ( !p )
p = new MyPrivateInitStuff( parent );
return p;
}
~MyPrivateInitStuff() {
// cleanup (the "post routine") goes here
}
}
\endcode
By selecting the right parent widget/object, this can often be made
to clean up the module's data at the exact right moment.
*/
Q_EXPORT void tqAddPostRoutine( TQtCleanUpFunction p)
{
if ( !postRList ) {
postRList = new TQVFuncList;
TQ_CHECK_PTR( postRList );
}
postRList->prepend( p );
}
Q_EXPORT void tqRemovePostRoutine( TQtCleanUpFunction p )
{
if ( !postRList ) return;
TQVFuncList::Iterator it = postRList->begin();
while ( it != postRList->end() ) {
if ( *it == p ) {
postRList->remove( it );
it = postRList->begin();
} else {
++it;
}
}
}
// Default application palettes and fonts (per widget type)
TQAsciiDict<TQPalette> *TQApplication::app_palettes = 0;
TQAsciiDict<TQFont> *TQApplication::app_fonts = 0;
#ifndef QT_NO_SESSIONMANAGER
TQString *TQApplication::session_key = 0; // ## session key. Should be a member in 4.0
#endif
TQWidgetList *TQApplication::popupWidgets = 0; // has keyboard input focus
TQDesktopWidget *tqt_desktopWidget = 0; // root window widgets
#ifndef QT_NO_CLIPBOARD
TQClipboard *tqt_clipboard = 0; // global clipboard object
#endif
TQWidgetList * tqt_modal_stack=0; // stack of modal widgets
#ifdef QT_THREAD_SUPPORT
// thread wrapper for the main() thread
class TQCoreApplicationThread : public TQThread
{
public:
inline TQCoreApplicationThread()
{
TQThreadInstance::setCurrentThread(this);
// thread should be running and not finished for the lifetime
// of the application (even if TQCoreApplication goes away)
d->running = true;
d->finished = false;
d->eventLoop = NULL;
}
inline ~TQCoreApplicationThread()
{
// avoid warning from TQThread
d->running = false;
}
private:
inline void run()
{
// this function should never be called, it is implemented
// only so that we can instantiate the object
tqFatal("TQCoreApplicationThread: internal error");
}
};
static TQCoreApplicationThread tqt_main_thread;
static TQThread *mainThread() { return &tqt_main_thread; }
#else
static TQThread* mainThread() { return TQThread::currentThread(); }
#endif
// Definitions for posted events
struct TQPostEvent {
TQPostEvent( TQObject *r, TQEvent *e ): receiver( r ), event( e ) {}
~TQPostEvent() { delete event; }
TQObject *receiver;
TQEvent *event;
};
class Q_EXPORT TQPostEventList : public TQPtrList<TQPostEvent>
{
public:
TQPostEventList() : TQPtrList<TQPostEvent>() {}
TQPostEventList( const TQPostEventList &list ) : TQPtrList<TQPostEvent>(list) {}
~TQPostEventList() { clear(); }
TQPostEventList &operator=(const TQPostEventList &list)
{ return (TQPostEventList&)TQPtrList<TQPostEvent>::operator=(list); }
};
class Q_EXPORT TQPostEventListIt : public TQPtrListIterator<TQPostEvent>
{
public:
TQPostEventListIt( const TQPostEventList &l ) : TQPtrListIterator<TQPostEvent>(l) {}
TQPostEventListIt &operator=(const TQPostEventListIt &i)
{ return (TQPostEventListIt&)TQPtrListIterator<TQPostEvent>::operator=(i); }
};
static TQPostEventList *globalPostedEvents = 0; // list of posted events
uint qGlobalPostedEventsCount()
{
if (!globalPostedEvents)
return 0;
return globalPostedEvents->count();
}
static TQSingleCleanupHandler<TQPostEventList> qapp_cleanup_events;
#ifndef QT_NO_PALETTE
TQPalette *tqt_std_pal = 0;
void tqt_create_std_palette()
{
if ( tqt_std_pal )
delete tqt_std_pal;
TQColor standardLightGray( 192, 192, 192 );
TQColor light( 255, 255, 255 );
TQColor dark( standardLightGray.dark( 150 ) );
TQColorGroup std_act( TQt::black, standardLightGray,
light, dark, TQt::gray,
TQt::black, TQt::white );
TQColorGroup std_dis( TQt::darkGray, standardLightGray,
light, dark, TQt::gray,
TQt::darkGray, std_act.background() );
TQColorGroup std_inact( TQt::black, standardLightGray,
light, dark, TQt::gray,
TQt::black, TQt::white );
tqt_std_pal = new TQPalette( std_act, std_dis, std_inact );
}
static void tqt_fix_tooltips()
{
// No resources for this yet (unlike on Windows).
TQColorGroup cg( TQt::black, TQColor(255,255,220),
TQColor(96,96,96), TQt::black, TQt::black,
TQt::black, TQColor(255,255,220) );
TQPalette pal( cg, cg, cg );
TQApplication::setPalette( pal, TRUE, "TQTipLabel");
}
#endif
void TQApplication::process_cmdline( int* argcptr, char ** argv )
{
// process platform-indep command line
if ( !tqt_is_gui_used || !*argcptr)
return;
int argc = *argcptr;
int i, j;
j = 1;
for ( i=1; i<argc; i++ ) {
if ( argv[i] && *argv[i] != '-' ) {
argv[j++] = argv[i];
continue;
}
TQCString arg = argv[i];
TQCString s;
if ( arg == "-qdevel" || arg == "-qdebug") {
// obsolete argument
} else if ( arg.find( "-style=", 0, FALSE ) != -1 ) {
s = arg.right( arg.length() - 7 );
} else if ( qstrcmp(arg,"-style") == 0 && i < argc-1 ) {
s = argv[++i];
s = s.lower();
#ifndef QT_NO_SESSIONMANAGER
} else if ( qstrcmp(arg,"-session") == 0 && i < argc-1 ) {
TQCString s = argv[++i];
if ( !s.isEmpty() ) {
session_id = TQString::fromLatin1( s );
int p = session_id.find( '_' );
if ( p >= 0 ) {
if ( !session_key )
session_key = new TQString;
*session_key = session_id.mid( p +1 );
session_id = session_id.left( p );
}
is_session_restored = TRUE;
}
#endif
} else if ( qstrcmp(arg, "-reverse") == 0 ) {
setReverseLayout( TRUE );
} else if ( qstrcmp(arg, "-widgetcount") == 0 ) {
widgetCount = TRUE;;
} else {
argv[j++] = argv[i];
}
#ifndef QT_NO_STYLE
if ( !s.isEmpty() ) {
setStyle( s );
}
#endif
}
if(j < argc) {
#ifdef Q_WS_MACX
static char* empty = "\0";
argv[j] = empty;
#else
argv[j] = 0;
#endif
*argcptr = j;
}
}
/*!
Initializes the window system and constructs an application object
with \a argc command line arguments in \a argv.
The global \c tqApp pointer refers to this application object. Only
one application object should be created.
This application object must be constructed before any \link
TQPaintDevice paint devices\endlink (including widgets, pixmaps, bitmaps
etc.).
Note that \a argc and \a argv might be changed. TQt removes command
line arguments that it recognizes. The modified \a argc and \a argv
can also be accessed later with \c tqApp->argc() and \c tqApp->argv().
The documentation for argv() contains a detailed description of how
to process command line arguments.
TQt debugging options (not available if TQt was compiled with the
QT_NO_DEBUG flag defined):
\list
\i -nograb, tells TQt that it must never grab the mouse or the keyboard.
\i -dograb (only under X11), running under a debugger can cause
an implicit -nograb, use -dograb to override.
\i -sync (only under X11), switches to synchronous mode for
debugging.
\endlist
See \link debug.html Debugging Techniques \endlink for a more
detailed explanation.
All TQt programs automatically support the following command line options:
\list
\i -reverse causes text to be formatted for right-to-left languages
rather than in the usual left-to-right direction.
\i -style= \e style, sets the application GUI style. Possible values
are \c motif, \c windows, and \c platinum. If you compiled TQt
with additional styles or have additional styles as plugins these
will be available to the \c -style command line option.
\i -style \e style, is the same as listed above.
\i -session= \e session, restores the application from an earlier
\link session.html session \endlink.
\i -session \e session, is the same as listed above.
\i -widgetcount, prints debug message at the end about number of widgets left
undestroyed and maximum number of widgets existed at the same time
\endlist
The X11 version of TQt also supports some traditional X11
command line options:
\list
\i -display \e display, sets the X display (default is $DISPLAY).
\i -geometry \e geometry, sets the client geometry of the
\link setMainWidget() main widget\endlink.
\i -fn or \c -font \e font, defines the application font. The
font should be specified using an X logical font description.
\i -bg or \c -background \e color, sets the default background color
and an application palette (light and dark shades are calculated).
\i -fg or \c -foreground \e color, sets the default foreground color.
\i -btn or \c -button \e color, sets the default button color.
\i -name \e name, sets the application name.
\i -title \e title, sets the application title (caption).
\i -visual \c TrueColor, forces the application to use a TrueColor visual
on an 8-bit display.
\i -ncols \e count, limits the number of colors allocated in the
color cube on an 8-bit display, if the application is using the
\c TQApplication::ManyColor color specification. If \e count is
216 then a 6x6x6 color cube is used (i.e. 6 levels of red, 6 of green,
and 6 of blue); for other values, a cube
approximately proportional to a 2x3x1 cube is used.
\i -cmap, causes the application to install a private color map
on an 8-bit display.
\endlist
\sa argc(), argv()
*/
//######### BINARY COMPATIBILITY constructor
TQApplication::TQApplication( int &argc, char **argv )
{
construct( argc, argv, GuiClient );
}
/*!
Constructs an application object with \a argc command line arguments
in \a argv. If \a GUIenabled is TRUE, a GUI application is
constructed, otherwise a non-GUI (console) application is created.
Set \a GUIenabled to FALSE for programs without a graphical user
interface that should be able to run without a window system.
On X11, the window system is initialized if \a GUIenabled is TRUE.
If \a GUIenabled is FALSE, the application does not connect to the
X-server.
On Windows and Macintosh, currently the window system is always
initialized, regardless of the value of GUIenabled. This may change in
future versions of TQt.
The following example shows how to create an application that
uses a graphical interface when available.
\code
int main( int argc, char **argv )
{
#ifdef Q_WS_X11
bool useGUI = getenv( "DISPLAY" ) != 0;
#else
bool useGUI = TRUE;
#endif
TQApplication app(argc, argv, useGUI);
if ( useGUI ) {
//start GUI version
...
} else {
//start non-GUI version
...
}
return app.exec();
}
\endcode
*/
TQApplication::TQApplication( int &argc, char **argv, bool GUIenabled )
{
construct( argc, argv, GUIenabled ? GuiClient : Tty );
}
/*!
Constructs an application object with \a argc command line arguments
in \a argv.
For TQt/Embedded, passing \c TQApplication::GuiServer for \a type
makes this application the server (equivalent to running with the
-qws option).
*/
TQApplication::TQApplication( int &argc, char **argv, Type type )
{
construct( argc, argv, type );
}
Q_EXPORT void tqt_ucm_initialize( TQApplication *theApp )
{
if ( tqApp )
return;
int argc = theApp->argc();
char **argv = theApp->argv();
theApp->construct( argc, argv, tqApp->type() );
Q_ASSERT( tqApp == theApp );
}
void TQApplication::construct( int &argc, char **argv, Type type )
{
tqt_appType = type;
tqt_is_gui_used = (type != Tty);
init_precmdline();
static const char *empty = "";
if ( argc == 0 || argv == 0 ) {
argc = 0;
argv = (char **)&empty; // ouch! careful with TQApplication::argv()!
}
app_argc = argc;
app_argv = argv;
tqt_init( &argc, argv, type ); // Must be called before initialize()
process_cmdline( &argc, argv );
initialize( argc, argv );
if ( tqt_is_gui_used )
tqt_maxWindowRect = desktop()->rect();
if ( currentEventLoop() )
currentEventLoop()->appStartingUp();
}
/*!
Returns the type of application, Tty, GuiClient or GuiServer.
*/
TQApplication::Type TQApplication::type() const
{
return tqt_appType;
}
#if defined(Q_WS_X11)
/*!
Create an application, given an already open display \a dpy. If \a
visual and \a colormap are non-zero, the application will use those as
the default Visual and Colormap contexts.
\warning TQt only supports TrueColor visuals at depths higher than 8
bits-per-pixel.
This is available only on X11.
*/
TQApplication::TQApplication( Display* dpy, HANDLE visual, HANDLE colormap )
{
static int aargc = 1;
// ### a string literal is a cont char*
// ### using it as a char* is wrong and could lead to segfaults
// ### if aargv is modified someday
static char *aargv[] = { (char*)"unknown", 0 };
app_argc = aargc;
app_argv = aargv;
tqt_appType = GuiClient;
tqt_is_gui_used = TRUE;
tqt_appType = GuiClient;
init_precmdline();
// ... no command line.
if ( ! dpy ) {
#ifdef QT_CHECK_STATE
tqWarning( "TQApplication: invalid Display* argument." );
#endif // QT_CHECK_STATE
tqt_init( &aargc, aargv, GuiClient );
} else {
tqt_init( dpy, visual, colormap );
}
initialize( aargc, aargv );
if ( tqt_is_gui_used )
tqt_maxWindowRect = desktop()->rect();
if ( currentEventLoop() )
currentEventLoop()->appStartingUp();
}
/*!
Create an application, given an already open display \a dpy and using
\a argc command line arguments in \a argv. If \a
visual and \a colormap are non-zero, the application will use those as
the default Visual and Colormap contexts.
\warning TQt only supports TrueColor visuals at depths higher than 8
bits-per-pixel.
This is available only on X11.
*/
TQApplication::TQApplication(Display *dpy, int argc, char **argv,
HANDLE visual, HANDLE colormap)
{
tqt_appType = GuiClient;
tqt_is_gui_used = TRUE;
tqt_appType = GuiClient;
init_precmdline();
app_argc = argc;
app_argv = argv;
if ( ! dpy ) {
#ifdef QT_CHECK_STATE
tqWarning( "TQApplication: invalid Display* argument." );
#endif // QT_CHECK_STATE
tqt_init( &argc, argv, GuiClient );
} else {
tqt_init( &argc, argv, dpy, visual, colormap );
}
process_cmdline( &argc, argv );
initialize(argc, argv);
if ( tqt_is_gui_used )
tqt_maxWindowRect = desktop()->rect();
if ( currentEventLoop() )
currentEventLoop()->appStartingUp();
}
#endif // Q_WS_X11
#ifdef QT_THREAD_SUPPORT
TQThread* TQApplication::guiThread() {
return mainThread();
}
bool TQApplication::isGuiThread() {
return (TQThread::currentThreadObject() == guiThread());
}
#else
bool TQApplication::isGuiThread() {
return true;
}
#endif
void TQApplication::init_precmdline()
{
translators = 0;
is_app_closing = FALSE;
#ifndef QT_NO_SESSIONMANAGER
is_session_restored = FALSE;
#endif
#if defined(QT_CHECK_STATE)
if ( tqApp )
tqWarning( "TQApplication: There should be max one application object" );
#endif
tqApp = (TQApplication*)this;
}
/*!
Initializes the TQApplication object, called from the constructors.
*/
void TQApplication::initialize( int argc, char **argv )
{
#ifdef QT_THREAD_SUPPORT
tqt_mutex = new TQMutex( TRUE );
postevent_mutex = new TQMutex( TRUE );
tqt_application_thread_id = TQThread::currentThread();
#endif // QT_THREAD_SUPPORT
app_argc = argc;
app_argv = argv;
quit_now = FALSE;
quit_code = 0;
TQWidget::createMapper(); // create widget mapper
#ifndef QT_NO_PALETTE
(void) palette(); // trigger creation of application palette
#endif
is_app_running = TRUE; // no longer starting up
#ifndef QT_NO_SESSIONMANAGER
// connect to the session manager
if ( !session_key )
session_key = new TQString;
session_manager = new TQSessionManager( tqApp, session_id, *session_key );
#endif
}
/*****************************************************************************
Functions returning the active popup and modal widgets.
*****************************************************************************/
/*!
Returns the active popup widget.
A popup widget is a special top level widget that sets the \c
WType_Popup widget flag, e.g. the TQPopupMenu widget. When the
application opens a popup widget, all events are sent to the popup.
Normal widgets and modal widgets cannot be accessed before the popup
widget is closed.
Only other popup widgets may be opened when a popup widget is shown.
The popup widgets are organized in a stack. This function returns
the active popup widget at the top of the stack.
\sa activeModalWidget(), topLevelWidgets()
*/
TQWidget *TQApplication::activePopupWidget()
{
return popupWidgets ? popupWidgets->getLast() : 0;
}
/*!
Returns the active modal widget.
A modal widget is a special top level widget which is a subclass of
TQDialog that specifies the modal parameter of the constructor as
TRUE. A modal widget must be closed before the user can continue
with other parts of the program.
Modal widgets are organized in a stack. This function returns
the active modal widget at the top of the stack.
\sa activePopupWidget(), topLevelWidgets()
*/
TQWidget *TQApplication::activeModalWidget()
{
return tqt_modal_stack ? tqt_modal_stack->getFirst() : 0;
}
/*!
Cleans up any window system resources that were allocated by this
application. Sets the global variable \c tqApp to 0.
*/
TQApplication::~TQApplication()
{
#ifndef QT_NO_CLIPBOARD
// flush clipboard contents
if ( tqt_clipboard ) {
TQCustomEvent event( TQEvent::Clipboard );
TQApplication::sendEvent( tqt_clipboard, &event );
}
#endif
if ( currentEventLoop() )
currentEventLoop()->appClosingDown();
if ( postRList ) {
TQVFuncList::Iterator it = postRList->begin();
while ( it != postRList->end() ) { // call post routines
(**it)();
postRList->remove( it );
it = postRList->begin();
}
delete postRList;
postRList = 0;
}
TQObject *tipmanager = child( "toolTipManager", "TQTipManager", FALSE );
delete tipmanager;
delete tqt_desktopWidget;
tqt_desktopWidget = 0;
is_app_closing = TRUE;
#ifndef QT_NO_CLIPBOARD
delete tqt_clipboard;
tqt_clipboard = 0;
#endif
TQWidget::destroyMapper();
#ifndef QT_NO_PALETTE
delete tqt_std_pal;
tqt_std_pal = 0;
delete app_pal;
app_pal = 0;
delete app_palettes;
app_palettes = 0;
#endif
delete app_font;
app_font = 0;
delete app_fonts;
app_fonts = 0;
#ifndef QT_NO_STYLE
delete app_style;
app_style = 0;
#endif
#ifndef QT_NO_CURSOR
delete app_cursor;
app_cursor = 0;
#endif
#ifndef QT_NO_TRANSLATION
delete translators;
#endif
#ifndef QT_NO_DRAGANDDROP
extern TQDragManager *qt_dnd_manager;
delete qt_dnd_manager;
#endif
tqt_cleanup();
#ifndef QT_NO_COMPONENT
delete app_libpaths;
app_libpaths = 0;
#endif
#ifdef QT_THREAD_SUPPORT
delete tqt_mutex;
tqt_mutex = 0;
delete postevent_mutex;
postevent_mutex = 0;
#endif // QT_THREAD_SUPPORT
if( tqApp == this ) {
if ( postedEvents )
removePostedEvents( this );
tqApp = 0;
}
is_app_running = FALSE;
if ( widgetCount ) {
tqDebug( "Widgets left: %i Max widgets: %i \n", TQWidget::instanceCounter, TQWidget::maxInstances );
}
#ifndef QT_NO_SESSIONMANAGER
delete session_manager;
session_manager = 0;
delete session_key;
session_key = 0;
#endif //QT_NO_SESSIONMANAGER
tqt_explicit_app_style = FALSE;
tqt_app_has_font = FALSE;
app_tracking = 0;
obey_desktop_settings = TRUE;
cursor_flash_time = 1000;
mouse_double_click_time = 400;
#ifndef QT_NO_WHEELEVENT
wheel_scroll_lines = 3;
#endif
drag_time = 500;
drag_distance = 4;
reverse_layout = FALSE;
app_strut = TQSize( 0, 0 );
animate_ui = TRUE;
animate_menu = FALSE;
fade_menu = FALSE;
animate_combo = FALSE;
animate_tooltip = FALSE;
fade_tooltip = FALSE;
widgetCount = FALSE;
}
/*!
\fn int TQApplication::argc() const
Returns the number of command line arguments.
The documentation for argv() describes how to process command line
arguments.
\sa argv(), TQApplication::TQApplication()
*/
/*!
\fn char **TQApplication::argv() const
Returns the command line argument vector.
\c argv()[0] is the program name, \c argv()[1] is the first
argument and \c argv()[argc()-1] is the last argument.
A TQApplication object is constructed by passing \e argc and \e
argv from the \c main() function. Some of the arguments may be
recognized as TQt options and removed from the argument vector. For
example, the X11 version of TQt knows about \c -display, \c -font
and a few more options.
Example:
\code
// showargs.cpp - displays program arguments in a list box
#include <ntqapplication.h>
#include <ntqlistbox.h>
int main( int argc, char **argv )
{
TQApplication a( argc, argv );
TQListBox b;
a.setMainWidget( &b );
for ( int i = 0; i < a.argc(); i++ ) // a.argc() == argc
b.insertItem( a.argv()[i] ); // a.argv()[i] == argv[i]
b.show();
return a.exec();
}
\endcode
If you run \c{showargs -display unix:0 -font 9x15bold hello world}
under X11, the list box contains the three strings "showargs",
"hello" and "world".
TQt provides a global pointer, \c tqApp, that points to the
TQApplication object, and through which you can access argc() and
argv() in functions other than main().
\sa argc(), TQApplication::TQApplication()
*/
/*!
\fn void TQApplication::setArgs( int argc, char **argv )
\internal
*/
#ifndef QT_NO_STYLE
static TQString *qt_style_override = 0;
/*!
Returns the application's style object.
\sa setStyle(), TQStyle
*/
TQStyle& TQApplication::style()
{
#ifndef QT_NO_STYLE
if ( app_style )
return *app_style;
if ( !tqt_is_gui_used )
tqFatal( "No style available in non-gui applications!" );
#if defined(Q_WS_X11)
if(!qt_style_override)
x11_initialize_style(); // run-time search for default style
#endif
if ( !app_style ) {
// Compile-time search for default style
//
TQString style;
if ( qt_style_override ) {
style = *qt_style_override;
delete qt_style_override;
qt_style_override = 0;
} else {
# if defined(Q_WS_WIN) && defined(Q_OS_TEMP)
style = "PocketPC";
#elif defined(Q_WS_WIN)
if ( qWinVersion() >= TQt::WV_XP && qWinVersion() < TQt::WV_NT_based )
style = "WindowsXP";
else
style = "Windows"; // default styles for Windows
#elif defined(Q_WS_X11) && defined(Q_OS_SOLARIS)
style = "CDE"; // default style for X11 on Solaris
#elif defined(Q_WS_X11) && defined(Q_OS_IRIX)
style = "SGI"; // default style for X11 on IRIX
#elif defined(Q_WS_X11)
style = "Motif"; // default style for X11
#elif defined(Q_WS_MAC)
style = "Macintosh"; // default style for all Mac's
#elif defined(Q_WS_QWS)
style = "Compact"; // default style for small devices
#endif
}
app_style = TQStyleFactory::create( style );
if ( !app_style && // platform default style not available, try alternatives
!(app_style = TQStyleFactory::create( "Windows" ) ) &&
!(app_style = TQStyleFactory::create( "Platinum" ) ) &&
!(app_style = TQStyleFactory::create( "MotifPlus" ) ) &&
!(app_style = TQStyleFactory::create( "Motif" ) ) &&
!(app_style = TQStyleFactory::create( "CDE" ) ) &&
!(app_style = TQStyleFactory::create( "Aqua" ) ) &&
!(app_style = TQStyleFactory::create( "SGI" ) ) &&
!(app_style = TQStyleFactory::create( "Compact" ) )
#ifndef QT_NO_STRINGLIST
&& !(app_style = TQStyleFactory::create( TQStyleFactory::keys()[0] ) )
#endif
)
tqFatal( "No %s style available!", style.latin1() );
}
TQPalette app_pal_copy ( *app_pal );
app_style->polish( *app_pal );
if ( is_app_running && !is_app_closing && (*app_pal != app_pal_copy) ) {
TQEvent e( TQEvent::ApplicationPaletteChange );
TQWidgetIntDictIt it( *((TQWidgetIntDict*)TQWidget::mapper) );
register TQWidget *w;
while ( (w=it.current()) ) { // for all widgets...
++it;
sendEvent( w, &e );
}
}
app_style->polish( tqApp );
#endif
return *app_style;
}
/*!
Sets the application's GUI style to \a style. Ownership of the style
object is transferred to TQApplication, so TQApplication will delete
the style object on application exit or when a new style is set.
Example usage:
\code
TQApplication::setStyle( new TQWindowsStyle );
\endcode
When switching application styles, the color palette is set back to
the initial colors or the system defaults. This is necessary since
certain styles have to adapt the color palette to be fully
style-guide compliant.
\sa style(), TQStyle, setPalette(), desktopSettingsAware()
*/
void TQApplication::setStyle( TQStyle *style )
{
TQStyle* old = app_style;
app_style = style;
#ifdef Q_WS_X11
tqt_explicit_app_style = TRUE;
#endif // Q_WS_X11
if ( startingUp() ) {
delete old;
return;
}
// clean up the old style
if (old) {
if ( is_app_running && !is_app_closing ) {
TQWidgetIntDictIt it( *((TQWidgetIntDict*)TQWidget::mapper) );
register TQWidget *w;
while ( (w=it.current()) ) { // for all widgets...
++it;
if ( !w->testWFlags(WType_Desktop) && // except desktop
w->testWState(WState_Polished) ) { // has been polished
old->unPolish(w);
}
}
}
old->unPolish( tqApp );
}
// take care of possible palette requirements of certain gui
// styles. Do it before polishing the application since the style
// might call TQApplication::setStyle() itself
if ( !tqt_std_pal )
tqt_create_std_palette();
TQPalette tmpPal = *tqt_std_pal;
setPalette( tmpPal, TRUE );
// initialize the application with the new style
app_style->polish( tqApp );
// re-polish existing widgets if necessary
if (old) {
if ( is_app_running && !is_app_closing ) {
TQWidgetIntDictIt it( *((TQWidgetIntDict*)TQWidget::mapper) );
register TQWidget *w;
while ( (w=it.current()) ) { // for all widgets...
++it;
if ( !w->testWFlags(WType_Desktop) ) { // except desktop
if ( w->testWState(WState_Polished) )
app_style->polish(w); // repolish
w->styleChange( *old );
if ( w->isVisible() ){
w->update();
}
}
}
}
delete old;
}
}
/*!
\overload
Requests a TQStyle object for \a style from the TQStyleFactory.
The string must be one of the TQStyleFactory::keys(), typically one
of "windows", "motif", "cde", "motifplus", "platinum", "sgi" and
"compact". Depending on the platform, "windowsxp", "aqua" or
"macintosh" may be available.
A later call to the TQApplication constructor will override the
requested style when a "-style" option is passed in as a commandline
parameter.
Returns 0 if an unknown \a style is passed, otherwise the TQStyle object
returned is set as the application's GUI style.
*/
TQStyle* TQApplication::setStyle( const TQString& style )
{
#ifdef Q_WS_X11
tqt_explicit_app_style = TRUE;
#endif // Q_WS_X11
if ( startingUp() ) {
if(qt_style_override)
*qt_style_override = style;
else
qt_style_override = new TQString(style);
return 0;
}
TQStyle *s = TQStyleFactory::create( style );
if ( !s )
return 0;
setStyle( s );
return s;
}
#endif
#if 1 /* OBSOLETE */
TQApplication::ColorMode TQApplication::colorMode()
{
return (TQApplication::ColorMode)app_cspec;
}
void TQApplication::setColorMode( TQApplication::ColorMode mode )
{
app_cspec = mode;
}
#endif
/*!
Returns the color specification.
\sa TQApplication::setColorSpec()
*/
int TQApplication::colorSpec()
{
return app_cspec;
}
/*!
Sets the color specification for the application to \a spec.
The color specification controls how the application allocates colors
when run on a display with a limited amount of colors, e.g. 8 bit / 256
color displays.
The color specification must be set before you create the TQApplication
object.
The options are:
\list
\i TQApplication::NormalColor.
This is the default color allocation strategy. Use this option if
your application uses buttons, menus, texts and pixmaps with few
colors. With this option, the application uses system global
colors. This works fine for most applications under X11, but on
Windows machines it may cause dithering of non-standard colors.
\i TQApplication::CustomColor.
Use this option if your application needs a small number of custom
colors. On X11, this option is the same as NormalColor. On Windows, TQt
creates a Windows palette, and allocates colors to it on demand.
\i TQApplication::ManyColor.
Use this option if your application is very color hungry
(e.g. it requires thousands of colors).
Under X11 the effect is:
\list
\i For 256-color displays which have at best a 256 color true color
visual, the default visual is used, and colors are allocated
from a color cube. The color cube is the 6x6x6 (216 color) "Web
palette"<sup>*</sup>, but the number of colors can be changed
by the \e -ncols option. The user can force the application to
use the true color visual with the \link
TQApplication::TQApplication() -visual \endlink option.
\i For 256-color displays which have a true color visual with more
than 256 colors, use that visual. Silicon Graphics X servers
have this feature, for example. They provide an 8 bit visual
by default but can deliver true color when asked.
\endlist
On Windows, TQt creates a Windows palette, and fills it with a color cube.
\endlist
Be aware that the CustomColor and ManyColor choices may lead to colormap
flashing: The foreground application gets (most) of the available
colors, while the background windows will look less attractive.
Example:
\code
int main( int argc, char **argv )
{
TQApplication::setColorSpec( TQApplication::ManyColor );
TQApplication a( argc, argv );
...
}
\endcode
TQColor provides more functionality for controlling color allocation and
freeing up certain colors. See TQColor::enterAllocContext() for more
information.
To check what mode you end up with, call TQColor::numBitPlanes() once
the TQApplication object exists. A value greater than 8 (typically
16, 24 or 32) means true color.
<sup>*</sup> The color cube used by TQt has 216 colors whose red,
green, and blue components always have one of the following values:
0x00, 0x33, 0x66, 0x99, 0xCC, or 0xFF.
\sa colorSpec(), TQColor::numBitPlanes(), TQColor::enterAllocContext() */
void TQApplication::setColorSpec( int spec )
{
#if defined(QT_CHECK_STATE)
if ( tqApp ) {
tqWarning( "TQApplication::setColorSpec: This function must be "
"called before the TQApplication object is created" );
}
#endif
app_cspec = spec;
}
/*!
\fn TQSize TQApplication::globalStrut()
Returns the application's global strut.
The strut is a size object whose dimensions are the minimum that any
GUI element that the user can interact with should have. For example
no button should be resized to be smaller than the global strut size.
\sa setGlobalStrut()
*/
/*!
Sets the application's global strut to \a strut.
The strut is a size object whose dimensions are the minimum that any
GUI element that the user can interact with should have. For example
no button should be resized to be smaller than the global strut size.
The strut size should be considered when reimplementing GUI controls
that may be used on touch-screens or similar IO-devices.
Example:
\code
TQSize& WidgetClass::sizeHint() const
{
return TQSize( 80, 25 ).expandedTo( TQApplication::globalStrut() );
}
\endcode
\sa globalStrut()
*/
void TQApplication::setGlobalStrut( const TQSize& strut )
{
app_strut = strut;
}
#if defined( Q_WS_WIN ) || defined( Q_WS_MAC )
extern const char *tqAppFileName();
#endif
#ifndef QT_NO_DIR
#ifndef Q_WS_WIN
static TQString resolveSymlinks( const TQString& path, int depth = 0 )
{
bool foundLink = FALSE;
TQString linkTarget;
TQString part = path;
int slashPos = path.length();
// too deep; we give up
if ( depth == 128 )
return TQString::null;
do {
part = part.left( slashPos );
TQFileInfo fileInfo( part );
if ( fileInfo.isSymLink() ) {
foundLink = TRUE;
linkTarget = fileInfo.readLink();
break;
}
} while ( (slashPos = part.findRev('/')) != -1 );
if ( foundLink ) {
TQString path2;
if ( linkTarget[0] == '/' ) {
path2 = linkTarget;
if ( slashPos < (int) path.length() )
path2 += "/" + path.right( path.length() - slashPos - 1 );
} else {
TQString relPath;
relPath = part.left( part.findRev('/') + 1 ) + linkTarget;
if ( slashPos < (int) path.length() ) {
if ( !linkTarget.endsWith( "/" ) )
relPath += "/";
relPath += path.right( path.length() - slashPos - 1 );
}
path2 = TQDir::current().absFilePath( relPath );
}
path2 = TQDir::cleanDirPath( path2 );
return resolveSymlinks( path2, depth + 1 );
} else {
return path;
}
}
#endif // Q_WS_WIN
/*!
Returns the directory that contains the application executable.
For example, if you have installed TQt in the \c{C:\Trolltech\TQt}
directory, and you run the \c{demo} example, this function will
return "C:/Trolltech/TQt/examples/demo".
On Mac OS X this will point to the directory actually containing the
executable, which may be inside of an application bundle (if the
application is bundled).
\warning On Unix, this function assumes that argv[0] contains the file
name of the executable (which it normally does). It also assumes that
the current directory hasn't been changed by the application.
\sa applicationFilePath()
*/
TQString TQApplication::applicationDirPath()
{
return TQFileInfo( applicationFilePath() ).dirPath();
}
/*!
Returns the file path of the application executable.
For example, if you have installed TQt in the \c{C:\Trolltech\TQt}
directory, and you run the \c{demo} example, this function will
return "C:/Trolltech/TQt/examples/demo/demo.exe".
\warning On Unix, this function assumes that argv[0] contains the file
name of the executable (which it normally does). It also assumes that
the current directory hasn't been changed by the application.
\sa applicationDirPath()
*/
TQString TQApplication::applicationFilePath()
{
#if defined( Q_WS_WIN )
TQFileInfo filePath;
QT_WA({
WCHAR module_name[256];
GetModuleFileNameW(0, module_name, sizeof(module_name));
filePath = TQString::fromUcs2((const unsigned short *)module_name);
}, {
char module_name[256];
GetModuleFileNameA(0, module_name, sizeof(module_name));
filePath = TQString::fromLocal8Bit(module_name);
});
return filePath.filePath();
#elif defined( Q_WS_MAC )
return TQDir::cleanDirPath( TQFile::decodeName( tqAppFileName() ) );
#else
TQString argv0 = TQFile::decodeName( argv()[0] );
TQString absPath;
if ( argv0[0] == '/' ) {
/*
If argv0 starts with a slash, it is already an absolute
file path.
*/
absPath = argv0;
} else if ( argv0.find('/') != -1 ) {
/*
If argv0 contains one or more slashes, it is a file path
relative to the current directory.
*/
absPath = TQDir::current().absFilePath( argv0 );
} else {
/*
Otherwise, the file path has to be determined using the
PATH environment variable.
*/
char *pEnv = getenv( "PATH" );
TQStringList paths( TQStringList::split(TQChar(':'), pEnv) );
TQStringList::const_iterator p = paths.begin();
while ( p != paths.end() ) {
TQString candidate = TQDir::current().absFilePath( *p + "/" + argv0 );
if ( TQFile::exists(candidate) ) {
absPath = candidate;
break;
}
++p;
}
}
absPath = TQDir::cleanDirPath( absPath );
if ( TQFile::exists(absPath) ) {
return resolveSymlinks( absPath );
} else {
return TQString::null;
}
#endif
}
#endif // QT_NO_DIR
#ifndef QT_NO_COMPONENT
/*!
Returns a list of paths that the application will search when
dynamically loading libraries.
The installation directory for plugins is the only entry if no
paths have been set. The default installation directory for plugins
is \c INSTALL/plugins, where \c INSTALL is the directory where TQt was
installed. The directory of the application executable (NOT the
working directory) is also added to the plugin paths.
If you want to iterate over the list, you should iterate over a
copy, e.g.
\code
TQStringList list = app.libraryPaths();
TQStringList::Iterator it = list.begin();
while( it != list.end() ) {
myProcessing( *it );
++it;
}
\endcode
See the \link plugins-howto.html plugins documentation\endlink for a
description of how the library paths are used.
\sa setLibraryPaths(), addLibraryPath(), removeLibraryPath(), TQLibrary
*/
TQStringList TQApplication::libraryPaths()
{
if ( !app_libpaths ) {
app_libpaths = new TQStringList;
TQString installPathPlugins = TQString::fromLocal8Bit(tqInstallPathPlugins());
if ( TQFile::exists(installPathPlugins) ) {
#ifdef Q_WS_WIN
installPathPlugins.replace('\\', '/');
#endif
app_libpaths->append(installPathPlugins);
}
TQString app_location;
if (tqApp)
app_location = tqApp->applicationFilePath();
#ifdef Q_WS_WIN
else {
app_location = TQString(tqAppFileName());
app_location.replace('\\', '/');
}
#endif
if (!app_location.isEmpty()) {
app_location.truncate( app_location.findRev( '/' ) );
if ( app_location != tqInstallPathPlugins() && TQFile::exists( app_location ) )
app_libpaths->append( app_location );
}
}
return *app_libpaths;
}
/*!
Sets the list of directories to search when loading libraries to \a paths.
All existing paths will be deleted and the path list will consist of the
paths given in \a paths.
\sa libraryPaths(), addLibraryPath(), removeLibraryPath(), TQLibrary
*/
void TQApplication::setLibraryPaths( const TQStringList &paths )
{
delete app_libpaths;
app_libpaths = new TQStringList( paths );
}
/*!
Append \a path to the end of the library path list. If \a path is
empty or already in the path list, the path list is not changed.
The default path list consists of a single entry, the installation
directory for plugins. The default installation directory for plugins
is \c INSTALL/plugins, where \c INSTALL is the directory where TQt was
installed.
\sa removeLibraryPath(), libraryPaths(), setLibraryPaths()
*/
void TQApplication::addLibraryPath( const TQString &path )
{
if ( path.isEmpty() )
return;
// make sure that library paths is initialized
libraryPaths();
if ( !app_libpaths->contains( path ) )
app_libpaths->prepend( path );
}
/*!
Removes \a path from the library path list. If \a path is empty or not
in the path list, the list is not changed.
\sa addLibraryPath(), libraryPaths(), setLibraryPaths()
*/
void TQApplication::removeLibraryPath( const TQString &path )
{
if ( path.isEmpty() )
return;
// make sure that library paths is initialized
libraryPaths();
if ( app_libpaths->contains( path ) )
app_libpaths->remove( path );
}
#endif //QT_NO_COMPONENT
/*!
Returns the application palette.
If a widget is passed in \a w, the default palette for the
widget's class is returned. This may or may not be the application
palette. In most cases there isn't a special palette for certain
types of widgets, but one notable exception is the popup menu under
Windows, if the user has defined a special background color for
menus in the display settings.
\sa setPalette(), TQWidget::palette()
*/
#ifndef QT_NO_PALETTE
TQPalette TQApplication::palette(const TQWidget* w)
{
#if defined(QT_CHECK_STATE)
if ( !tqApp )
tqWarning( "TQApplication::palette: This function can only be "
"called after the TQApplication object has been created" );
#endif
if ( !app_pal ) {
if ( !tqt_std_pal )
tqt_create_std_palette();
app_pal = new TQPalette( *tqt_std_pal );
tqt_fix_tooltips();
}
if ( w && app_palettes ) {
TQPalette* wp = app_palettes->find( w->className() );
if ( wp )
return *wp;
TQAsciiDictIterator<TQPalette> it( *app_palettes );
const char* name;
while ( (name=it.currentKey()) != 0 ) {
if ( w->inherits( name ) )
return *it.current();
++it;
}
}
return *app_pal;
}
TQPalette TQApplication::palette(TQStringList objectTypeList)
{
#if defined(QT_CHECK_STATE)
if ( !tqApp )
tqWarning( "TQApplication::palette: This function can only be "
"called after the TQApplication object has been created" );
#endif
if ( !app_pal ) {
if ( !tqt_std_pal )
tqt_create_std_palette();
app_pal = new TQPalette( *tqt_std_pal );
tqt_fix_tooltips();
}
if ( (objectTypeList.count() > 0) && app_palettes ) {
TQPalette* wp = app_palettes->find( objectTypeList[objectTypeList.count()-1] );
if ( wp ) {
return *wp;
}
TQAsciiDictIterator<TQPalette> it( *app_palettes );
const char* name;
while ( (name=it.currentKey()) != 0 ) {
if ( objectTypeList.contains(name) ) {
return *it.current();
}
++it;
}
}
return *app_pal;
}
/*!
Changes the default application palette to \a palette. If \a
informWidgets is TRUE, then existing widgets are informed about the
change and may adjust themselves to the new application
setting. If \a informWidgets is FALSE, the change only affects newly
created widgets.
If \a className is passed, the change applies only to widgets that
inherit \a className (as reported by TQObject::inherits()). If
\a className is left 0, the change affects all widgets, thus overriding
any previously set class specific palettes.
The palette may be changed according to the current GUI style in
TQStyle::polish().
\sa TQWidget::setPalette(), palette(), TQStyle::polish()
*/
void TQApplication::setPalette( const TQPalette &palette, bool informWidgets,
const char* className )
{
TQPalette pal = palette;
TQPalette *oldpal = 0;
#ifndef QT_NO_STYLE
if ( !startingUp() ) // on startup this has been done already
tqApp->style().polish( pal ); // NB: non-const reference
#endif
bool all = FALSE;
if ( !className ) {
if ( !app_pal ) {
app_pal = new TQPalette( pal );
TQ_CHECK_PTR( app_pal );
} else {
*app_pal = pal;
}
all = app_palettes != 0;
delete app_palettes;
app_palettes = 0;
tqt_fix_tooltips();
} else {
if ( !app_palettes ) {
app_palettes = new TQAsciiDict<TQPalette>;
TQ_CHECK_PTR( app_palettes );
app_palettes->setAutoDelete( TRUE );
}
oldpal = app_palettes->find( className );
app_palettes->insert( className, new TQPalette( pal ) );
}
if ( informWidgets && is_app_running && !is_app_closing ) {
if ( !oldpal || ( *oldpal != pal ) ) {
TQEvent e( TQEvent::ApplicationPaletteChange );
TQWidgetIntDictIt it( *((TQWidgetIntDict*)TQWidget::mapper) );
register TQWidget *w;
while ( (w=it.current()) ) { // for all widgets...
++it;
if ( all || (!className && w->isTopLevel() ) || w->inherits(className) ) // matching class
sendEvent( w, &e );
}
}
}
}
#endif // QT_NO_PALETTE
/*!
Returns the default font for the widget \a w, or the default
application font if \a w is 0.
\sa setFont(), fontMetrics(), TQWidget::font()
*/
TQFont TQApplication::font( const TQWidget *w )
{
if ( w && app_fonts ) {
TQFont* wf = app_fonts->find( w->className() );
if ( wf )
return *wf;
TQAsciiDictIterator<TQFont> it( *app_fonts );
const char* name;
while ( (name=it.currentKey()) != 0 ) {
if ( w->inherits( name ) )
return *it.current();
++it;
}
}
if ( !app_font ) {
app_font = new TQFont( "Helvetica" );
TQ_CHECK_PTR( app_font );
}
return *app_font;
}
/*! Changes the default application font to \a font. If \a
informWidgets is TRUE, then existing widgets are informed about the
change and may adjust themselves to the new application
setting. If \a informWidgets is FALSE, the change only affects newly
created widgets. If \a className is passed, the change applies only
to classes that inherit \a className (as reported by
TQObject::inherits()).
On application start-up, the default font depends on the window
system. It can vary depending on both the window system version and
the locale. This function lets you override the default font; but
overriding may be a bad idea because, for example, some locales need
extra-large fonts to support their special characters.
\sa font(), fontMetrics(), TQWidget::setFont()
*/
void TQApplication::setFont( const TQFont &font, bool informWidgets,
const char* className )
{
bool all = FALSE;
if ( !className ) {
tqt_app_has_font = TRUE;
if ( !app_font ) {
app_font = new TQFont( font );
TQ_CHECK_PTR( app_font );
} else {
*app_font = font;
}
// make sure the application font is complete
app_font->detach();
app_font->d->mask = TQFontPrivate::Complete;
all = app_fonts != 0;
delete app_fonts;
app_fonts = 0;
} else {
if (!app_fonts){
app_fonts = new TQAsciiDict<TQFont>;
TQ_CHECK_PTR( app_fonts );
app_fonts->setAutoDelete( TRUE );
}
TQFont* fnt = new TQFont(font);
TQ_CHECK_PTR( fnt );
app_fonts->insert(className, fnt);
}
if ( informWidgets && is_app_running && !is_app_closing ) {
TQEvent e( TQEvent::ApplicationFontChange );
TQWidgetIntDictIt it( *((TQWidgetIntDict*)TQWidget::mapper) );
register TQWidget *w;
while ( (w=it.current()) ) { // for all widgets...
++it;
if ( all || (!className && w->isTopLevel() ) || w->inherits(className) ) // matching class
sendEvent( w, &e );
}
}
}
/*!
Initialization of the appearance of the widget \a w \e before it is first
shown.
Usually widgets call this automatically when they are polished. It
may be used to do some style-based central customization of widgets.
Note that you are not limited to the public functions of TQWidget.
Instead, based on meta information like TQObject::className() you are
able to customize any kind of widget.
\sa TQStyle::polish(), TQWidget::polish(), setPalette(), setFont()
*/
void TQApplication::polish( TQWidget *w )
{
#ifndef QT_NO_STYLE
w->style().polish( w );
#endif
}
/*!
Returns a list of the top level widgets in the application.
The list is created using \c new and must be deleted by the caller.
The list is empty (TQPtrList::isEmpty()) if there are no top level
widgets.
Note that some of the top level widgets may be hidden, for example
the tooltip if no tooltip is currently shown.
Example:
\code
// Show all hidden top level widgets.
TQWidgetList *list = TQApplication::topLevelWidgets();
TQWidgetListIt it( *list ); // iterate over the widgets
TQWidget * w;
while ( (w=it.current()) != 0 ) { // for each top level widget...
++it;
if ( !w->isVisible() )
w->show();
}
delete list; // delete the list, not the widgets
\endcode
\warning Delete the list as soon you have finished using it.
The widgets in the list may be deleted by someone else at any time.
\sa allWidgets(), TQWidget::isTopLevel(), TQWidget::isVisible(),
TQPtrList::isEmpty()
*/
TQWidgetList *TQApplication::topLevelWidgets()
{
return TQWidget::tlwList();
}
/*!
Returns a list of all the widgets in the application.
The list is created using \c new and must be deleted by the caller.
The list is empty (TQPtrList::isEmpty()) if there are no widgets.
Note that some of the widgets may be hidden.
Example that updates all widgets:
\code
TQWidgetList *list = TQApplication::allWidgets();
TQWidgetListIt it( *list ); // iterate over the widgets
TQWidget * w;
while ( (w=it.current()) != 0 ) { // for each widget...
++it;
w->update();
}
delete list; // delete the list, not the widgets
\endcode
The TQWidgetList class is defined in the \c ntqwidgetlist.h header
file.
\warning Delete the list as soon as you have finished using it.
The widgets in the list may be deleted by someone else at any time.
\sa topLevelWidgets(), TQWidget::isVisible(), TQPtrList::isEmpty(),
*/
TQWidgetList *TQApplication::allWidgets()
{
return TQWidget::wList();
}
/*!
\fn TQWidget *TQApplication::focusWidget() const
Returns the application widget that has the keyboard input focus, or
0 if no widget in this application has the focus.
\sa TQWidget::setFocus(), TQWidget::hasFocus(), activeWindow()
*/
/*!
\fn TQWidget *TQApplication::activeWindow() const
Returns the application top-level window that has the keyboard input
focus, or 0 if no application window has the focus. Note that
there might be an activeWindow() even if there is no focusWidget(),
for example if no widget in that window accepts key events.
\sa TQWidget::setFocus(), TQWidget::hasFocus(), focusWidget()
*/
/*!
Returns display (screen) font metrics for the application font.
\sa font(), setFont(), TQWidget::fontMetrics(), TQPainter::fontMetrics()
*/
TQFontMetrics TQApplication::fontMetrics()
{
return desktop()->fontMetrics();
}
/*!
Tells the application to exit with return code 0 (success).
Equivalent to calling TQApplication::exit( 0 ).
It's common to connect the lastWindowClosed() signal to quit(), and
you also often connect e.g. TQButton::clicked() or signals in
TQAction, TQPopupMenu or TQMenuBar to it.
Example:
\code
TQPushButton *quitButton = new TQPushButton( "Quit" );
connect( quitButton, SIGNAL(clicked()), tqApp, SLOT(quit()) );
\endcode
\sa exit() aboutToQuit() lastWindowClosed() TQAction
*/
void TQApplication::quit()
{
TQApplication::exit( 0 );
}
/*!
Closes all top-level windows.
This function is particularly useful for applications with many
top-level windows. It could, for example, be connected to a "Quit"
entry in the file menu as shown in the following code example:
\code
// the "Quit" menu entry should try to close all windows
TQPopupMenu* file = new TQPopupMenu( this );
file->insertItem( "&Quit", tqApp, SLOT(closeAllWindows()), CTRL+Key_Q );
// when the last window is closed, the application should quit
connect( tqApp, SIGNAL( lastWindowClosed() ), tqApp, SLOT( quit() ) );
\endcode
The windows are closed in random order, until one window does not
accept the close event.
\sa TQWidget::close(), TQWidget::closeEvent(), lastWindowClosed(),
quit(), topLevelWidgets(), TQWidget::isTopLevel()
*/
void TQApplication::closeAllWindows()
{
bool did_close = TRUE;
TQWidget *w;
while((w = activeModalWidget()) && did_close) {
if(w->isHidden())
break;
did_close = w->close();
}
TQWidgetList *list = TQApplication::topLevelWidgets();
for ( w = list->first(); did_close && w; ) {
if ( !w->isHidden() ) {
did_close = w->close();
delete list;
list = TQApplication::topLevelWidgets();
w = list->first();
} else {
w = list->next();
}
}
delete list;
}
/*!
Displays a simple message box about TQt. The message includes the
version number of TQt being used by the application.
This is useful for inclusion in the Help menu of an application.
See the examples/menu/menu.cpp example.
This function is a convenience slot for TQMessageBox::aboutTQt().
*/
void TQApplication::aboutTQt()
{
#ifndef QT_NO_MESSAGEBOX
TQMessageBox::aboutTQt( mainWidget() );
#endif // QT_NO_MESSAGEBOX
}
/*!
\fn void TQApplication::lastWindowClosed()
This signal is emitted when the user has closed the last
top level window.
The signal is very useful when your application has many top level
widgets but no main widget. You can then connect it to the quit()
slot.
For convenience, this signal is \e not emitted for transient top level
widgets such as popup menus and dialogs.
\sa mainWidget(), topLevelWidgets(), TQWidget::isTopLevel(), TQWidget::close()
*/
/*!
\fn void TQApplication::aboutToQuit()
This signal is emitted when the application is about to quit the
main event loop, e.g. when the event loop level drops to zero.
This may happen either after a call to quit() from inside the
application or when the users shuts down the entire desktop session.
The signal is particularly useful if your application has to do some
last-second cleanup. Note that no user interaction is possible in
this state.
\sa quit()
*/
/*!
\fn void TQApplication::guiThreadAwake()
This signal is emitted after the event loop returns from a function
that could block.
\sa wakeUpGuiThread()
*/
/*!
\fn bool TQApplication::sendEvent( TQObject *receiver, TQEvent *event )
Sends event \a event directly to receiver \a receiver, using the
notify() function. Returns the value that was returned from the event
handler.
The event is \e not deleted when the event has been sent. The normal
approach is to create the event on the stack, e.g.
\code
TQMouseEvent me( TQEvent::MouseButtonPress, pos, 0, 0 );
TQApplication::sendEvent( mainWindow, &me );
\endcode
If you create the event on the heap you must delete it.
\sa postEvent(), notify()
*/
/*!
Sends event \a e to \a receiver: \a {receiver}->event(\a e).
Returns the value that is returned from the receiver's event handler.
For certain types of events (e.g. mouse and key events),
the event will be propagated to the receiver's parent and so on up to
the top-level object if the receiver is not interested in the event
(i.e., it returns FALSE).
There are five different ways that events can be processed;
reimplementing this virtual function is just one of them. All five
approaches are listed below:
\list 1
\i Reimplementing this function. This is very powerful, providing
complete control; but only one subclass can be tqApp.
\i Installing an event filter on tqApp. Such an event filter is able
to process all events for all widgets, so it's just as powerful as
reimplementing notify(); furthermore, it's possible to have more
than one application-global event filter. Global event filters even
see mouse events for \link TQWidget::isEnabled() disabled
widgets, \endlink and if \link setGlobalMouseTracking() global mouse
tracking \endlink is enabled, as well as mouse move events for all
widgets.
\i Reimplementing TQObject::event() (as TQWidget does). If you do
this you get Tab key presses, and you get to see the events before
any widget-specific event filters.
\i Installing an event filter on the object. Such an event filter
gets all the events except Tab and Shift-Tab key presses.
\i Reimplementing paintEvent(), mousePressEvent() and so
on. This is the commonest, easiest and least powerful way.
\endlist
\sa TQObject::event(), installEventFilter()
*/
bool TQApplication::notify( TQObject *receiver, TQEvent *e )
{
// no events are delivered after ~TQApplication() has started
if ( is_app_closing )
return FALSE;
if ( receiver == 0 ) { // serious error
#if defined(QT_CHECK_NULL)
tqWarning( "TQApplication::notify: Unexpected null receiver" );
#endif
return FALSE;
}
if ( e->type() == TQEvent::ChildRemoved && receiver->postedEvents && globalPostedEvents) {
#ifdef QT_THREAD_SUPPORT
TQMutexLocker locker( postevent_mutex );
#endif // QT_THREAD_SUPPORT
// the TQObject destructor calls TQObject::removeChild, which calls
// TQApplication::sendEvent() directly. this can happen while the event
// loop is in the middle of posting events, and when we get here, we may
// not have any more posted events for this object.
if ( receiver->postedEvents ) {
// if this is a child remove event and the child insert
// hasn't been dispatched yet, kill that insert
TQPostEventList * l = receiver->postedEvents;
TQObject * c = ((TQChildEvent*)e)->child();
TQPostEvent * pe;
l->first();
while( ( pe = l->current()) != 0 ) {
if ( pe->event && pe->receiver == receiver &&
pe->event->type() == TQEvent::ChildInserted &&
((TQChildEvent*)pe->event)->child() == c ) {
pe->event->posted = FALSE;
delete pe->event;
pe->event = 0;
l->remove();
continue;
}
l->next();
}
}
}
bool res = FALSE;
if ( !receiver->isWidgetType() )
res = internalNotify( receiver, e );
else switch ( e->type() ) {
#ifndef QT_NO_ACCEL
case TQEvent::Accel:
{
TQKeyEvent* key = (TQKeyEvent*) e;
res = internalNotify( receiver, e );
if ( !res && !key->isAccepted() )
res = tqt_dispatchAccelEvent( (TQWidget*)receiver, key );
// next lines are for compatibility with TQt <= 3.0.x: old
// TQAccel was listening on toplevel widgets
if ( !res && !key->isAccepted() && !((TQWidget*)receiver)->isTopLevel() )
res = internalNotify( ((TQWidget*)receiver)->topLevelWidget(), e );
}
break;
#endif //QT_NO_ACCEL
case TQEvent::KeyPress:
case TQEvent::KeyRelease:
case TQEvent::AccelOverride:
{
TQWidget* w = (TQWidget*)receiver;
TQKeyEvent* key = (TQKeyEvent*) e;
#ifndef QT_NO_ACCEL
if ( tqt_tryComposeUnicode( w, key ) )
break;
#endif
bool def = key->isAccepted();
while ( w ) {
if ( def )
key->accept();
else
key->ignore();
res = internalNotify( w, e );
if ( res || key->isAccepted() )
break;
w = w->parentWidget( TRUE );
}
}
break;
case TQEvent::MouseButtonPress:
if ( e->spontaneous() ) {
TQWidget* fw = (TQWidget*)receiver;
while ( fw->focusProxy() )
fw = fw->focusProxy();
if ( fw->isEnabled() && fw->focusPolicy() & TQWidget::ClickFocus ) {
TQFocusEvent::setReason( TQFocusEvent::Mouse);
fw->setFocus();
TQFocusEvent::resetReason();
}
}
// fall through intended
case TQEvent::MouseButtonRelease:
case TQEvent::MouseButtonDblClick:
case TQEvent::MouseMove:
{
TQWidget* w = (TQWidget*)receiver;
TQMouseEvent* mouse = (TQMouseEvent*) e;
TQPoint relpos = mouse->pos();
while ( w ) {
TQMouseEvent me(mouse->type(), relpos, mouse->globalPos(), mouse->button(), mouse->state());
me.spont = mouse->spontaneous();
res = internalNotify( w, w == receiver ? mouse : &me );
e->spont = FALSE;
if (res || w->isTopLevel() || w->testWFlags(WNoMousePropagation))
break;
relpos += w->pos();
w = w->parentWidget();
}
if ( res )
mouse->accept();
else
mouse->ignore();
}
break;
#ifndef QT_NO_WHEELEVENT
case TQEvent::Wheel:
{
if ( e->spontaneous() ) {
TQWidget* fw = (TQWidget*)receiver;
while ( fw->focusProxy() )
fw = fw->focusProxy();
if ( fw->isEnabled() && (fw->focusPolicy() & TQWidget::WheelFocus) == TQWidget::WheelFocus ) {
TQFocusEvent::setReason( TQFocusEvent::Mouse);
fw->setFocus();
TQFocusEvent::resetReason();
}
}
TQWidget* w = (TQWidget*)receiver;
TQWheelEvent* wheel = (TQWheelEvent*) e;
TQPoint relpos = wheel->pos();
while ( w ) {
TQWheelEvent we(relpos, wheel->globalPos(), wheel->delta(), wheel->state(), wheel->orientation());
we.spont = wheel->spontaneous();
res = internalNotify( w, w == receiver ? wheel : &we );
e->spont = FALSE;
if (res || w->isTopLevel() || w->testWFlags(WNoMousePropagation))
break;
relpos += w->pos();
w = w->parentWidget();
}
if ( res )
wheel->accept();
else
wheel->ignore();
}
break;
#endif
case TQEvent::ContextMenu:
{
TQWidget* w = (TQWidget*)receiver;
TQContextMenuEvent *context = (TQContextMenuEvent*) e;
TQPoint relpos = context->pos();
while ( w ) {
TQContextMenuEvent ce(context->reason(), relpos, context->globalPos(), context->state());
ce.spont = e->spontaneous();
res = internalNotify( w, w == receiver ? context : &ce );
e->spont = FALSE;
if (res || w->isTopLevel() || w->testWFlags(WNoMousePropagation))
break;
relpos += w->pos();
w = w->parentWidget();
}
if ( res )
context->accept();
else
context->ignore();
}
break;
#if defined (QT_TABLET_SUPPORT)
case TQEvent::TabletMove:
case TQEvent::TabletPress:
case TQEvent::TabletRelease:
{
TQWidget *w = (TQWidget*)receiver;
TQTabletEvent *tablet = (TQTabletEvent*)e;
TQPoint relpos = tablet->pos();
while ( w ) {
TQTabletEvent te(tablet->pos(), tablet->globalPos(), tablet->device(),
tablet->pressure(), tablet->xTilt(), tablet->yTilt(),
tablet->uniqueId());
te.spont = e->spontaneous();
res = internalNotify( w, w == receiver ? tablet : &te );
e->spont = FALSE;
if (res || w->isTopLevel() || w->testWFlags(WNoMousePropagation))
break;
relpos += w->pos();
w = w->parentWidget();
}
if ( res )
tablet->accept();
else
tablet->ignore();
chokeMouse = tablet->isAccepted();
}
break;
#endif
default:
res = internalNotify( receiver, e );
break;
}
return res;
}
/*!\reimp
*/
bool TQApplication::event( TQEvent *e )
{
if(e->type() == TQEvent::Close) {
TQCloseEvent *ce = (TQCloseEvent*)e;
ce->accept();
closeAllWindows();
TQWidgetList *list = topLevelWidgets();
for(TQWidget *w = list->first(); w; w = list->next()) {
if ( !w->isHidden() && !w->isDesktop() && !w->isPopup() &&
(!w->isDialog() || !w->parentWidget())) {
ce->ignore();
break;
}
}
if(ce->isAccepted())
return TRUE;
} else if (e->type() == TQEvent::Quit) {
quit();
return TRUE;
}
return TQObject::event(e);
}
#define HOVER_SENSITIVE_WIDGET_SELECT if ( widget->inherits("TQPushButton") \
|| widget->inherits("TQComboBox") \
|| widget->inherits("TQSpinWidget") \
|| widget->inherits("TQCheckBox") \
|| widget->inherits("TQRadioButton") \
|| widget->inherits("TQToolButton") \
|| widget->inherits("TQSlider") \
|| widget->inherits("TQScrollBar") \
|| widget->inherits("TQTabBar") \
|| widget->inherits("TQDockWindowHandle") \
|| widget->inherits("TQSplitterHandle") )
#define FOCUS_SENSITIVE_WIDGET_SELECT if ( widget->inherits("TQLineEdit") )
#define FOCUS_SENSITIVE_PARENT_WIDGET_SELECT if ( widget->parentWidget() && widget->parentWidget()->inherits("TQSpinWidget") )
/*!\internal
Helper function called by notify()
*/
bool TQApplication::internalNotify( TQObject *receiver, TQEvent * e)
{
if ( eventFilters ) {
TQObjectListIt it( *eventFilters );
register TQObject *obj;
while ( (obj=it.current()) != 0 ) { // send to all filters
++it; // until one returns TRUE
if ( obj->eventFilter(receiver,e) )
return TRUE;
}
}
bool consumed = FALSE;
bool handled = FALSE;
if ( receiver->isWidgetType() ) {
TQWidget *widget = (TQWidget*)receiver;
// toggle HasMouse widget state on enter and leave
if ( e->type() == TQEvent::Enter || e->type() == TQEvent::DragEnter ) {
widget->setWState( WState_HasMouse );
HOVER_SENSITIVE_WIDGET_SELECT {
widget->repaint(false);
}
}
else if ( e->type() == TQEvent::Leave || e->type() == TQEvent::DragLeave ) {
widget->clearWState( WState_HasMouse );
HOVER_SENSITIVE_WIDGET_SELECT {
widget->repaint(false);
}
}
// repaint information entry widgets on focus set/unset
if ( e->type() == TQEvent::FocusIn || e->type() == TQEvent::FocusOut ) {
FOCUS_SENSITIVE_WIDGET_SELECT {
widget->repaint(false);
}
FOCUS_SENSITIVE_PARENT_WIDGET_SELECT {
widget->parentWidget()->repaint(false);
}
}
// throw away any mouse-tracking-only mouse events
if ( e->type() == TQEvent::MouseMove &&
(((TQMouseEvent*)e)->state()&TQMouseEvent::MouseButtonMask) == 0 &&
!widget->hasMouseTracking() ) {
handled = TRUE;
consumed = TRUE;
} else if ( !widget->isEnabled() ) { // throw away mouse events to disabled widgets
switch(e->type()) {
case TQEvent::MouseButtonPress:
case TQEvent::MouseButtonRelease:
case TQEvent::MouseButtonDblClick:
case TQEvent::MouseMove:
( (TQMouseEvent*) e)->ignore();
handled = TRUE;
consumed = TRUE;
break;
#ifndef QT_NO_DRAGANDDROP
case TQEvent::DragEnter:
case TQEvent::DragMove:
( (TQDragMoveEvent*) e)->ignore();
handled = TRUE;
break;
case TQEvent::DragLeave:
case TQEvent::DragResponse:
handled = TRUE;
break;
case TQEvent::Drop:
( (TQDropEvent*) e)->ignore();
handled = TRUE;
break;
#endif
#ifndef QT_NO_WHEELEVENT
case TQEvent::Wheel:
( (TQWheelEvent*) e)->ignore();
handled = TRUE;
break;
#endif
case TQEvent::ContextMenu:
( (TQContextMenuEvent*) e)->ignore();
handled = TRUE;
break;
default:
break;
}
}
}
if (!handled) {
#if defined(QT_THREAD_SUPPORT)
int locklevel = 0;
int llcount;
if (TQApplication::tqt_mutex) {
TQApplication::tqt_mutex->lock(); // 1 of 2
locklevel = tqt_mutex->level() - 1;
for (llcount=0; llcount<locklevel; llcount++) {
TQApplication::tqt_mutex->unlock();
}
TQApplication::tqt_mutex->unlock(); // 2 of 2
}
#endif
consumed = receiver->event( e );
#if defined(QT_THREAD_SUPPORT)
if (TQApplication::tqt_mutex) {
for (llcount=0; llcount<locklevel; llcount++) {
TQApplication::tqt_mutex->lock();
}
}
#endif
}
e->spont = FALSE;
return consumed;
}
/*!
Returns TRUE if an application object has not been created yet;
otherwise returns FALSE.
\sa closingDown()
*/
bool TQApplication::startingUp()
{
return !is_app_running;
}
/*!
Returns TRUE if the application objects are being destroyed;
otherwise returns FALSE.
\sa startingUp()
*/
bool TQApplication::closingDown()
{
return is_app_closing;
}
/*!
Processes pending events, for 3 seconds or until there are no more
events to process, whichever is shorter.
You can call this function occasionally when your program is busy
performing a long operation (e.g. copying a file).
\sa exec(), TQTimer, TQEventLoop::processEvents()
*/
void TQApplication::processEvents()
{
processEvents( 3000 );
}
/*!
\overload
Processes pending events for \a maxtime milliseconds or until
there are no more events to process, whichever is shorter.
You can call this function occasionally when you program is busy
doing a long operation (e.g. copying a file).
\sa exec(), TQTimer, TQEventLoop::processEvents()
*/
void TQApplication::processEvents( int maxtime )
{
eventLoop()->processEvents( TQEventLoop::AllEvents, maxtime );
}
/*! \obsolete
Waits for an event to occur, processes it, then returns.
This function is useful for adapting TQt to situations where the
event processing must be grafted onto existing program loops.
Using this function in new applications may be an indication of design
problems.
\sa processEvents(), exec(), TQTimer
*/
void TQApplication::processOneEvent()
{
eventLoop()->processEvents( TQEventLoop::AllEvents |
TQEventLoop::WaitForMore );
}
/*****************************************************************************
Main event loop wrappers
*****************************************************************************/
/*!
Returns the application event loop. This function will return
zero if called during and after destroying TQApplication.
To create your own instance of TQEventLoop or TQEventLoop subclass create
it before you create the TQApplication object.
\sa TQEventLoop
*/
TQEventLoop *TQApplication::eventLoop()
{
if ( !currentEventLoop() && !is_app_closing ) {
(void) new TQEventLoop( tqApp, "default event loop" );
}
return currentEventLoop();
}
/*!
Enters the main event loop and waits until exit() is called or the
main widget is destroyed, and returns the value that was set to
exit() (which is 0 if exit() is called via quit()).
It is necessary to call this function to start event handling. The
main event loop receives events from the window system and
dispatches these to the application widgets.
Generally speaking, no user interaction can take place before
calling exec(). As a special case, modal widgets like TQMessageBox
can be used before calling exec(), because modal widgets call
exec() to start a local event loop.
To make your application perform idle processing, i.e. executing a
special function whenever there are no pending events, use a
TQTimer with 0 timeout. More advanced idle processing schemes can
be achieved using processEvents().
\sa quit(), exit(), processEvents(), setMainWidget()
*/
int TQApplication::exec()
{
return eventLoop()->exec();
}
/*!
Tells the application to exit with a return code.
After this function has been called, the application leaves the main
event loop and returns from the call to exec(). The exec() function
returns \a retcode.
By convention, a \a retcode of 0 means success, and any non-zero
value indicates an error.
Note that unlike the C library function of the same name, this
function \e does return to the caller -- it is event processing that
stops.
\sa quit(), exec()
*/
void TQApplication::exit( int retcode )
{
TQThread* thread = tqApp->guiThread();
if (thread) {
if (thread->d) {
if (thread->d->eventLoop) {
thread->d->eventLoop->exit( retcode );
}
}
}
}
/*!
\obsolete
This function enters the main event loop (recursively). Do not call
it unless you really know what you are doing.
Use TQApplication::eventLoop()->enterLoop() instead.
*/
int TQApplication::enter_loop()
{
return eventLoop()->enterLoop();
}
/*!
\obsolete
This function exits from a recursive call to the main event loop.
Do not call it unless you are an expert.
Use TQApplication::eventLoop()->exitLoop() instead.
*/
void TQApplication::exit_loop()
{
eventLoop()->exitLoop();
}
/*!
\obsolete
Returns the current loop level.
Use TQApplication::eventLoop()->loopLevel() instead.
*/
int TQApplication::loopLevel() const
{
return eventLoop()->loopLevel();
}
/*!
Wakes up the GUI thread.
\sa guiThreadAwake() \link threads.html Thread Support in TQt\endlink
*/
void TQApplication::wakeUpGuiThread()
{
eventLoop()->wakeUp();
}
/*!
This function returns TRUE if there are pending events; otherwise
returns FALSE. Pending events can be either from the window system
or posted events using TQApplication::postEvent().
*/
bool TQApplication::hasPendingEvents()
{
return eventLoop()->hasPendingEvents();
}
#if !defined(Q_WS_X11)
// The doc and X implementation of these functions is in qapplication_x11.cpp
void TQApplication::flushX() {} // do nothing
void TQApplication::syncX() {} // do nothing
#endif
/*!
\fn void TQApplication::setWinStyleHighlightColor( const TQColor & )
\obsolete
Sets the color used to mark selections in windows style for all widgets
in the application. Will repaint all widgets if the color is changed.
The default color is \c darkBlue.
\sa winStyleHighlightColor()
*/
/*!
\fn const TQColor& TQApplication::winStyleHighlightColor()
\obsolete
Returns the color used to mark selections in windows style.
\sa setWinStyleHighlightColor()
*/
/*!
Returns the version of the Windows operating system that is running:
\list
\i TQt::WV_95 - Windows 95
\i TQt::WV_98 - Windows 98
\i TQt::WV_Me - Windows Me
\i TQt::WV_NT - Windows NT 4.x
\i TQt::WV_2000 - Windows 2000 (NT5)
\i TQt::WV_XP - Windows XP
\i TQt::WV_2003 - Windows Server 2003 family
\i TQt::WV_CE - Windows CE
\i TQt::WV_CENET - Windows CE.NET
\endlist
Note that this function is implemented for the Windows version
of TQt only.
*/
#if defined(Q_OS_CYGWIN)
TQt::WindowsVersion TQApplication::winVersion()
{
return qt_winver;
}
#endif
#ifndef QT_NO_TRANSLATION
bool qt_detectRTLLanguage()
{
return TQApplication::tr( "QT_LAYOUT_DIRECTION",
"Translate this string to the string 'LTR' in left-to-right"
" languages or to 'RTL' in right-to-left languages (such as Hebrew"
" and Arabic) to get proper widget layout." ) == "RTL";
}
/*!
Adds the message file \a mf to the list of message files to be used
for translations.
Multiple message files can be installed. Translations are searched
for in the last installed message file, then the one from last, and
so on, back to the first installed message file. The search stops as
soon as a matching translation is found.
\sa removeTranslator() translate() TQTranslator::load()
*/
void TQApplication::installTranslator( TQTranslator * mf )
{
if ( !mf )
return;
if ( !translators )
translators = new TQValueList<TQTranslator*>;
translators->prepend( mf );
#ifndef QT_NO_TRANSLATION_BUILDER
if ( mf->isEmpty() )
return;
#endif
// hook to set the layout direction of dialogs
setReverseLayout( qt_detectRTLLanguage() );
TQWidgetList *list = topLevelWidgets();
TQWidgetListIt it( *list );
TQWidget *w;
while ( ( w=it.current() ) != 0 ) {
++it;
if (!w->isDesktop())
postEvent( w, new TQEvent( TQEvent::LanguageChange ) );
}
delete list;
}
/*!
Removes the message file \a mf from the list of message files used by
this application. (It does not delete the message file from the file
system.)
\sa installTranslator() translate(), TQObject::tr()
*/
void TQApplication::removeTranslator( TQTranslator * mf )
{
if ( !translators || !mf )
return;
if ( translators->remove( mf ) && ! tqApp->closingDown() ) {
setReverseLayout( qt_detectRTLLanguage() );
TQWidgetList *list = topLevelWidgets();
TQWidgetListIt it( *list );
TQWidget *w;
while ( ( w=it.current() ) != 0 ) {
++it;
postEvent( w, new TQEvent( TQEvent::LanguageChange ) );
}
delete list;
}
}
#ifndef QT_NO_TEXTCODEC
/*! \obsolete
This is the same as TQTextCodec::setCodecForTr().
*/
void TQApplication::setDefaultCodec( TQTextCodec* codec )
{
TQTextCodec::setCodecForTr( codec );
}
/*! \obsolete
Returns TQTextCodec::codecForTr().
*/
TQTextCodec* TQApplication::defaultCodec() const
{
return TQTextCodec::codecForTr();
}
#endif //QT_NO_TEXTCODEC
/*! \enum TQApplication::Encoding
This enum type defines the 8-bit encoding of character string
arguments to translate():
\value DefaultCodec - the encoding specified by
TQTextCodec::codecForTr() (Latin-1 if none has been set)
\value UnicodeUTF8 - UTF-8
\sa TQObject::tr(), TQObject::trUtf8(), TQString::fromUtf8()
*/
/*! \reentrant
Returns the translation text for \a sourceText, by querying the
installed messages files. The message files are searched from the most
recently installed message file back to the first installed message
file.
TQObject::tr() and TQObject::trUtf8() provide this functionality more
conveniently.
\a context is typically a class name (e.g., "MyDialog") and
\a sourceText is either English text or a short identifying text, if
the output text will be very long (as for help texts).
\a comment is a disambiguating comment, for when the same \a
sourceText is used in different roles within the same context. By
default, it is null. \a encoding indicates the 8-bit encoding of
character stings
See the \l TQTranslator documentation for more information about
contexts and comments.
If none of the message files contain a translation for \a
sourceText in \a context, this function returns a TQString
equivalent of \a sourceText. The encoding of \a sourceText is
specified by \e encoding; it defaults to \c DefaultCodec.
This function is not virtual. You can use alternative translation
techniques by subclassing \l TQTranslator.
\warning This method is reentrant only if all translators are
installed \e before calling this method. Installing or removing
translators while performing translations is not supported. Doing
so will most likely result in crashes or other undesirable behavior.
\sa TQObject::tr() installTranslator() defaultCodec()
*/
TQString TQApplication::translate( const char * context, const char * sourceText,
const char * comment, Encoding encoding ) const
{
if ( !sourceText )
return TQString::null;
if ( translators ) {
TQValueList<TQTranslator*>::iterator it;
TQTranslator * mf;
TQString result;
for ( it = translators->begin(); it != translators->end(); ++it ) {
mf = *it;
result = mf->findMessage( context, sourceText, comment ).translation();
if ( !result.isNull() )
return result;
}
}
#ifndef QT_NO_TEXTCODEC
if ( encoding == UnicodeUTF8 )
return TQString::fromUtf8( sourceText );
else if ( TQTextCodec::codecForTr() != 0 )
return TQTextCodec::codecForTr()->toUnicode( sourceText );
else
#endif
return TQString::fromLatin1( sourceText );
}
#endif
/*****************************************************************************
TQApplication management of posted events
*****************************************************************************/
//see also notify(), which does the removal of ChildInserted when ChildRemoved.
/*!
Adds the event \a event with the object \a receiver as the receiver of the
event, to an event queue and returns immediately.
The event must be allocated on the heap since the post event queue
will take ownership of the event and delete it once it has been posted.
When control returns to the main event loop, all events that are
stored in the queue will be sent using the notify() function.
\threadsafe
\sa sendEvent(), notify()
*/
void TQApplication::postEvent( TQObject *receiver, TQEvent *event )
{
if ( receiver == 0 ) {
#if defined(QT_CHECK_NULL)
tqWarning( "TQApplication::postEvent: Unexpected null receiver" );
#endif
delete event;
return;
}
#ifdef QT_THREAD_SUPPORT
TQMutexLocker locker( postevent_mutex );
#endif // QT_THREAD_SUPPORT
if ( !globalPostedEvents ) { // create list
globalPostedEvents = new TQPostEventList;
TQ_CHECK_PTR( globalPostedEvents );
globalPostedEvents->setAutoDelete( TRUE );
qapp_cleanup_events.set( &globalPostedEvents );
}
if ( !receiver->postedEvents )
receiver->postedEvents = new TQPostEventList;
TQPostEventList * l = receiver->postedEvents;
// if this is one of the compressible events, do compression
if ( event->type() == TQEvent::Paint ||
event->type() == TQEvent::LayoutHint ||
event->type() == TQEvent::Resize ||
event->type() == TQEvent::Move ||
event->type() == TQEvent::LanguageChange ) {
l->first();
TQPostEvent * cur = 0;
for ( ;; ) {
while ( (cur=l->current()) != 0 &&
( cur->receiver != receiver ||
cur->event == 0 ||
cur->event->type() != event->type() ) )
l->next();
if ( l->current() != 0 ) {
if ( cur->event->type() == TQEvent::Paint ) {
TQPaintEvent * p = (TQPaintEvent*)(cur->event);
if ( p->erase != ((TQPaintEvent*)event)->erase ) {
l->next();
continue;
}
p->reg = p->reg.unite( ((TQPaintEvent *)event)->reg );
p->rec = p->rec.unite( ((TQPaintEvent *)event)->rec );
delete event;
return;
} else if ( cur->event->type() == TQEvent::LayoutHint ) {
delete event;
return;
} else if ( cur->event->type() == TQEvent::Resize ) {
((TQResizeEvent *)(cur->event))->s = ((TQResizeEvent *)event)->s;
delete event;
return;
} else if ( cur->event->type() == TQEvent::Move ) {
((TQMoveEvent *)(cur->event))->p = ((TQMoveEvent *)event)->p;
delete event;
return;
} else if ( cur->event->type() == TQEvent::LanguageChange ) {
delete event;
return;
}
}
break;
};
}
#if !defined(QT_NO_IM)
// if this is one of the compressible IM events, do compression
else if ( event->type() == TQEvent::IMCompose ) {
l->last();
TQPostEvent * cur = 0;
for ( ;; ) {
while ( (cur=l->current()) != 0 &&
( cur->receiver != receiver ||
cur->event == 0 ||
cur->event->type() != event->type() ||
cur->event->type() != TQEvent::IMStart ) )
l->prev();
if ( l->current() != 0 ) {
// IMCompose must not be compressed with another one
// beyond its IMStart boundary
if ( cur->event->type() == TQEvent::IMStart ) {
break;
} else if ( cur->event->type() == TQEvent::IMCompose ) {
TQIMComposeEvent * e = (TQIMComposeEvent *)(cur->event);
*e = *(TQIMComposeEvent *)event;
delete event;
return;
}
}
break;
};
}
#endif
// if no compression could be done, just append something
event->posted = TRUE;
TQPostEvent * pe = new TQPostEvent( receiver, event );
l->append( pe );
globalPostedEvents->append( pe );
#ifdef QT_THREAD_SUPPORT
if ( event->type() == TQEvent::MetaCall ) {
// Wake up the receiver thread event loop
TQThread* thread = receiver->contextThreadObject();
if (thread) {
if (thread->d) {
if (thread->d->eventLoop) {
thread->d->eventLoop->wakeUp();
}
}
}
return;
}
#endif
if (currentEventLoop())
currentEventLoop()->wakeUp();
}
/*! \overload
Dispatches all posted events, i.e. empties the event queue.
*/
void TQApplication::sendPostedEvents()
{
sendPostedEvents( 0, 0 );
}
/*!
Immediately dispatches all events which have been previously queued
with TQApplication::postEvent() and which are for the object \a receiver
and have the event type \a event_type.
Note that events from the window system are \e not dispatched by this
function, but by processEvents().
If \a receiver is null, the events of \a event_type are sent for all
objects. If \a event_type is 0, all the events are sent for \a receiver.
*/
void TQApplication::sendPostedEvents( TQObject *receiver, int event_type )
{
// Make sure the object hierarchy is stable before processing events
// to avoid endless loops
if ( receiver == 0 && event_type == 0 )
sendPostedEvents( 0, TQEvent::ChildInserted );
if ( !globalPostedEvents || ( receiver && !receiver->postedEvents ) )
return;
#ifdef QT_THREAD_SUPPORT
TQMutexLocker locker( postevent_mutex );
#endif
bool sent = TRUE;
while ( sent ) {
sent = FALSE;
if ( !globalPostedEvents || ( receiver && !receiver->postedEvents ) )
return;
// if we have a receiver, use the local list. Otherwise, use the
// global list
TQPostEventList * l = receiver ? receiver->postedEvents : globalPostedEvents;
// okay. here is the tricky loop. be careful about optimizing
// this, it looks the way it does for good reasons.
TQPostEventListIt it( *l );
TQPostEvent *pe;
while ( (pe=it.current()) != 0 ) {
++it;
if ( pe->event // hasn't been sent yet
&& ( receiver == 0 // we send to all receivers
|| receiver == pe->receiver ) // we send to THAT receiver
&& ( event_type == 0 // we send all types
|| event_type == pe->event->type() ) // we send THAT type
&& ( (!pe->receiver) || (pe->receiver->contextThreadObject() == TQThread::currentThreadObject()) ) ) { // only send if active thread is receiver object owning thread
// first, we diddle the event so that we can deliver
// it, and that noone will try to touch it later.
pe->event->posted = FALSE;
TQEvent * e = pe->event;
TQObject * r = pe->receiver;
pe->event = 0;
// next, update the data structure so that we're ready
// for the next event.
// look for the local list, and take whatever we're
// delivering out of it. r->postedEvents maybe *l
if ( r->postedEvents ) {
r->postedEvents->removeRef( pe );
// if possible, get rid of that list. this is not
// ideal - we will create and delete a list for
// each update() call. it would be better if we'd
// leave the list empty here, and delete it
// somewhere else if it isn't being used.
if ( r->postedEvents->isEmpty() ) {
delete r->postedEvents;
r->postedEvents = 0;
}
}
#ifdef QT_THREAD_SUPPORT
if ( locker.mutex() ) locker.mutex()->unlock();
#endif // QT_THREAD_SUPPORT
// after all that work, it's time to deliver the event.
if ( e->type() == TQEvent::Paint && r->isWidgetType() ) {
TQWidget * w = (TQWidget*)r;
TQPaintEvent * p = (TQPaintEvent*)e;
if ( w->isVisible() )
w->repaint( p->reg, p->erase );
} else {
sent = TRUE;
TQApplication::sendEvent( r, e );
}
#ifdef QT_THREAD_SUPPORT
if ( locker.mutex() ) locker.mutex()->lock();
#endif // QT_THREAD_SUPPORT
delete e;
// careful when adding anything below this point - the
// sendEvent() call might invalidate any invariants this
// function depends on.
}
}
// clear the global list, i.e. remove everything that was
// delivered.
if ( l == globalPostedEvents ) {
globalPostedEvents->first();
while( (pe=globalPostedEvents->current()) != 0 ) {
if ( pe->event )
globalPostedEvents->next();
else
globalPostedEvents->remove();
}
}
}
}
/*!
Removes all events posted using postEvent() for \a receiver.
The events are \e not dispatched, instead they are removed from the
queue. You should never need to call this function. If you do call it,
be aware that killing events may cause \a receiver to break one or
more invariants.
\threadsafe
*/
void TQApplication::removePostedEvents( TQObject *receiver )
{
removePostedEvents( receiver, 0 );
}
/*!
Removes all events that have the event type \a event_type posted
using postEvent() for \a receiver.
The events are \e not dispatched, instead they are removed from the
queue.
If \a event_type is 0, all the events are removed from the queue.
\threadsafe
*/
void TQApplication::removePostedEvents( TQObject *receiver, int event_type )
{
if ( !receiver )
return;
#ifdef QT_THREAD_SUPPORT
TQMutexLocker locker( postevent_mutex );
#endif // QT_THREAD_SUPPORT
// the TQObject destructor calls this function directly. this can
// happen while the event loop is in the middle of posting events,
// and when we get here, we may not have any more posted events
// for this object.
if ( !receiver->postedEvents )
return;
// iterate over the object-specifc list and delete the events.
// leave the TQPostEvent objects; they'll be deleted by
// sendPostedEvents().
TQPostEventList * l = receiver->postedEvents;
l->first();
TQPostEvent * pe;
while( (pe=l->current()) != 0 ) {
if ( !event_type || pe->event->type() == event_type ) {
if ( pe->event ) {
pe->event->posted = FALSE;
delete pe->event;
pe->event = 0;
}
l->remove();
} else {
l->next();
}
}
if ( !event_type || !l->count() ) {
receiver->postedEvents = 0;
delete l;
}
}
/*!
Removes \a event from the queue of posted events, and emits a
warning message if appropriate.
\warning This function can be \e really slow. Avoid using it, if
possible.
\threadsafe
*/
void TQApplication::removePostedEvent( TQEvent * event )
{
if ( !event || !event->posted )
return;
if ( !globalPostedEvents ) {
#if defined(QT_DEBUG)
tqDebug( "TQApplication::removePostedEvent: %p %d is posted: impossible",
(void*)event, event->type() );
return;
#endif
}
#ifdef QT_THREAD_SUPPORT
TQMutexLocker locker( postevent_mutex );
#endif // QT_THREAD_SUPPORT
TQPostEventListIt it( *globalPostedEvents );
TQPostEvent * pe;
while( (pe = it.current()) != 0 ) {
++it;
if ( pe->event == event ) {
#if defined(QT_DEBUG)
const char *n;
switch ( event->type() ) {
case TQEvent::Timer:
n = "Timer";
break;
case TQEvent::MouseButtonPress:
n = "MouseButtonPress";
break;
case TQEvent::MouseButtonRelease:
n = "MouseButtonRelease";
break;
case TQEvent::MouseButtonDblClick:
n = "MouseButtonDblClick";
break;
case TQEvent::MouseMove:
n = "MouseMove";
break;
#ifndef QT_NO_WHEELEVENT
case TQEvent::Wheel:
n = "Wheel";
break;
#endif
case TQEvent::KeyPress:
n = "KeyPress";
break;
case TQEvent::KeyRelease:
n = "KeyRelease";
break;
case TQEvent::FocusIn:
n = "FocusIn";
break;
case TQEvent::FocusOut:
n = "FocusOut";
break;
case TQEvent::Enter:
n = "Enter";
break;
case TQEvent::Leave:
n = "Leave";
break;
case TQEvent::Paint:
n = "Paint";
break;
case TQEvent::Move:
n = "Move";
break;
case TQEvent::Resize:
n = "Resize";
break;
case TQEvent::Create:
n = "Create";
break;
case TQEvent::Destroy:
n = "Destroy";
break;
case TQEvent::Close:
n = "Close";
break;
case TQEvent::Quit:
n = "Quit";
break;
default:
n = "<other>";
break;
}
tqWarning("TQEvent: Warning: %s event deleted while posted to %s %s",
n,
pe->receiver ? pe->receiver->className() : "null",
pe->receiver ? pe->receiver->name() : "object" );
// note the beautiful uglehack if !pe->receiver :)
#endif
event->posted = FALSE;
delete pe->event;
pe->event = 0;
return;
}
}
}
/*!\internal
Sets the active window in reaction to a system event. Call this
from the platform specific event handlers.
It sets the activeWindow() and focusWidget() attributes and sends
proper WindowActivate/WindowDeactivate and FocusIn/FocusOut events
to all appropriate widgets.
\sa activeWindow()
*/
void TQApplication::setActiveWindow( TQWidget* act )
{
TQWidget* window = act?act->topLevelWidget():0;
if ( active_window == window )
return;
// first the activation/deactivation events
if ( active_window ) {
TQWidgetList deacts;
#ifndef QT_NO_STYLE
if ( style().styleHint(TQStyle::SH_Widget_ShareActivation, active_window ) ) {
TQWidgetList *list = topLevelWidgets();
if ( list ) {
for ( TQWidget *w = list->first(); w; w = list->next() ) {
if ( w->isVisible() && w->isActiveWindow() )
deacts.append(w);
}
delete list;
}
} else
#endif
deacts.append(active_window);
active_window = 0;
TQEvent e( TQEvent::WindowDeactivate );
for(TQWidget *w = deacts.first(); w; w = deacts.next())
TQApplication::sendSpontaneousEvent( w, &e );
}
active_window = window;
if ( active_window ) {
TQEvent e( TQEvent::WindowActivate );
TQWidgetList acts;
#ifndef QT_NO_STYLE
if ( style().styleHint(TQStyle::SH_Widget_ShareActivation, active_window ) ) {
TQWidgetList *list = topLevelWidgets();
if ( list ) {
for ( TQWidget *w = list->first(); w; w = list->next() ) {
if ( w->isVisible() && w->isActiveWindow() )
acts.append(w);
}
delete list;
}
} else
#endif
acts.append(active_window);
for(TQWidget *w = acts.first(); w; w = acts.next())
TQApplication::sendSpontaneousEvent( w, &e );
}
// then focus events
TQFocusEvent::setReason( TQFocusEvent::ActiveWindow );
if ( !active_window && focus_widget ) {
TQFocusEvent out( TQEvent::FocusOut );
TQWidget *tmp = focus_widget;
focus_widget = 0;
#ifdef Q_WS_WIN
TQInputContext::accept( tmp );
#elif defined(Q_WS_X11)
tmp->unfocusInputContext();
#endif
TQApplication::sendSpontaneousEvent( tmp, &out );
} else if ( active_window ) {
TQWidget *w = active_window->focusWidget();
if ( w && w->focusPolicy() != TQWidget::NoFocus )
w->setFocus();
else
active_window->focusNextPrevChild( TRUE );
}
TQFocusEvent::resetReason();
}
/*!\internal
Creates the proper Enter/Leave event when widget \a enter is entered
and widget \a leave is left.
*/
Q_EXPORT void tqt_dispatchEnterLeave( TQWidget* enter, TQWidget* leave ) {
#if 0
if ( leave ) {
TQEvent e( TQEvent::Leave );
TQApplication::sendEvent( leave, & e );
}
if ( enter ) {
TQEvent e( TQEvent::Enter );
TQApplication::sendEvent( enter, & e );
}
return;
#endif
TQWidget* w ;
if ( !enter && !leave )
return;
TQWidgetList leaveList;
TQWidgetList enterList;
bool sameWindow = leave && enter && leave->topLevelWidget() == enter->topLevelWidget();
if ( leave && !sameWindow ) {
w = leave;
do {
leaveList.append( w );
} while ( (w = w->parentWidget( TRUE ) ) );
}
if ( enter && !sameWindow ) {
w = enter;
do {
enterList.prepend( w );
} while ( (w = w->parentWidget(TRUE) ) );
}
if ( sameWindow ) {
int enterDepth = 0;
int leaveDepth = 0;
w = enter;
while ( ( w = w->parentWidget( TRUE ) ) )
enterDepth++;
w = leave;
while ( ( w = w->parentWidget( TRUE ) ) )
leaveDepth++;
TQWidget* wenter = enter;
TQWidget* wleave = leave;
while ( enterDepth > leaveDepth ) {
wenter = wenter->parentWidget();
enterDepth--;
}
while ( leaveDepth > enterDepth ) {
wleave = wleave->parentWidget();
leaveDepth--;
}
while ( !wenter->isTopLevel() && wenter != wleave ) {
wenter = wenter->parentWidget();
wleave = wleave->parentWidget();
}
w = leave;
while ( w != wleave ) {
leaveList.append( w );
w = w->parentWidget();
}
w = enter;
while ( w != wenter ) {
enterList.prepend( w );
w = w->parentWidget();
}
}
TQEvent leaveEvent( TQEvent::Leave );
for ( w = leaveList.first(); w; w = leaveList.next() ) {
if ( !tqApp->activeModalWidget() || tqt_tryModalHelper( w, 0 ))
TQApplication::sendEvent( w, &leaveEvent );
}
TQEvent enterEvent( TQEvent::Enter );
for ( w = enterList.first(); w; w = enterList.next() ) {
if ( !tqApp->activeModalWidget() || tqt_tryModalHelper( w, 0 ))
TQApplication::sendEvent( w, &enterEvent );
}
}
#ifdef Q_WS_MACX
extern TQWidget *tqt_tryModalHelperMac( TQWidget * top ); //qapplication_mac.cpp
#endif
/*!\internal
Called from qapplication_<platform>.cpp, returns TRUE
if the widget should accept the event.
*/
Q_EXPORT bool tqt_tryModalHelper( TQWidget *widget, TQWidget **rettop ) {
TQWidget *modal=0, *top=TQApplication::activeModalWidget();
if ( rettop ) *rettop = top;
if ( tqApp->activePopupWidget() )
return TRUE;
#ifdef Q_WS_MACX
top = tqt_tryModalHelperMac( top );
if ( rettop ) *rettop = top;
#endif
TQWidget* groupLeader = widget;
widget = widget->topLevelWidget();
if ( widget->testWFlags(TQt::WShowModal) ) // widget is modal
modal = widget;
if ( !top || modal == top ) // don't block event
return TRUE;
TQWidget * p = widget->parentWidget(); // Check if the active modal widget is a parent of our widget
while ( p ) {
if ( p == top )
return TRUE;
p = p->parentWidget();
}
while ( groupLeader && !groupLeader->testWFlags( TQt::WGroupLeader ) )
groupLeader = groupLeader->parentWidget();
if ( groupLeader ) {
// Does groupLeader have a child in tqt_modal_stack?
bool unrelated = TRUE;
modal = tqt_modal_stack->first();
while (modal && unrelated) {
TQWidget* p = modal->parentWidget();
while ( p && p != groupLeader && !p->testWFlags( TQt::WGroupLeader) ) {
p = p->parentWidget();
}
modal = tqt_modal_stack->next();
if ( p == groupLeader ) unrelated = FALSE;
}
if ( unrelated )
return TRUE; // don't block event
}
return FALSE;
}
/*!
Returns the desktop widget (also called the root window).
The desktop widget is useful for obtaining the size of the screen.
It may also be possible to draw on the desktop. We recommend against
assuming that it's possible to draw on the desktop, since this does
not work on all operating systems.
\code
TQDesktopWidget *d = TQApplication::desktop();
int w = d->width(); // returns desktop width
int h = d->height(); // returns desktop height
\endcode
*/
TQDesktopWidget *TQApplication::desktop()
{
if ( !tqt_desktopWidget || // not created yet
!tqt_desktopWidget->isDesktop() ) { // reparented away
tqt_desktopWidget = new TQDesktopWidget();
TQ_CHECK_PTR( tqt_desktopWidget );
}
return tqt_desktopWidget;
}
#ifndef QT_NO_CLIPBOARD
/*!
Returns a pointer to the application global clipboard.
*/
TQClipboard *TQApplication::clipboard()
{
if ( tqt_clipboard == 0 ) {
tqt_clipboard = new TQClipboard;
TQ_CHECK_PTR( tqt_clipboard );
}
return tqt_clipboard;
}
#endif // QT_NO_CLIPBOARD
/*!
By default, TQt will try to use the current standard colors, fonts
etc., from the underlying window system's desktop settings,
and use them for all relevant widgets. This behavior can be switched off
by calling this function with \a on set to FALSE.
This static function must be called before creating the TQApplication
object, like this:
\code
int main( int argc, char** argv ) {
TQApplication::setDesktopSettingsAware( FALSE ); // I know better than the user
TQApplication myApp( argc, argv ); // Use default fonts & colors
...
}
\endcode
\sa desktopSettingsAware()
*/
void TQApplication::setDesktopSettingsAware( bool on )
{
obey_desktop_settings = on;
}
/*!
Returns the value set by setDesktopSettingsAware(); by default TRUE.
\sa setDesktopSettingsAware()
*/
bool TQApplication::desktopSettingsAware()
{
return obey_desktop_settings;
}
/*! \fn void TQApplication::lock()
Lock the TQt Library Mutex. If another thread has already locked the
mutex, the calling thread will block until the other thread has
unlocked the mutex.
\sa unlock() locked() \link threads.html Thread Support in TQt\endlink
*/
/*! \fn void TQApplication::unlock(bool wakeUpGui)
Unlock the TQt Library Mutex. If \a wakeUpGui is TRUE (the default),
then the GUI thread will be woken with TQApplication::wakeUpGuiThread().
\sa lock(), locked() \link threads.html Thread Support in TQt\endlink
*/
/*! \fn bool TQApplication::locked()
Returns TRUE if the TQt Library Mutex is locked by a different thread;
otherwise returns FALSE.
\warning Due to different implementations of recursive mutexes on
the supported platforms, calling this function from the same thread
that previously locked the mutex will give undefined results.
\sa lock() unlock() \link threads.html Thread Support in TQt\endlink
*/
/*! \fn bool TQApplication::tryLock()
Attempts to lock the TQt Library Mutex, and returns immediately. If
the lock was obtained, this function returns TRUE. If another thread
has locked the mutex, this function returns FALSE, instead of
waiting for the lock to become available.
The mutex must be unlocked with unlock() before another thread can
successfully lock it.
\sa lock(), unlock() \link threads.html Thread Support in TQt\endlink
*/
#if defined(QT_THREAD_SUPPORT)
void TQApplication::lock()
{
tqt_mutex->lock();
}
void TQApplication::unlock(bool wakeUpGui)
{
tqt_mutex->unlock();
if (wakeUpGui)
wakeUpGuiThread();
}
bool TQApplication::locked()
{
return tqt_mutex->locked();
}
bool TQApplication::tryLock()
{
return tqt_mutex->tryLock();
}
#endif
/*!
\fn bool TQApplication::isSessionRestored() const
Returns TRUE if the application has been restored from an earlier
\link session.html session\endlink; otherwise returns FALSE.
\sa sessionId(), commitData(), saveState()
*/
/*!
\fn TQString TQApplication::sessionId() const
Returns the current \link session.html session's\endlink identifier.
If the application has been restored from an earlier session, this
identifier is the same as it was in that previous session.
The session identifier is guaranteed to be unique both for different
applications and for different instances of the same application.
\sa isSessionRestored(), sessionKey(), commitData(), saveState()
*/
/*!
\fn TQString TQApplication::sessionKey() const
Returns the session key in the current \link session.html
session\endlink.
If the application has been restored from an earlier session, this
key is the same as it was when the previous session ended.
The session key changes with every call of commitData() or
saveState().
\sa isSessionRestored(), sessionId(), commitData(), saveState()
*/
/*!
\fn void TQApplication::commitData( TQSessionManager& sm )
This function deals with \link session.html session
management\endlink. It is invoked when the TQSessionManager wants the
application to commit all its data.
Usually this means saving all open files, after getting
permission from the user. Furthermore you may want to provide a means
by which the user can cancel the shutdown.
Note that you should not exit the application within this function.
Instead, the session manager may or may not do this afterwards,
depending on the context.
\warning Within this function, no user interaction is possible, \e
unless you ask the session manager \a sm for explicit permission.
See TQSessionManager::allowsInteraction() and
TQSessionManager::allowsErrorInteraction() for details and example
usage.
The default implementation requests interaction and sends a close
event to all visible top level widgets. If any event was
rejected, the shutdown is canceled.
\sa isSessionRestored(), sessionId(), saveState(), \link session.html the Session Management overview\endlink
*/
#ifndef QT_NO_SESSIONMANAGER
void TQApplication::commitData( TQSessionManager& sm )
{
if ( sm.allowsInteraction() ) {
TQWidgetList done;
TQWidgetList *list = TQApplication::topLevelWidgets();
bool cancelled = FALSE;
TQWidget* w = list->first();
while ( !cancelled && w ) {
if ( !w->isHidden() ) {
TQCloseEvent e;
sendEvent( w, &e );
cancelled = !e.isAccepted();
if ( !cancelled )
done.append( w );
delete list; // one never knows...
list = TQApplication::topLevelWidgets();
w = list->first();
} else {
w = list->next();
}
while ( w && done.containsRef( w ) )
w = list->next();
}
delete list;
if ( cancelled )
sm.cancel();
}
}
/*!
\fn void TQApplication::saveState( TQSessionManager& sm )
This function deals with \link session.html session
management\endlink. It is invoked when the
\link TQSessionManager session manager \endlink wants the application
to preserve its state for a future session.
For example, a text editor would create a temporary file that
includes the current contents of its edit buffers, the location of
the cursor and other aspects of the current editing session.
Note that you should never exit the application within this
function. Instead, the session manager may or may not do this
afterwards, depending on the context. Futhermore, most session
managers will very likely request a saved state immediately after
the application has been started. This permits the session manager
to learn about the application's restart policy.
\warning Within this function, no user interaction is possible, \e
unless you ask the session manager \a sm for explicit permission.
See TQSessionManager::allowsInteraction() and
TQSessionManager::allowsErrorInteraction() for details.
\sa isSessionRestored(), sessionId(), commitData(), \link session.html the Session Management overview\endlink
*/
void TQApplication::saveState( TQSessionManager& /* sm */ )
{
}
#endif //QT_NO_SESSIONMANAGER
/*!
Sets the time after which a drag should start to \a ms ms.
\sa startDragTime()
*/
void TQApplication::setStartDragTime( int ms )
{
drag_time = ms;
}
/*!
If you support drag and drop in you application and a drag should
start after a mouse click and after a certain time elapsed, you
should use the value which this method returns as the delay (in ms).
TQt also uses this delay internally, e.g. in TQTextEdit and TQLineEdit,
for starting a drag.
The default value is 500 ms.
\sa setStartDragTime(), startDragDistance()
*/
int TQApplication::startDragTime()
{
return drag_time;
}
/*!
Sets the distance after which a drag should start to \a l pixels.
\sa startDragDistance()
*/
void TQApplication::setStartDragDistance( int l )
{
drag_distance = l;
}
/*!
If you support drag and drop in you application and a drag should
start after a mouse click and after moving the mouse a certain
distance, you should use the value which this method returns as the
distance.
For example, if the mouse position of the click is stored in \c
startPos and the current position (e.g. in the mouse move event) is
\c currPos, you can find out if a drag should be started with code
like this:
\code
if ( ( startPos - currPos ).manhattanLength() >
TQApplication::startDragDistance() )
startTheDrag();
\endcode
TQt uses this value internally, e.g. in TQFileDialog.
The default value is 4 pixels.
\sa setStartDragDistance(), startDragTime(), TQPoint::manhattanLength()
*/
int TQApplication::startDragDistance()
{
return drag_distance;
}
/*!
If \a b is TRUE, all dialogs and widgets will be laid out in a
mirrored fashion, as required by right to left languages such as
Arabic and Hebrew. If \a b is FALSE, dialogs and widgets are laid
out left to right.
Changing this flag in runtime does not cause a relayout of already
instantiated widgets.
\sa reverseLayout()
*/
void TQApplication::setReverseLayout( bool b )
{
if ( reverse_layout == b )
return;
reverse_layout = b;
TQWidgetList *list = topLevelWidgets();
TQWidgetListIt it( *list );
TQWidget *w;
while ( ( w=it.current() ) != 0 ) {
++it;
postEvent( w, new TQEvent( TQEvent::LayoutDirectionChange ) );
}
delete list;
}
/*!
Returns TRUE if all dialogs and widgets will be laid out in a
mirrored (right to left) fashion. Returns FALSE if dialogs and
widgets will be laid out left to right.
\sa setReverseLayout()
*/
bool TQApplication::reverseLayout()
{
return reverse_layout;
}
/*!
\class TQSessionManager ntqsessionmanager.h
\brief The TQSessionManager class provides access to the session manager.
\ingroup application
\ingroup environment
The session manager is responsible for session management, most
importantly for interruption and resumption. A "session" is a kind
of record of the state of the system, e.g. which applications were
run at start up and which applications are currently running. The
session manager is used to save the session, e.g. when the machine
is shut down; and to restore a session, e.g. when the machine is
started up. Use TQSettings to save and restore an individual
application's settings, e.g. window positions, recently used files,
etc.
TQSessionManager provides an interface between the application and
the session manager so that the program can work well with the
session manager. In TQt, session management requests for action
are handled by the two virtual functions TQApplication::commitData()
and TQApplication::saveState(). Both provide a reference to
a session manager object as argument, to allow the application
to communicate with the session manager.
During a session management action (i.e. within commitData() and
saveState()), no user interaction is possible \e unless the
application got explicit permission from the session manager. You
ask for permission by calling allowsInteraction() or, if it's really
urgent, allowsErrorInteraction(). TQt does not enforce this, but the
session manager may.
You can try to abort the shutdown process by calling cancel(). The
default commitData() function does this if some top-level window
rejected its closeEvent().
For sophisticated session managers provided on Unix/X11, TQSessionManager
offers further possibilites to fine-tune an application's session
management behavior: setRestartCommand(), setDiscardCommand(),
setRestartHint(), setProperty(), requestPhase2(). See the respective
function descriptions for further details.
*/
/*! \enum TQSessionManager::RestartHint
This enum type defines the circumstances under which this
application wants to be restarted by the session manager. The
current values are
\value RestartIfRunning if the application is still running when
the session is shut down, it wants to be restarted at the start of
the next session.
\value RestartAnyway the application wants to be started at the
start of the next session, no matter what. (This is useful for
utilities that run just after startup and then quit.)
\value RestartImmediately the application wants to be started
immediately whenever it is not running.
\value RestartNever the application does not want to be restarted
automatically.
The default hint is \c RestartIfRunning.
*/
/*!
\fn TQString TQSessionManager::sessionId() const
Returns the identifier of the current session.
If the application has been restored from an earlier session, this
identifier is the same as it was in that earlier session.
\sa sessionKey(), TQApplication::sessionId()
*/
/*!
\fn TQString TQSessionManager::sessionKey() const
Returns the session key in the current session.
If the application has been restored from an earlier session, this
key is the same as it was when the previous session ended.
The session key changes with every call of commitData() or
saveState().
\sa sessionId(), TQApplication::sessionKey()
*/
// ### Note: This function is undocumented, since it is #ifdef'd.
/*!
\fn void* TQSessionManager::handle() const
X11 only: returns a handle to the current \c SmcConnection.
*/
/*!
\fn bool TQSessionManager::allowsInteraction()
Asks the session manager for permission to interact with the
user. Returns TRUE if interaction is permitted; otherwise
returns FALSE.
The rationale behind this mechanism is to make it possible to
synchronize user interaction during a shutdown. Advanced session
managers may ask all applications simultaneously to commit their
data, resulting in a much faster shutdown.
When the interaction is completed we strongly recommend releasing the
user interaction semaphore with a call to release(). This way, other
applications may get the chance to interact with the user while your
application is still busy saving data. (The semaphore is implicitly
released when the application exits.)
If the user decides to cancel the shutdown process during the
interaction phase, you must tell the session manager that this has
happened by calling cancel().
Here's an example of how an application's TQApplication::commitData()
might be implemented:
\code
void MyApplication::commitData( TQSessionManager& sm ) {
if ( sm.allowsInteraction() ) {
switch ( TQMessageBox::warning(
yourMainWindow,
tr("Application Name"),
tr("Save changes to document Foo?"),
tr("&Yes"),
tr("&No"),
tr("Cancel"),
0, 2) ) {
case 0: // yes
sm.release();
// save document here; if saving fails, call sm.cancel()
break;
case 1: // continue without saving
break;
default: // cancel
sm.cancel();
break;
}
} else {
// we did not get permission to interact, then
// do something reasonable instead.
}
}
\endcode
If an error occurred within the application while saving its data,
you may want to try allowsErrorInteraction() instead.
\sa TQApplication::commitData(), release(), cancel()
*/
/*!
\fn bool TQSessionManager::allowsErrorInteraction()
This is similar to allowsInteraction(), but also tells the session
manager that an error occurred. Session managers may give error
interaction request higher priority, which means that it is more likely
that an error interaction is permitted. However, you are still not
guaranteed that the session manager will allow interaction.
\sa allowsInteraction(), release(), cancel()
*/
/*!
\fn void TQSessionManager::release()
Releases the session manager's interaction semaphore after an
interaction phase.
\sa allowsInteraction(), allowsErrorInteraction()
*/
/*!
\fn void TQSessionManager::cancel()
Tells the session manager to cancel the shutdown process. Applications
should not call this function without first asking the user.
\sa allowsInteraction(), allowsErrorInteraction()
*/
/*!
\fn void TQSessionManager::setRestartHint( RestartHint hint )
Sets the application's restart hint to \a hint. On application
startup the hint is set to \c RestartIfRunning.
Note that these flags are only hints, a session manager may or may
not respect them.
We recommend setting the restart hint in TQApplication::saveState()
because most session managers perform a checkpoint shortly after an
application's startup.
\sa restartHint()
*/
/*!
\fn TQSessionManager::RestartHint TQSessionManager::restartHint() const
Returns the application's current restart hint. The default is
\c RestartIfRunning.
\sa setRestartHint()
*/
/*!
\fn void TQSessionManager::setRestartCommand( const TQStringList& command )
If the session manager is capable of restoring sessions it will
execute \a command in order to restore the application. The command
defaults to
\code
appname -session id
\endcode
The \c -session option is mandatory; otherwise TQApplication cannot
tell whether it has been restored or what the current session
identifier is. See TQApplication::isSessionRestored() and
TQApplication::sessionId() for details.
If your application is very simple, it may be possible to store the
entire application state in additional command line options. This
is usually a very bad idea because command lines are often limited
to a few hundred bytes. Instead, use TQSettings, or temporary files
or a database for this purpose. By marking the data with the unique
sessionId(), you will be able to restore the application in a future
session.
\sa restartCommand(), setDiscardCommand(), setRestartHint()
*/
/*!
\fn TQStringList TQSessionManager::restartCommand() const
Returns the currently set restart command.
Note that if you want to iterate over the list, you should
iterate over a copy, e.g.
\code
TQStringList list = mySession.restartCommand();
TQStringList::Iterator it = list.begin();
while( it != list.end() ) {
myProcessing( *it );
++it;
}
\endcode
\sa setRestartCommand(), restartHint()
*/
/*!
\fn void TQSessionManager::setDiscardCommand( const TQStringList& )
\sa discardCommand(), setRestartCommand()
*/
/*!
\fn TQStringList TQSessionManager::discardCommand() const
Returns the currently set discard command.
Note that if you want to iterate over the list, you should
iterate over a copy, e.g.
\code
TQStringList list = mySession.discardCommand();
TQStringList::Iterator it = list.begin();
while( it != list.end() ) {
myProcessing( *it );
++it;
}
\endcode
\sa setDiscardCommand(), restartCommand(), setRestartCommand()
*/
/*!
\overload void TQSessionManager::setManagerProperty( const TQString& name,
const TQString& value )
Low-level write access to the application's identification and state
records are kept in the session manager.
The property called \a name has its value set to the string \a value.
*/
/*!
\fn void TQSessionManager::setManagerProperty( const TQString& name,
const TQStringList& value )
Low-level write access to the application's identification and state
record are kept in the session manager.
The property called \a name has its value set to the string list \a value.
*/
/*!
\fn bool TQSessionManager::isPhase2() const
Returns TRUE if the session manager is currently performing a second
session management phase; otherwise returns FALSE.
\sa requestPhase2()
*/
/*!
\fn void TQSessionManager::requestPhase2()
Requests a second session management phase for the application. The
application may then return immediately from the
TQApplication::commitData() or TQApplication::saveState() function,
and they will be called again once most or all other applications have
finished their session management.
The two phases are useful for applications such as the X11 window manager
that need to store information about another application's windows
and therefore have to wait until these applications have completed their
respective session management tasks.
Note that if another application has requested a second phase it
may get called before, simultaneously with, or after your
application's second phase.
\sa isPhase2()
*/
/*!
\fn int TQApplication::horizontalAlignment( int align )
Strips out vertical alignment flags and transforms an
alignment \a align of AlignAuto into AlignLeft or
AlignRight according to the language used. The other horizontal
alignment flags are left untouched.
*/
/*****************************************************************************
Stubbed session management support
*****************************************************************************/
#ifndef QT_NO_SESSIONMANAGER
#if defined( QT_NO_SM_SUPPORT ) || defined( Q_WS_WIN ) || defined( Q_WS_MAC ) || defined( Q_WS_QWS )
class TQSessionManagerData
{
public:
TQStringList restartCommand;
TQStringList discardCommand;
TQString sessionId;
TQString sessionKey;
TQSessionManager::RestartHint restartHint;
};
TQSessionManager* qt_session_manager_self = 0;
TQSessionManager::TQSessionManager( TQApplication * app, TQString &id, TQString &key )
: TQObject( app, "qt_sessionmanager" )
{
qt_session_manager_self = this;
d = new TQSessionManagerData;
#if defined(Q_WS_WIN) && !defined(Q_OS_TEMP)
wchar_t guidstr[40];
GUID guid;
CoCreateGuid( &guid );
StringFromGUID2(guid, guidstr, 40);
id = TQString::fromUcs2((ushort*)guidstr);
CoCreateGuid( &guid );
StringFromGUID2(guid, guidstr, 40);
key = TQString::fromUcs2((ushort*)guidstr);
#endif
d->sessionId = id;
d->sessionKey = key;
d->restartHint = RestartIfRunning;
}
TQSessionManager::~TQSessionManager()
{
delete d;
qt_session_manager_self = 0;
}
TQString TQSessionManager::sessionId() const
{
return d->sessionId;
}
TQString TQSessionManager::sessionKey() const
{
return d->sessionKey;
}
#if defined(Q_WS_X11) || defined(Q_WS_MAC)
void* TQSessionManager::handle() const
{
return 0;
}
#endif
#if !defined(Q_WS_WIN)
bool TQSessionManager::allowsInteraction()
{
return TRUE;
}
bool TQSessionManager::allowsErrorInteraction()
{
return TRUE;
}
void TQSessionManager::release()
{
}
void TQSessionManager::cancel()
{
}
#endif
void TQSessionManager::setRestartHint( TQSessionManager::RestartHint hint)
{
d->restartHint = hint;
}
TQSessionManager::RestartHint TQSessionManager::restartHint() const
{
return d->restartHint;
}
void TQSessionManager::setRestartCommand( const TQStringList& command)
{
d->restartCommand = command;
}
TQStringList TQSessionManager::restartCommand() const
{
return d->restartCommand;
}
void TQSessionManager::setDiscardCommand( const TQStringList& command)
{
d->discardCommand = command;
}
TQStringList TQSessionManager::discardCommand() const
{
return d->discardCommand;
}
void TQSessionManager::setManagerProperty( const TQString&, const TQString&)
{
}
void TQSessionManager::setManagerProperty( const TQString&, const TQStringList& )
{
}
bool TQSessionManager::isPhase2() const
{
return FALSE;
}
void TQSessionManager::requestPhase2()
{
}
#endif // QT_NO_SM_SUPPORT
#endif //QT_NO_SESSIONMANAGER