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/****************************************************************************
**
**
** TQt thread support
**
** Copyright (C) 1992-2008 Trolltech ASA. All rights reserved.
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/*! \page threads.html
\title Thread Support in Qt
\tableofcontents
\section1 Introduction
Qt provides thread support in the form of basic platform-independent
threading classes, a thread-safe way of posting events, and a global
Qt library lock that allows you to call TQt methods from different
threads.
This document is intended for an audience that has knowledge of, and
experience with, multithreaded applications. If you are new to
threading see our \link #reading Recommended Reading\endlink list.
\section1 Enabling Thread Support
When TQt is installed on Windows, thread support is an option on some
compilers.
On Mac OS X and Unix, thread support is enabled by adding the
\c{-thread} option when running the \c{configure} script. On Unix
platforms where multithreaded programs must be linked in special ways,
such as with a special libc, installation will create a separate
library, \c{libtqt-mt} and hence threaded programs must be linked
against this library (with \c{-ltqt-mt}) rather than the standard Qt
library.
On both platforms, you should compile with the macro \c
TQT_THREAD_SUPPORT defined (e.g. compile with
\c{-DTQT_THREAD_SUPPORT}). On Windows, this is usually done by an
entry in \c{ntqconfig.h}.
\section1 The Thread Classes
These classes are built into the TQt library when thread support is enabled:
\list
\i TQThread - Provides the means to start a new thread, which begins
execution in your reimplementation of TQThread::run(). This is similar
to the Java thread class.
\i TQThreadStorage - Provides per-thread data storage. This class can
only be used with threads started with TQThread; it cannot be used with
threads started with platform-specific APIs.
\i TQMutex - Provides a mutual exclusion lock (also know as a mutex).
\i TQMutexLocker - A convenience class which automatically locks and
unlocks a TQMutex. TQMutexLocker is useful in complicated code, or in
code which uses exceptions. See the documentation for more details.
\i TQWaitCondition - Provides a way for threads to go to sleep until
woken up by another thread.
\i TQSemaphore - Provides a simple integer semaphore.
\endlist
\section1 Important Definitions
\target reentrant
\target threadsafe
When using TQt in a multithreaded program, it is important to
understand the definition of the terms \e reentrant and \e
thread-safe:
\list
\i \e reentrant - Describes a function which can be called
simultaneously by multiple threads when each invocation of the
function references unique data. Calling a reentrant function
simultaneously with the same data is not safe, and such invocations
should be serialized.
\i \e thread-safe - Describes a function which can be called
simultaneously by multiple threads when each invocation references
shared data. Calling a thread-safe function simultaneously with the
same data is safe, since all access to the shared data are serialized.
\endlist
Note that TQt provides both implictly and explicitly shared
classes. For more information, see the \link
threads.html#threads-shared Threads and Shared Data \endlink
section.
Most C++ member functions are inherently reentrant, since they only
reference class member data. Any thread can call such a member
function on an instance, as long as no other thread is calling a
member function on the same instance. For example, given the class \c
Number below:
\code
class Number
{
public:
inline Number( int n ) : num( n ) { }
inline int number() const { return num; }
inline void setNumber( int n ) { num = n; }
private:
int num;
};
\endcode
The methods \c Number::number() and \c Number::setNumber() are
reentrant, since they only reference unique data. Only one thread at
a time can call member functions on each instance of \c Number.
However, multiple threads can call member functions on separate
instances of \c Number.
Thread-safe functions usually use a mutex (e.g a TQMutex) to serialize
access to shared data. Because of this, thread-safe functions are
usually slower than reentrant functions, because of the extra overhead
of locking and unlocking the mutex. For example, given the class \c
Counter below:
\code
class Counter
{
public:
inline Counter() { ++instances; }
inline ~Counter() { --instances; }
private:
static int instances;
};
\endcode
Since the modifications of the static \c instances integer are not
serialized, this class is not thread-safe. So make it threadsafe, a
mutex must be used:
\code
class Counter
{
public:
inline Counter()
{
mutex.lock();
++instances;
mutex.unlock();
}
...
private:
static TQMutex mutex;
static int instances;
};
\endcode
\section1 Thread-safe Event Posting
In Qt, one thread is always the GUI or event thread. This is the
thread that creates a QApplication object and calls
QApplication::exec(). This is also the initial thread that calls
main() at program start. This thread is the only thread that is
allowed to perform GUI operations, including generating and receiving
events from the window system. TQt does not support creating
QApplication and running the event loop (with QApplication::exec()) in
a secondary thread. You must create the QApplication object and call
QApplication::exec() from the main() function in your program.
Threads that wish to display data in a widget cannot modify the widget
directly, so they must post an event to the widget using
QApplication::postEvent(). The event will be delivered later on by
the GUI thread.
Normally, the programmer would like to include some information in the
event sent to the widget. See the documentation for TQCustomEvent for
more information on user-defined events.
\section1 Threads and TQObject subclasses
The TQObject class itself is \e reentrant. However, certain rules
apply when creating and using TQObjects in a thread that is not the GUI
thread.
\list 1
\i \e None of the TQObject based classes included in the TQt library are
\e reentrant. This includes all widgets (e.g. TQWidget and
subclasses), OS kernel classes (e.g. TQProcess, TQAccel, TQTimer), and
all networking classes (e.g. TQSocket, TQDns).
\i TQObject and all of its subclasses are \e not \e thread-safe. This
includes the entire event delivery system. It is important to
remember that the GUI thread may be delivering events to your TQObject
subclass while you are accessing the object from another thread. If
you are using TQObject in a thread that is not the GUI thread, and you
are handling events sent to this object, you \e must protect all
access to your data with a mutex; otherwise you may experience crashes
or other undesired behavior.
\i As a corollary to the above, deleting a TQObject while pending
events are waiting to be delivered can cause a crash. You must not
delete the TQObject directly from a thread that is not the GUI thread.
Use the TQObject::deleteLater() method instead, which will cause the
event loop to delete the object after all pending events have been
delivered to the object.
\endlist
\section1 The TQt Library Mutex
QApplication includes a mutex that is used to protect access to window
system functions. This mutex is locked while the event loop is
running (e.g. during event delivery) and unlocked when the eventloop
goes to sleep. Note: The TQt event loop is recursive, and the library
mutex is \e not unlocked when re-entering the event loop (e.g. when
executing a modal dialog with TQDialog::exec()).
If another thread locks the TQt library mutex, then the event loop will
stop processing events, and the locking thread may do simple GUI
operations. Operations such as creating a TQPainter and drawing a line
are examples of simple GUI operations:
\code
...
tqApp->lock();
TQPainter p;
p.begin( mywidget );
p.setPen( TQColor( "red" ) );
p.drawLine( 0,0,100,100 );
p.end();
tqApp->unlock();
...
\endcode
Any operations that generate events must not be called by any thread
other than the GUI thread. Examples of such operations are:
\list
\i creating a TQWidget, TQTimer, TQSocketNotifier, TQSocket or other network class.
\i moving, resizing, showing or hiding a TQWidget.
\i starting or stoping a TQTimer.
\i enabling or disabling a TQSocketNotifier.
\i using a TQSocket or other network class.
\endlist
Events generated by these operations will be lost on some platforms.
\section1 Threads and Signals and Slots
The Signals and Slots mechanism can be used in separate threads, as
long as the rules for TQObject based classes are followed. The Signals
and Slots mechanism is synchronous: when a signal is emitted, all
slots are called immediately. The slots are executed in the thread
context that emitted the signal.
\warning Slots that generate window system events or use window system
functions \e must \e not be connected to a signal that is emitted from
a thread that is not the GUI thread. See the TQt Library Mutex section
above for more details.
\target threads-shared
\section1 Threads and Shared Data
Qt provides many implicitly shared and explicitly shared classes. In
a multithreaded program, multiple instances of a shared class can
reference shared data, which is dangerous if one or more threads
attempt to modify the data. TQt provides the TQDeepCopy class, which
ensures that shared classes reference unique data.
See the description of \link shclass.html implicit sharing\endlink for more
information.
\target threads-sql
\section1 Threads and the SQL Module
A connection can only be used from within the thread that created it.
Moving connections between threads or creating queries from a different
thread is not supported.
In addition, the third party libraries used by the TQSqlDrivers can impose
further restrictions on using the SQL Module in a multithreaded program.
Consult the manual of your database client for more information.
\section1 Caveats
Some things to watch out for when programming with threads:
\list
\i As mentioned above, TQObject based classes are neither thread-safe
nor reentrant. This includes all widgets (e.g. TQWidget and
subclasses), OS kernel classes (e.g. TQProcess, TQAccel), and all
networking classes (e.g. TQSocket, TQDns).
\i Deleting a TQObject while pending events are waiting to be delivered
will cause a crash. If you are creating TQObjects in a thread that is
not the GUI thread and posting events to these objects, you should not
delete the TQObject directly. Use the TQObject::deleteLater() method
instead, which will cause the event loop to delete the object after
all pending events have been delivered to the object.
\i Don't do any blocking operations while holding the TQt library
mutex. This will freeze up the event loop.
\i Make sure you unlock a recursive TQMutex as many times as you lock
it, no more and no less.
\i Don't mix the normal TQt library and the threaded TQt library in your
application. This means that if your application uses the threaded Qt
library, you should not link with the normal TQt library, dynamically
load the normal TQt library or dynamically load another library or
plugin that depends on the normal TQt library. On some systems, doing
this can corrupt the static data used in the TQt library.
\i TQt does not support creating QApplication and running the event
loop (with QApplication::exec()) in a secondary thread. You must
create the QApplication object and call QApplication::exec() from the
main() function in your program.
\endlist
\target reading
\section1 Recommended Reading
\list
\i \link http://www.amazon.com/exec/obidos/ASIN/0134436989/trolltech/t
Threads Primer: A Guide to Multithreaded Programming\endlink
\i \link http://www.amazon.com/exec/obidos/ASIN/0131900676/trolltech/t
Thread Time: The Multithreaded Programming Guide\endlink
\i \link http://www.amazon.com/exec/obidos/ASIN/1565921151/trolltech/t
Pthreads Programming: A POSIX Standard for Better Multiprocessing (O'Reilly Nutshell)\endlink
\i \link http://www.amazon.com/exec/obidos/ASIN/1565922964/trolltech/t
Win32 Multithreaded Programming\endlink
\endlist
*/