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/*! \defgroup i18n
\title Internationalization with Qt
\keyword internationalization
\keyword i18n
The internationalization of an application is the process of making
the application usable by people in countries other than one's own.
\tableofcontents
In some cases internationalization is simple, for example, making a US
application accessible to Australian or British users may require
little more than a few spelling corrections. But to make a US
application usable by Japanese users, or a Korean application usable
by German users, will require that the software operate not only in
different languages, but use different input techniques, character
encodings and presentation conventions.
Qt tries to make internationalization as painless as possible for
developers. All input widgets and text drawing methods in TQt offer
built-in support for all supported languages. The built-in font engine
is capable of correctly and attractively rendering text that contains
characters from a variety of different writing systems at the same
time.
Qt supports most languages in use today, in particular:
\list
\i All East Asian languages (Chinese, Japanese and Korean)
\i All Western languages (using Latin script)
\i Arabic
\i Cyrillic languages (Russian)
\i Greek
\i Hebrew
\i Thai and Lao
\i All scripts in Unicode 3.2 that do not require special processing
\endlist
On Windows NT/2000/XP and Unix/X11 with Xft (client side font support)
the following languages are also supported:
\list
\i Bengali
\i Devanagari
\i Dhivehi (Thaana)
\i Gujarati
\i Gurmukhi
\i Kannada
\i Khmer
\i Malayalam (X11 only)
\i Myanmar (X11 only)
\i Syriac
\i Tamil
\i Telugu
\i Tibetan (X11 only)
\endlist
Many of these writing systems exhibit special features:
\list
\i <b>Special line breaking behavior.</b> Some of the Asian languages are
written without spaces between words. Line breaking can occur either
after every character (with exceptions) as in Chinese, Japanese and
Korean, or after logical word boundaries as in Thai.
\i <b>Bidirectional writing.</b> Arabic and Hebrew are written from right to
left, except for numbers and embedded English text which is written
left to right. The exact behavior is defined in the \link
http://www.unicode.org/unicode/reports/tr9/ Unicode Technical Report
#9 \endlink.
\i <b>Non spacing or diacritical marks</b> (accents or umlauts in European
languages). Some languages such as Vietnamese make extensive use of
these marks and some characters can have more than one mark at the
same time to clarify pronunciation.
\i <b>Ligatures.</b> In special contexts, some pairs of characters get
replaced by a combined glyph forming a ligature. Common examples are
the fl and fi ligatures used in typesetting US and European books.
\endlist
Qt tries to take care of all the special features listed above. You
usually don't have to worry about these features so long as you use
Qt's input widgets (e.g. QLineEdit, TQTextEdit, and derived classes)
and Qt's display widgets (e.g. QLabel).
Support for these writing systems is transparent to the programmer
and completely encapsulated in Qt's text engine. This means that you
don't need to have any knowledge about the writing system used in a
particular language, except for the following small points:
\list
\i QPainter::drawText( int x, int y, const TQString &str ) will always
draw the string with it's left edge at the position specified with
the x, y parameters. This will usually give you left aligned strings.
Arabic and Hebrew application strings are usually right
aligned, so for these languages use the version of drawText() that
takes a QRect since this will align in accordance with the language.
\i When you write your own text input controls, use \l
QFontMetrics::charWidth() to determine the width of a character in a
string. In some languages (e.g. Arabic or languages from the Indian
subcontinent), the width and shape of a glyph changes depending on the
surrounding characters. Writing input controls usually requires a
certain knowledge of the scripts it is going to be used in. Usually
the easiest way is to subclass QLineEdit or TQTextEdit.
\endlist
The following sections give some information on the status
of the internationalization (i18n) support in Qt.
See also the \link linguist-manual.book TQt Linguist\endlink manual.
\section1 Step by Step
Writing multi-platform international software with TQt is a gentle,
incremental process. Your software can become internationalized in
the following stages:
\section2 Use TQString for all User-visible Text
Since TQString uses the Unicode encoding internally, every
language in the world can be processed transparently using
familiar text processing operations. Also, since all Qt
functions that present text to the user take a TQString as a
parameter, there is no char* to TQString conversion overhead.
Strings that are in "programmer space" (such as TQObject names
and file format texts) need not use TQString; the traditional
char* or the TQCString class will suffice.
You're unlikely to notice that you are using Unicode;
TQString, and TQChar are just like easier versions of the crude
const char* and char from traditional C.
\section2 Use tr() for all Literal Text
Wherever your program uses \c{"quoted text"} for text that will
be presented to the user, ensure that it is processed by the \l
QApplication::translate() function. Essentially all that is necessary
to achieve this is to use \l TQObject::tr(). For example, assuming the
\c LoginWidget is a subclass of TQWidget:
\code
LoginWidget::LoginWidget()
{
QLabel *label = new QLabel( tr("Password:"), this );
...
}
\endcode
This accounts for 99% of the user-visible strings you're likely to
write.
If the quoted text is not in a member function of a
TQObject subclass, use either the tr() function of an
appropriate class, or the QApplication::translate() function
directly:
\code
void some_global_function( LoginWidget *logwid )
{
QLabel *label = new QLabel(
LoginWidget::tr("Password:"), logwid );
}
void same_global_function( LoginWidget *logwid )
{
QLabel *label = new QLabel(
tqApp->translate("LoginWidget", "Password:"),
logwid );
}
\endcode
If you need to have translatable text completely
outside a function, there are two macros to help: TQT_TR_NOOP()
and TQT_TRANSLATE_NOOP(). They merely mark the text for
extraction by the \e lupdate utility described below.
The macros expand to just the text (without the context).
Example of TQT_TR_NOOP():
\code
TQString FriendlyConversation::greeting( int greet_type )
{
static const char* greeting_strings[] = {
TQT_TR_NOOP( "Hello" ),
TQT_TR_NOOP( "Goodbye" )
};
return tr( greeting_strings[greet_type] );
}
\endcode
Example of TQT_TRANSLATE_NOOP():
\code
static const char* greeting_strings[] = {
TQT_TRANSLATE_NOOP( "FriendlyConversation", "Hello" ),
TQT_TRANSLATE_NOOP( "FriendlyConversation", "Goodbye" )
};
TQString FriendlyConversation::greeting( int greet_type )
{
return tr( greeting_strings[greet_type] );
}
TQString global_greeting( int greet_type )
{
return tqApp->translate( "FriendlyConversation",
greeting_strings[greet_type] );
}
\endcode
If you disable the const char* to TQString automatic conversion
by compiling your software with the macro TQT_NO_CAST_ASCII
defined, you'll be very likely to catch any strings you are
missing. See TQString::fromLatin1() for more information.
Disabling the conversion can make programming a bit cumbersome.
If your source language uses characters outside Latin-1, you
might find TQObject::trUtf8() more convenient than
TQObject::tr(), as tr() depends on the
QApplication::defaultCodec(), which makes it more fragile than
TQObject::trUtf8().
\section2 Use QKeySequence() for Accelerator Values
Accelerator values such as Ctrl+Q or Alt+F need to be
translated too. If you hardcode \c CTRL+Key_Q for "Quit" in
your application, translators won't be able to override
it. The correct idiom is
\code
TQPopupMenu *file = new TQPopupMenu( this );
file->insertItem( tr("&Quit"), this, TQ_SLOT(quit()),
QKeySequence(tr("Ctrl+Q", "File|Quit")) );
\endcode
\section2 Use TQString::arg() for Dynamic Text
The TQString::arg() functions offer a simple means for substituting
arguments:
\code
void FileCopier::showProgress( int done, int total,
const TQString& current_file )
{
label.setText( tr("%1 of %2 files copied.\nCopying: %3")
.arg(done)
.arg(total)
.arg(current_file) );
}
\endcode
In some languages the order of arguments may need to change, and this
can easily be achieved by changing the order of the % arguments. For
example:
\code
TQString s1 = "%1 of %2 files copied. Copying: %3";
TQString s2 = "Kopierer nu %3. Av totalt %2 filer er %1 kopiert.";
tqDebug( s1.arg(5).arg(10).arg("somefile.txt").ascii() );
tqDebug( s2.arg(5).arg(10).arg("somefile.txt").ascii() );
\endcode
produces the correct output in English and Norwegian:
\code
5 of 10 files copied. Copying: somefile.txt
Kopierer nu somefile.txt. Av totalt 10 filer er 5 kopiert.
\endcode
\section2 Produce Translations
Once you are using tr() throughout an application, you can start
producing translations of the user-visible text in your program.
\link linguist-manual.book TQt Linguist\endlink's manual provides
further information about Qt's translation tools, \e{Qt Linguist}, \e
lupdate and \e lrelease.
Translation of a TQt application is a three-step process:
\list 1
\i Run \e lupdate to extract translatable text from the C++ source
code of the TQt application, resulting in a message file for
translators (a \c .ts file). The utility recognizes the tr() construct
and the QT_*_NOOP macros described above and produces \c .ts files
(usually one per language).
\i Provide translations for the source texts in the \c .ts file, using
\e{Qt Linguist}. Since \c .ts files are in XML format, you can also
edit them by hand.
\i Run \e lrelease to obtain a light-weight message file (a \c .qm
file) from the \c .ts file, suitable only for end use. Think of the \c
.ts files as "source files", and \c .qm files as "object files". The
translator edits the \c .ts files, but the users of your application
only need the \c .qm files. Both kinds of files are platform and
locale independent.
\endlist
Typically, you will repeat these steps for every release of your
application. The \e lupdate utility does its best to reuse the
translations from previous releases.
Before you run \e lupdate, you should prepare a project file. Here's
an example project file (\c .pro file):
\code
HEADERS = funnydialog.h \
wackywidget.h
SOURCES = funnydialog.cpp \
main.cpp \
wackywidget.cpp
FORMS = fancybox.ui
TRANSLATIONS = superapp_dk.ts \
superapp_fi.ts \
superapp_no.ts \
superapp_se.ts
\endcode
When you run \e lupdate or \e lrelease, you must give the name of the
project file as a command-line argument.
In this example, four exotic languages are supported: Danish, Finnish,
Norwegian and Swedish. If you use \link qmake-manual.book
qmake\endlink, you usually don't need an extra project
file for \e lupdate; your \c qmake project file will work fine once
you add the \c TRANSLATIONS entry.
In your application, you must \l QTranslator::load() the translation
files appropriate for the user's language, and install them using \l
QApplication::installTranslator().
If you have been using the old TQt tools (\c tqtfindtr, \c msg2tqm and \c
tqtmergetr), you can use \e tqm2ts to convert your old \c .qm files.
\e linguist, \e lupdate and \e lrelease are installed in the \c bin
subdirectory of the base directory TQt is installed into. Click Help|Manual
in \e{Qt Linguist} to access the user's manual; it contains a tutorial
to get you started.
While these utilities offer a convenient way to create \c .qm files,
any system that writes \c .qm files is sufficient. You could make an
application that adds translations to a QTranslator with
QTranslator::insert() and then writes a \c .qm file with
QTranslator::save(). This way the translations can come from any
source you choose.
\target qt-itself
Qt itself contains over 400 strings that will also need to be
translated into the languages that you are targeting. You will find
translation files for French and German in \c $TQTDIR/translations as
well as a template for translating to other languages. (This directory
also contains some additional unsupported translations which may be
useful.)
Typically, your application's main() function will look like this:
\code
int main( int argc, char **argv )
{
QApplication app( argc, argv );
// translation file for Qt
QTranslator qt( 0 );
qt.load( TQString( "qt_" ) + TQTextCodec::locale(), "." );
app.installTranslator( &qt );
// translation file for application strings
QTranslator myapp( 0 );
myapp.load( TQString( "myapp_" ) + TQTextCodec::locale(), "." );
app.installTranslator( &myapp );
...
return app.exec();
}
\endcode
\section2 Support for Encodings
The TQTextCodec class and the facilities in TQTextStream make it easy to
support many input and output encodings for your users' data. When an
application starts, the locale of the machine will determine the 8-bit
encoding used when dealing with 8-bit data: such as for font
selection, text display, 8-bit text I/O and character input.
The application may occasionally require encodings other than the
default local 8-bit encoding. For example, an application in a
Cyrillic KOI8-R locale (the de-facto standard locale in Russia) might
need to output Cyrillic in the ISO 8859-5 encoding. Code for this
would be:
\code
TQString string = ...; // some Unicode text
TQTextCodec* codec = TQTextCodec::codecForName( "ISO 8859-5" );
TQCString encoded_string = codec->fromUnicode( string );
...; // use encoded_string in 8-bit operations
\endcode
For converting Unicode to local 8-bit encodings, a shortcut is
available: the \link TQString::local8Bit() local8Bit\endlink() method
of TQString returns such 8-bit data. Another useful shortcut is the
\link TQString::utf8() utf8\endlink() method, which returns text in the
8-bit UTF-8 encoding: this perfectly preserves Unicode information
while looking like plain US-ASCII if the text is wholly US-ASCII.
For converting the other way, there are the TQString::fromUtf8() and
TQString::fromLocal8Bit() convenience functions, or the general code,
demonstrated by this conversion from ISO 8859-5 Cyrillic to Unicode
conversion:
\code
TQCString encoded_string = ...; // Some ISO 8859-5 encoded text.
TQTextCodec* codec = TQTextCodec::codecForName("ISO 8859-5");
TQString string = codec->toUnicode(encoded_string);
...; // Use string in all of Qt's TQString operations.
\endcode
Ideally Unicode I/O should be used as this maximizes the portability
of documents between users around the world, but in reality it is
useful to support all the appropriate encodings that your users will
need to process existing documents. In general, Unicode (UTF-16 or
UTF-8) is best for information transferred between arbitrary people,
while within a language or national group, a local standard is often
more appropriate. The most important encoding to support is the one
returned by TQTextCodec::codecForLocale(), as this is the one the user
is most likely to need for communicating with other people and
applications (this is the codec used by local8Bit()).
Qt supports most of the more frequently used encodings natively. For a
complete list of supported encodings see the \l TQTextCodec
documentation.
In some cases and for less frequently used encodings it may be
necessary to write your own TQTextCodec subclass. Depending on the
urgency, it may be useful to contact Trolltech technical support or
ask on the \c qt-interest mailing list to see if someone else is
already working on supporting the encoding. A useful interim measure
can be to use the TQTextCodec::loadCharmapFile() function to build a
data-driven codec, although this approach has a memory and speed
penalty, especially with dynamically loaded libraries. For details of
writing your own TQTextCodec, see the main TQTextCodec class
documentation.
\keyword localization
\section2 Localize
Localization is the process of adapting to local conventions, for
example presenting dates and times using the locally preferred
formats. Such localizations can be accomplished using appropriate tr()
strings.
\code
void Clock::setTime(const TQTime& t)
{
if ( tr("AMPM") == "AMPM" ) {
// 12-hour clock
} else {
// 24-hour clock
}
}
\endcode
In the example, for the US we would leave the translation of "AMPM" as
it is and thereby use the 12-hour clock branch; but in Europe we would
translate it as something else (anything else, e.g. "EU") and this
will make the code use the 24-hour clock branch.
Localizing images is not recommended. Choose clear icons that are
appropriate for all localities, rather than relying on local puns or
stretched metaphors.
\section1 Dynamic Translation
Some applications, such as TQt Linguist, must be able to support changes
to the user's language settings while they are still running. To make
widgets aware of changes to the system language, implement a public
slot called \c languageChange() in each widget that needs to be notified.
In this slot, you should update the text displayed by widgets using the
\l{TQObject::tr()}{tr()} function in the usual way; for example:
\code
void MyWidget::languageChange()
{
titleLabel->setText(tr("Document Title"));
...
okPushButton->setText(tr("&OK"));
}
\endcode
The default event handler for TQWidget subclasses responds to the
\link QEvent::Type LanguageChange\endlink event, and will call this slot
when necessary; other application components can also connect signals
to this slot to force widgets to update themselves.
\section1 System Support
Some of the operating systems and windowing systems that TQt runs on
only have limited support for Unicode. The level of support available
in the underlying system has some influence on the support that TQt can
provide on those platforms, although in general TQt applications need
not be too concerned with platform-specific limitations.
\section2 Unix/X11
\list
\i Locale-oriented fonts and input methods. TQt hides these and
provides Unicode input and output.
\i Filesystem conventions such as
\link http://www.ietf.org/rfc/rfc2279.txt UTF-8 \endlink
are under development
in some Unix variants. All TQt file functions allow Unicode,
but convert filenames to the local 8-bit encoding, as
this is the Unix convention
(see TQFile::setEncodingFunction()
to explore alternative encodings).
\i File I/O defaults to the local 8-bit encoding,
with Unicode options in TQTextStream.
\endlist
\section2 Windows
\list
\i TQt provides full Unicode support, including input methods, fonts,
clipboard, drag-and-drop and file names.
\i File I/O defaults to Latin-1, with Unicode options in TQTextStream.
Note that some Windows programs do not understand big-endian
Unicode text files even though that is the order prescribed by
the Unicode Standard in the absence of higher-level protocols.
\i Unlike programs written with MFC or plain winlib, TQt programs
are portable between Windows 95/98 and Windows NT.
\e {You do not need different binaries to support Unicode.}
\endlist
\section1 Note about Locales on X11
Many Unix distributions contain only partial support for some locales.
For example, if you have a \c /usr/share/locale/ja_JP.EUC directory,
this does not necessarily mean you can display Japanese text; you also
need JIS encoded fonts (or Unicode fonts), and the \c
/usr/share/locale/ja_JP.EUC directory needs to be complete. For best
results, use complete locales from your system vendor.
\section1 Relevant TQt Classes
These classes are relevant to internationalizing TQt applications.
*/