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** Contact: Nokia Corporation (qt-info@nokia.com)
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** No Commercial Usage
** This file contains pre-release code and may not be distributed.
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** contained in the Technology Preview License Agreement accompanying
** this package.
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** General Public License version 2.1 as published by the Free Software
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#include "qplatformdefs.h"
#include "qstring.h"
#include "qvector.h"
#include "qlist.h"
#include "qthreadstorage.h"
#include "qdir.h"
#include "qstringlist.h"
#include "qdatetime.h"
#ifndef QT_NO_QOBJECT
#include <private/qthread_p.h>
#endif
#include <stdio.h>
#include <stdlib.h>
#include <limits.h>
#include <stdarg.h>
#include <string.h>
#if !defined(Q_OS_WINCE)
# include <errno.h>
# if defined(Q_CC_MSVC)
# include <crtdbg.h>
# endif
#endif
#if defined(Q_OS_VXWORKS)
# include <envLib.h>
#endif
#if defined(Q_CC_MWERKS) && defined(Q_OS_MACX)
#include <CoreServices/CoreServices.h>
#endif
#if defined(Q_OS_SYMBIAN)
#include <e32def.h>
#include <e32debug.h>
#include <flogger.h>
#include <f32file.h>
#include <e32math.h>
# include "private/qcore_symbian_p.h"
_LIT(qt_S60Filter, "Series60v?.*.sis");
_LIT(qt_S60SystemInstallDir, "z:\\system\\install\\");
#endif
QT_BEGIN_NAMESPACE
/*!
\class QFlag
\brief The QFlag class is a helper data type for QFlags.
It is equivalent to a plain \c int, except with respect to
function overloading and type conversions. You should never need
to use this class in your applications.
\sa QFlags
*/
/*!
\fn QFlag::QFlag(int value)
Constructs a QFlag object that stores the given \a value.
*/
/*!
\fn QFlag::operator int() const
Returns the value stored by the QFlag object.
*/
/*!
\class QFlags
\brief The QFlags class provides a type-safe way of storing
OR-combinations of enum values.
\ingroup tools
The QFlags<Enum> class is a template class, where Enum is an enum
type. QFlags is used throughout Qt for storing combinations of
enum values.
The traditional C++ approach for storing OR-combinations of enum
values is to use an \c int or \c uint variable. The inconvenience
with this approach is that there's no type checking at all; any
enum value can be OR'd with any other enum value and passed on to
a function that takes an \c int or \c uint.
Qt uses QFlags to provide type safety. For example, the
Qt::Alignment type is simply a typedef for
QFlags<Qt::AlignmentFlag>. QLabel::setAlignment() takes a
Qt::Alignment parameter, which means that any combination of
Qt::AlignmentFlag values,or 0, is legal:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 0
If you try to pass a value from another enum or just a plain
integer other than 0, the compiler will report an error. If you
need to cast integer values to flags in a untyped fashion, you can
use the explicit QFlags constructor as cast operator.
If you want to use QFlags for your own enum types, use
the Q_DECLARE_FLAGS() and Q_DECLARE_OPERATORS_FOR_FLAGS().
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 1
You can then use the \c MyClass::Options type to store
combinations of \c MyClass::Option values.
\section1 Flags and the Meta-Object System
The Q_DECLARE_FLAGS() macro does not expose the flags to the meta-object
system, so they cannot be used by Qt Script or edited in Qt Designer.
To make the flags available for these purposes, the Q_FLAGS() macro must
be used:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp meta-object flags
\section1 Naming Convention
A sensible naming convention for enum types and associated QFlags
types is to give a singular name to the enum type (e.g., \c
Option) and a plural name to the QFlags type (e.g., \c Options).
When a singular name is desired for the QFlags type (e.g., \c
Alignment), you can use \c Flag as the suffix for the enum type
(e.g., \c AlignmentFlag).
\sa QFlag
*/
/*!
\typedef QFlags::enum_type
Typedef for the Enum template type.
*/
/*!
\fn QFlags::QFlags(const QFlags &other)
Constructs a copy of \a other.
*/
/*!
\fn QFlags::QFlags(Enum flag)
Constructs a QFlags object storing the given \a flag.
*/
/*!
\fn QFlags::QFlags(Zero zero)
Constructs a QFlags object with no flags set. \a zero must be a
literal 0 value.
*/
/*!
\fn QFlags::QFlags(QFlag value)
Constructs a QFlags object initialized with the given integer \a
value.
The QFlag type is a helper type. By using it here instead of \c
int, we effectively ensure that arbitrary enum values cannot be
cast to a QFlags, whereas untyped enum values (i.e., \c int
values) can.
*/
/*!
\fn QFlags &QFlags::operator=(const QFlags &other)
Assigns \a other to this object and returns a reference to this
object.
*/
/*!
\fn QFlags &QFlags::operator&=(int mask)
Performs a bitwise AND operation with \a mask and stores the
result in this QFlags object. Returns a reference to this object.
\sa operator&(), operator|=(), operator^=()
*/
/*!
\fn QFlags &QFlags::operator&=(uint mask)
\overload
*/
/*!
\fn QFlags &QFlags::operator|=(QFlags other)
Performs a bitwise OR operation with \a other and stores the
result in this QFlags object. Returns a reference to this object.
\sa operator|(), operator&=(), operator^=()
*/
/*!
\fn QFlags &QFlags::operator|=(Enum other)
\overload
*/
/*!
\fn QFlags &QFlags::operator^=(QFlags other)
Performs a bitwise XOR operation with \a other and stores the
result in this QFlags object. Returns a reference to this object.
\sa operator^(), operator&=(), operator|=()
*/
/*!
\fn QFlags &QFlags::operator^=(Enum other)
\overload
*/
/*!
\fn QFlags::operator int() const
Returns the value stored in the QFlags object as an integer.
*/
/*!
\fn QFlags QFlags::operator|(QFlags other) const
Returns a QFlags object containing the result of the bitwise OR
operation on this object and \a other.
\sa operator|=(), operator^(), operator&(), operator~()
*/
/*!
\fn QFlags QFlags::operator|(Enum other) const
\overload
*/
/*!
\fn QFlags QFlags::operator^(QFlags other) const
Returns a QFlags object containing the result of the bitwise XOR
operation on this object and \a other.
\sa operator^=(), operator&(), operator|(), operator~()
*/
/*!
\fn QFlags QFlags::operator^(Enum other) const
\overload
*/
/*!
\fn QFlags QFlags::operator&(int mask) const
Returns a QFlags object containing the result of the bitwise AND
operation on this object and \a mask.
\sa operator&=(), operator|(), operator^(), operator~()
*/
/*!
\fn QFlags QFlags::operator&(uint mask) const
\overload
*/
/*!
\fn QFlags QFlags::operator&(Enum mask) const
\overload
*/
/*!
\fn QFlags QFlags::operator~() const
Returns a QFlags object that contains the bitwise negation of
this object.
\sa operator&(), operator|(), operator^()
*/
/*!
\fn bool QFlags::operator!() const
Returns true if no flag is set (i.e., if the value stored by the
QFlags object is 0); otherwise returns false.
*/
/*!
\fn bool QFlags::testFlag(Enum flag) const
\since 4.2
Returns true if the \a flag is set, otherwise false.
*/
/*!
\macro Q_DISABLE_COPY(Class)
\relates QObject
Disables the use of copy constructors and assignment operators
for the given \a Class.
Instances of subclasses of QObject should not be thought of as
values that can be copied or assigned, but as unique identities.
This means that when you create your own subclass of QObject
(director or indirect), you should \e not give it a copy constructor
or an assignment operator. However, it may not enough to simply
omit them from your class, because, if you mistakenly write some code
that requires a copy constructor or an assignment operator (it's easy
to do), your compiler will thoughtfully create it for you. You must
do more.
The curious user will have seen that the Qt classes derived
from QObject typically include this macro in a private section:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 43
It declares a copy constructor and an assignment operator in the
private section, so that if you use them by mistake, the compiler
will report an error.
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 44
But even this might not catch absolutely every case. You might be
tempted to do something like this:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 45
First of all, don't do that. Most compilers will generate code that
uses the copy constructor, so the privacy violation error will be
reported, but your C++ compiler is not required to generate code for
this statement in a specific way. It could generate code using
\e{neither} the copy constructor \e{nor} the assignment operator we
made private. In that case, no error would be reported, but your
application would probably crash when you called a member function
of \c{w}.
*/
/*!
\macro Q_DECLARE_FLAGS(Flags, Enum)
\relates QFlags
The Q_DECLARE_FLAGS() macro expands to
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 2
\a Enum is the name of an existing enum type, whereas \a Flags is
the name of the QFlags<\e{Enum}> typedef.
See the QFlags documentation for details.
\sa Q_DECLARE_OPERATORS_FOR_FLAGS()
*/
/*!
\macro Q_DECLARE_OPERATORS_FOR_FLAGS(Flags)
\relates QFlags
The Q_DECLARE_OPERATORS_FOR_FLAGS() macro declares global \c
operator|() functions for \a Flags, which is of type QFlags<T>.
See the QFlags documentation for details.
\sa Q_DECLARE_FLAGS()
*/
/*!
\headerfile <QtGlobal>
\title Global Qt Declarations
\ingroup funclists
\brief The <QtGlobal> header file includes the fundamental global
declarations. It is included by most other Qt header files.
The global declarations include \l{types}, \l{functions} and
\l{macros}.
The type definitions are partly convenience definitions for basic
types (some of which guarantee certain bit-sizes on all platforms
supported by Qt), partly types related to Qt message handling. The
functions are related to generating messages, Qt version handling
and comparing and adjusting object values. And finally, some of
the declared macros enable programmers to add compiler or platform
specific code to their applications, while others are convenience
macros for larger operations.
\section1 Types
The header file declares several type definitions that guarantee a
specified bit-size on all platforms supported by Qt for various
basic types, for example \l qint8 which is a signed char
guaranteed to be 8-bit on all platforms supported by Qt. The
header file also declares the \l qlonglong type definition for \c
{long long int } (\c __int64 on Windows).
Several convenience type definitions are declared: \l qreal for \c
double, \l uchar for \c unsigned char, \l uint for \c unsigned
int, \l ulong for \c unsigned long and \l ushort for \c unsigned
short.
Finally, the QtMsgType definition identifies the various messages
that can be generated and sent to a Qt message handler;
QtMsgHandler is a type definition for a pointer to a function with
the signature \c {void myMsgHandler(QtMsgType, const char *)}.
\section1 Functions
The <QtGlobal> header file contains several functions comparing
and adjusting an object's value. These functions take a template
type as argument: You can retrieve the absolute value of an object
using the qAbs() function, and you can bound a given object's
value by given minimum and maximum values using the qBound()
function. You can retrieve the minimum and maximum of two given
objects using qMin() and qMax() respectively. All these functions
return a corresponding template type; the template types can be
replaced by any other type.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 3
<QtGlobal> also contains functions that generate messages from the
given string argument: qCritical(), qDebug(), qFatal() and
qWarning(). These functions call the message handler with the
given message.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 4
The remaining functions are qRound() and qRound64(), which both
accept a \l qreal value as their argument returning the value
rounded up to the nearest integer and 64-bit integer respectively,
the qInstallMsgHandler() function which installs the given
QtMsgHandler, and the qVersion() function which returns the
version number of Qt at run-time as a string.
\section1 Macros
The <QtGlobal> header file provides a range of macros (Q_CC_*)
that are defined if the application is compiled using the
specified platforms. For example, the Q_CC_SUN macro is defined if
the application is compiled using Forte Developer, or Sun Studio
C++. The header file also declares a range of macros (Q_OS_*)
that are defined for the specified platforms. For example,
Q_OS_X11 which is defined for the X Window System.
The purpose of these macros is to enable programmers to add
compiler or platform specific code to their application.
The remaining macros are convenience macros for larger operations:
The QT_TRANSLATE_NOOP() and QT_TR_NOOP() macros provide the
possibility of marking text for dynamic translation,
i.e. translation without changing the stored source text. The
Q_ASSERT() and Q_ASSERT_X() enables warning messages of various
level of refinement. The Q_FOREACH() and foreach() macros
implement Qt's foreach loop.
The Q_INT64_C() and Q_UINT64_C() macros wrap signed and unsigned
64-bit integer literals in a platform-independent way. The
Q_CHECK_PTR() macro prints a warning containing the source code's
file name and line number, saying that the program ran out of
memory, if the pointer is 0. The qPrintable() macro represent an
easy way of printing text.
Finally, the QT_POINTER_SIZE macro expands to the size of a
pointer in bytes, and the QT_VERSION and QT_VERSION_STR macros
expand to a numeric value or a string, respectively, specifying
Qt's version number, i.e the version the application is compiled
against.
\sa <QtAlgorithms>, QSysInfo
*/
/*!
\typedef qreal
\relates <QtGlobal>
Typedef for \c double on all platforms except for those using CPUs with
ARM architectures.
On ARM-based platforms, \c qreal is a typedef for \c float for performance
reasons.
*/
/*! \typedef uchar
\relates <QtGlobal>
Convenience typedef for \c{unsigned char}.
*/
/*!
\fn qt_set_sequence_auto_mnemonic(bool on)
\relates <QtGlobal>
Enables automatic mnemonics on Mac if \a on is true; otherwise
this feature is disabled.
Note that this function is only available on Mac where mnemonics
are disabled by default.
To access to this function, use an extern declaration:
extern void qt_set_sequence_auto_mnemonic(bool b);
\sa {QShortcut#mnemonic}{QShortcut}
*/
/*! \typedef ushort
\relates <QtGlobal>
Convenience typedef for \c{unsigned short}.
*/
/*! \typedef uint
\relates <QtGlobal>
Convenience typedef for \c{unsigned int}.
*/
/*! \typedef ulong
\relates <QtGlobal>
Convenience typedef for \c{unsigned long}.
*/
/*! \typedef qint8
\relates <QtGlobal>
Typedef for \c{signed char}. This type is guaranteed to be 8-bit
on all platforms supported by Qt.
*/
/*!
\typedef quint8
\relates <QtGlobal>
Typedef for \c{unsigned char}. This type is guaranteed to
be 8-bit on all platforms supported by Qt.
*/
/*! \typedef qint16
\relates <QtGlobal>
Typedef for \c{signed short}. This type is guaranteed to be
16-bit on all platforms supported by Qt.
*/
/*!
\typedef quint16
\relates <QtGlobal>
Typedef for \c{unsigned short}. This type is guaranteed to
be 16-bit on all platforms supported by Qt.
*/
/*! \typedef qint32
\relates <QtGlobal>
Typedef for \c{signed int}. This type is guaranteed to be 32-bit
on all platforms supported by Qt.
*/
/*!
\typedef quint32
\relates <QtGlobal>
Typedef for \c{unsigned int}. This type is guaranteed to
be 32-bit on all platforms supported by Qt.
*/
/*! \typedef qint64
\relates <QtGlobal>
Typedef for \c{long long int} (\c __int64 on Windows). This type
is guaranteed to be 64-bit on all platforms supported by Qt.
Literals of this type can be created using the Q_INT64_C() macro:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 5
\sa Q_INT64_C(), quint64, qlonglong
*/
/*!
\typedef quint64
\relates <QtGlobal>
Typedef for \c{unsigned long long int} (\c{unsigned __int64} on
Windows). This type is guaranteed to be 64-bit on all platforms
supported by Qt.
Literals of this type can be created using the Q_UINT64_C()
macro:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 6
\sa Q_UINT64_C(), qint64, qulonglong
*/
/*!
\typedef quintptr
\relates <QtGlobal>
Integral type for representing a pointers (useful for hashing,
etc.).
Typedef for either quint32 or quint64. This type is guaranteed to
be the same size as a pointer on all platforms supported by Qt. On
a system with 32-bit pointers, quintptr is a typedef for quint32;
on a system with 64-bit pointers, quintptr is a typedef for
quint64.
Note that quintptr is unsigned. Use qptrdiff for signed values.
\sa qptrdiff, quint32, quint64
*/
/*!
\typedef qptrdiff
\relates <QtGlobal>
Integral type for representing pointer differences.
Typedef for either qint32 or qint64. This type is guaranteed to be
the same size as a pointer on all platforms supported by Qt. On a
system with 32-bit pointers, quintptr is a typedef for quint32; on
a system with 64-bit pointers, quintptr is a typedef for quint64.
Note that qptrdiff is signed. Use quintptr for unsigned values.
\sa quintptr, qint32, qint64
*/
/*!
\typedef QtMsgHandler
\relates <QtGlobal>
This is a typedef for a pointer to a function with the following
signature:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 7
\sa QtMsgType, qInstallMsgHandler()
*/
/*!
\enum QtMsgType
\relates <QtGlobal>
This enum describes the messages that can be sent to a message
handler (QtMsgHandler). You can use the enum to identify and
associate the various message types with the appropriate
actions.
\value QtDebugMsg
A message generated by the qDebug() function.
\value QtWarningMsg
A message generated by the qWarning() function.
\value QtCriticalMsg
A message generated by the qCritical() function.
\value QtFatalMsg
A message generated by the qFatal() function.
\value QtSystemMsg
\sa QtMsgHandler, qInstallMsgHandler()
*/
/*! \macro qint64 Q_INT64_C(literal)
\relates <QtGlobal>
Wraps the signed 64-bit integer \a literal in a
platform-independent way.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 8
\sa qint64, Q_UINT64_C()
*/
/*! \macro quint64 Q_UINT64_C(literal)
\relates <QtGlobal>
Wraps the unsigned 64-bit integer \a literal in a
platform-independent way.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 9
\sa quint64, Q_INT64_C()
*/
/*! \typedef qlonglong
\relates <QtGlobal>
Typedef for \c{long long int} (\c __int64 on Windows). This is
the same as \l qint64.
\sa qulonglong, qint64
*/
/*!
\typedef qulonglong
\relates <QtGlobal>
Typedef for \c{unsigned long long int} (\c{unsigned __int64} on
Windows). This is the same as \l quint64.
\sa quint64, qlonglong
*/
/*! \fn const T &qAbs(const T &value)
\relates <QtGlobal>
Compares \a value to the 0 of type T and returns the absolute
value. Thus if T is \e {double}, then \a value is compared to
\e{(double) 0}.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 10
*/
/*! \fn int qRound(qreal value)
\relates <QtGlobal>
Rounds \a value to the nearest integer.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 11
*/
/*! \fn qint64 qRound64(qreal value)
\relates <QtGlobal>
Rounds \a value to the nearest 64-bit integer.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 12
*/
/*! \fn const T &qMin(const T &value1, const T &value2)
\relates <QtGlobal>
Returns the minimum of \a value1 and \a value2.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 13
\sa qMax(), qBound()
*/
/*! \fn const T &qMax(const T &value1, const T &value2)
\relates <QtGlobal>
Returns the maximum of \a value1 and \a value2.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 14
\sa qMin(), qBound()
*/
/*! \fn const T &qBound(const T &min, const T &value, const T &max)
\relates <QtGlobal>
Returns \a value bounded by \a min and \a max. This is equivalent
to qMax(\a min, qMin(\a value, \a max)).
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 15
\sa qMin(), qMax()
*/
/*!
\typedef Q_INT8
\relates <QtGlobal>
\compat
Use \l qint8 instead.
*/
/*!
\typedef Q_UINT8
\relates <QtGlobal>
\compat
Use \l quint8 instead.
*/
/*!
\typedef Q_INT16
\relates <QtGlobal>
\compat
Use \l qint16 instead.
*/
/*!
\typedef Q_UINT16
\relates <QtGlobal>
\compat
Use \l quint16 instead.
*/
/*!
\typedef Q_INT32
\relates <QtGlobal>
\compat
Use \l qint32 instead.
*/
/*!
\typedef Q_UINT32
\relates <QtGlobal>
\compat
Use \l quint32 instead.
*/
/*!
\typedef Q_INT64
\relates <QtGlobal>
\compat
Use \l qint64 instead.
*/
/*!
\typedef Q_UINT64
\relates <QtGlobal>
\compat
Use \l quint64 instead.
*/
/*!
\typedef Q_LLONG
\relates <QtGlobal>
\compat
Use \l qint64 instead.
*/
/*!
\typedef Q_ULLONG
\relates <QtGlobal>
\compat
Use \l quint64 instead.
*/
/*!
\typedef Q_LONG
\relates <QtGlobal>
\compat
Use \c{void *} instead.
*/
/*!
\typedef Q_ULONG
\relates <QtGlobal>
\compat
Use \c{void *} instead.
*/
/*! \fn bool qSysInfo(int *wordSize, bool *bigEndian)
\relates <QtGlobal>
Use QSysInfo::WordSize and QSysInfo::ByteOrder instead.
*/
/*!
\fn bool qt_winUnicode()
\relates <QtGlobal>
This function always returns true.
\sa QSysInfo
*/
/*!
\fn int qWinVersion()
\relates <QtGlobal>
Use QSysInfo::WindowsVersion instead.
\sa QSysInfo
*/
/*!
\fn int qMacVersion()
\relates <QtGlobal>
Use QSysInfo::MacintoshVersion instead.
\sa QSysInfo
*/
/*!
\macro QT_VERSION_CHECK
\relates <QtGlobal>
Turns the major, minor and patch numbers of a version into an
integer, 0xMMNNPP (MM = major, NN = minor, PP = patch). This can
be compared with another similarly processed version id.
\sa QT_VERSION
*/
/*!
\macro QT_VERSION
\relates <QtGlobal>
This macro expands a numeric value of the form 0xMMNNPP (MM =
major, NN = minor, PP = patch) that specifies Qt's version
number. For example, if you compile your application against Qt
4.1.2, the QT_VERSION macro will expand to 0x040102.
You can use QT_VERSION to use the latest Qt features where
available.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 16
\sa QT_VERSION_STR, qVersion()
*/
/*!
\macro QT_VERSION_STR
\relates <QtGlobal>
This macro expands to a string that specifies Qt's version number
(for example, "4.1.2"). This is the version against which the
application is compiled.
\sa qVersion(), QT_VERSION
*/
/*!
\relates <QtGlobal>
Returns the version number of Qt at run-time as a string (for
example, "4.1.2"). This may be a different version than the
version the application was compiled against.
\sa QT_VERSION_STR
*/
const char *qVersion()
{
return QT_VERSION_STR;
}
bool qSharedBuild()
{
#ifdef QT_SHARED
return true;
#else
return false;
#endif
}
/*****************************************************************************
System detection routines
*****************************************************************************/
/*!
\class QSysInfo
\brief The QSysInfo class provides information about the system.
\list
\o \l WordSize specifies the size of a pointer for the platform
on which the application is compiled.
\o \l ByteOrder specifies whether the platform is big-endian or
little-endian.
\o \l WindowsVersion specifies the version of the Windows operating
system on which the application is run (Windows only)
\o \l MacintoshVersion specifies the version of the Macintosh
operating system on which the application is run (Mac only).
\endlist
Some constants are defined only on certain platforms. You can use
the preprocessor symbols Q_WS_WIN and Q_WS_MAC to test that
the application is compiled under Windows or Mac.
\sa QLibraryInfo
*/
/*!
\enum QSysInfo::Sizes
This enum provides platform-specific information about the sizes of data
structures used by the underlying architecture.
\value WordSize The size in bits of a pointer for the platform on which
the application is compiled (32 or 64).
*/
/*!
\variable QSysInfo::WindowsVersion
\brief the version of the Windows operating system on which the
application is run (Windows only)
*/
/*!
\fn QSysInfo::WindowsVersion QSysInfo::windowsVersion()
\since 4.4
Returns the version of the Windows operating system on which the
application is run (Windows only).
*/
/*!
\variable QSysInfo::MacintoshVersion
\brief the version of the Macintosh operating system on which
the application is run (Mac only).
*/
/*!
\fn QSysInfo::SymbianVersion QSysInfo::symbianVersion()
\since 4.6
Returns the version of the Symbian operating system on which the
application is run (Symbian only).
*/
/*!
\fn QSysInfo::S60Version QSysInfo::s60Version()
\since 4.6
Returns the version of the S60 SDK system on which the
application is run (S60 only).
*/
/*!
\enum QSysInfo::Endian
\value BigEndian Big-endian byte order (also called Network byte order)
\value LittleEndian Little-endian byte order
\value ByteOrder Equals BigEndian or LittleEndian, depending on
the platform's byte order.
*/
/*!
\enum QSysInfo::WinVersion
This enum provides symbolic names for the various versions of the
Windows operating system. On Windows, the
QSysInfo::WindowsVersion variable gives the version of the system
on which the application is run.
MS-DOS-based versions:
\value WV_32s Windows 3.1 with Win 32s
\value WV_95 Windows 95
\value WV_98 Windows 98
\value WV_Me Windows Me
NT-based versions (note that each operating system version is only represented once rather than each Windows edition):
\value WV_NT Windows NT (operating system version 4.0)
\value WV_2000 Windows 2000 (operating system version 5.0)
\value WV_XP Windows XP (operating system version 5.1)
\value WV_2003 Windows Server 2003, Windows Server 2003 R2, Windows Home Server, Windows XP Professional x64 Edition (operating system version 5.2)
\value WV_VISTA Windows Vista, Windows Server 2008 (operating system version 6.0)
\value WV_WINDOWS7 Windows 7, Windows Server 2008 R2 (operating system version 6.1)
Alternatively, you may use the following macros which correspond directly to the Windows operating system version number:
\value WV_4_0 Operating system version 4.0, corresponds to Windows NT
\value WV_5_0 Operating system version 5.0, corresponds to Windows 2000
\value WV_5_1 Operating system version 5.1, corresponds to Windows XP
\value WV_5_2 Operating system version 5.2, corresponds to Windows Server 2003, Windows Server 2003 R2, Windows Home Server, and Windows XP Professional x64 Edition
\value WV_6_0 Operating system version 6.0, corresponds to Windows Vista and Windows Server 2008
\value WV_6_1 Operating system version 6.1, corresponds to Windows 7 and Windows Server 2008 R2
CE-based versions:
\value WV_CE Windows CE
\value WV_CENET Windows CE .NET
\value WV_CE_5 Windows CE 5.x
\value WV_CE_6 Windows CE 6.x
The following masks can be used for testing whether a Windows
version is MS-DOS-based, NT-based, or CE-based:
\value WV_DOS_based MS-DOS-based version of Windows
\value WV_NT_based NT-based version of Windows
\value WV_CE_based CE-based version of Windows
\sa MacVersion, SymbianVersion
*/
/*!
\enum QSysInfo::MacVersion
This enum provides symbolic names for the various versions of the
Macintosh operating system. On Mac, the
QSysInfo::MacintoshVersion variable gives the version of the
system on which the application is run.
\value MV_9 Mac OS 9 (unsupported)
\value MV_10_0 Mac OS X 10.0 (unsupported)
\value MV_10_1 Mac OS X 10.1 (unsupported)
\value MV_10_2 Mac OS X 10.2 (unsupported)
\value MV_10_3 Mac OS X 10.3
\value MV_10_4 Mac OS X 10.4
\value MV_10_5 Mac OS X 10.5
\value MV_10_6 Mac OS X 10.6
\value MV_Unknown An unknown and currently unsupported platform
\value MV_CHEETAH Apple codename for MV_10_0
\value MV_PUMA Apple codename for MV_10_1
\value MV_JAGUAR Apple codename for MV_10_2
\value MV_PANTHER Apple codename for MV_10_3
\value MV_TIGER Apple codename for MV_10_4
\value MV_LEOPARD Apple codename for MV_10_5
\value MV_SNOWLEOPARD Apple codename for MV_10_6
\sa WinVersion, SymbianVersion
*/
/*!
\enum QSysInfo::SymbianVersion
This enum provides symbolic names for the various versions of the
Symbian operating system. On Symbian, the
QSysInfo::symbianVersion() function gives the version of the
system on which the application is run.
\value SV_9_2 Symbian OS v9.2
\value SV_9_3 Symbian OS v9.3
\value SV_9_4 Symbian OS v9.4
\value SV_SF_1 Symbian^1
\value SV_SF_2 Symbian^2
\value SV_SF_3 Symbian^3
\value SV_SF_4 Symbian^4
\value SV_Unknown An unknown and currently unsupported platform
\sa S60Version, WinVersion, MacVersion
*/
/*!
\enum QSysInfo::S60Version
This enum provides symbolic names for the various versions of the
S60 SDK. On S60, the
QSysInfo::s60Version() function gives the version of the
SDK on which the application is run.
\value SV_S60_3_1 S60 3rd Edition Feature Pack 1
\value SV_S60_3_2 S60 3rd Edition Feature Pack 2
\value SV_S60_5_0 S60 5th Edition
\value SV_S60_5_1 S60 5th Edition Feature Pack 1
\value SV_S60_5_2 S60 5th Edition Feature Pack 2
\value SV_S60_Unknown An unknown and currently unsupported platform
\omitvalue SV_S60_None
\sa SymbianVersion, WinVersion, MacVersion
*/
/*!
\macro Q_WS_MAC
\relates <QtGlobal>
Defined on Mac OS X.
\sa Q_WS_WIN, Q_WS_X11, Q_WS_QWS, Q_WS_S60
*/
/*!
\macro Q_WS_WIN
\relates <QtGlobal>
Defined on Windows.
\sa Q_WS_MAC, Q_WS_X11, Q_WS_QWS, Q_WS_S60
*/
/*!
\macro Q_WS_X11
\relates <QtGlobal>
Defined on X11.
\sa Q_WS_MAC, Q_WS_WIN, Q_WS_QWS, Q_WS_S60
*/
/*!
\macro Q_WS_QWS
\relates <QtGlobal>
Defined on Qt for Embedded Linux.
\sa Q_WS_MAC, Q_WS_WIN, Q_WS_X11, Q_WS_S60
*/
/*!
\macro Q_OS_DARWIN
\relates <QtGlobal>
Defined on Darwin OS (synonym for Q_OS_MAC).
*/
/*!
\macro Q_OS_MSDOS
\relates <QtGlobal>
Defined on MS-DOS and Windows.
*/
/*!
\macro Q_OS_OS2
\relates <QtGlobal>
Defined on OS/2.
*/
/*!
\macro Q_OS_OS2EMX
\relates <QtGlobal>
Defined on XFree86 on OS/2 (not PM).
*/
/*!
\macro Q_OS_WIN32
\relates <QtGlobal>
Defined on all supported versions of Windows.
*/
/*!
\macro Q_OS_WINCE
\relates <QtGlobal>
Defined on Windows CE.
*/
/*!
\macro Q_OS_CYGWIN
\relates <QtGlobal>
Defined on Cygwin.
*/
/*!
\macro Q_OS_SOLARIS
\relates <QtGlobal>
Defined on Sun Solaris.
*/
/*!
\macro Q_OS_HPUX
\relates <QtGlobal>
Defined on HP-UX.
*/
/*!
\macro Q_OS_ULTRIX
\relates <QtGlobal>
Defined on DEC Ultrix.
*/
/*!
\macro Q_OS_LINUX
\relates <QtGlobal>
Defined on Linux.
*/
/*!
\macro Q_OS_FREEBSD
\relates <QtGlobal>
Defined on FreeBSD.
*/
/*!
\macro Q_OS_NETBSD
\relates <QtGlobal>
Defined on NetBSD.
*/
/*!
\macro Q_OS_OPENBSD
\relates <QtGlobal>
Defined on OpenBSD.
*/
/*!
\macro Q_OS_BSDI
\relates <QtGlobal>
Defined on BSD/OS.
*/
/*!
\macro Q_OS_IRIX
\relates <QtGlobal>
Defined on SGI Irix.
*/
/*!
\macro Q_OS_OSF
\relates <QtGlobal>
Defined on HP Tru64 UNIX.
*/
/*!
\macro Q_OS_SCO
\relates <QtGlobal>
Defined on SCO OpenServer 5.
*/
/*!
\macro Q_OS_UNIXWARE
\relates <QtGlobal>
Defined on UnixWare 7, Open UNIX 8.
*/
/*!
\macro Q_OS_AIX
\relates <QtGlobal>
Defined on AIX.
*/
/*!
\macro Q_OS_HURD
\relates <QtGlobal>
Defined on GNU Hurd.
*/
/*!
\macro Q_OS_DGUX
\relates <QtGlobal>
Defined on DG/UX.
*/
/*!
\macro Q_OS_RELIANT
\relates <QtGlobal>
Defined on Reliant UNIX.
*/
/*!
\macro Q_OS_DYNIX
\relates <QtGlobal>
Defined on DYNIX/ptx.
*/
/*!
\macro Q_OS_QNX
\relates <QtGlobal>
Defined on QNX Neutrino.
*/
/*!
\macro Q_OS_LYNX
\relates <QtGlobal>
Defined on LynxOS.
*/
/*!
\macro Q_OS_BSD4
\relates <QtGlobal>
Defined on Any BSD 4.4 system.
*/
/*!
\macro Q_OS_UNIX
\relates <QtGlobal>
Defined on Any UNIX BSD/SYSV system.
*/
/*!
\macro Q_CC_SYM
\relates <QtGlobal>
Defined if the application is compiled using Digital Mars C/C++
(used to be Symantec C++).
*/
/*!
\macro Q_CC_MWERKS
\relates <QtGlobal>
Defined if the application is compiled using Metrowerks
CodeWarrior.
*/
/*!
\macro Q_CC_MSVC
\relates <QtGlobal>
Defined if the application is compiled using Microsoft Visual
C/C++, Intel C++ for Windows.
*/
/*!
\macro Q_CC_BOR
\relates <QtGlobal>
Defined if the application is compiled using Borland/Turbo C++.
*/
/*!
\macro Q_CC_WAT
\relates <QtGlobal>
Defined if the application is compiled using Watcom C++.
*/
/*!
\macro Q_CC_GNU
\relates <QtGlobal>
Defined if the application is compiled using GNU C++.
*/
/*!
\macro Q_CC_COMEAU
\relates <QtGlobal>
Defined if the application is compiled using Comeau C++.
*/
/*!
\macro Q_CC_EDG
\relates <QtGlobal>
Defined if the application is compiled using Edison Design Group
C++.
*/
/*!
\macro Q_CC_OC
\relates <QtGlobal>
Defined if the application is compiled using CenterLine C++.
*/
/*!
\macro Q_CC_SUN
\relates <QtGlobal>
Defined if the application is compiled using Forte Developer, or
Sun Studio C++.
*/
/*!
\macro Q_CC_MIPS
\relates <QtGlobal>
Defined if the application is compiled using MIPSpro C++.
*/
/*!
\macro Q_CC_DEC
\relates <QtGlobal>
Defined if the application is compiled using DEC C++.
*/
/*!
\macro Q_CC_HPACC
\relates <QtGlobal>
Defined if the application is compiled using HP aC++.
*/
/*!
\macro Q_CC_USLC
\relates <QtGlobal>
Defined if the application is compiled using SCO OUDK and UDK.
*/
/*!
\macro Q_CC_CDS
\relates <QtGlobal>
Defined if the application is compiled using Reliant C++.
*/
/*!
\macro Q_CC_KAI
\relates <QtGlobal>
Defined if the application is compiled using KAI C++.
*/
/*!
\macro Q_CC_INTEL
\relates <QtGlobal>
Defined if the application is compiled using Intel C++ for Linux,
Intel C++ for Windows.
*/
/*!
\macro Q_CC_HIGHC
\relates <QtGlobal>
Defined if the application is compiled using MetaWare High C/C++.
*/
/*!
\macro Q_CC_PGI
\relates <QtGlobal>
Defined if the application is compiled using Portland Group C++.
*/
/*!
\macro Q_CC_GHS
\relates <QtGlobal>
Defined if the application is compiled using Green Hills
Optimizing C++ Compilers.
*/
/*!
\macro Q_OS_MAC
\relates <QtGlobal>
Defined on MAC OS (synonym for Darwin).
*/
/*!
\macro Q_OS_SYMBIAN
\relates <QtGlobal>
Defined on Symbian.
*/
/*!
\macro Q_WS_S60
\relates <QtGlobal>
Defined on S60.
\sa Q_WS_MAC, Q_WS_WIN, Q_WS_X11, Q_WS_QWS
*/
#if defined(QT_BUILD_QMAKE)
// needed to bootstrap qmake
static const unsigned int qt_one = 1;
const int QSysInfo::ByteOrder = ((*((unsigned char *) &qt_one) == 0) ? BigEndian : LittleEndian);
#endif
#if !defined(QWS) && defined(Q_OS_MAC)
QT_BEGIN_INCLUDE_NAMESPACE
#include "private/qcore_mac_p.h"
#include "qnamespace.h"
QT_END_INCLUDE_NAMESPACE
Q_CORE_EXPORT OSErr qt_mac_create_fsref(const QString &file, FSRef *fsref)
{
return FSPathMakeRef(reinterpret_cast<const UInt8 *>(file.toUtf8().constData()), fsref, 0);
}
// Don't use this function, it won't work in 10.5 (Leopard) and up
Q_CORE_EXPORT OSErr qt_mac_create_fsspec(const QString &file, FSSpec *spec)
{
FSRef fsref;
OSErr ret = qt_mac_create_fsref(file, &fsref);
if (ret == noErr)
ret = FSGetCatalogInfo(&fsref, kFSCatInfoNone, 0, 0, spec, 0);
return ret;
}
Q_CORE_EXPORT void qt_mac_to_pascal_string(QString s, Str255 str, TextEncoding encoding=0, int len=-1)
{
if(len == -1)
len = s.length();
#if 0
UnicodeMapping mapping;
mapping.unicodeEncoding = CreateTextEncoding(kTextEncodingUnicodeDefault,
kTextEncodingDefaultVariant,
kUnicode16BitFormat);
mapping.otherEncoding = (encoding ? encoding : );
mapping.mappingVersion = kUnicodeUseLatestMapping;
UnicodeToTextInfo info;
OSStatus err = CreateUnicodeToTextInfo(&mapping, &info);
if(err != noErr) {
qDebug("Qt: internal: Unable to create pascal string '%s'::%d [%ld]",
s.left(len).latin1(), (int)encoding, err);
return;
}
const int unilen = len * 2;
const UniChar *unibuf = (UniChar *)s.unicode();
ConvertFromUnicodeToPString(info, unilen, unibuf, str);
DisposeUnicodeToTextInfo(&info);
#else
Q_UNUSED(encoding);
CFStringGetPascalString(QCFString(s), str, 256, CFStringGetSystemEncoding());
#endif
}
Q_CORE_EXPORT QString qt_mac_from_pascal_string(const Str255 pstr) {
return QCFString(CFStringCreateWithPascalString(0, pstr, CFStringGetSystemEncoding()));
}
static QSysInfo::MacVersion macVersion()
{
SInt32 gestalt_version;
if (Gestalt(gestaltSystemVersion, &gestalt_version) == noErr) {
return QSysInfo::MacVersion(((gestalt_version & 0x00F0) >> 4) + 2);
}
return QSysInfo::MV_Unknown;
}
const QSysInfo::MacVersion QSysInfo::MacintoshVersion = macVersion();
#elif defined(Q_OS_WIN32) || defined(Q_OS_CYGWIN) || defined(Q_OS_WINCE)
QT_BEGIN_INCLUDE_NAMESPACE
#include "qt_windows.h"
QT_END_INCLUDE_NAMESPACE
QSysInfo::WinVersion QSysInfo::windowsVersion()
{
#ifndef VER_PLATFORM_WIN32s
#define VER_PLATFORM_WIN32s 0
#endif
#ifndef VER_PLATFORM_WIN32_WINDOWS
#define VER_PLATFORM_WIN32_WINDOWS 1
#endif
#ifndef VER_PLATFORM_WIN32_NT
#define VER_PLATFORM_WIN32_NT 2
#endif
#ifndef VER_PLATFORM_WIN32_CE
#define VER_PLATFORM_WIN32_CE 3
#endif
static QSysInfo::WinVersion winver;
if (winver)
return winver;
winver = QSysInfo::WV_NT;
OSVERSIONINFOW osver;
osver.dwOSVersionInfoSize = sizeof(osver);
GetVersionEx(&osver);
#ifdef Q_OS_WINCE
DWORD qt_cever = 0;
qt_cever = osver.dwMajorVersion * 100;
qt_cever += osver.dwMinorVersion * 10;
#endif
switch (osver.dwPlatformId) {
case VER_PLATFORM_WIN32s:
winver = QSysInfo::WV_32s;
break;
case VER_PLATFORM_WIN32_WINDOWS:
// We treat Windows Me (minor 90) the same as Windows 98
if (osver.dwMinorVersion == 90)
winver = QSysInfo::WV_Me;
else if (osver.dwMinorVersion == 10)
winver = QSysInfo::WV_98;
else
winver = QSysInfo::WV_95;
break;
#ifdef Q_OS_WINCE
case VER_PLATFORM_WIN32_CE:
if (qt_cever >= 600)
winver = QSysInfo::WV_CE_6;
if (qt_cever >= 500)
winver = QSysInfo::WV_CE_5;
else if (qt_cever >= 400)
winver = QSysInfo::WV_CENET;
else
winver = QSysInfo::WV_CE;
break;
#endif
default: // VER_PLATFORM_WIN32_NT
if (osver.dwMajorVersion < 5) {
winver = QSysInfo::WV_NT;
} else if (osver.dwMajorVersion == 5 && osver.dwMinorVersion == 0) {
winver = QSysInfo::WV_2000;
} else if (osver.dwMajorVersion == 5 && osver.dwMinorVersion == 1) {
winver = QSysInfo::WV_XP;
} else if (osver.dwMajorVersion == 5 && osver.dwMinorVersion == 2) {
winver = QSysInfo::WV_2003;
} else if (osver.dwMajorVersion == 6 && osver.dwMinorVersion == 0) {
winver = QSysInfo::WV_VISTA;
} else if (osver.dwMajorVersion == 6 && osver.dwMinorVersion == 1) {
winver = QSysInfo::WV_WINDOWS7;
} else {
qWarning("Qt: Untested Windows version %d.%d detected!",
int(osver.dwMajorVersion), int(osver.dwMinorVersion));
winver = QSysInfo::WV_NT_based;
}
}
#ifdef QT_DEBUG
{
QByteArray override = qgetenv("QT_WINVER_OVERRIDE");
if (override.isEmpty())
return winver;
if (override == "Me")
winver = QSysInfo::WV_Me;
if (override == "95")
winver = QSysInfo::WV_95;
else if (override == "98")
winver = QSysInfo::WV_98;
else if (override == "NT")
winver = QSysInfo::WV_NT;
else if (override == "2000")
winver = QSysInfo::WV_2000;
else if (override == "2003")
winver = QSysInfo::WV_2003;
else if (override == "XP")
winver = QSysInfo::WV_XP;
else if (override == "VISTA")
winver = QSysInfo::WV_VISTA;
else if (override == "WINDOWS7")
winver = QSysInfo::WV_WINDOWS7;
}
#endif
return winver;
}
const QSysInfo::WinVersion QSysInfo::WindowsVersion = QSysInfo::windowsVersion();
#endif
#ifdef Q_OS_SYMBIAN
# ifdef Q_WS_S60
static QSysInfo::S60Version cachedS60Version = QSysInfo::S60Version(-1);
QSysInfo::S60Version QSysInfo::s60Version()
{
if (cachedS60Version != -1)
return cachedS60Version;
// Use pure Symbian code, because if done using QDir, there will be a call back
// to this method, resulting doing this expensive operation twice before the cache kicks in.
// Pure Symbian code also makes this method ~10x faster, speeding up the application launch.
RFs rfs = qt_s60GetRFs();
TFindFile fileFinder(rfs);
CDir* contents;
TInt err = fileFinder.FindWildByDir(qt_S60Filter, qt_S60SystemInstallDir, contents);
if (err == KErrNone) {
err = contents->Sort(EDescending|ESortByName);
if (err == KErrNone && contents->Count() > 0 && (*contents)[0].iName.Length() >= 12) {
TInt major = (*contents)[0].iName[9] - '0';
TInt minor = (*contents)[0].iName[11] - '0';
if (major == 3) {
if (minor == 1) {
return cachedS60Version = SV_S60_3_1;
} else if (minor == 2) {
return cachedS60Version = SV_S60_3_2;
}
} else if (major == 5) {
if (minor == 0) {
return cachedS60Version = SV_S60_5_0;
}
else if (minor == 1) {
return cachedS60Version = SV_S60_5_1;
}
else if (minor == 2) {
return cachedS60Version = SV_S60_5_2;
}
}
}
delete contents;
}
# ifdef Q_CC_NOKIAX86
// Some emulator environments may not contain the version specific .sis files, so
// simply hardcode the version on those environments.
# if defined(__SERIES60_31__)
return cachedS60Version = SV_S60_3_1;
# elif defined(__S60_32__)
return cachedS60Version = SV_S60_3_2;
# elif defined(__S60_50__)
return cachedS60Version = SV_S60_5_0;
# endif
# endif
//If reaching here, it was not possible to determine the version
return cachedS60Version = SV_S60_Unknown;
}
QSysInfo::SymbianVersion QSysInfo::symbianVersion()
{
switch (s60Version()) {
case SV_S60_3_1:
return SV_9_2;
case SV_S60_3_2:
return SV_9_3;
case SV_S60_5_0:
return SV_9_4;
case SV_S60_5_1:
return SV_9_4;
case SV_S60_5_2:
return SV_9_4;
default:
return SV_Unknown;
}
}
#else
QSysInfo::S60Version QSysInfo::s60Version()
{
return SV_S60_None;
}
QSysInfo::SymbianVersion QSysInfo::symbianVersion()
{
return SV_Unknown;
}
# endif // ifdef Q_WS_S60
#endif // ifdef Q_OS_SYMBIAN
/*!
\macro void Q_ASSERT(bool test)
\relates <QtGlobal>
Prints a warning message containing the source code file name and
line number if \a test is false.
Q_ASSERT() is useful for testing pre- and post-conditions
during development. It does nothing if \c QT_NO_DEBUG was defined
during compilation.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 17
If \c b is zero, the Q_ASSERT statement will output the following
message using the qFatal() function:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 18
\sa Q_ASSERT_X(), qFatal(), {Debugging Techniques}
*/
/*!
\macro void Q_ASSERT_X(bool test, const char *where, const char *what)
\relates <QtGlobal>
Prints the message \a what together with the location \a where,
the source file name and line number if \a test is false.
Q_ASSERT_X is useful for testing pre- and post-conditions during
development. It does nothing if \c QT_NO_DEBUG was defined during
compilation.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 19
If \c b is zero, the Q_ASSERT_X statement will output the following
message using the qFatal() function:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 20
\sa Q_ASSERT(), qFatal(), {Debugging Techniques}
*/
/*!
\macro void Q_CHECK_PTR(void *pointer)
\relates <QtGlobal>
If \a pointer is 0, prints a warning message containing the source
code's file name and line number, saying that the program ran out
of memory.
Q_CHECK_PTR does nothing if \c QT_NO_DEBUG was defined during
compilation.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 21
\sa qWarning(), {Debugging Techniques}
*/
/*!
\fn T *q_check_ptr(T *pointer)
\relates <QtGlobal>
Users Q_CHECK_PTR on \a pointer, then returns \a pointer.
This can be used as an inline version of Q_CHECK_PTR.
*/
/*!
\macro const char* Q_FUNC_INFO()
\relates <QtGlobal>
Expands to a string that describe the function the macro resides in. How this string looks
more specifically is compiler dependent. With GNU GCC it is typically the function signature,
while with other compilers it might be the line and column number.
Q_FUNC_INFO can be conveniently used with qDebug(). For example, this function:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 22
when instantiated with the integer type, will with the GCC compiler produce:
\tt{const TInputType& myMin(const TInputType&, const TInputType&) [with TInputType = int] was called with value1: 3 value2: 4}
If this macro is used outside a function, the behavior is undefined.
*/
/*
The Q_CHECK_PTR macro calls this function if an allocation check
fails.
*/
void qt_check_pointer(const char *n, int l)
{
qWarning("In file %s, line %d: Out of memory", n, l);
}
/* \internal
Allows you to throw an exception without including <new>
Called internally from Q_CHECK_PTR on certain OS combinations
*/
void qBadAlloc()
{
QT_THROW(std::bad_alloc());
}
/*
The Q_ASSERT macro calls this function when the test fails.
*/
void qt_assert(const char *assertion, const char *file, int line)
{
qFatal("ASSERT: \"%s\" in file %s, line %d", assertion, file, line);
}
/*
The Q_ASSERT_X macro calls this function when the test fails.
*/
void qt_assert_x(const char *where, const char *what, const char *file, int line)
{
qFatal("ASSERT failure in %s: \"%s\", file %s, line %d", where, what, file, line);
}
/*
Dijkstra's bisection algorithm to find the square root of an integer.
Deliberately not exported as part of the Qt API, but used in both
qsimplerichtext.cpp and qgfxraster_qws.cpp
*/
Q_CORE_EXPORT unsigned int qt_int_sqrt(unsigned int n)
{
// n must be in the range 0...UINT_MAX/2-1
if (n >= (UINT_MAX>>2)) {
unsigned int r = 2 * qt_int_sqrt(n / 4);
unsigned int r2 = r + 1;
return (n >= r2 * r2) ? r2 : r;
}
uint h, p= 0, q= 1, r= n;
while (q <= n)
q <<= 2;
while (q != 1) {
q >>= 2;
h= p + q;
p >>= 1;
if (r >= h) {
p += q;
r -= h;
}
}
return p;
}
#if defined(qMemCopy)
# undef qMemCopy
#endif
#if defined(qMemSet)
# undef qMemSet
#endif
void *qMemCopy(void *dest, const void *src, size_t n) { return memcpy(dest, src, n); }
void *qMemSet(void *dest, int c, size_t n) { return memset(dest, c, n); }
static QtMsgHandler handler = 0; // pointer to debug handler
#if defined(Q_CC_MWERKS) && defined(Q_OS_MACX)
extern bool qt_is_gui_used;
static void mac_default_handler(const char *msg)
{
if (qt_is_gui_used) {
Str255 pmsg;
qt_mac_to_pascal_string(msg, pmsg);
DebugStr(pmsg);
} else {
fprintf(stderr, msg);
}
}
#endif // Q_CC_MWERKS && Q_OS_MACX
QString qt_error_string(int errorCode)
{
const char *s = 0;
QString ret;
if (errorCode == -1) {
#if defined(Q_OS_WIN)
errorCode = GetLastError();
#else
errorCode = errno;
#endif
}
switch (errorCode) {
case 0:
break;
case EACCES:
s = QT_TRANSLATE_NOOP("QIODevice", "Permission denied");
break;
case EMFILE:
s = QT_TRANSLATE_NOOP("QIODevice", "Too many open files");
break;
case ENOENT:
s = QT_TRANSLATE_NOOP("QIODevice", "No such file or directory");
break;
case ENOSPC:
s = QT_TRANSLATE_NOOP("QIODevice", "No space left on device");
break;
default: {
#ifdef Q_OS_WIN
wchar_t *string = 0;
FormatMessage(FORMAT_MESSAGE_ALLOCATE_BUFFER|FORMAT_MESSAGE_FROM_SYSTEM,
NULL,
errorCode,
MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT),
(LPWSTR)&string,
0,
NULL);
ret = QString::fromWCharArray(string);
LocalFree((HLOCAL)string);
if (ret.isEmpty() && errorCode == ERROR_MOD_NOT_FOUND)
ret = QString::fromLatin1("The specified module could not be found.");
#elif !defined(QT_NO_THREAD) && defined(_POSIX_THREAD_SAFE_FUNCTIONS) && _POSIX_VERSION >= 200112L && !defined(Q_OS_INTEGRITY) && !defined(Q_OS_QNX)
QByteArray buf(1024, '\0');
strerror_r(errorCode, buf.data(), buf.size());
ret = QString::fromLocal8Bit(buf.constData());
#else
ret = QString::fromLocal8Bit(strerror(errorCode));
#endif
break; }
}
if (s)
// ######## this breaks moc build currently
// ret = QCoreApplication::translate("QIODevice", s);
ret = QString::fromLatin1(s);
return ret.trimmed();
}
/*!
\fn QtMsgHandler qInstallMsgHandler(QtMsgHandler handler)
\relates <QtGlobal>
Installs a Qt message \a handler which has been defined
previously. Returns a pointer to the previous message handler
(which may be 0).
The message handler is a function that prints out debug messages,
warnings, critical and fatal error messages. The Qt library (debug
mode) contains hundreds of warning messages that are printed
when internal errors (usually invalid function arguments)
occur. Qt built in release mode also contains such warnings unless
QT_NO_WARNING_OUTPUT and/or QT_NO_DEBUG_OUTPUT have been set during
compilation. If you implement your own message handler, you get total
control of these messages.
The default message handler prints the message to the standard
output under X11 or to the debugger under Windows. If it is a
fatal message, the application aborts immediately.
Only one message handler can be defined, since this is usually
done on an application-wide basis to control debug output.
To restore the message handler, call \c qInstallMsgHandler(0).
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 23
\sa qDebug(), qWarning(), qCritical(), qFatal(), QtMsgType,
{Debugging Techniques}
*/
#if defined(Q_OS_WIN) && defined(QT_BUILD_CORE_LIB)
extern bool usingWinMain;
extern Q_CORE_EXPORT void qWinMsgHandler(QtMsgType t, const char* str);
#endif
QtMsgHandler qInstallMsgHandler(QtMsgHandler h)
{
QtMsgHandler old = handler;
handler = h;
#if defined(Q_OS_WIN) && defined(QT_BUILD_CORE_LIB)
if (!handler && usingWinMain)
handler = qWinMsgHandler;
#endif
return old;
}
/*!
\internal
*/
void qt_message_output(QtMsgType msgType, const char *buf)
{
if (handler) {
(*handler)(msgType, buf);
} else {
#if defined(Q_CC_MWERKS) && defined(Q_OS_MACX)
mac_default_handler(buf);
#elif defined(Q_OS_WINCE)
QString fstr = QString::fromLatin1(buf);
fstr += QLatin1Char('\n');
OutputDebugString(reinterpret_cast<const wchar_t *> (fstr.utf16()));
#elif defined(Q_OS_SYMBIAN)
// RDebug::Print has a cap of 256 characters so break it up
_LIT(format, "[Qt Message] %S");
const int maxBlockSize = 256 - ((const TDesC &)format).Length();
const TPtrC8 ptr(reinterpret_cast<const TUint8*>(buf));
HBufC* hbuffer = q_check_ptr(HBufC::New(qMin(maxBlockSize, ptr.Length())));
for (int i = 0; i < ptr.Length(); i += hbuffer->Length()) {
hbuffer->Des().Copy(ptr.Mid(i, qMin(maxBlockSize, ptr.Length()-i)));
RDebug::Print(format, hbuffer);
}
delete hbuffer;
_LIT( KLogDir, "QT" );
_LIT( KLogFile, "QT.log" );
_LIT( KLogStarting, "Starting: %S");
static bool logStarted;
if ( !logStarted ){
RProcess curProc;
TBuf<KMaxFullName + 20> procName;
TFullName fullName = curProc.FullName();
procName.Format(KLogStarting, &fullName);
RFileLogger::Write( KLogDir, KLogFile, EFileLoggingModeAppend, procName);
logStarted = true;
}
RFileLogger::Write( KLogDir, KLogFile, EFileLoggingModeAppend, ptr );
#else
fprintf(stderr, "%s\n", buf);
fflush(stderr);
#endif
}
if (msgType == QtFatalMsg
|| (msgType == QtWarningMsg
&& (!qgetenv("QT_FATAL_WARNINGS").isNull())) ) {
#if defined(Q_CC_MSVC) && defined(QT_DEBUG) && defined(_DEBUG) && defined(_CRT_ERROR)
// get the current report mode
int reportMode = _CrtSetReportMode(_CRT_ERROR, _CRTDBG_MODE_WNDW);
_CrtSetReportMode(_CRT_ERROR, reportMode);
#if !defined(Q_OS_WINCE)
int ret = _CrtDbgReport(_CRT_ERROR, __FILE__, __LINE__, QT_VERSION_STR, buf);
#else
int ret = _CrtDbgReportW(_CRT_ERROR, _CRT_WIDE(__FILE__),
__LINE__, _CRT_WIDE(QT_VERSION_STR), reinterpret_cast<const wchar_t *> (QString::fromLatin1(buf).utf16()));
#endif
if (ret == 0 && reportMode & _CRTDBG_MODE_WNDW)
return; // ignore
else if (ret == 1)
_CrtDbgBreak();
#endif
#if defined(Q_OS_SYMBIAN)
__DEBUGGER(); // on the emulator, get the debugger to kick in if there's one around
TBuf<256> tmp;
TPtrC8 ptr(reinterpret_cast<const TUint8*>(buf));
TInt len = Min(tmp.MaxLength(), ptr.Length());
tmp.Copy(ptr.Left(len));
// Panic the current thread. We don't use real panic codes, so 0 has no special meaning.
User::Panic(tmp, 0);
#elif (defined(Q_OS_UNIX) || defined(Q_CC_MINGW))
abort(); // trap; generates core dump
#else
exit(1); // goodbye cruel world
#endif
}
}
#if !defined(QT_NO_EXCEPTIONS)
/*!
\internal
Uses a local buffer to output the message. Not locale safe + cuts off
everything after character 255, but will work in out of memory situations.
*/
static void qEmergencyOut(QtMsgType msgType, const char *msg, va_list ap)
{
char emergency_buf[256] = { '\0' };
emergency_buf[255] = '\0';
if (msg)
qvsnprintf(emergency_buf, 255, msg, ap);
qt_message_output(msgType, emergency_buf);
}
#endif
/*!
\internal
*/
static void qt_message(QtMsgType msgType, const char *msg, va_list ap)
{
#if !defined(QT_NO_EXCEPTIONS)
if (std::uncaught_exception()) {
qEmergencyOut(msgType, msg, ap);
return;
}
#endif
QByteArray buf;
if (msg) {
QT_TRY {
buf = QString().vsprintf(msg, ap).toLocal8Bit();
} QT_CATCH(const std::bad_alloc &) {
#if !defined(QT_NO_EXCEPTIONS)
qEmergencyOut(msgType, msg, ap);
// don't rethrow - we use qWarning and friends in destructors.
return;
#endif
}
}
qt_message_output(msgType, buf.constData());
}
#undef qDebug
/*!
\relates <QtGlobal>
Calls the message handler with the debug message \a msg. If no
message handler has been installed, the message is printed to
stderr. Under Windows, the message is sent to the console, if it is a
console application; otherwise, it is sent to the debugger. This
function does nothing if \c QT_NO_DEBUG_OUTPUT was defined
during compilation.
If you pass the function a format string and a list of arguments,
it works in similar way to the C printf() function. The format
should be a Latin-1 string.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 24
If you include \c <QtDebug>, a more convenient syntax is also
available:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 25
With this syntax, the function returns a QDebug object that is
configured to use the QtDebugMsg message type. It automatically
puts a single space between each item, and outputs a newline at
the end. It supports many C++ and Qt types.
To suppress the output at run-time, install your own message handler
with qInstallMsgHandler().
\sa qWarning(), qCritical(), qFatal(), qInstallMsgHandler(),
{Debugging Techniques}
*/
void qDebug(const char *msg, ...)
{
va_list ap;
va_start(ap, msg); // use variable arg list
qt_message(QtDebugMsg, msg, ap);
va_end(ap);
}
#undef qWarning
/*!
\relates <QtGlobal>
Calls the message handler with the warning message \a msg. If no
message handler has been installed, the message is printed to
stderr. Under Windows, the message is sent to the debugger. This
function does nothing if \c QT_NO_WARNING_OUTPUT was defined
during compilation; it exits if the environment variable \c
QT_FATAL_WARNINGS is defined.
This function takes a format string and a list of arguments,
similar to the C printf() function. The format should be a Latin-1
string.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 26
If you include <QtDebug>, a more convenient syntax is
also available:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 27
This syntax inserts a space between each item, and
appends a newline at the end.
To supress the output at runtime, install your own message handler
with qInstallMsgHandler().
\sa qDebug(), qCritical(), qFatal(), qInstallMsgHandler(),
{Debugging Techniques}
*/
void qWarning(const char *msg, ...)
{
va_list ap;
va_start(ap, msg); // use variable arg list
qt_message(QtWarningMsg, msg, ap);
va_end(ap);
}
/*!
\relates <QtGlobal>
Calls the message handler with the critical message \a msg. If no
message handler has been installed, the message is printed to
stderr. Under Windows, the message is sent to the debugger.
This function takes a format string and a list of arguments,
similar to the C printf() function. The format should be a Latin-1
string.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 28
If you include <QtDebug>, a more convenient syntax is
also available:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 29
A space is inserted between the items, and a newline is
appended at the end.
To supress the output at runtime, install your own message handler
with qInstallMsgHandler().
\sa qDebug(), qWarning(), qFatal(), qInstallMsgHandler(),
{Debugging Techniques}
*/
void qCritical(const char *msg, ...)
{
va_list ap;
va_start(ap, msg); // use variable arg list
qt_message(QtCriticalMsg, msg, ap);
va_end(ap);
}
#ifdef QT3_SUPPORT
void qSystemWarning(const char *msg, int code)
{ qCritical("%s (%s)", msg, qt_error_string(code).toLocal8Bit().constData()); }
#endif // QT3_SUPPORT
void qErrnoWarning(const char *msg, ...)
{
// qt_error_string() will allocate anyway, so we don't have
// to be careful here (like we do in plain qWarning())
QString buf;
va_list ap;
va_start(ap, msg);
if (msg)
buf.vsprintf(msg, ap);
va_end(ap);
qCritical("%s (%s)", buf.toLocal8Bit().constData(), qt_error_string(-1).toLocal8Bit().constData());
}
void qErrnoWarning(int code, const char *msg, ...)
{
// qt_error_string() will allocate anyway, so we don't have
// to be careful here (like we do in plain qWarning())
QString buf;
va_list ap;
va_start(ap, msg);
if (msg)
buf.vsprintf(msg, ap);
va_end(ap);
qCritical("%s (%s)", buf.toLocal8Bit().constData(), qt_error_string(code).toLocal8Bit().constData());
}
/*!
\relates <QtGlobal>
Calls the message handler with the fatal message \a msg. If no
message handler has been installed, the message is printed to
stderr. Under Windows, the message is sent to the debugger.
If you are using the \bold{default message handler} this function will
abort on Unix systems to create a core dump. On Windows, for debug builds,
this function will report a _CRT_ERROR enabling you to connect a debugger
to the application.
This function takes a format string and a list of arguments,
similar to the C printf() function.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 30
To supress the output at runtime, install your own message handler
with qInstallMsgHandler().
\sa qDebug(), qCritical(), qWarning(), qInstallMsgHandler(),
{Debugging Techniques}
*/
void qFatal(const char *msg, ...)
{
va_list ap;
va_start(ap, msg); // use variable arg list
qt_message(QtFatalMsg, msg, ap);
va_end(ap);
}
// getenv is declared as deprecated in VS2005. This function
// makes use of the new secure getenv function.
QByteArray qgetenv(const char *varName)
{
#if defined(_MSC_VER) && _MSC_VER >= 1400
size_t requiredSize = 0;
QByteArray buffer;
getenv_s(&requiredSize, 0, 0, varName);
if (requiredSize == 0)
return buffer;
buffer.resize(int(requiredSize));
getenv_s(&requiredSize, buffer.data(), requiredSize, varName);
// requiredSize includes the terminating null, which we don't want.
Q_ASSERT(buffer.endsWith('\0'));
buffer.chop(1);
return buffer;
#else
return QByteArray(::getenv(varName));
#endif
}
bool qputenv(const char *varName, const QByteArray& value)
{
#if defined(_MSC_VER) && _MSC_VER >= 1400
return _putenv_s(varName, value.constData()) == 0;
#else
QByteArray buffer(varName);
buffer += '=';
buffer += value;
char* envVar = qstrdup(buffer.constData());
int result = putenv(envVar);
if (result != 0) // error. we have to delete the string.
delete[] envVar;
return result == 0;
#endif
}
#if (defined(Q_OS_UNIX) || defined(Q_OS_WIN)) && !defined(QT_NO_THREAD)
# if defined(Q_OS_INTEGRITY) && defined(__GHS_VERSION_NUMBER) && (__GHS_VERSION_NUMBER < 500)
// older versions of INTEGRITY used a long instead of a uint for the seed.
typedef long SeedStorageType;
# else
typedef uint SeedStorageType;
# endif
typedef QThreadStorage<SeedStorageType *> SeedStorage;
Q_GLOBAL_STATIC(SeedStorage, randTLS) // Thread Local Storage for seed value
#endif
/*!
\relates <QtGlobal>
\since 4.2
Thread-safe version of the standard C++ \c srand() function.
Sets the argument \a seed to be used to generate a new random number sequence of
pseudo random integers to be returned by qrand().
The sequence of random numbers generated is deterministic per thread. For example,
if two threads call qsrand(1) and subsequently calls qrand(), the threads will get
the same random number sequence.
\sa qrand()
*/
void qsrand(uint seed)
{
#if defined(Q_OS_UNIX) && !defined(QT_NO_THREAD) && !defined(Q_OS_SYMBIAN)
SeedStorage *seedStorage = randTLS();
if (seedStorage) {
SeedStorageType *pseed = seedStorage->localData();
if (!pseed)
seedStorage->setLocalData(pseed = new SeedStorageType);
*pseed = seed;
} else {
//golbal static seed storage should always exist,
//except after being deleted by QGlobalStaticDeleter.
//But since it still can be called from destructor of another
//global static object, fallback to sqrand(seed)
srand(seed);
}
#else
// On Windows and Symbian srand() and rand() already use Thread-Local-Storage
// to store the seed between calls
// this is also valid for QT_NO_THREAD
srand(seed);
#endif
}
/*! \internal
\relates <QtGlobal>
\since 4.6
Seed the PRNG, but only if it has not already been seeded.
The default seed is a combination of current time, a stack address and a
serial counter (since thread stack addresses are re-used).
*/
void qsrand()
{
#if (defined(Q_OS_UNIX) || defined(Q_OS_WIN)) && !defined(QT_NO_THREAD)
SeedStorage *seedStorage = randTLS();
if (seedStorage) {
SeedStorageType *pseed = seedStorage->localData();
if (pseed) {
// already seeded
return;
}
seedStorage->setLocalData(pseed = new SeedStorageType);
// start beyond 1 to avoid the sequence reset
static QBasicAtomicInt serial = Q_BASIC_ATOMIC_INITIALIZER(2);
*pseed = QDateTime::currentDateTime().toTime_t()
+ quintptr(&pseed)
+ serial.fetchAndAddRelaxed(1);
#if defined(Q_OS_WIN) || defined(Q_OS_SYMBIAN)
// for Windows and Symbian the srand function must still be called.
srand(*pseed);
#endif
}
//QT_NO_THREAD implementations
#else
static unsigned int seed = 0;
if (seed)
return;
#if defined(Q_OS_SYMBIAN)
seed = Math::Random();
#elif defined(Q_OS_WIN)
seed = GetTickCount();
#else
seed = quintptr(&seed) + QDateTime::currentDateTime().toTime_t();
#endif
srand(seed);
#endif // defined(Q_OS_UNIX) || defined(Q_OS_WIN)) && !defined(QT_NO_THREAD)
}
/*!
\relates <QtGlobal>
\since 4.2
Thread-safe version of the standard C++ \c rand() function.
Returns a value between 0 and \c RAND_MAX (defined in \c <cstdlib> and
\c <stdlib.h>), the next number in the current sequence of pseudo-random
integers.
Use \c qsrand() to initialize the pseudo-random number generator with
a seed value.
\sa qsrand()
*/
int qrand()
{
#if defined(Q_OS_UNIX) && !defined(QT_NO_THREAD) && !defined(Q_OS_SYMBIAN)
SeedStorage *seedStorage = randTLS();
if (seedStorage) {
SeedStorageType *pseed = seedStorage->localData();
if (!pseed) {
seedStorage->setLocalData(pseed = new SeedStorageType);
*pseed = 1;
}
return rand_r(pseed);
} else {
//golbal static seed storage should always exist,
//except after being deleted by QGlobalStaticDeleter.
//But since it still can be called from destructor of another
//global static object, fallback to qrand()
return rand();
}
#else
// On Windows and Symbian srand() and rand() already use Thread-Local-Storage
// to store the seed between calls
// this is also valid for QT_NO_THREAD
return rand();
#endif
}
/*!
\macro forever
\relates <QtGlobal>
This macro is provided for convenience for writing infinite
loops.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 31
It is equivalent to \c{for (;;)}.
If you're worried about namespace pollution, you can disable this
macro by adding the following line to your \c .pro file:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 32
\sa Q_FOREVER
*/
/*!
\macro Q_FOREVER
\relates <QtGlobal>
Same as \l{forever}.
This macro is available even when \c no_keywords is specified
using the \c .pro file's \c CONFIG variable.
\sa foreach()
*/
/*!
\macro foreach(variable, container)
\relates <QtGlobal>
This macro is used to implement Qt's \c foreach loop. The \a
variable parameter is a variable name or variable definition; the
\a container parameter is a Qt container whose value type
corresponds to the type of the variable. See \l{The foreach
Keyword} for details.
If you're worried about namespace pollution, you can disable this
macro by adding the following line to your \c .pro file:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 33
\sa Q_FOREACH()
*/
/*!
\macro Q_FOREACH(variable, container)
\relates <QtGlobal>
Same as foreach(\a variable, \a container).
This macro is available even when \c no_keywords is specified
using the \c .pro file's \c CONFIG variable.
\sa foreach()
*/
/*!
\macro QT_TR_NOOP(sourceText)
\relates <QtGlobal>
Marks the string literal \a sourceText for dynamic translation in
the current context (class), i.e the stored \a sourceText will not
be altered.
The macro expands to \a sourceText.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 34
The macro QT_TR_NOOP_UTF8() is identical except that it tells lupdate
that the source string is encoded in UTF-8. Corresponding variants
exist in the QT_TRANSLATE_NOOP() family of macros, too. Note that
using these macros is not required if \c CODECFORTR is already set to
UTF-8 in the qmake project file.
\sa QT_TRANSLATE_NOOP(), {Internationalization with Qt}
*/
/*!
\macro QT_TRANSLATE_NOOP(context, sourceText)
\relates <QtGlobal>
Marks the string literal \a sourceText for dynamic translation in
the given \a context; i.e, the stored \a sourceText will not be
altered. The \a context is typically a class and also needs to
be specified as string literal.
The macro expands to \a sourceText.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 35
\sa QT_TR_NOOP(), QT_TRANSLATE_NOOP3(), {Internationalization with Qt}
*/
/*!
\macro QT_TRANSLATE_NOOP3(context, sourceText, comment)
\relates <QtGlobal>
\since 4.4
Marks the string literal \a sourceText for dynamic translation in the
given \a context and with \a comment, i.e the stored \a sourceText will
not be altered. The \a context is typically a class and also needs to
be specified as string literal. The string literal \a comment
will be available for translators using e.g. Qt Linguist.
The macro expands to anonymous struct of the two string
literals passed as \a sourceText and \a comment.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 36
\sa QT_TR_NOOP(), QT_TRANSLATE_NOOP(), {Internationalization with Qt}
*/
/*!
\fn QString qtTrId(const char *id, int n = -1)
\relates <QtGlobal>
\reentrant
\since 4.6
\brief The qtTrId function finds and returns a translated string.
Returns a translated string identified by \a id.
If no matching string is found, the id itself is returned. This
should not happen under normal conditions.
If \a n >= 0, all occurrences of \c %n in the resulting string
are replaced with a decimal representation of \a n. In addition,
depending on \a n's value, the translation text may vary.
Meta data and comments can be passed as documented for QObject::tr().
In addition, it is possible to supply a source string template like that:
\tt{//% <C string>}
or
\tt{\begincomment% <C string> \endcomment}
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp qttrid
Creating QM files suitable for use with this function requires passing
the \c -idbased option to the \c lrelease tool.
\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 probably result in crashes or other undesirable behavior.
\sa QObject::tr(), QCoreApplication::translate(), {Internationalization with Qt}
*/
/*!
\macro QT_TRID_NOOP(id)
\relates <QtGlobal>
\since 4.6
\brief The QT_TRID_NOOP macro marks an id for dynamic translation.
The only purpose of this macro is to provide an anchor for attaching
meta data like to qtTrId().
The macro expands to \a id.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp qttrid_noop
\sa qtTrId(), {Internationalization with Qt}
*/
/*!
\macro QT_POINTER_SIZE
\relates <QtGlobal>
Expands to the size of a pointer in bytes (4 or 8). This is
equivalent to \c sizeof(void *) but can be used in a preprocessor
directive.
*/
/*!
\macro TRUE
\relates <QtGlobal>
\obsolete
Synonym for \c true.
\sa FALSE
*/
/*!
\macro FALSE
\relates <QtGlobal>
\obsolete
Synonym for \c false.
\sa TRUE
*/
/*!
\macro QABS(n)
\relates <QtGlobal>
\obsolete
Use qAbs(\a n) instead.
\sa QMIN(), QMAX()
*/
/*!
\macro QMIN(x, y)
\relates <QtGlobal>
\obsolete
Use qMin(\a x, \a y) instead.
\sa QMAX(), QABS()
*/
/*!
\macro QMAX(x, y)
\relates <QtGlobal>
\obsolete
Use qMax(\a x, \a y) instead.
\sa QMIN(), QABS()
*/
/*!
\macro const char *qPrintable(const QString &str)
\relates <QtGlobal>
Returns \a str as a \c{const char *}. This is equivalent to
\a{str}.toLocal8Bit().constData().
The char pointer will be invalid after the statement in which
qPrintable() is used. This is because the array returned by
toLocal8Bit() will fall out of scope.
Example:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 37
\sa qDebug(), qWarning(), qCritical(), qFatal()
*/
/*!
\macro Q_DECLARE_TYPEINFO(Type, Flags)
\relates <QtGlobal>
You can use this macro to specify information about a custom type
\a Type. With accurate type information, Qt's \l{generic
containers} can choose appropriate storage methods and algorithms.
\a Flags can be one of the following:
\list
\o \c Q_PRIMITIVE_TYPE specifies that \a Type is a POD (plain old
data) type with no constructor or destructor.
\o \c Q_MOVABLE_TYPE specifies that \a Type has a constructor
and/or a destructor but can be moved in memory using \c
memcpy().
\o \c Q_COMPLEX_TYPE (the default) specifies that \a Type has
constructors and/or a destructor and that it may not be moved
in memory.
\endlist
Example of a "primitive" type:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 38
Example of a movable type:
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 39
*/
/*!
\macro Q_UNUSED(name)
\relates <QtGlobal>
Indicates to the compiler that the parameter with the specified
\a name is not used in the body of a function. This can be used to
suppress compiler warnings while allowing functions to be defined
with meaningful parameter names in their signatures.
*/
#if defined(QT3_SUPPORT) && !defined(QT_NO_SETTINGS)
QT_BEGIN_INCLUDE_NAMESPACE
#include <qlibraryinfo.h>
QT_END_INCLUDE_NAMESPACE
static const char *qInstallLocation(QLibraryInfo::LibraryLocation loc)
{
static QByteArray ret;
ret = QLibraryInfo::location(loc).toLatin1();
return ret.constData();
}
const char *qInstallPath()
{
return qInstallLocation(QLibraryInfo::PrefixPath);
}
const char *qInstallPathDocs()
{
return qInstallLocation(QLibraryInfo::DocumentationPath);
}
const char *qInstallPathHeaders()
{
return qInstallLocation(QLibraryInfo::HeadersPath);
}
const char *qInstallPathLibs()
{
return qInstallLocation(QLibraryInfo::LibrariesPath);
}
const char *qInstallPathBins()
{
return qInstallLocation(QLibraryInfo::BinariesPath);
}
const char *qInstallPathPlugins()
{
return qInstallLocation(QLibraryInfo::PluginsPath);
}
const char *qInstallPathData()
{
return qInstallLocation(QLibraryInfo::DataPath);
}
const char *qInstallPathTranslations()
{
return qInstallLocation(QLibraryInfo::TranslationsPath);
}
const char *qInstallPathSysconf()
{
return qInstallLocation(QLibraryInfo::SettingsPath);
}
#endif
struct QInternal_CallBackTable {
QVector<QList<qInternalCallback> > callbacks;
};
Q_GLOBAL_STATIC(QInternal_CallBackTable, global_callback_table)
bool QInternal::registerCallback(Callback cb, qInternalCallback callback)
{
if (cb >= 0 && cb < QInternal::LastCallback) {
QInternal_CallBackTable *cbt = global_callback_table();
cbt->callbacks.resize(cb + 1);
cbt->callbacks[cb].append(callback);
return true;
}
return false;
}
bool QInternal::unregisterCallback(Callback cb, qInternalCallback callback)
{
if (cb >= 0 && cb < QInternal::LastCallback) {
QInternal_CallBackTable *cbt = global_callback_table();
return (bool) cbt->callbacks[cb].removeAll(callback);
}
return false;
}
bool QInternal::activateCallbacks(Callback cb, void **parameters)
{
Q_ASSERT_X(cb >= 0, "QInternal::activateCallback()", "Callback id must be a valid id");
QInternal_CallBackTable *cbt = global_callback_table();
if (cbt && cb < cbt->callbacks.size()) {
QList<qInternalCallback> callbacks = cbt->callbacks[cb];
bool ret = false;
for (int i=0; i<callbacks.size(); ++i)
ret |= (callbacks.at(i))(parameters);
return ret;
}
return false;
}
extern void qt_set_current_thread_to_main_thread();
bool QInternal::callFunction(InternalFunction func, void **args)
{
Q_ASSERT_X(func >= 0,
"QInternal::callFunction()", "Callback id must be a valid id");
#ifndef QT_NO_QOBJECT
switch (func) {
#ifndef QT_NO_THREAD
case QInternal::CreateThreadForAdoption:
*args = QAdoptedThread::createThreadForAdoption();
return true;
#endif
case QInternal::RefAdoptedThread:
QThreadData::get2((QThread *) *args)->ref();
return true;
case QInternal::DerefAdoptedThread:
QThreadData::get2((QThread *) *args)->deref();
return true;
case QInternal::SetCurrentThreadToMainThread:
qt_set_current_thread_to_main_thread();
return true;
case QInternal::SetQObjectSender: {
QObject *receiver = (QObject *) args[0];
QObjectPrivate::Sender *sender = new QObjectPrivate::Sender;
sender->sender = (QObject *) args[1];
sender->signal = *(int *) args[2];
sender->ref = 1;
// Store the old sender as "return value"
args[3] = QObjectPrivate::setCurrentSender(receiver, sender);
args[4] = sender;
return true;
}
case QInternal::GetQObjectSender: {
QObject *receiver = (QObject *) args[0];
QObjectPrivate *d = QObjectPrivate::get(receiver);
args[1] = d->currentSender ? d->currentSender->sender : 0;
return true;
}
case QInternal::ResetQObjectSender: {
QObject *receiver = (QObject *) args[0];
QObjectPrivate::Sender *oldSender = (QObjectPrivate::Sender *) args[1];
QObjectPrivate::Sender *sender = (QObjectPrivate::Sender *) args[2];
QObjectPrivate::resetCurrentSender(receiver, sender, oldSender);
delete sender;
return true;
}
default:
break;
}
#else
Q_UNUSED(args);
Q_UNUSED(func);
#endif
return false;
}
/*!
\macro Q_BYTE_ORDER
\relates <QtGlobal>
This macro can be used to determine the byte order your system
uses for storing data in memory. i.e., whether your system is
little-endian or big-endian. It is set by Qt to one of the macros
Q_LITTLE_ENDIAN or Q_BIG_ENDIAN. You normally won't need to worry
about endian-ness, but you might, for example if you need to know
which byte of an integer or UTF-16 character is stored in the
lowest address. Endian-ness is important in networking, where
computers with different values for Q_BYTE_ORDER must pass data
back and forth.
Use this macro as in the following examples.
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 40
\sa Q_BIG_ENDIAN, Q_LITTLE_ENDIAN
*/
/*!
\macro Q_LITTLE_ENDIAN
\relates <QtGlobal>
This macro represents a value you can compare to the macro
Q_BYTE_ORDER to determine the endian-ness of your system. In a
little-endian system, the least significant byte is stored at the
lowest address. The other bytes follow in increasing order of
significance.
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 41
\sa Q_BYTE_ORDER, Q_BIG_ENDIAN
*/
/*!
\macro Q_BIG_ENDIAN
\relates <QtGlobal>
This macro represents a value you can compare to the macro
Q_BYTE_ORDER to determine the endian-ness of your system. In a
big-endian system, the most significant byte is stored at the
lowest address. The other bytes follow in decreasing order of
significance.
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 42
\sa Q_BYTE_ORDER, Q_LITTLE_ENDIAN
*/
/*!
\macro Q_GLOBAL_STATIC(type, name)
\internal
Declares a global static variable with the given \a type and \a name.
Use this macro to instantiate an object in a thread-safe way, creating
a global pointer that can be used to refer to it.
\warning This macro is subject to a race condition that can cause the object
to be constructed twice. However, if this occurs, the second instance will
be immediately deleted.
See also
\l{http://www.aristeia.com/publications.html}{"C++ and the perils of Double-Checked Locking"}
by Scott Meyers and Andrei Alexandrescu.
*/
/*!
\macro Q_GLOBAL_STATIC_WITH_ARGS(type, name, arguments)
\internal
Declares a global static variable with the specified \a type and \a name.
Use this macro to instantiate an object using the \a arguments specified
in a thread-safe way, creating a global pointer that can be used to refer
to it.
\warning This macro is subject to a race condition that can cause the object
to be constructed twice. However, if this occurs, the second instance will
be immediately deleted.
See also
\l{http://www.aristeia.com/publications.html}{"C++ and the perils of Double-Checked Locking"}
by Scott Meyers and Andrei Alexandrescu.
*/
/*!
\macro QT_NAMESPACE
\internal
If this macro is defined to \c ns all Qt classes are put in a namespace
called \c ns. Also, moc will output code putting metaobjects etc.
into namespace \c ns.
\sa QT_BEGIN_NAMESPACE, QT_END_NAMESPACE,
QT_PREPEND_NAMESPACE, QT_USE_NAMESPACE,
QT_BEGIN_INCLUDE_NAMESPACE, QT_END_INCLUDE_NAMESPACE,
QT_BEGIN_MOC_NAMESPACE, QT_END_MOC_NAMESPACE,
*/
/*!
\macro QT_PREPEND_NAMESPACE(identifier)
\internal
This macro qualifies \a identifier with the full namespace.
It expands to \c{::QT_NAMESPACE::identifier} if \c QT_NAMESPACE is defined
and only \a identifier otherwise.
\sa QT_NAMESPACE
*/
/*!
\macro QT_USE_NAMESPACE
\internal
This macro expands to using QT_NAMESPACE if QT_NAMESPACE is defined
and nothing otherwise.
\sa QT_NAMESPACE
*/
/*!
\macro QT_BEGIN_NAMESPACE
\internal
This macro expands to
\snippet snippets/code/src_corelib_global_qglobal.cpp begin namespace macro
if \c QT_NAMESPACE is defined and nothing otherwise. If should always
appear in the file-level scope and be followed by \c QT_END_NAMESPACE
at the same logical level with respect to preprocessor conditionals
in the same file.
As a rule of thumb, \c QT_BEGIN_NAMESPACE should appear in all Qt header
and Qt source files after the last \c{#include} line and before the first
declaration. In Qt headers using \c QT_BEGIN_HEADER, \c QT_BEGIN_NAMESPACE
follows \c QT_BEGIN_HEADER immediately.
If that rule can't be followed because, e.g., \c{#include} lines and
declarations are wildly mixed, place \c QT_BEGIN_NAMESPACE before
the first declaration and wrap the \c{#include} lines in
\c QT_BEGIN_INCLUDE_NAMESPACE and \c QT_END_INCLUDE_NAMESPACE.
When using the \c QT_NAMESPACE feature in user code
(e.g., when building plugins statically linked to Qt) where
the user code is not intended to go into the \c QT_NAMESPACE
namespace, all forward declarations of Qt classes need to
be wrapped in \c QT_BEGIN_NAMESPACE and \c QT_END_NAMESPACE.
After that, a \c QT_USE_NAMESPACE should follow.
No further changes should be needed.
\sa QT_NAMESPACE
*/
/*!
\macro QT_END_NAMESPACE
\internal
This macro expands to
\snippet snippets/code/src_corelib_global_qglobal.cpp end namespace macro
if \c QT_NAMESPACE is defined and nothing otherwise. It is used to cancel
the effect of \c QT_BEGIN_NAMESPACE.
If a source file ends with a \c{#include} directive that includes a moc file,
\c QT_END_NAMESPACE should be placed before that \c{#include}.
\sa QT_NAMESPACE
*/
/*!
\macro QT_BEGIN_INCLUDE_NAMESPACE
\internal
This macro is equivalent to \c QT_END_NAMESPACE.
It only serves as syntactic sugar and is intended
to be used before #include lines within a
\c QT_BEGIN_NAMESPACE ... \c QT_END_NAMESPACE block.
\sa QT_NAMESPACE
*/
/*!
\macro QT_END_INCLUDE_NAMESPACE
\internal
This macro is equivalent to \c QT_BEGIN_NAMESPACE.
It only serves as syntactic sugar and is intended
to be used after #include lines within a
\c QT_BEGIN_NAMESPACE ... \c QT_END_NAMESPACE block.
\sa QT_NAMESPACE
*/
/*!
\macro QT_BEGIN_MOC_NAMESPACE
\internal
This macro is output by moc at the beginning of
moc files. It is equivalent to \c QT_USE_NAMESPACE.
\sa QT_NAMESPACE
*/
/*!
\macro QT_END_MOC_NAMESPACE
\internal
This macro is output by moc at the beginning of
moc files. It expands to nothing.
\sa QT_NAMESPACE
*/
/*!
\fn bool qFuzzyCompare(double p1, double p2)
\relates <QtGlobal>
\since 4.4
\threadsafe
Compares the floating point value \a p1 and \a p2 and
returns \c true if they are considered equal, otherwise \c false.
Note that comparing values where either \a p1 or \a p2 is 0.0 will not work.
The solution to this is to compare against values greater than or equal to 1.0.
\snippet doc/src/snippets/code/src_corelib_global_qglobal.cpp 46
The two numbers are compared in a relative way, where the
exactness is stronger the smaller the numbers are.
*/
/*!
\fn bool qFuzzyCompare(float p1, float p2)
\relates <QtGlobal>
\since 4.4
\threadsafe
Compares the floating point value \a p1 and \a p2 and
returns \c true if they are considered equal, otherwise \c false.
The two numbers are compared in a relative way, where the
exactness is stronger the smaller the numbers are.
*/
/*!
\macro QT_REQUIRE_VERSION(int argc, char **argv, const char *version)
\relates <QtGlobal>
This macro can be used to ensure that the application is run
against a recent enough version of Qt. This is especially useful
if your application depends on a specific bug fix introduced in a
bug-fix release (e.g., 4.0.2).
The \a argc and \a argv parameters are the \c main() function's
\c argc and \c argv parameters. The \a version parameter is a
string literal that specifies which version of Qt the application
requires (e.g., "4.0.2").
Example:
\snippet doc/src/snippets/code/src_gui_dialogs_qmessagebox.cpp 4
*/
/*!
\macro Q_DECL_EXPORT
\relates <QtGlobal>
This macro marks a symbol for shared library export (see
\l{sharedlibrary.html}{Creating Shared Libraries}).
\sa Q_DECL_IMPORT
*/
/*!
\macro Q_DECL_IMPORT
\relates <QtGlobal>
This macro declares a symbol to be an import from a shared library (see
\l{sharedlibrary.html}{Creating Shared Libraries}).
\sa Q_DECL_EXPORT
*/
#if defined(Q_OS_SYMBIAN)
#include <typeinfo>
/*! \macro QT_TRAP_THROWING(function)
\relates <QtGlobal>
\ingroup qts60
TRAP leaves from Symbian \a function and throws an appropriate
standard C++ exception instead.
This must be used when calling Symbian OS leaving functions
from inside Qt or standard C++ code, so that the code can respond
correctly to the exception.
\warning This macro is only available on Symbian.
Example:
\code
// A Symbian leaving function is being called within a Qt function.
// Any leave must be converted to an exception
CAknTitlePane* titlePane = S60->titlePane();
if (titlePane) {
TPtrC captionPtr(qt_QString2TPtrC(caption));
QT_TRAP_THROWING(titlePane->SetTextL(captionPtr));
}
\endcode
\sa QT_TRYCATCH_ERROR(), QT_TRYCATCH_LEAVING()
*/
/*! \macro QT_TRYCATCH_ERROR(error, function)
\relates <QtGlobal>
\ingroup qts60
Catch standard C++ exceptions from a \a function and convert them to a Symbian OS
\a error code, or \c KErrNone if there is no exception.
This must be used inside Qt or standard C++ code when using exception throwing
code (practically anything) and returning an error code to Symbian OS.
\warning This macro is only available on Symbian.
Example:
\code
// An exception might be thrown in this Symbian TInt error returning function.
// It is caught and translated to an error code
TInt QServerApp::Connect(const QString &serverName)
{
TPtrC name;
TInt err;
QT_TRYCATCH_ERROR(err, name.Set(qt_QString2TPtrC(serverName)));
if (err != KErrNone)
return err;
return iServer.Connect(name);
}
\endcode
}
\sa QT_TRYCATCH_LEAVING(), QT_TRAP_THROWING()
*/
/*! \macro QT_TRYCATCH_LEAVING(function)
\relates <QtGlobal>
\ingroup qts60
Catch standard C++ exceptions from \a function and convert them to Symbian OS
leaves. This must be used inside Qt or standard C++ code when using exception
throwing code (practically anything) and returning to Symbian OS from a leaving function.
For example inside a Symbian active object's \c RunL function implemented with Qt code.
\warning This macro is only available on Symbian.
Example:
\code
// This active object signals Qt code
// Exceptions from the Qt code must be converted to Symbian OS leaves for the active scheduler
void QWakeUpActiveObject::RunL()
{
iStatus = KRequestPending;
SetActive();
QT_TRYCATCH_LEAVING(m_dispatcher->wakeUpWasCalled());
}
\endcode
\sa QT_TRAP_THROWING(), QT_TRYCATCH_ERROR()
*/
#include <stdexcept>
class QSymbianLeaveException : public std::exception
{
public:
inline QSymbianLeaveException(int err) : error(err) {}
inline const char* what() const throw() { return "Symbian leave exception"; }
public:
int error;
};
/*! \relates <QtGlobal>
\ingroup qts60
Throws an exception if the \a error parameter is a symbian error code.
This is the exception throwing equivalent of Symbian's User::LeaveIfError.
\warning This function is only available on Symbian.
\sa qt_symbian_exception2LeaveL(), qt_symbian_exception2Error()
*/
void qt_symbian_throwIfError(int error)
{
if (error >= KErrNone)
return; // do nothing - not an exception
switch (error) {
case KErrNoMemory:
throw std::bad_alloc();
case KErrArgument:
throw std::invalid_argument("from Symbian error");
case KErrOverflow:
throw std::overflow_error("from Symbian error");
case KErrUnderflow:
throw std::underflow_error("from Symbian error");
default:
throw QSymbianLeaveException(error);
}
}
/*! \relates <QtGlobal>
\ingroup qts60
Convert a caught standard C++ exception \a aThrow to a Symbian leave
\warning This function is only available on Symbian.
\sa qt_symbian_throwIfError(), qt_symbian_exception2Error()
*/
void qt_symbian_exception2LeaveL(const std::exception& aThrow)
{
User::Leave(qt_symbian_exception2Error(aThrow));
}
/*! \relates <QtGlobal>
\ingroup qts60
Convert a caught standard C++ exception \a aThrow to a Symbian error code
\warning This function is only available on Symbian.
\sa qt_symbian_throwIfError(), qt_symbian_exception2LeaveL()
*/
int qt_symbian_exception2Error(const std::exception& aThrow)
{
const std::type_info& atype = typeid(aThrow);
int err = KErrGeneral;
if(atype == typeid (std::bad_alloc))
err = KErrNoMemory;
else if(atype == typeid(QSymbianLeaveException))
err = static_cast<const QSymbianLeaveException&>(aThrow).error;
else {
if(atype == typeid(std::invalid_argument))
err = KErrArgument;
else if(atype == typeid(std::out_of_range))
// std::out_of_range is of type logic_error which by definition means that it is
// "presumably detectable before the program executes".
// std::out_of_range is used to report an argument is not within the expected range.
// The description of KErrArgument says an argument is out of range. Hence the mapping.
err = KErrArgument;
else if(atype == typeid(std::overflow_error))
err = KErrOverflow;
else if(atype == typeid(std::underflow_error))
err = KErrUnderflow;
qWarning("translation from std exception \"%s\" to %d", aThrow.what(), err);
}
return err;
}
#endif
QT_END_NAMESPACE