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|
/****************************************************************************
**
** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies).
** All rights reserved.
** Contact: Nokia Corporation (qt-info@nokia.com)
**
** This file is part of the QtCore module of the Qt Toolkit.
**
** $QT_BEGIN_LICENSE:LGPL$
** No Commercial Usage
** This file contains pre-release code and may not be distributed.
** You may use this file in accordance with the terms and conditions
** contained in the Technology Preview License Agreement accompanying
** this package.
**
** GNU Lesser General Public License Usage
** Alternatively, this file may be used under the terms of the GNU Lesser
** General Public License version 2.1 as published by the Free Software
** Foundation and appearing in the file LICENSE.LGPL included in the
** packaging of this file. Please review the following information to
** ensure the GNU Lesser General Public License version 2.1 requirements
** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html.
**
** In addition, as a special exception, Nokia gives you certain additional
** rights. These rights are described in the Nokia Qt LGPL Exception
** version 1.1, included in the file LGPL_EXCEPTION.txt in this package.
**
** If you have questions regarding the use of this file, please contact
** Nokia at qt-info@nokia.com.
**
**
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**
**
**
**
** $QT_END_LICENSE$
**
****************************************************************************/
#include "qstringlist.h"
#include "qregexp.h"
#include "qunicodetables_p.h"
#ifndef QT_NO_TEXTCODEC
#include <qtextcodec.h>
#endif
#include <private/qutfcodec_p.h>
#include "qsimd_p.h"
#include <qdatastream.h>
#include <qlist.h>
#include "qlocale.h"
#include "qlocale_p.h"
#include "qstringmatcher.h"
#include "qvarlengtharray.h"
#include "qtools_p.h"
#include "qhash.h"
#include "qdebug.h"
#include "qendian.h"
#ifdef Q_OS_MAC
#include <private/qcore_mac_p.h>
#endif
#include <private/qfunctions_p.h>
#if defined(Q_OS_WINCE)
#include <windows.h>
#include <winnls.h>
#endif
#ifdef Q_OS_SYMBIAN
#include <e32cmn.h>
#endif
#include <limits.h>
#include <string.h>
#include <stdlib.h>
#include <stdio.h>
#include <stdarg.h>
#ifdef truncate
#undef truncate
#endif
#include "qchar.cpp"
#include "qstringmatcher.cpp"
#ifndef LLONG_MAX
#define LLONG_MAX qint64_C(9223372036854775807)
#endif
#ifndef LLONG_MIN
#define LLONG_MIN (-LLONG_MAX - qint64_C(1))
#endif
#ifndef ULLONG_MAX
#define ULLONG_MAX quint64_C(18446744073709551615)
#endif
QT_BEGIN_NAMESPACE
#ifndef QT_NO_TEXTCODEC
QTextCodec *QString::codecForCStrings;
#endif
#ifdef QT3_SUPPORT
static QHash<void *, QByteArray> *asciiCache = 0;
#endif
// internal
int qFindString(const QChar *haystack, int haystackLen, int from,
const QChar *needle, int needleLen, Qt::CaseSensitivity cs);
int qFindStringBoyerMoore(const QChar *haystack, int haystackLen, int from,
const QChar *needle, int needleLen, Qt::CaseSensitivity cs);
// Unicode case-insensitive comparison
static int ucstricmp(const ushort *a, const ushort *ae, const ushort *b, const ushort *be)
{
if (a == b)
return (ae - be);
if (a == 0)
return 1;
if (b == 0)
return -1;
const ushort *e = ae;
if (be - b < ae - a)
e = a + (be - b);
uint alast = 0;
uint blast = 0;
while (a < e) {
// qDebug() << hex << alast << blast;
// qDebug() << hex << "*a=" << *a << "alast=" << alast << "folded=" << foldCase (*a, alast);
// qDebug() << hex << "*b=" << *b << "blast=" << blast << "folded=" << foldCase (*b, blast);
int diff = foldCase(*a, alast) - foldCase(*b, blast);
if ((diff))
return diff;
++a;
++b;
}
if (a == ae) {
if (b == be)
return 0;
return -1;
}
return 1;
}
// Case-insensitive comparison between a Unicode string and a QLatin1String
static int ucstricmp(const ushort *a, const ushort *ae, const uchar *b)
{
if (a == 0) {
if (b == 0)
return 0;
return 1;
}
if (b == 0)
return -1;
while (a < ae && *b) {
int diff = foldCase(*a) - foldCase(*b);
if ((diff))
return diff;
++a;
++b;
}
if (a == ae) {
if (!*b)
return 0;
return -1;
}
return 1;
}
// Unicode case-sensitive compare two same-sized strings
static int ucstrncmp(const QChar *a, const QChar *b, int l)
{
while (l-- && *a == *b)
a++,b++;
if (l==-1)
return 0;
return a->unicode() - b->unicode();
}
// Unicode case-sensitive comparison
static int ucstrcmp(const QChar *a, int alen, const QChar *b, int blen)
{
if (a == b && alen == blen)
return 0;
int l = qMin(alen, blen);
int cmp = ucstrncmp(a, b, l);
return cmp ? cmp : (alen-blen);
}
// Unicode case-insensitive compare two same-sized strings
static int ucstrnicmp(const ushort *a, const ushort *b, int l)
{
return ucstricmp(a, a + l, b, b + l);
}
// Benchmarking indicates that doing memcmp is much slower than
// executing the comparison ourselves.
//
// The profiling was done on a population of calls to qMemEquals, generated
// during a run of the demo browser. The profile of the data (32-bit x86
// Linux) was:
//
// total number of comparisons: 21353
// longest string compared: 95
// average comparison length: 14.8786
// cache-line crosses: 5661 (13.3%)
// alignment histogram:
// 0xXXX0 = 512 (1.2%) strings, 0 (0.0%) of which same-aligned
// 0xXXX2 = 15087 (35.3%) strings, 5145 (34.1%) of which same-aligned
// 0xXXX4 = 525 (1.2%) strings, 0 (0.0%) of which same-aligned
// 0xXXX6 = 557 (1.3%) strings, 6 (1.1%) of which same-aligned
// 0xXXX8 = 509 (1.2%) strings, 0 (0.0%) of which same-aligned
// 0xXXXa = 24358 (57.0%) strings, 9901 (40.6%) of which same-aligned
// 0xXXXc = 557 (1.3%) strings, 0 (0.0%) of which same-aligned
// 0xXXXe = 601 (1.4%) strings, 15 (2.5%) of which same-aligned
// total = 42706 (100%) strings, 15067 (35.3%) of which same-aligned
//
// 92% of the strings have alignment of 2 or 10, which is due to malloc on
// 32-bit Linux returning values aligned to 8 bytes, and offsetof(array, QString::Data) == 18.
//
// The profile on 64-bit will be different since offsetof(array, QString::Data) == 26.
//
// The benchmark results were, for a Core-i7 @ 2.67 GHz 32-bit, compiled with -O3 -funroll-loops:
// 16-bit loads only: 872,301 CPU ticks [Qt 4.5 / memcmp]
// 32- and 16-bit loads: 773,362 CPU ticks [Qt 4.6]
// SSE2 "movdqu" 128-bit loads: 618,736 CPU ticks
// SSE3 "lddqu" 128-bit loads: 619,954 CPU ticks
// SSSE3 "palignr" corrections: 852,147 CPU ticks
// SSE4.2 "pcmpestrm": 738,702 CPU ticks
//
// The same benchmark on an Atom N450 @ 1.66 GHz, is:
// 16-bit loads only: 2,185,882 CPU ticks
// 32- and 16-bit loads: 1,805,060 CPU ticks
// SSE2 "movdqu" 128-bit loads: 2,529,843 CPU ticks
// SSE3 "lddqu" 128-bit loads: 2,514,858 CPU ticks
// SSSE3 "palignr" corrections: 2,160,325 CPU ticks
// SSE4.2 not available
//
// The conclusion we reach is that alignment the SSE2 unaligned code can gain
// 20% improvement in performance in some systems, but suffers a penalty due
// to the unaligned loads on others.
static bool qMemEquals(const quint16 *a, const quint16 *b, int length)
{
if (a == b || !length)
return true;
register union {
const quint16 *w;
const quint32 *d;
quintptr value;
} sa, sb;
sa.w = a;
sb.w = b;
// check alignment
if ((sa.value & 2) == (sb.value & 2)) {
// both addresses have the same alignment
if (sa.value & 2) {
// both addresses are not aligned to 4-bytes boundaries
// compare the first character
if (*sa.w != *sb.w)
return false;
--length;
++sa.w;
++sb.w;
// now both addresses are 4-bytes aligned
}
// both addresses are 4-bytes aligned
// do a fast 32-bit comparison
register const quint32 *e = sa.d + (length >> 1);
for ( ; sa.d != e; ++sa.d, ++sb.d) {
if (*sa.d != *sb.d)
return false;
}
// do we have a tail?
return (length & 1) ? *sa.w == *sb.w : true;
} else {
// one of the addresses isn't 4-byte aligned but the other is
register const quint16 *e = sa.w + length;
for ( ; sa.w != e; ++sa.w, ++sb.w) {
if (*sa.w != *sb.w)
return false;
}
}
return true;
}
/*!
\internal
Returns the index position of the first occurrence of the
character \a ch in the string given by \a str and \a len,
searching forward from index
position \a from. Returns -1 if \a ch could not be found.
*/
static int findChar(const QChar *str, int len, QChar ch, int from,
Qt::CaseSensitivity cs)
{
const ushort *s = (const ushort *)str;
ushort c = ch.unicode();
if (from < 0)
from = qMax(from + len, 0);
if (from < len) {
const ushort *n = s + from - 1;
const ushort *e = s + len;
if (cs == Qt::CaseSensitive) {
while (++n != e)
if (*n == c)
return n - s;
} else {
c = foldCase(c);
while (++n != e)
if (foldCase(*n) == c)
return n - s;
}
}
return -1;
}
#define REHASH(a) \
if (sl_minus_1 < (int)sizeof(int) * CHAR_BIT) \
hashHaystack -= (a) << sl_minus_1; \
hashHaystack <<= 1
inline bool qIsUpper(char ch)
{
return ch >= 'A' && ch <= 'Z';
}
inline bool qIsDigit(char ch)
{
return ch >= '0' && ch <= '9';
}
inline char qToLower(char ch)
{
if (ch >= 'A' && ch <= 'Z')
return ch - 'A' + 'a';
else
return ch;
}
#if defined(Q_CC_MSVC) && _MSC_VER <= 1300
const QString::Null QString::null;
#else
const QString::Null QString::null = { };
#endif
/*!
\macro QT_NO_CAST_FROM_ASCII
\relates QString
Disables automatic conversions from 8-bit strings (char *) to unicode QStrings
\sa QT_NO_CAST_TO_ASCII, QT_NO_CAST_FROM_BYTEARRAY
*/
/*!
\macro QT_NO_CAST_TO_ASCII
\relates QString
disables automatic conversion from QString to 8-bit strings (char *)
\sa QT_NO_CAST_FROM_ASCII, QT_NO_CAST_FROM_BYTEARRAY
*/
/*!
\macro QT_ASCII_CAST_WARNINGS
\internal
\relates QString
This macro can be defined to force a warning whenever a function is
called that automatically converts between unicode and 8-bit encodings.
Note: This only works for compilers that support warnings for
deprecated API.
\sa QT_NO_CAST_TO_ASCII, QT_NO_CAST_FROM_ASCII
*/
/*!
\class QCharRef
\reentrant
\brief The QCharRef class is a helper class for QString.
\internal
\ingroup string-processing
When you get an object of type QCharRef, if you can assign to it,
the assignment will apply to the character in the string from
which you got the reference. That is its whole purpose in life.
The QCharRef becomes invalid once modifications are made to the
string: if you want to keep the character, copy it into a QChar.
Most of the QChar member functions also exist in QCharRef.
However, they are not explicitly documented here.
\sa QString::operator[]() QString::at() QChar
*/
/*!
\class QString
\reentrant
\brief The QString class provides a Unicode character string.
\ingroup tools
\ingroup shared
\ingroup string-processing
QString stores a string of 16-bit \l{QChar}s, where each QChar
corresponds one Unicode 4.0 character. (Unicode characters
with code values above 65535 are stored using surrogate pairs,
i.e., two consecutive \l{QChar}s.)
\l{Unicode} is an international standard that supports most of the
writing systems in use today. It is a superset of US-ASCII (ANSI
X3.4-1986) and Latin-1 (ISO 8859-1), and all the US-ASCII/Latin-1
characters are available at the same code positions.
Behind the scenes, QString uses \l{implicit sharing}
(copy-on-write) to reduce memory usage and to avoid the needless
copying of data. This also helps reduce the inherent overhead of
storing 16-bit characters instead of 8-bit characters.
In addition to QString, Qt also provides the QByteArray class to
store raw bytes and traditional 8-bit '\\0'-terminated strings.
For most purposes, QString is the class you want to use. It is
used throughout the Qt API, and the Unicode support ensures that
your applications will be easy to translate if you want to expand
your application's market at some point. The two main cases where
QByteArray is appropriate are when you need to store raw binary
data, and when memory conservation is critical (e.g., with
\l{Qt for Embedded Linux}).
\tableofcontents
\section1 Initializing a String
One way to initialize a QString is simply to pass a \c{const char
*} to its constructor. For example, the following code creates a
QString of size 5 containing the data "Hello":
\snippet doc/src/snippets/qstring/main.cpp 0
QString converts the \c{const char *} data into Unicode using the
fromAscii() function. By default, fromAscii() treats character
above 128 as Latin-1 characters, but this can be changed by
calling QTextCodec::setCodecForCStrings().
In all of the QString functions that take \c{const char *}
parameters, the \c{const char *} is interpreted as a classic
C-style '\\0'-terminated string. It is legal for the \c{const char
*} parameter to be 0.
You can also provide string data as an array of \l{QChar}s:
\snippet doc/src/snippets/qstring/main.cpp 1
QString makes a deep copy of the QChar data, so you can modify it
later without experiencing side effects. (If for performance
reasons you don't want to take a deep copy of the character data,
use QString::fromRawData() instead.)
Another approach is to set the size of the string using resize()
and to initialize the data character per character. QString uses
0-based indexes, just like C++ arrays. To access the character at
a particular index position, you can use \l operator[](). On
non-const strings, \l operator[]() returns a reference to a
character that can be used on the left side of an assignment. For
example:
\snippet doc/src/snippets/qstring/main.cpp 2
For read-only access, an alternative syntax is to use the at()
function:
\snippet doc/src/snippets/qstring/main.cpp 3
The at() function can be faster than \l operator[](), because it
never causes a \l{deep copy} to occur. Alternatively, use the
left(), right(), or mid() functions to extract several characters
at a time.
A QString can embed '\\0' characters (QChar::Null). The size()
function always returns the size of the whole string, including
embedded '\\0' characters.
After a call to the resize() function, newly allocated characters
have undefined values. To set all the characters in the string to
a particular value, use the fill() function.
QString provides dozens of overloads designed to simplify string
usage. For example, if you want to compare a QString with a string
literal, you can write code like this and it will work as expected:
\snippet doc/src/snippets/qstring/main.cpp 4
You can also pass string literals to functions that take QStrings
as arguments, invoking the QString(const char *)
constructor. Similarly, you can pass a QString to a function that
takes a \c{const char *} argument using the \l qPrintable() macro
which returns the given QString as a \c{const char *}. This is
equivalent to calling <QString>.toLocal8Bit().constData().
\section1 Manipulating String Data
QString provides the following basic functions for modifying the
character data: append(), prepend(), insert(), replace(), and
remove(). For example:
\snippet doc/src/snippets/qstring/main.cpp 5
If you are building a QString gradually and know in advance
approximately how many characters the QString will contain, you
can call reserve(), asking QString to preallocate a certain amount
of memory. You can also call capacity() to find out how much
memory QString actually allocated.
The replace() and remove() functions' first two arguments are the
position from which to start erasing and the number of characters
that should be erased. If you want to replace all occurrences of
a particular substring with another, use one of the two-parameter
replace() overloads.
A frequent requirement is to remove whitespace characters from a
string ('\\n', '\\t', ' ', etc.). If you want to remove whitespace
from both ends of a QString, use the trimmed() function. If you
want to remove whitespace from both ends and replace multiple
consecutive whitespaces with a single space character within the
string, use simplified().
If you want to find all occurrences of a particular character or
substring in a QString, use the indexOf() or lastIndexOf()
functions. The former searches forward starting from a given index
position, the latter searches backward. Both return the index
position of the character or substring if they find it; otherwise,
they return -1. For example, here's a typical loop that finds all
occurrences of a particular substring:
\snippet doc/src/snippets/qstring/main.cpp 6
QString provides many functions for converting numbers into
strings and strings into numbers. See the arg() functions, the
setNum() functions, the number() static functions, and the
toInt(), toDouble(), and similar functions.
To get an upper- or lowercase version of a string use toUpper() or
toLower().
Lists of strings are handled by the QStringList class. You can
split a string into a list of strings using the split() function,
and join a list of strings into a single string with an optional
separator using QStringList::join(). You can obtain a list of
strings from a string list that contain a particular substring or
that match a particular QRegExp using the QStringList::find()
function.
:
\section1 Querying String Data
If you want to see if a QString starts or ends with a particular
substring use startsWith() or endsWith(). If you simply want to
check whether a QString contains a particular character or
substring, use the contains() function. If you want to find out
how many times a particular character or substring occurs in the
string, use count().
QStrings can be compared using overloaded operators such as \l
operator<(), \l operator<=(), \l operator==(), \l operator>=(),
and so on. Note that the comparison is based exclusively on the
numeric Unicode values of the characters. It is very fast, but is
not what a human would expect; the QString::localeAwareCompare()
function is a better choice for sorting user-interface strings.
To obtain a pointer to the actual character data, call data() or
constData(). These functions return a pointer to the beginning of
the QChar data. The pointer is guaranteed to remain valid until a
non-const function is called on the QString.
\section1 Converting Between 8-Bit Strings and Unicode Strings
QString provides the following four functions that return a
\c{const char *} version of the string as QByteArray: toAscii(),
toLatin1(), toUtf8(), and toLocal8Bit().
\list
\o toAscii() returns an 8-bit string encoded using the codec
specified by QTextCodec::codecForCStrings (by default, that is
Latin 1).
\o toLatin1() returns a Latin-1 (ISO 8859-1) encoded 8-bit string.
\o toUtf8() returns a UTF-8 encoded 8-bit string. UTF-8 is a
superset of US-ASCII (ANSI X3.4-1986) that supports the entire
Unicode character set through multibyte sequences.
\o toLocal8Bit() returns an 8-bit string using the system's local
encoding.
\endlist
To convert from one of these encodings, QString provides
fromAscii(), fromLatin1(), fromUtf8(), and fromLocal8Bit(). Other
encodings are supported through the QTextCodec class.
As mentioned above, QString provides a lot of functions and
operators that make it easy to interoperate with \c{const char *}
strings. But this functionality is a double-edged sword: It makes
QString more convenient to use if all strings are US-ASCII or
Latin-1, but there is always the risk that an implicit conversion
from or to \c{const char *} is done using the wrong 8-bit
encoding. To minimize these risks, you can turn off these implicit
conversions by defining the following two preprocessor symbols:
\list
\o \c QT_NO_CAST_FROM_ASCII disables automatic conversions from
C string literals and pointers to Unicode.
\o \c QT_NO_CAST_TO_ASCII disables automatic conversion from QString
to C strings.
\endlist
One way to define these preprocessor symbols globally for your
application is to add the following entry to your
\l{qmake Project Files}{qmake project file}:
\snippet doc/src/snippets/code/src_corelib_tools_qstring.cpp 0
You then need to explicitly call fromAscii(), fromLatin1(),
fromUtf8(), or fromLocal8Bit() to construct a QString from an
8-bit string, or use the lightweight QLatin1String class, for
example:
\snippet doc/src/snippets/code/src_corelib_tools_qstring.cpp 1
Similarly, you must call toAscii(), toLatin1(), toUtf8(), or
toLocal8Bit() explicitly to convert the QString to an 8-bit
string. (Other encodings are supported through the QTextCodec
class.)
\table 100 %
\row
\o
\section1 Note for C Programmers
Due to C++'s type system and the fact that QString is
\l{implicitly shared}, QStrings may be treated like \c{int}s or
other basic types. For example:
\snippet doc/src/snippets/qstring/main.cpp 7
The \c result variable, is a normal variable allocated on the
stack. When \c return is called, and because we're returning by
value, the copy constructor is called and a copy of the string is
returned. No actual copying takes place thanks to the implicit
sharing.
\endtable
\section1 Distinction Between Null and Empty Strings
For historical reasons, QString distinguishes between a null
string and an empty string. A \e null string is a string that is
initialized using QString's default constructor or by passing
(const char *)0 to the constructor. An \e empty string is any
string with size 0. A null string is always empty, but an empty
string isn't necessarily null:
\snippet doc/src/snippets/qstring/main.cpp 8
All functions except isNull() treat null strings the same as empty
strings. For example, toAscii().constData() returns a pointer to a
'\\0' character for a null string (\e not a null pointer), and
QString() compares equal to QString(""). We recommend that you
always use the isEmpty() function and avoid isNull().
\section1 Argument Formats
In member functions where an argument \e format can be specified
(e.g., arg(), number()), the argument \e format can be one of the
following:
\table
\header \o Format \o Meaning
\row \o \c e \o format as [-]9.9e[+|-]999
\row \o \c E \o format as [-]9.9E[+|-]999
\row \o \c f \o format as [-]9.9
\row \o \c g \o use \c e or \c f format, whichever is the most concise
\row \o \c G \o use \c E or \c f format, whichever is the most concise
\endtable
A \e precision is also specified with the argument \e format. For
the 'e', 'E', and 'f' formats, the \e precision represents the
number of digits \e after the decimal point. For the 'g' and 'G'
formats, the \e precision represents the maximum number of
significant digits (trailing zeroes are omitted).
\section1 More Efficient String Construction
Using the QString \c{'+'} operator, it is easy to construct a
complex string from multiple substrings. You will often write code
like this:
\snippet doc/src/snippets/qstring/stringbuilder.cpp 0
There is nothing wrong with either of these string constructions,
but there are a few hidden inefficiencies. Beginning with Qt 4.6,
you can eliminate them.
First, multiple uses of the \c{'+'} operator usually means
multiple memory allocations. When concatenating \e{n} substrings,
where \e{n > 2}, there can be as many as \e{n - 1} calls to the
memory allocator.
Second, QLatin1String does not store its length internally but
calls qstrlen() when it needs to know its length.
In 4.6, an internal template class \c{QStringBuilder} has been
added along with a few helper functions. This class is marked
internal and does not appear in the documentation, because you
aren't meant to instantiate it in your code. Its use will be
automatic, as described below. The class is found in
\c {src/corelib/tools/qstringbuilder.cpp} if you want to have a
look at it.
\c{QStringBuilder} uses expression templates and reimplements the
\c{'%'} operator so that when you use \c{'%'} for string
concatenation instead of \c{'+'}, multiple substring
concatenations will be postponed until the final result is about
to be assigned to a QString. At this point, the amount of memory
required for the final result is known. The memory allocator is
then called \e{once} to get the required space, and the substrings
are copied into it one by one.
\c{QLatin1Literal} is a second internal class that can replace
QLatin1String, which can't be changed for compatibility reasons.
\c{QLatin1Literal} stores its length, thereby saving time when
\c{QStringBuilder} computes the amount of memory required for the
final string.
Additional efficiency is gained by inlining and reduced reference
counting (the QString created from a \c{QStringBuilder} typically
has a ref count of 1, whereas QString::append() needs an extra
test).
There are three ways you can access this improved method of string
construction. The straightforward way is to include
\c{QStringBuilder} wherever you want to use it, and use the
\c{'%'} operator instead of \c{'+'} when concatenating strings:
\snippet doc/src/snippets/qstring/stringbuilder.cpp 5
A more global approach is to include this define:
\snippet doc/src/snippets/qstring/stringbuilder.cpp 3
and use \c{'%'} instead of \c{'+'} for string concatenation
everywhere. The third approach, which is the most convenient but
not entirely source compatible, is to include two defines:
\snippet doc/src/snippets/qstring/stringbuilder.cpp 4
and the \c{'+'} will automatically be performed as the
\c{QStringBuilder} \c{'%'} everywhere.
\sa fromRawData(), QChar, QLatin1String, QByteArray, QStringRef
*/
/*!
\enum QString::SplitBehavior
This enum specifies how the split() function should behave with
respect to empty strings.
\value KeepEmptyParts If a field is empty, keep it in the result.
\value SkipEmptyParts If a field is empty, don't include it in the result.
\sa split()
*/
QString::Data QString::shared_null = { Q_BASIC_ATOMIC_INITIALIZER(1),
0, 0, shared_null.array, 0, 0, 0, 0, 0, 0, {0} };
QString::Data QString::shared_empty = { Q_BASIC_ATOMIC_INITIALIZER(1),
0, 0, shared_empty.array, 0, 0, 0, 0, 0, 0, {0} };
int QString::grow(int size)
{
return qAllocMore(size * sizeof(QChar), sizeof(Data)) / sizeof(QChar);
}
/*! \typedef QString::ConstIterator
Qt-style synonym for QString::const_iterator.
*/
/*! \typedef QString::Iterator
Qt-style synonym for QString::iterator.
*/
/*! \typedef QString::const_iterator
The QString::const_iterator typedef provides an STL-style const
iterator for QString.
\sa QString::iterator
*/
/*! \typedef QString::iterator
The QString::iterator typedef provides an STL-style non-const
iterator for QString.
\sa QString::const_iterator
*/
/*! \fn QString::iterator QString::begin()
Returns an \l{STL-style iterator} pointing to the first character in
the string.
\sa constBegin(), end()
*/
/*! \fn QString::const_iterator QString::begin() const
\overload begin()
*/
/*! \fn QString::const_iterator QString::constBegin() const
Returns a const \l{STL-style iterator} pointing to the first character
in the string.
\sa begin(), constEnd()
*/
/*! \fn QString::iterator QString::end()
Returns an \l{STL-style iterator} pointing to the imaginary character
after the last character in the string.
\sa begin(), constEnd()
*/
/*! \fn QString::const_iterator QString::end() const
\overload end()
*/
/*! \fn QString::const_iterator QString::constEnd() const
Returns a const \l{STL-style iterator} pointing to the imaginary
item after the last item in the list.
\sa constBegin(), end()
*/
/*!
\fn QString::QString()
Constructs a null string. Null strings are also empty.
\sa isEmpty()
*/
/*! \fn QString::QString(const char *str)
Constructs a string initialized with the 8-bit string \a str. The
given const char pointer is converted to Unicode using the
fromAscii() function.
You can disable this constructor by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
\sa fromAscii(), fromLatin1(), fromLocal8Bit(), fromUtf8()
*/
/*! \fn QString QString::fromStdString(const std::string &str)
Returns a copy of the \a str string. The given string is converted
to Unicode using the fromAscii() function.
This constructor is only available if Qt is configured with STL
compatibility enabled.
\sa fromAscii(), fromLatin1(), fromLocal8Bit(), fromUtf8()
*/
/*! \fn QString QString::fromStdWString(const std::wstring &str)
Returns a copy of the \a str string. The given string is assumed
to be encoded in utf16 if the size of wchar_t is 2 bytes (e.g. on
windows) and ucs4 if the size of wchar_t is 4 bytes (most Unix
systems).
This method is only available if Qt is configured with STL
compatibility enabled.
\sa fromUtf16(), fromLatin1(), fromLocal8Bit(), fromUtf8(), fromUcs4()
*/
/*!
\since 4.2
Returns a copy of the \a string, where the encoding of \a string depends on
the size of wchar. If wchar is 4 bytes, the \a string is interpreted as ucs-4,
if wchar is 2 bytes it is interpreted as ucs-2.
If \a size is -1 (default), the \a string has to be 0 terminated.
\sa fromUtf16(), fromLatin1(), fromLocal8Bit(), fromUtf8(), fromUcs4(), fromStdWString()
*/
QString QString::fromWCharArray(const wchar_t *string, int size)
{
if (sizeof(wchar_t) == sizeof(QChar)) {
return fromUtf16((const ushort *)string, size);
} else {
return fromUcs4((uint *)string, size);
}
}
/*! \fn std::wstring QString::toStdWString() const
Returns a std::wstring object with the data contained in this
QString. The std::wstring is encoded in utf16 on platforms where
wchar_t is 2 bytes wide (e.g. windows) and in ucs4 on platforms
where wchar_t is 4 bytes wide (most Unix systems).
This operator is mostly useful to pass a QString to a function
that accepts a std::wstring object.
This operator is only available if Qt is configured with STL
compatibility enabled.
\sa utf16(), toAscii(), toLatin1(), toUtf8(), toLocal8Bit()
*/
/*!
\since 4.2
Fills the \a array with the data contained in this QString object.
The array is encoded in utf16 on platforms where
wchar_t is 2 bytes wide (e.g. windows) and in ucs4 on platforms
where wchar_t is 4 bytes wide (most Unix systems).
\a array has to be allocated by the caller and contain enough space to
hold the complete string (allocating the array with the same length as the
string is always sufficient).
returns the actual length of the string in \a array.
\note This function does not append a null character to the array.
\sa utf16(), toUcs4(), toAscii(), toLatin1(), toUtf8(), toLocal8Bit(), toStdWString()
*/
int QString::toWCharArray(wchar_t *array) const
{
if (sizeof(wchar_t) == sizeof(QChar)) {
memcpy(array, utf16(), sizeof(wchar_t)*length());
return length();
} else {
wchar_t *a = array;
const unsigned short *uc = utf16();
for (int i = 0; i < length(); ++i) {
uint u = uc[i];
if (QChar::isHighSurrogate(u) && i + 1 < length()) {
ushort low = uc[i+1];
if (QChar::isLowSurrogate(low)) {
u = QChar::surrogateToUcs4(u, low);
++i;
}
}
*a = wchar_t(u);
++a;
}
return a - array;
}
}
/*! \fn QString::QString(const QString &other)
Constructs a copy of \a other.
This operation takes \l{constant time}, because QString is
\l{implicitly shared}. This makes returning a QString from a
function very fast. If a shared instance is modified, it will be
copied (copy-on-write), and that takes \l{linear time}.
\sa operator=()
*/
/*!
Constructs a string initialized with the first \a size characters
of the QChar array \a unicode.
QString makes a deep copy of the string data. The unicode data is copied as
is and the Byte Order Mark is preserved if present.
*/
QString::QString(const QChar *unicode, int size)
{
if (!unicode) {
d = &shared_null;
d->ref.ref();
} else if (size <= 0) {
d = &shared_empty;
d->ref.ref();
} else {
d = (Data*) qMalloc(sizeof(Data)+size*sizeof(QChar));
Q_CHECK_PTR(d);
d->ref = 1;
d->alloc = d->size = size;
d->clean = d->asciiCache = d->simpletext = d->righttoleft = d->capacity = 0;
d->data = d->array;
memcpy(d->array, unicode, size * sizeof(QChar));
d->array[size] = '\0';
}
}
/*!
\since 4.7
Constructs a string initialized with the characters of the QChar array
\a unicode, which must be terminated with a 0.
QString makes a deep copy of the string data. The unicode data is copied as
is and the Byte Order Mark is preserved if present.
*/
QString::QString(const QChar *unicode)
{
if (!unicode) {
d = &shared_null;
d->ref.ref();
} else {
int size = 0;
while (unicode[size] != 0)
++size;
if (!size) {
d = &shared_empty;
d->ref.ref();
} else {
d = (Data*) qMalloc(sizeof(Data)+size*sizeof(QChar));
Q_CHECK_PTR(d);
d->ref = 1;
d->alloc = d->size = size;
d->clean = d->asciiCache = d->simpletext = d->righttoleft = d->capacity = 0;
d->data = d->array;
memcpy(d->array, unicode, size * sizeof(QChar));
d->array[size] = '\0';
}
}
}
/*!
Constructs a string of the given \a size with every character set
to \a ch.
\sa fill()
*/
QString::QString(int size, QChar ch)
{
if (size <= 0) {
d = &shared_empty;
d->ref.ref();
} else {
d = (Data*) qMalloc(sizeof(Data)+size*sizeof(QChar));
Q_CHECK_PTR(d);
d->ref = 1;
d->alloc = d->size = size;
d->clean = d->asciiCache = d->simpletext = d->righttoleft = d->capacity = 0;
d->data = d->array;
d->array[size] = '\0';
ushort *i = d->array + size;
ushort *b = d->array;
const ushort value = ch.unicode();
while (i != b)
*--i = value;
}
}
/*! \fn QString::QString(int size, Qt::Initialization)
\internal
Constructs a string of the given \a size without initializing the
characters. This is only used in \c QStringBuilder::toString().
*/
QString::QString(int size, Qt::Initialization)
{
d = (Data*) qMalloc(sizeof(Data)+size*sizeof(QChar));
Q_CHECK_PTR(d);
d->ref = 1;
d->alloc = d->size = size;
d->clean = d->asciiCache = d->simpletext = d->righttoleft = d->capacity = 0;
d->data = d->array;
d->array[size] = '\0';
}
/*! \fn QString::QString(const QLatin1String &str)
Constructs a copy of the Latin-1 string \a str.
\sa fromLatin1()
*/
/*!
Constructs a string of size 1 containing the character \a ch.
*/
QString::QString(QChar ch)
{
void *buf = qMalloc(sizeof(Data) + sizeof(QChar));
Q_CHECK_PTR(buf);
d = reinterpret_cast<Data *>(buf);
d->ref = 1;
d->alloc = d->size = 1;
d->clean = d->asciiCache = d->simpletext = d->righttoleft = d->capacity = 0;
d->data = d->array;
d->array[0] = ch.unicode();
d->array[1] = '\0';
}
/*! \fn QString::QString(const QByteArray &ba)
Constructs a string initialized with the byte array \a ba. The
given byte array is converted to Unicode using fromAscii(). Stops
copying at the first 0 character, otherwise copies the entire byte
array.
You can disable this constructor by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
\sa fromAscii(), fromLatin1(), fromLocal8Bit(), fromUtf8()
*/
/*! \fn QString::QString(const Null &)
\internal
*/
/*! \fn QString &QString::operator=(const Null &)
\internal
*/
/*!
\fn QString::~QString()
Destroys the string.
*/
/*! \fn void QString::detach()
\internal
*/
/*! \fn bool QString::isDetached() const
\internal
*/
/*! \fn bool QString::isSharedWith(const QString &other) const
\internal
*/
// ### Qt 5: rename freeData() to avoid confusion. See task 197625.
void QString::free(Data *d)
{
#ifdef QT3_SUPPORT
if (d->asciiCache) {
Q_ASSERT(asciiCache);
asciiCache->remove(d);
}
#endif
qFree(d);
}
/*!
Sets the size of the string to \a size characters.
If \a size is greater than the current size, the string is
extended to make it \a size characters long with the extra
characters added to the end. The new characters are uninitialized.
If \a size is less than the current size, characters are removed
from the end.
Example:
\snippet doc/src/snippets/qstring/main.cpp 45
If you want to append a certain number of identical characters to
the string, use \l operator+=() as follows rather than resize():
\snippet doc/src/snippets/qstring/main.cpp 46
If you want to expand the string so that it reaches a certain
width and fill the new positions with a particular character, use
the leftJustified() function:
If \a size is negative, it is equivalent to passing zero.
\snippet doc/src/snippets/qstring/main.cpp 47
\sa truncate(), reserve()
*/
void QString::resize(int size)
{
if (size < 0)
size = 0;
if (size == 0 && !d->capacity) {
Data *x = &shared_empty;
x->ref.ref();
if (!d->ref.deref())
QString::free(d);
d = x;
} else {
if (d->ref != 1 || size > d->alloc ||
(!d->capacity && size < d->size && size < d->alloc >> 1))
realloc(grow(size));
if (d->alloc >= size) {
d->size = size;
if (d->data == d->array) {
d->array[size] = '\0';
}
}
}
}
/*! \fn int QString::capacity() const
Returns the maximum number of characters that can be stored in
the string without forcing a reallocation.
The sole purpose of this function is to provide a means of fine
tuning QString's memory usage. In general, you will rarely ever
need to call this function. If you want to know how many
characters are in the string, call size().
\sa reserve(), squeeze()
*/
/*!
\fn void QString::reserve(int size)
Attempts to allocate memory for at least \a size characters. If
you know in advance how large the string will be, you can call
this function, and if you resize the string often you are likely
to get better performance. If \a size is an underestimate, the
worst that will happen is that the QString will be a bit slower.
The sole purpose of this function is to provide a means of fine
tuning QString's memory usage. In general, you will rarely ever
need to call this function. If you want to change the size of the
string, call resize().
This function is useful for code that needs to build up a long
string and wants to avoid repeated reallocation. In this example,
we want to add to the string until some condition is true, and
we're fairly sure that size is large enough to make a call to
reserve() worthwhile:
\snippet doc/src/snippets/qstring/main.cpp 44
\sa squeeze(), capacity()
*/
/*!
\fn void QString::squeeze()
Releases any memory not required to store the character data.
The sole purpose of this function is to provide a means of fine
tuning QString's memory usage. In general, you will rarely ever
need to call this function.
\sa reserve(), capacity()
*/
// ### Qt 5: rename reallocData() to avoid confusion. 197625
void QString::realloc(int alloc)
{
if (d->ref != 1 || d->data != d->array) {
Data *x = static_cast<Data *>(qMalloc(sizeof(Data) + alloc * sizeof(QChar)));
Q_CHECK_PTR(x);
x->size = qMin(alloc, d->size);
::memcpy(x->array, d->data, x->size * sizeof(QChar));
x->array[x->size] = 0;
x->asciiCache = 0;
x->ref = 1;
x->alloc = alloc;
x->clean = d->clean;
x->simpletext = d->simpletext;
x->righttoleft = d->righttoleft;
x->capacity = d->capacity;
x->data = x->array;
if (!d->ref.deref())
QString::free(d);
d = x;
} else {
#ifdef QT3_SUPPORT
if (d->asciiCache) {
Q_ASSERT(asciiCache);
asciiCache->remove(d);
}
#endif
d = static_cast<Data *>(q_check_ptr(qRealloc(d, sizeof(Data) + alloc * sizeof(QChar))));
d->alloc = alloc;
d->data = d->array;
}
}
void QString::realloc()
{
realloc(d->size);
}
void QString::expand(int i)
{
int sz = d->size;
resize(qMax(i + 1, sz));
if (d->size - 1 > sz) {
ushort *n = d->data + d->size - 1;
ushort *e = d->data + sz;
while (n != e)
* --n = ' ';
}
}
/*! \fn void QString::clear()
Clears the contents of the string and makes it empty.
\sa resize(), isEmpty()
*/
/*! \fn QString &QString::operator=(const QString &other)
Assigns \a other to this string and returns a reference to this
string.
*/
QString &QString::operator=(const QString &other)
{
other.d->ref.ref();
if (!d->ref.deref())
QString::free(d);
d = other.d;
return *this;
}
/*! \fn QString &QString::operator=(const QLatin1String &str)
\overload operator=()
Assigns the Latin-1 string \a str to this string.
*/
/*! \fn QString &QString::operator=(const QByteArray &ba)
\overload operator=()
Assigns \a ba to this string. The byte array is converted to Unicode
using the fromAscii() function. This function stops conversion at the
first NUL character found, or the end of the \a ba byte array.
You can disable this operator by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*! \fn QString &QString::operator=(const char *str)
\overload operator=()
Assigns \a str to this string. The const char pointer is converted
to Unicode using the fromAscii() function.
You can disable this operator by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*! \fn QString &QString::operator=(char ch)
\overload operator=()
Assigns character \a ch to this string. The character is converted
to Unicode using the fromAscii() function.
You can disable this operator by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*!
\overload operator=()
Sets the string to contain the single character \a ch.
*/
QString &QString::operator=(QChar ch)
{
return operator=(QString(ch));
}
/*!
\fn QString& QString::insert(int position, const QString &str)
Inserts the string \a str at the given index \a position and
returns a reference to this string.
Example:
\snippet doc/src/snippets/qstring/main.cpp 26
If the given \a position is greater than size(), the array is
first extended using resize().
\sa append(), prepend(), replace(), remove()
*/
/*!
\fn QString &QString::insert(int position, const QLatin1String &str)
\overload insert()
Inserts the Latin-1 string \a str at the given index \a position.
*/
QString &QString::insert(int i, const QLatin1String &str)
{
const uchar *s = (const uchar *)str.latin1();
if (i < 0 || !s || !(*s))
return *this;
int len = qstrlen(str.latin1());
expand(qMax(d->size, i) + len - 1);
::memmove(d->data + i + len, d->data + i, (d->size - i - len) * sizeof(QChar));
for (int j = 0; j < len; ++j)
d->data[i + j] = s[j];
return *this;
}
/*!
\fn QString& QString::insert(int position, const QChar *unicode, int size)
\overload insert()
Inserts the first \a size characters of the QChar array \a unicode
at the given index \a position in the string.
*/
QString& QString::insert(int i, const QChar *unicode, int size)
{
if (i < 0 || size <= 0)
return *this;
const ushort *s = (const ushort *)unicode;
if (s >= d->data && s < d->data + d->alloc) {
// Part of me - take a copy
ushort *tmp = static_cast<ushort *>(qMalloc(size * sizeof(QChar)));
Q_CHECK_PTR(tmp);
memcpy(tmp, s, size * sizeof(QChar));
insert(i, reinterpret_cast<const QChar *>(tmp), size);
qFree(tmp);
return *this;
}
expand(qMax(d->size, i) + size - 1);
::memmove(d->data + i + size, d->data + i, (d->size - i - size) * sizeof(QChar));
memcpy(d->data + i, s, size * sizeof(QChar));
return *this;
}
/*!
\fn QString& QString::insert(int position, QChar ch)
\overload insert()
Inserts \a ch at the given index \a position in the string.
*/
QString& QString::insert(int i, QChar ch)
{
if (i < 0)
i += d->size;
if (i < 0)
return *this;
expand(qMax(i, d->size));
::memmove(d->data + i + 1, d->data + i, (d->size - i) * sizeof(QChar));
d->data[i] = ch.unicode();
return *this;
}
/*!
Appends the string \a str onto the end of this string.
Example:
\snippet doc/src/snippets/qstring/main.cpp 9
This is the same as using the insert() function:
\snippet doc/src/snippets/qstring/main.cpp 10
The append() function is typically very fast (\l{constant time}),
because QString preallocates extra space at the end of the string
data so it can grow without reallocating the entire string each
time.
\sa operator+=(), prepend(), insert()
*/
QString &QString::append(const QString &str)
{
if (str.d != &shared_null) {
if (d == &shared_null) {
operator=(str);
} else {
if (d->ref != 1 || d->size + str.d->size > d->alloc)
realloc(grow(d->size + str.d->size));
memcpy(d->data + d->size, str.d->data, str.d->size * sizeof(QChar));
d->size += str.d->size;
d->data[d->size] = '\0';
}
}
return *this;
}
/*!
\overload append()
Appends the Latin-1 string \a str to this string.
*/
QString &QString::append(const QLatin1String &str)
{
const uchar *s = (const uchar *)str.latin1();
if (s) {
int len = qstrlen((char *)s);
if (d->ref != 1 || d->size + len > d->alloc)
realloc(grow(d->size + len));
ushort *i = d->data + d->size;
while ((*i++ = *s++))
;
d->size += len;
}
return *this;
}
/*! \fn QString &QString::append(const QByteArray &ba)
\overload append()
Appends the byte array \a ba to this string. The given byte array
is converted to Unicode using the fromAscii() function.
You can disable this function by defining \c QT_NO_CAST_FROM_ASCII
when you compile your applications. This can be useful if you want
to ensure that all user-visible strings go through QObject::tr(),
for example.
*/
/*! \fn QString &QString::append(const char *str)
\overload append()
Appends the string \a str to this string. The given const char
pointer is converted to Unicode using the fromAscii() function.
You can disable this function by defining \c QT_NO_CAST_FROM_ASCII
when you compile your applications. This can be useful if you want
to ensure that all user-visible strings go through QObject::tr(),
for example.
*/
/*!
\overload append()
Appends the character \a ch to this string.
*/
QString &QString::append(QChar ch)
{
if (d->ref != 1 || d->size + 1 > d->alloc)
realloc(grow(d->size + 1));
d->data[d->size++] = ch.unicode();
d->data[d->size] = '\0';
return *this;
}
/*! \fn QString &QString::prepend(const QString &str)
Prepends the string \a str to the beginning of this string and
returns a reference to this string.
Example:
\snippet doc/src/snippets/qstring/main.cpp 36
\sa append(), insert()
*/
/*! \fn QString &QString::prepend(const QLatin1String &str)
\overload prepend()
Prepends the Latin-1 string \a str to this string.
*/
/*! \fn QString &QString::prepend(const QByteArray &ba)
\overload prepend()
Prepends the byte array \a ba to this string. The byte array is
converted to Unicode using the fromAscii() function.
You can disable this function by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*! \fn QString &QString::prepend(const char *str)
\overload prepend()
Prepends the string \a str to this string. The const char pointer
is converted to Unicode using the fromAscii() function.
You can disable this function by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*! \fn QString &QString::prepend(QChar ch)
\overload prepend()
Prepends the character \a ch to this string.
*/
/*!
\fn QString &QString::remove(int position, int n)
Removes \a n characters from the string, starting at the given \a
position index, and returns a reference to the string.
If the specified \a position index is within the string, but \a
position + \a n is beyond the end of the string, the string is
truncated at the specified \a position.
\snippet doc/src/snippets/qstring/main.cpp 37
\sa insert(), replace()
*/
QString &QString::remove(int pos, int len)
{
if (pos < 0) // count from end of string
pos += d->size;
if (pos < 0 || pos >= d->size) {
// range problems
} else if (len >= d->size - pos) {
resize(pos); // truncate
} else if (len > 0) {
detach();
memmove(d->data + pos, d->data + pos + len,
(d->size - pos - len + 1) * sizeof(ushort));
d->size -= len;
}
return *this;
}
/*!
Removes every occurrence of the given \a str string in this
string, and returns a reference to this string.
If \a cs is Qt::CaseSensitive (default), the search is
case sensitive; otherwise the search is case insensitive.
This is the same as \c replace(str, "", cs).
\sa replace()
*/
QString &QString::remove(const QString &str, Qt::CaseSensitivity cs)
{
if (str.d->size) {
int i = 0;
while ((i = indexOf(str, i, cs)) != -1)
remove(i, str.d->size);
}
return *this;
}
/*!
Removes every occurrence of the character \a ch in this string, and
returns a reference to this string.
If \a cs is Qt::CaseSensitive (default), the search is case
sensitive; otherwise the search is case insensitive.
Example:
\snippet doc/src/snippets/qstring/main.cpp 38
This is the same as \c replace(ch, "", cs).
\sa replace()
*/
QString &QString::remove(QChar ch, Qt::CaseSensitivity cs)
{
int i = 0;
ushort c = ch.unicode();
if (cs == Qt::CaseSensitive) {
while (i < d->size)
if (d->data[i] == ch)
remove(i, 1);
else
i++;
} else {
c = foldCase(c);
while (i < d->size)
if (foldCase(d->data[i]) == c)
remove(i, 1);
else
i++;
}
return *this;
}
/*!
\fn QString &QString::remove(const QRegExp &rx)
Removes every occurrence of the regular expression \a rx in the
string, and returns a reference to the string. For example:
\snippet doc/src/snippets/qstring/main.cpp 39
\sa indexOf(), lastIndexOf(), replace()
*/
/*!
\fn QString &QString::replace(int position, int n, const QString &after)
Replaces \a n characters beginning at index \a position with
the string \a after and returns a reference to this string.
Example:
\snippet doc/src/snippets/qstring/main.cpp 40
\sa insert(), remove()
*/
QString &QString::replace(int pos, int len, const QString &after)
{
QString copy = after;
return replace(pos, len, copy.constData(), copy.length());
}
/*!
\fn QString &QString::replace(int position, int n, const QChar *unicode, int size)
\overload replace()
Replaces \a n characters beginning at index \a position with the
first \a size characters of the QChar array \a unicode and returns a
reference to this string.
*/
QString &QString::replace(int pos, int len, const QChar *unicode, int size)
{
if (pos < 0 || pos > d->size)
return *this;
if (pos + len > d->size)
len = d->size - pos;
uint index = pos;
replace_helper(&index, 1, len, unicode, size);
return *this;
}
/*!
\fn QString &QString::replace(int position, int n, QChar after)
\overload replace()
Replaces \a n characters beginning at index \a position with the
character \a after and returns a reference to this string.
*/
QString &QString::replace(int pos, int len, QChar after)
{
return replace(pos, len, &after, 1);
}
/*!
\overload replace()
Replaces every occurrence of the string \a before with the string \a
after and returns a reference to this string.
If \a cs is Qt::CaseSensitive (default), the search is case
sensitive; otherwise the search is case insensitive.
Example:
\snippet doc/src/snippets/qstring/main.cpp 41
\note The replacement text is not rescanned after it is inserted.
Example:
\snippet doc/src/snippets/qstring/main.cpp 86
*/
QString &QString::replace(const QString &before, const QString &after, Qt::CaseSensitivity cs)
{
return replace(before.constData(), before.size(), after.constData(), after.size(), cs);
}
/*!
\internal
*/
void QString::replace_helper(uint *indices, int nIndices, int blen, const QChar *after, int alen)
{
// copy *after in case it lies inside our own d->data area
// (which we could possibly invalidate via a realloc or corrupt via memcpy operations.)
QChar *afterBuffer = const_cast<QChar *>(after);
if (after >= reinterpret_cast<QChar *>(d->data) && after < reinterpret_cast<QChar *>(d->data) + d->size) {
afterBuffer = static_cast<QChar *>(qMalloc(alen*sizeof(QChar)));
Q_CHECK_PTR(afterBuffer);
::memcpy(afterBuffer, after, alen*sizeof(QChar));
}
QT_TRY {
if (blen == alen) {
// replace in place
detach();
for (int i = 0; i < nIndices; ++i)
memcpy(d->data + indices[i], afterBuffer, alen * sizeof(QChar));
} else if (alen < blen) {
// replace from front
detach();
uint to = indices[0];
if (alen)
memcpy(d->data+to, after, alen*sizeof(QChar));
to += alen;
uint movestart = indices[0] + blen;
for (int i = 1; i < nIndices; ++i) {
int msize = indices[i] - movestart;
if (msize > 0) {
memmove(d->data + to, d->data + movestart, msize * sizeof(QChar));
to += msize;
}
if (alen) {
memcpy(d->data + to, afterBuffer, alen*sizeof(QChar));
to += alen;
}
movestart = indices[i] + blen;
}
int msize = d->size - movestart;
if (msize > 0)
memmove(d->data + to, d->data + movestart, msize * sizeof(QChar));
resize(d->size - nIndices*(blen-alen));
} else {
// replace from back
int adjust = nIndices*(alen-blen);
int newLen = d->size + adjust;
int moveend = d->size;
resize(newLen);
while (nIndices) {
--nIndices;
int movestart = indices[nIndices] + blen;
int insertstart = indices[nIndices] + nIndices*(alen-blen);
int moveto = insertstart + alen;
memmove(d->data + moveto, d->data + movestart,
(moveend - movestart)*sizeof(QChar));
memcpy(d->data + insertstart, afterBuffer, alen*sizeof(QChar));
moveend = movestart-blen;
}
}
} QT_CATCH(const std::bad_alloc &) {
if (afterBuffer != after)
qFree(afterBuffer);
QT_RETHROW;
}
if (afterBuffer != after)
qFree(afterBuffer);
}
/*!
\since 4.5
\overload replace()
Replaces each occurrence in this string of the first \a blen
characters of \a before with the first \a alen characters of \a
after and returns a reference to this string.
If \a cs is Qt::CaseSensitive (default), the search is case
sensitive; otherwise the search is case insensitive.
*/
QString &QString::replace(const QChar *before, int blen,
const QChar *after, int alen,
Qt::CaseSensitivity cs)
{
if (d->size == 0) {
if (blen)
return *this;
} else {
if (cs == Qt::CaseSensitive && before == after && blen == alen)
return *this;
}
if (alen == 0 && blen == 0)
return *this;
QStringMatcher matcher(before, blen, cs);
int index = 0;
while (1) {
uint indices[1024];
uint pos = 0;
while (pos < 1023) {
index = matcher.indexIn(*this, index);
if (index == -1)
break;
indices[pos++] = index;
index += blen;
// avoid infinite loop
if (!blen)
index++;
}
if (!pos)
break;
replace_helper(indices, pos, blen, after, alen);
if (index == -1)
break;
// index has to be adjusted in case we get back into the loop above.
index += pos*(alen-blen);
}
return *this;
}
/*!
\overload replace()
Replaces every occurrence of the character \a ch in the string with
\a after and returns a reference to this string.
If \a cs is Qt::CaseSensitive (default), the search is case
sensitive; otherwise the search is case insensitive.
*/
QString& QString::replace(QChar ch, const QString &after, Qt::CaseSensitivity cs)
{
if (after.d->size == 0)
return remove(ch, cs);
if (after.d->size == 1)
return replace(ch, after.d->data[0], cs);
if (d->size == 0)
return *this;
ushort cc = (cs == Qt::CaseSensitive ? ch.unicode() : ch.toCaseFolded().unicode());
int index = 0;
while (1) {
uint indices[1024];
uint pos = 0;
if (cs == Qt::CaseSensitive) {
while (pos < 1023 && index < d->size) {
if (d->data[index] == cc)
indices[pos++] = index;
index++;
}
} else {
while (pos < 1023 && index < d->size) {
if (QChar::toCaseFolded(d->data[index]) == cc)
indices[pos++] = index;
index++;
}
}
if (!pos)
break;
replace_helper(indices, pos, 1, after.constData(), after.d->size);
if (index == -1)
break;
// index has to be adjusted in case we get back into the loop above.
index += pos*(after.d->size - 1);
}
return *this;
}
/*!
\overload replace()
Replaces every occurrence of the character \a before with the
character \a after and returns a reference to this string.
If \a cs is Qt::CaseSensitive (default), the search is case
sensitive; otherwise the search is case insensitive.
*/
QString& QString::replace(QChar before, QChar after, Qt::CaseSensitivity cs)
{
ushort a = after.unicode();
ushort b = before.unicode();
if (d->size) {
detach();
ushort *i = d->data;
const ushort *e = i + d->size;
if (cs == Qt::CaseSensitive) {
for (; i != e; ++i)
if (*i == b)
*i = a;
} else {
b = foldCase(b);
for (; i != e; ++i)
if (foldCase(*i) == b)
*i = a;
}
}
return *this;
}
/*!
\since 4.5
\overload replace()
Replaces every occurrence of the string \a before with the string \a
after and returns a reference to this string.
If \a cs is Qt::CaseSensitive (default), the search is case
sensitive; otherwise the search is case insensitive.
\note The text is not rescanned after a replacement.
*/
QString &QString::replace(const QLatin1String &before,
const QLatin1String &after,
Qt::CaseSensitivity cs)
{
int alen = qstrlen(after.latin1());
QVarLengthArray<ushort> a(alen);
for (int i = 0; i < alen; ++i)
a[i] = (uchar)after.latin1()[i];
int blen = qstrlen(before.latin1());
QVarLengthArray<ushort> b(blen);
for (int i = 0; i < blen; ++i)
b[i] = (uchar)before.latin1()[i];
return replace((const QChar *)b.data(), blen, (const QChar *)a.data(), alen, cs);
}
/*!
\since 4.5
\overload replace()
Replaces every occurrence of the string \a before with the string \a
after and returns a reference to this string.
If \a cs is Qt::CaseSensitive (default), the search is case
sensitive; otherwise the search is case insensitive.
\note The text is not rescanned after a replacement.
*/
QString &QString::replace(const QLatin1String &before,
const QString &after,
Qt::CaseSensitivity cs)
{
int blen = qstrlen(before.latin1());
QVarLengthArray<ushort> b(blen);
for (int i = 0; i < blen; ++i)
b[i] = (uchar)before.latin1()[i];
return replace((const QChar *)b.data(), blen, after.constData(), after.d->size, cs);
}
/*!
\since 4.5
\overload replace()
Replaces every occurrence of the string \a before with the string \a
after and returns a reference to this string.
If \a cs is Qt::CaseSensitive (default), the search is case
sensitive; otherwise the search is case insensitive.
\note The text is not rescanned after a replacement.
*/
QString &QString::replace(const QString &before,
const QLatin1String &after,
Qt::CaseSensitivity cs)
{
int alen = qstrlen(after.latin1());
QVarLengthArray<ushort> a(alen);
for (int i = 0; i < alen; ++i)
a[i] = (uchar)after.latin1()[i];
return replace(before.constData(), before.d->size, (const QChar *)a.data(), alen, cs);
}
/*!
\since 4.5
\overload replace()
Replaces every occurrence of the character \a c with the string \a
after and returns a reference to this string.
If \a cs is Qt::CaseSensitive (default), the search is case
sensitive; otherwise the search is case insensitive.
\note The text is not rescanned after a replacement.
*/
QString &QString::replace(QChar c, const QLatin1String &after, Qt::CaseSensitivity cs)
{
int alen = qstrlen(after.latin1());
QVarLengthArray<ushort> a(alen);
for (int i = 0; i < alen; ++i)
a[i] = (uchar)after.latin1()[i];
return replace(&c, 1, (const QChar *)a.data(), alen, cs);
}
/*!
Returns true if string \a other is equal to this string; otherwise
returns false.
The comparison is based exclusively on the numeric Unicode values of
the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings with
localeAwareCompare().
*/
bool QString::operator==(const QString &other) const
{
if (d->size != other.d->size)
return false;
return qMemEquals(d->data, other.d->data, d->size);
}
/*!
\overload operator==()
*/
bool QString::operator==(const QLatin1String &other) const
{
const ushort *uc = d->data;
const ushort *e = uc + d->size;
const uchar *c = (uchar *)other.latin1();
if (!c)
return isEmpty();
while (*c) {
if (uc == e || *uc != *c)
return false;
++uc;
++c;
}
return (uc == e);
}
/*! \fn bool QString::operator==(const QByteArray &other) const
\overload operator==()
The \a other byte array is converted to a QString using the
fromAscii() function. This function stops conversion at the
first NUL character found, or the end of the byte array.
You can disable this operator by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*! \fn bool QString::operator==(const char *other) const
\overload operator==()
The \a other const char pointer is converted to a QString using
the fromAscii() function.
You can disable this operator by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*!
Returns true if this string is lexically less than string \a
other; otherwise returns false.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings using the
QString::localeAwareCompare() function.
*/
bool QString::operator<(const QString &other) const
{
return ucstrcmp(constData(), length(), other.constData(), other.length()) < 0;
}
/*!
\overload operator<()
*/
bool QString::operator<(const QLatin1String &other) const
{
const ushort *uc = d->data;
const ushort *e = uc + d->size;
const uchar *c = (uchar *) other.latin1();
if (!c || *c == 0)
return false;
while (*c) {
if (uc == e || *uc != *c)
break;
++uc;
++c;
}
return (uc == e ? *c : *uc < *c);
}
/*! \fn bool QString::operator<(const QByteArray &other) const
\overload operator<()
The \a other byte array is converted to a QString using the
fromAscii() function. If any NUL characters ('\0') are embedded
in the byte array, they will be included in the transformation.
You can disable this operator by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*! \fn bool QString::operator<(const char *other) const
\overload operator<()
The \a other const char pointer is converted to a QString using
the fromAscii() function.
You can disable this operator by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*! \fn bool QString::operator<=(const QString &other) const
Returns true if this string is lexically less than or equal to
string \a other; otherwise returns false.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings with
localeAwareCompare().
*/
/*! \fn bool QString::operator<=(const QLatin1String &other) const
\overload operator<=()
*/
/*! \fn bool QString::operator<=(const QByteArray &other) const
\overload operator<=()
The \a other byte array is converted to a QString using the
fromAscii() function. If any NUL characters ('\0') are embedded
in the byte array, they will be included in the transformation.
You can disable this operator by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*! \fn bool QString::operator<=(const char *other) const
\overload operator<=()
The \a other const char pointer is converted to a QString using
the fromAscii() function.
You can disable this operator by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*! \fn bool QString::operator>(const QString &other) const
Returns true if this string is lexically greater than string \a
other; otherwise returns false.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings with
localeAwareCompare().
*/
/*!
\overload operator>()
*/
bool QString::operator>(const QLatin1String &other) const
{
const ushort *uc = d->data;;
const ushort *e = uc + d->size;
const uchar *c = (uchar *) other.latin1();
if (!c || *c == '\0')
return !isEmpty();
while (*c) {
if (uc == e || *uc != *c)
break;
++uc;
++c;
}
return (uc == e ? false : *uc > *c);
}
/*! \fn bool QString::operator>(const QByteArray &other) const
\overload operator>()
The \a other byte array is converted to a QString using the
fromAscii() function. If any NUL characters ('\0') are embedded
in the byte array, they will be included in the transformation.
You can disable this operator by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*! \fn bool QString::operator>(const char *other) const
\overload operator>()
The \a other const char pointer is converted to a QString using
the fromAscii() function.
You can disable this operator by defining \c QT_NO_CAST_FROM_ASCII
when you compile your applications. This can be useful if you want
to ensure that all user-visible strings go through QObject::tr(),
for example.
*/
/*! \fn bool QString::operator>=(const QString &other) const
Returns true if this string is lexically greater than or equal to
string \a other; otherwise returns false.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings with
localeAwareCompare().
*/
/*! \fn bool QString::operator>=(const QLatin1String &other) const
\overload operator>=()
*/
/*! \fn bool QString::operator>=(const QByteArray &other) const
\overload operator>=()
The \a other byte array is converted to a QString using the
fromAscii() function. If any NUL characters ('\0') are embedded in
the byte array, they will be included in the transformation.
You can disable this operator by defining \c QT_NO_CAST_FROM_ASCII
when you compile your applications. This can be useful if you want
to ensure that all user-visible strings go through QObject::tr(),
for example.
*/
/*! \fn bool QString::operator>=(const char *other) const
\overload operator>=()
The \a other const char pointer is converted to a QString using
the fromAscii() function.
You can disable this operator by defining \c QT_NO_CAST_FROM_ASCII
when you compile your applications. This can be useful if you want
to ensure that all user-visible strings go through QObject::tr(),
for example.
*/
/*! \fn bool QString::operator!=(const QString &other) const
Returns true if this string is not equal to string \a other;
otherwise returns false.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings with
localeAwareCompare().
*/
/*! \fn bool QString::operator!=(const QLatin1String &other) const
\overload operator!=()
*/
/*! \fn bool QString::operator!=(const QByteArray &other) const
\overload operator!=()
The \a other byte array is converted to a QString using the
fromAscii() function. If any NUL characters ('\0') are embedded
in the byte array, they will be included in the transformation.
You can disable this operator by defining \c QT_NO_CAST_FROM_ASCII
when you compile your applications. This can be useful if you want
to ensure that all user-visible strings go through QObject::tr(),
for example.
*/
/*! \fn bool QString::operator!=(const char *other) const
\overload operator!=()
The \a other const char pointer is converted to a QString using
the fromAscii() function.
You can disable this operator by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*!
Returns the index position of the first occurrence of the string \a
str in this string, searching forward from index position \a
from. Returns -1 if \a str is not found.
If \a cs is Qt::CaseSensitive (default), the search is case
sensitive; otherwise the search is case insensitive.
Example:
\snippet doc/src/snippets/qstring/main.cpp 24
If \a from is -1, the search starts at the last character; if it is
-2, at the next to last character and so on.
\sa lastIndexOf(), contains(), count()
*/
int QString::indexOf(const QString &str, int from, Qt::CaseSensitivity cs) const
{
return qFindString(unicode(), length(), from, str.unicode(), str.length(), cs);
}
/*!
\since 4.5
Returns the index position of the first occurrence of the string \a
str in this string, searching forward from index position \a
from. Returns -1 if \a str is not found.
If \a cs is Qt::CaseSensitive (default), the search is case
sensitive; otherwise the search is case insensitive.
Example:
\snippet doc/src/snippets/qstring/main.cpp 24
If \a from is -1, the search starts at the last character; if it is
-2, at the next to last character and so on.
\sa lastIndexOf(), contains(), count()
*/
int QString::indexOf(const QLatin1String &str, int from, Qt::CaseSensitivity cs) const
{
int len = qstrlen(str.latin1());
QVarLengthArray<ushort> s(len);
for (int i = 0; i < len; ++i)
s[i] = str.latin1()[i];
return qFindString(unicode(), length(), from, (const QChar *)s.data(), len, cs);
}
int qFindString(
const QChar *haystack0, int haystackLen, int from,
const QChar *needle0, int needleLen, Qt::CaseSensitivity cs)
{
const int l = haystackLen;
const int sl = needleLen;
if (from < 0)
from += l;
if (uint(sl + from) > (uint)l)
return -1;
if (!sl)
return from;
if (!l)
return -1;
if (sl == 1)
return findChar(haystack0, haystackLen, needle0[0], from, cs);
/*
We use the Boyer-Moore algorithm in cases where the overhead
for the skip table should pay off, otherwise we use a simple
hash function.
*/
if (l > 500 && sl > 5)
return qFindStringBoyerMoore(haystack0, haystackLen, from,
needle0, needleLen, cs);
/*
We use some hashing for efficiency's sake. Instead of
comparing strings, we compare the hash value of str with that
of a part of this QString. Only if that matches, we call
ucstrncmp() or ucstrnicmp().
*/
const ushort *needle = (const ushort *)needle0;
const ushort *haystack = (const ushort *)haystack0 + from;
const ushort *end = (const ushort *)haystack0 + (l-sl);
const int sl_minus_1 = sl-1;
int hashNeedle = 0, hashHaystack = 0, idx;
if (cs == Qt::CaseSensitive) {
for (idx = 0; idx < sl; ++idx) {
hashNeedle = ((hashNeedle<<1) + needle[idx]);
hashHaystack = ((hashHaystack<<1) + haystack[idx]);
}
hashHaystack -= haystack[sl_minus_1];
while (haystack <= end) {
hashHaystack += haystack[sl_minus_1];
if (hashHaystack == hashNeedle
&& ucstrncmp((const QChar *)needle, (const QChar *)haystack, sl) == 0)
return haystack - (const ushort *)haystack0;
REHASH(*haystack);
++haystack;
}
} else {
const ushort *haystack_start = (const ushort *)haystack0;
for (idx = 0; idx < sl; ++idx) {
hashNeedle = (hashNeedle<<1) + foldCase(needle + idx, needle);
hashHaystack = (hashHaystack<<1) + foldCase(haystack + idx, haystack_start);
}
hashHaystack -= foldCase(haystack + sl_minus_1, haystack_start);
while (haystack <= end) {
hashHaystack += foldCase(haystack + sl_minus_1, haystack_start);
if (hashHaystack == hashNeedle && ucstrnicmp(needle, haystack, sl) == 0)
return haystack - (const ushort *)haystack0;
REHASH(foldCase(haystack, haystack_start));
++haystack;
}
}
return -1;
}
/*!
\overload indexOf()
Returns the index position of the first occurrence of the
character \a ch in the string, searching forward from index
position \a from. Returns -1 if \a ch could not be found.
*/
int QString::indexOf(QChar ch, int from, Qt::CaseSensitivity cs) const
{
return findChar(unicode(), length(), ch, from, cs);
}
static int lastIndexOfHelper(const ushort *haystack, int from, const ushort *needle, int sl, Qt::CaseSensitivity cs)
{
/*
See indexOf() for explanations.
*/
const ushort *end = haystack;
haystack += from;
const int sl_minus_1 = sl-1;
const ushort *n = needle+sl_minus_1;
const ushort *h = haystack+sl_minus_1;
int hashNeedle = 0, hashHaystack = 0, idx;
if (cs == Qt::CaseSensitive) {
for (idx = 0; idx < sl; ++idx) {
hashNeedle = ((hashNeedle<<1) + *(n-idx));
hashHaystack = ((hashHaystack<<1) + *(h-idx));
}
hashHaystack -= *haystack;
while (haystack >= end) {
hashHaystack += *haystack;
if (hashHaystack == hashNeedle
&& ucstrncmp((const QChar *)needle, (const QChar *)haystack, sl) == 0)
return haystack - end;
--haystack;
REHASH(haystack[sl]);
}
} else {
for (idx = 0; idx < sl; ++idx) {
hashNeedle = ((hashNeedle<<1) + foldCase(n-idx, needle));
hashHaystack = ((hashHaystack<<1) + foldCase(h-idx, end));
}
hashHaystack -= foldCase(haystack, end);
while (haystack >= end) {
hashHaystack += foldCase(haystack, end);
if (hashHaystack == hashNeedle && ucstrnicmp(needle, haystack, sl) == 0)
return haystack - end;
--haystack;
REHASH(foldCase(haystack + sl, end));
}
}
return -1;
}
/*!
Returns the index position of the last occurrence of the string \a
str in this string, searching backward from index position \a
from. If \a from is -1 (default), the search starts at the last
character; if \a from is -2, at the next to last character and so
on. Returns -1 if \a str is not found.
If \a cs is Qt::CaseSensitive (default), the search is case
sensitive; otherwise the search is case insensitive.
Example:
\snippet doc/src/snippets/qstring/main.cpp 29
\sa indexOf(), contains(), count()
*/
int QString::lastIndexOf(const QString &str, int from, Qt::CaseSensitivity cs) const
{
const int sl = str.d->size;
if (sl == 1)
return lastIndexOf(QChar(str.d->data[0]), from, cs);
const int l = d->size;
if (from < 0)
from += l;
int delta = l-sl;
if (from == l && sl == 0)
return from;
if (from < 0 || from >= l || delta < 0)
return -1;
if (from > delta)
from = delta;
return lastIndexOfHelper(d->data, from, str.d->data, str.d->size, cs);
}
/*!
\since 4.5
Returns the index position of the last occurrence of the string \a
str in this string, searching backward from index position \a
from. If \a from is -1 (default), the search starts at the last
character; if \a from is -2, at the next to last character and so
on. Returns -1 if \a str is not found.
If \a cs is Qt::CaseSensitive (default), the search is case
sensitive; otherwise the search is case insensitive.
Example:
\snippet doc/src/snippets/qstring/main.cpp 29
\sa indexOf(), contains(), count()
*/
int QString::lastIndexOf(const QLatin1String &str, int from, Qt::CaseSensitivity cs) const
{
const int sl = qstrlen(str.latin1());
if (sl == 1)
return lastIndexOf(QLatin1Char(str.latin1()[0]), from, cs);
const int l = d->size;
if (from < 0)
from += l;
int delta = l-sl;
if (from == l && sl == 0)
return from;
if (from < 0 || from >= l || delta < 0)
return -1;
if (from > delta)
from = delta;
QVarLengthArray<ushort> s(sl);
for (int i = 0; i < sl; ++i)
s[i] = str.latin1()[i];
return lastIndexOfHelper(d->data, from, s.data(), sl, cs);
}
/*!
\overload lastIndexOf()
Returns the index position of the last occurrence of the character
\a ch, searching backward from position \a from.
*/
int QString::lastIndexOf(QChar ch, int from, Qt::CaseSensitivity cs) const
{
ushort c = ch.unicode();
if (from < 0)
from += d->size;
if (from < 0 || from >= d->size)
return -1;
if (from >= 0) {
const ushort *n = d->data + from;
const ushort *b = d->data;
if (cs == Qt::CaseSensitive) {
for (; n >= b; --n)
if (*n == c)
return n - b;
} else {
c = foldCase(c);
for (; n >= b; --n)
if (foldCase(*n) == c)
return n - b;
}
}
return -1;
}
#ifndef QT_NO_REGEXP
struct QStringCapture
{
int pos;
int len;
int no;
};
/*!
\overload replace()
Replaces every occurrence of the regular expression \a rx in the
string with \a after. Returns a reference to the string. For
example:
\snippet doc/src/snippets/qstring/main.cpp 42
For regular expressions containing \l{capturing parentheses},
occurrences of \bold{\\1}, \bold{\\2}, ..., in \a after are replaced
with \a{rx}.cap(1), cap(2), ...
\snippet doc/src/snippets/qstring/main.cpp 43
\sa indexOf(), lastIndexOf(), remove(), QRegExp::cap()
*/
QString& QString::replace(const QRegExp &rx, const QString &after)
{
QRegExp rx2(rx);
if (isEmpty() && rx2.indexIn(*this) == -1)
return *this;
realloc();
int index = 0;
int numCaptures = rx2.captureCount();
int al = after.length();
QRegExp::CaretMode caretMode = QRegExp::CaretAtZero;
if (numCaptures > 0) {
const QChar *uc = after.unicode();
int numBackRefs = 0;
for (int i = 0; i < al - 1; i++) {
if (uc[i] == QLatin1Char('\\')) {
int no = uc[i + 1].digitValue();
if (no > 0 && no <= numCaptures)
numBackRefs++;
}
}
/*
This is the harder case where we have back-references.
*/
if (numBackRefs > 0) {
QVarLengthArray<QStringCapture, 16> captures(numBackRefs);
int j = 0;
for (int i = 0; i < al - 1; i++) {
if (uc[i] == QLatin1Char('\\')) {
int no = uc[i + 1].digitValue();
if (no > 0 && no <= numCaptures) {
QStringCapture capture;
capture.pos = i;
capture.len = 2;
if (i < al - 2) {
int secondDigit = uc[i + 2].digitValue();
if (secondDigit != -1 && ((no * 10) + secondDigit) <= numCaptures) {
no = (no * 10) + secondDigit;
++capture.len;
}
}
capture.no = no;
captures[j++] = capture;
}
}
}
while (index <= length()) {
index = rx2.indexIn(*this, index, caretMode);
if (index == -1)
break;
QString after2(after);
for (j = numBackRefs - 1; j >= 0; j--) {
const QStringCapture &capture = captures[j];
after2.replace(capture.pos, capture.len, rx2.cap(capture.no));
}
replace(index, rx2.matchedLength(), after2);
index += after2.length();
// avoid infinite loop on 0-length matches (e.g., QRegExp("[a-z]*"))
if (rx2.matchedLength() == 0)
++index;
caretMode = QRegExp::CaretWontMatch;
}
return *this;
}
}
/*
This is the simple and optimized case where we don't have
back-references.
*/
while (index != -1) {
struct {
int pos;
int length;
} replacements[2048];
int pos = 0;
int adjust = 0;
while (pos < 2047) {
index = rx2.indexIn(*this, index, caretMode);
if (index == -1)
break;
int ml = rx2.matchedLength();
replacements[pos].pos = index;
replacements[pos++].length = ml;
index += ml;
adjust += al - ml;
// avoid infinite loop
if (!ml)
index++;
}
if (!pos)
break;
replacements[pos].pos = d->size;
int newlen = d->size + adjust;
// to continue searching at the right position after we did
// the first round of replacements
if (index != -1)
index += adjust;
QString newstring;
newstring.reserve(newlen + 1);
QChar *newuc = newstring.data();
QChar *uc = newuc;
int copystart = 0;
int i = 0;
while (i < pos) {
int copyend = replacements[i].pos;
int size = copyend - copystart;
memcpy(uc, d->data + copystart, size * sizeof(QChar));
uc += size;
memcpy(uc, after.d->data, al * sizeof(QChar));
uc += al;
copystart = copyend + replacements[i].length;
i++;
}
memcpy(uc, d->data + copystart, (d->size - copystart) * sizeof(QChar));
newstring.resize(newlen);
*this = newstring;
caretMode = QRegExp::CaretWontMatch;
}
return *this;
}
#endif
/*!
Returns the number of (potentially overlapping) occurrences of
the string \a str in this string.
If \a cs is Qt::CaseSensitive (default), the search is
case sensitive; otherwise the search is case insensitive.
\sa contains(), indexOf()
*/
int QString::count(const QString &str, Qt::CaseSensitivity cs) const
{
int num = 0;
int i = -1;
if (d->size > 500 && str.d->size > 5) {
QStringMatcher matcher(str, cs);
while ((i = matcher.indexIn(*this, i + 1)) != -1)
++num;
} else {
while ((i = indexOf(str, i + 1, cs)) != -1)
++num;
}
return num;
}
/*!
\overload count()
Returns the number of occurrences of character \a ch in the string.
*/
int QString::count(QChar ch, Qt::CaseSensitivity cs) const
{
ushort c = ch.unicode();
int num = 0;
const ushort *i = d->data + d->size;
const ushort *b = d->data;
if (cs == Qt::CaseSensitive) {
while (i != b)
if (*--i == c)
++num;
} else {
c = foldCase(c);
while (i != b)
if (foldCase(*(--i)) == c)
++num;
}
return num;
}
/*! \fn bool QString::contains(const QString &str, Qt::CaseSensitivity cs = Qt::CaseSensitive) const
Returns true if this string contains an occurrence of the string
\a str; otherwise returns false.
If \a cs is Qt::CaseSensitive (default), the search is
case sensitive; otherwise the search is case insensitive.
Example:
\snippet doc/src/snippets/qstring/main.cpp 17
\sa indexOf(), count()
*/
/*! \fn bool QString::contains(QChar ch, Qt::CaseSensitivity cs = Qt::CaseSensitive) const
\overload contains()
Returns true if this string contains an occurrence of the
character \a ch; otherwise returns false.
*/
/*! \fn bool QString::contains(const QRegExp &rx) const
\overload contains()
Returns true if the regular expression \a rx matches somewhere in
this string; otherwise returns false.
*/
/*! \fn bool QString::contains(QRegExp &rx) const
\overload contains()
\since 4.5
Returns true if the regular expression \a rx matches somewhere in
this string; otherwise returns false.
If there is a match, the \a rx regular expression will contain the
matched captures (see QRegExp::matchedLength, QRegExp::cap).
*/
#ifndef QT_NO_REGEXP
/*!
\overload indexOf()
Returns the index position of the first match of the regular
expression \a rx in the string, searching forward from index
position \a from. Returns -1 if \a rx didn't match anywhere.
Example:
\snippet doc/src/snippets/qstring/main.cpp 25
*/
int QString::indexOf(const QRegExp& rx, int from) const
{
QRegExp rx2(rx);
return rx2.indexIn(*this, from);
}
/*!
\overload indexOf()
\since 4.5
Returns the index position of the first match of the regular
expression \a rx in the string, searching forward from index
position \a from. Returns -1 if \a rx didn't match anywhere.
If there is a match, the \a rx regular expression will contain the
matched captures (see QRegExp::matchedLength, QRegExp::cap).
Example:
\snippet doc/src/snippets/qstring/main.cpp 25
*/
int QString::indexOf(QRegExp& rx, int from) const
{
return rx.indexIn(*this, from);
}
/*!
\overload lastIndexOf()
Returns the index position of the last match of the regular
expression \a rx in the string, searching backward from index
position \a from. Returns -1 if \a rx didn't match anywhere.
Example:
\snippet doc/src/snippets/qstring/main.cpp 30
*/
int QString::lastIndexOf(const QRegExp& rx, int from) const
{
QRegExp rx2(rx);
return rx2.lastIndexIn(*this, from);
}
/*!
\overload lastIndexOf()
\since 4.5
Returns the index position of the last match of the regular
expression \a rx in the string, searching backward from index
position \a from. Returns -1 if \a rx didn't match anywhere.
If there is a match, the \a rx regular expression will contain the
matched captures (see QRegExp::matchedLength, QRegExp::cap).
Example:
\snippet doc/src/snippets/qstring/main.cpp 30
*/
int QString::lastIndexOf(QRegExp& rx, int from) const
{
return rx.lastIndexIn(*this, from);
}
/*!
\overload count()
Returns the number of times the regular expression \a rx matches
in the string.
This function counts overlapping matches, so in the example
below, there are four instances of "ana" or "ama":
\snippet doc/src/snippets/qstring/main.cpp 18
*/
int QString::count(const QRegExp& rx) const
{
QRegExp rx2(rx);
int count = 0;
int index = -1;
int len = length();
while (index < len - 1) { // count overlapping matches
index = rx2.indexIn(*this, index + 1);
if (index == -1)
break;
count++;
}
return count;
}
#endif // QT_NO_REGEXP
/*! \fn int QString::count() const
\overload count()
Same as size().
*/
/*!
\enum QString::SectionFlag
This enum specifies flags that can be used to affect various
aspects of the section() function's behavior with respect to
separators and empty fields.
\value SectionDefault Empty fields are counted, leading and
trailing separators are not included, and the separator is
compared case sensitively.
\value SectionSkipEmpty Treat empty fields as if they don't exist,
i.e. they are not considered as far as \e start and \e end are
concerned.
\value SectionIncludeLeadingSep Include the leading separator (if
any) in the result string.
\value SectionIncludeTrailingSep Include the trailing separator
(if any) in the result string.
\value SectionCaseInsensitiveSeps Compare the separator
case-insensitively.
\sa section()
*/
/*!
\fn QString QString::section(QChar sep, int start, int end = -1, SectionFlags flags) const
This function returns a section of the string.
This string is treated as a sequence of fields separated by the
character, \a sep. The returned string consists of the fields from
position \a start to position \a end inclusive. If \a end is not
specified, all fields from position \a start to the end of the
string are included. Fields are numbered 0, 1, 2, etc., counting
from the left, and -1, -2, etc., counting from right to left.
The \a flags argument can be used to affect some aspects of the
function's behavior, e.g. whether to be case sensitive, whether
to skip empty fields and how to deal with leading and trailing
separators; see \l{SectionFlags}.
\snippet doc/src/snippets/qstring/main.cpp 52
If \a start or \a end is negative, we count fields from the right
of the string, the right-most field being -1, the one from
right-most field being -2, and so on.
\snippet doc/src/snippets/qstring/main.cpp 53
\sa split()
*/
/*!
\overload section()
\snippet doc/src/snippets/qstring/main.cpp 51
\snippet doc/src/snippets/qstring/main.cpp 54
\sa split()
*/
QString QString::section(const QString &sep, int start, int end, SectionFlags flags) const
{
QStringList sections = split(sep, KeepEmptyParts,
(flags & SectionCaseInsensitiveSeps) ? Qt::CaseInsensitive : Qt::CaseSensitive);
if (sections.isEmpty())
return QString();
if (!(flags & SectionSkipEmpty)) {
if (start < 0)
start += sections.count();
if (end < 0)
end += sections.count();
} else {
int skip = 0;
for (int k=0; k<sections.size(); ++k) {
if (sections.at(k).isEmpty())
skip++;
}
if (start < 0)
start += sections.count() - skip;
if (end < 0)
end += sections.count() - skip;
}
int x = 0;
QString ret;
int first_i = start, last_i = end;
for (int i = 0; x <= end && i < sections.size(); ++i) {
QString section = sections.at(i);
const bool empty = section.isEmpty();
if (x >= start) {
if(x == start)
first_i = i;
if(x == end)
last_i = i;
if(x > start)
ret += sep;
ret += section;
}
if (!empty || !(flags & SectionSkipEmpty))
x++;
}
if((flags & SectionIncludeLeadingSep) && first_i)
ret.prepend(sep);
if((flags & SectionIncludeTrailingSep) && last_i < sections.size()-1)
ret += sep;
return ret;
}
#ifndef QT_NO_REGEXP
class qt_section_chunk {
public:
qt_section_chunk(int l, QString s) { length = l; string = s; }
int length;
QString string;
};
/*!
\overload section()
This string is treated as a sequence of fields separated by the
regular expression, \a reg.
\snippet doc/src/snippets/qstring/main.cpp 55
\warning Using this QRegExp version is much more expensive than
the overloaded string and character versions.
\sa split() simplified()
*/
QString QString::section(const QRegExp ®, int start, int end, SectionFlags flags) const
{
const QChar *uc = unicode();
if(!uc)
return QString();
QRegExp sep(reg);
sep.setCaseSensitivity((flags & SectionCaseInsensitiveSeps) ? Qt::CaseInsensitive
: Qt::CaseSensitive);
QList<qt_section_chunk> sections;
int n = length(), m = 0, last_m = 0, last_len = 0;
while ((m = sep.indexIn(*this, m)) != -1) {
sections.append(qt_section_chunk(last_len, QString(uc + last_m, m - last_m)));
last_m = m;
last_len = sep.matchedLength();
m += qMax(sep.matchedLength(), 1);
}
sections.append(qt_section_chunk(last_len, QString(uc + last_m, n - last_m)));
if(start < 0)
start += sections.count();
if(end < 0)
end += sections.count();
QString ret;
int x = 0;
int first_i = start, last_i = end;
for (int i = 0; x <= end && i < sections.size(); ++i) {
const qt_section_chunk §ion = sections.at(i);
const bool empty = (section.length == section.string.length());
if (x >= start) {
if(x == start)
first_i = i;
if(x == end)
last_i = i;
if(x != start)
ret += section.string;
else
ret += section.string.mid(section.length);
}
if (!empty || !(flags & SectionSkipEmpty))
x++;
}
if((flags & SectionIncludeLeadingSep) && first_i < sections.size()) {
const qt_section_chunk §ion = sections.at(first_i);
ret.prepend(section.string.left(section.length));
}
if((flags & SectionIncludeTrailingSep) && last_i+1 <= sections.size()-1) {
const qt_section_chunk §ion = sections.at(last_i+1);
ret += section.string.left(section.length);
}
return ret;
}
#endif
/*!
Returns a substring that contains the \a n leftmost characters
of the string.
The entire string is returned if \a n is greater than size() or
less than zero.
\snippet doc/src/snippets/qstring/main.cpp 31
\sa right(), mid(), startsWith()
*/
QString QString::left(int n) const
{
if (n >= d->size || n < 0)
return *this;
return QString((const QChar*) d->data, n);
}
/*!
Returns a substring that contains the \a n rightmost characters
of the string.
The entire string is returned if \a n is greater than size() or
less than zero.
\snippet doc/src/snippets/qstring/main.cpp 48
\sa left(), mid(), endsWith()
*/
QString QString::right(int n) const
{
if (n >= d->size || n < 0)
return *this;
return QString((const QChar*) d->data + d->size - n, n);
}
/*!
Returns a string that contains \a n characters of this string,
starting at the specified \a position index.
Returns a null string if the \a position index exceeds the
length of the string. If there are less than \a n characters
available in the string starting at the given \a position, or if
\a n is -1 (default), the function returns all characters that
are available from the specified \a position.
Example:
\snippet doc/src/snippets/qstring/main.cpp 34
\sa left(), right()
*/
QString QString::mid(int position, int n) const
{
if (d == &shared_null || position >= d->size)
return QString();
if (n < 0)
n = d->size - position;
if (position < 0) {
n += position;
position = 0;
}
if (n + position > d->size)
n = d->size - position;
if (position == 0 && n == d->size)
return *this;
return QString((const QChar*) d->data + position, n);
}
/*!
Returns true if the string starts with \a s; otherwise returns
false.
If \a cs is Qt::CaseSensitive (default), the search is
case sensitive; otherwise the search is case insensitive.
\snippet doc/src/snippets/qstring/main.cpp 65
\sa endsWith()
*/
bool QString::startsWith(const QString& s, Qt::CaseSensitivity cs) const
{
if (d == &shared_null)
return (s.d == &shared_null);
if (d->size == 0)
return s.d->size == 0;
if (s.d->size > d->size)
return false;
if (cs == Qt::CaseSensitive) {
return qMemEquals(d->data, s.d->data, s.d->size);
} else {
uint last = 0;
uint olast = 0;
for (int i = 0; i < s.d->size; ++i)
if (foldCase(d->data[i], last) != foldCase(s.d->data[i], olast))
return false;
}
return true;
}
/*!
\overload startsWith()
*/
bool QString::startsWith(const QLatin1String& s, Qt::CaseSensitivity cs) const
{
if (d == &shared_null)
return (s.latin1() == 0);
if (d->size == 0)
return !s.latin1() || *s.latin1() == 0;
int slen = qstrlen(s.latin1());
if (slen > d->size)
return false;
const uchar *latin = (const uchar *)s.latin1();
if (cs == Qt::CaseSensitive) {
for (int i = 0; i < slen; ++i)
if (d->data[i] != latin[i])
return false;
} else {
for (int i = 0; i < slen; ++i)
if (foldCase(d->data[i]) != foldCase((ushort)latin[i]))
return false;
}
return true;
}
/*!
\overload startsWith()
Returns true if the string starts with \a c; otherwise returns
false.
*/
bool QString::startsWith(const QChar &c, Qt::CaseSensitivity cs) const
{
return d->size
&& (cs == Qt::CaseSensitive
? d->data[0] == c
: foldCase(d->data[0]) == foldCase(c.unicode()));
}
/*!
Returns true if the string ends with \a s; otherwise returns
false.
If \a cs is Qt::CaseSensitive (default), the search is case
sensitive; otherwise the search is case insensitive.
\snippet doc/src/snippets/qstring/main.cpp 20
\sa startsWith()
*/
bool QString::endsWith(const QString& s, Qt::CaseSensitivity cs) const
{
if (d == &shared_null)
return (s.d == &shared_null);
if (d->size == 0)
return s.d->size == 0;
int pos = d->size - s.d->size;
if (pos < 0)
return false;
if (cs == Qt::CaseSensitive) {
return qMemEquals(d->data + pos, s.d->data, s.d->size);
} else {
uint last = 0;
uint olast = 0;
for (int i = 0; i < s.length(); i++)
if (foldCase(d->data[pos+i], last) != foldCase(s.d->data[i], olast))
return false;
}
return true;
}
/*!
\overload endsWith()
*/
bool QString::endsWith(const QLatin1String& s, Qt::CaseSensitivity cs) const
{
if (d == &shared_null)
return (s.latin1() == 0);
if (d->size == 0)
return !s.latin1() || *s.latin1() == 0;
int slen = qstrlen(s.latin1());
int pos = d->size - slen;
const uchar *latin = (const uchar *)s.latin1();
if (pos < 0)
return false;
if (cs == Qt::CaseSensitive) {
for (int i = 0; i < slen; i++)
if (d->data[pos+i] != latin[i])
return false;
} else {
for (int i = 0; i < slen; i++)
if (foldCase(d->data[pos+i]) != foldCase((ushort)latin[i]))
return false;
}
return true;
}
/*!
Returns true if the string ends with \a c; otherwise returns
false.
\overload endsWith()
*/
bool QString::endsWith(const QChar &c, Qt::CaseSensitivity cs) const
{
return d->size
&& (cs == Qt::CaseSensitive
? d->data[d->size - 1] == c
: foldCase(d->data[d->size - 1]) == foldCase(c.unicode()));
}
/*! \fn const char *QString::ascii() const
\nonreentrant
Use toAscii() instead.
*/
/*! \fn const char *QString::latin1() const
\nonreentrant
Use toLatin1() instead.
*/
/*! \fn const char *QString::utf8() const
\nonreentrant
Use toUtf8() instead.
*/
/*! \fn const char *QString::local8Bit() const
\nonreentrant
Use toLocal8Bit() instead.
*/
static QByteArray toLatin1_helper(const QChar *data, int length)
{
QByteArray ba;
if (length) {
ba.resize(length);
const ushort *src = reinterpret_cast<const ushort *>(data);
uchar *dst = (uchar*) ba.data();
#if defined(QT_ALWAYS_HAVE_SSE2)
if (length >= 16) {
const int chunkCount = length >> 4; // divided by 16
const __m128i questionMark = _mm_set1_epi16('?');
// SSE has no compare instruction for unsigned comparison.
// The variables must be shiffted + 0x8000 to be compared
const __m128i signedBitOffset = _mm_set1_epi16(0x8000);
const __m128i thresholdMask = _mm_set1_epi16(0xff + 0x8000);
for (int i = 0; i < chunkCount; ++i) {
__m128i chunk1 = _mm_loadu_si128((__m128i*)src); // load
src += 8;
{
// each 16 bit is equal to 0xFF if the source is outside latin 1 (>0xff)
const __m128i signedChunk = _mm_add_epi16(chunk1, signedBitOffset);
const __m128i offLimitMask = _mm_cmpgt_epi16(signedChunk, thresholdMask);
// offLimitQuestionMark contains '?' for each 16 bits that was off-limit
// the 16 bits that were correct contains zeros
const __m128i offLimitQuestionMark = _mm_and_si128(offLimitMask, questionMark);
// correctBytes contains the bytes that were in limit
// the 16 bits that were off limits contains zeros
const __m128i correctBytes = _mm_andnot_si128(offLimitMask, chunk1);
// merge offLimitQuestionMark and correctBytes to have the result
chunk1 = _mm_or_si128(correctBytes, offLimitQuestionMark);
}
__m128i chunk2 = _mm_loadu_si128((__m128i*)src); // load
src += 8;
{
// exactly the same operations as for the previous chunk of data
const __m128i signedChunk = _mm_add_epi16(chunk2, signedBitOffset);
const __m128i offLimitMask = _mm_cmpgt_epi16(signedChunk, thresholdMask);
const __m128i offLimitQuestionMark = _mm_and_si128(offLimitMask, questionMark);
const __m128i correctBytes = _mm_andnot_si128(offLimitMask, chunk2);
chunk2 = _mm_or_si128(correctBytes, offLimitQuestionMark);
}
// pack the two vector to 16 x 8bits elements
const __m128i result = _mm_packus_epi16(chunk1, chunk2);
_mm_storeu_si128((__m128i*)dst, result); // store
dst += 16;
}
length = length % 16;
}
#elif QT_HAVE_NEON
// Refer to the documentation of the SSE2 implementation
// this use eactly the same method as for SSE except:
// 1) neon has unsigned comparison
// 2) packing is done to 64 bits (8 x 8bits component).
if (length >= 16) {
const int chunkCount = length >> 3; // divided by 8
const uint16x8_t questionMark = vdupq_n_u16('?'); // set
const uint16x8_t thresholdMask = vdupq_n_u16(0xff); // set
for (int i = 0; i < chunkCount; ++i) {
uint16x8_t chunk = vld1q_u16((uint16_t *)src); // load
src += 8;
const uint16x8_t offLimitMask = vcgtq_u16(chunk, thresholdMask); // chunk > thresholdMask
const uint16x8_t offLimitQuestionMark = vandq_u16(offLimitMask, questionMark); // offLimitMask & questionMark
const uint16x8_t correctBytes = vbicq_u16(chunk, offLimitMask); // !offLimitMask & chunk
chunk = vorrq_u16(correctBytes, offLimitQuestionMark); // correctBytes | offLimitQuestionMark
const uint8x8_t result = vmovn_u16(chunk); // narrowing move->packing
vst1_u8(dst, result); // store
dst += 8;
}
length = length % 8;
}
#endif
while (length--) {
*dst++ = (*src>0xff) ? '?' : (uchar) *src;
++src;
}
}
return ba;
}
/*!
Returns a Latin-1 representation of the string as a QByteArray.
The returned byte array is undefined if the string contains non-Latin1
characters. Those characters may be suppressed or replaced with a
question mark.
\sa fromLatin1(), toAscii(), toUtf8(), toLocal8Bit(), QTextCodec
*/
QByteArray QString::toLatin1() const
{
return toLatin1_helper(unicode(), length());
}
// ### Qt 5: Change the return type of at least toAscii(),
// toLatin1() and unicode() such that the use of Q_COMPILER_MANGLES_RETURN_TYPE
// isn't necessary in the header. See task 177402.
/*!
Returns an 8-bit representation of the string as a QByteArray.
If a codec has been set using QTextCodec::setCodecForCStrings(),
it is used to convert Unicode to 8-bit char; otherwise this
function does the same as toLatin1().
Note that, despite the name, this function does not necessarily return an US-ASCII
(ANSI X3.4-1986) string and its result may not be US-ASCII compatible.
\sa fromAscii(), toLatin1(), toUtf8(), toLocal8Bit(), QTextCodec
*/
QByteArray QString::toAscii() const
{
#ifndef QT_NO_TEXTCODEC
if (codecForCStrings)
return codecForCStrings->fromUnicode(*this);
#endif // QT_NO_TEXTCODEC
return toLatin1();
}
#if !defined(Q_WS_MAC) && defined(Q_OS_UNIX)
static QByteArray toLocal8Bit_helper(const QChar *data, int length)
{
#ifndef QT_NO_TEXTCODEC
if (QTextCodec::codecForLocale())
return QTextCodec::codecForLocale()->fromUnicode(data, length);
#endif // QT_NO_TEXTCODEC
return toLatin1_helper(data, length);
}
#endif
/*!
Returns the local 8-bit representation of the string as a
QByteArray. The returned byte array is undefined if the string
contains characters not supported by the local 8-bit encoding.
QTextCodec::codecForLocale() is used to perform the conversion from
Unicode. If the locale encoding could not be determined, this function
does the same as toLatin1().
If this string contains any characters that cannot be encoded in the
locale, the returned byte array is undefined. Those characters may be
suppressed or replaced by another.
\sa fromLocal8Bit(), toAscii(), toLatin1(), toUtf8(), QTextCodec
*/
QByteArray QString::toLocal8Bit() const
{
#ifndef QT_NO_TEXTCODEC
if (QTextCodec::codecForLocale())
return QTextCodec::codecForLocale()->fromUnicode(*this);
#endif // QT_NO_TEXTCODEC
return toLatin1();
}
/*!
Returns a UTF-8 representation of the string as a QByteArray.
UTF-8 is a Unicode codec and can represent all characters in a Unicode
string like QString.
However, in the Unicode range, there are certain codepoints that are not
considered characters. The Unicode standard reserves the last two
codepoints in each Unicode Plane (U+FFFE, U+FFFF, U+1FFFE, U+1FFFF,
U+2FFFE, etc.), as well as 16 codepoints in the range U+FDD0..U+FDDF,
inclusive, as non-characters. If any of those appear in the string, they
may be discarded and will not appear in the UTF-8 representation, or they
may be replaced by one or more replacement characters.
\sa fromUtf8(), toAscii(), toLatin1(), toLocal8Bit(), QTextCodec
*/
QByteArray QString::toUtf8() const
{
if (isNull())
return QByteArray();
return QUtf8::convertFromUnicode(constData(), length(), 0);
}
/*!
\since 4.2
Returns a UCS-4/UTF-32 representation of the string as a QVector<uint>.
UCS-4 is a Unicode codec and is lossless. All characters from this string
can be encoded in UCS-4. The vector is not null terminated.
\sa fromUtf8(), toAscii(), toLatin1(), toLocal8Bit(), QTextCodec, fromUcs4(), toWCharArray()
*/
QVector<uint> QString::toUcs4() const
{
QVector<uint> v(length());
uint *a = v.data();
const unsigned short *uc = utf16();
for (int i = 0; i < length(); ++i) {
uint u = uc[i];
if (QChar(u).isHighSurrogate() && i < length()-1) {
ushort low = uc[i+1];
if (QChar(low).isLowSurrogate()) {
++i;
u = QChar::surrogateToUcs4(u, low);
}
}
*a = u;
++a;
}
v.resize(a - v.data());
return v;
}
QString::Data *QString::fromLatin1_helper(const char *str, int size)
{
Data *d;
if (!str) {
d = &shared_null;
d->ref.ref();
} else if (size == 0 || (!*str && size < 0)) {
d = &shared_empty;
d->ref.ref();
} else {
if (size < 0)
size = qstrlen(str);
d = static_cast<Data *>(qMalloc(sizeof(Data) + size * sizeof(QChar)));
Q_CHECK_PTR(d);
d->ref = 1;
d->alloc = d->size = size;
d->clean = d->asciiCache = d->simpletext = d->righttoleft = d->capacity = 0;
d->data = d->array;
d->array[size] = '\0';
ushort *dst = d->data;
/* SIMD:
* Unpacking with SSE has been shown to improve performance on recent CPUs
* The same method gives no improvement with NEON.
*/
#if defined(QT_ALWAYS_HAVE_SSE2)
if (size >= 16) {
int chunkCount = size >> 4; // divided by 16
const __m128i nullMask = _mm_set1_epi32(0);
for (int i = 0; i < chunkCount; ++i) {
const __m128i chunk = _mm_loadu_si128((__m128i*)str); // load
str += 16;
// unpack the first 8 bytes, padding with zeros
const __m128i firstHalf = _mm_unpacklo_epi8(chunk, nullMask);
_mm_storeu_si128((__m128i*)dst, firstHalf); // store
dst += 8;
// unpack the last 8 bytes, padding with zeros
const __m128i secondHalf = _mm_unpackhi_epi8 (chunk, nullMask);
_mm_storeu_si128((__m128i*)dst, secondHalf); // store
dst += 8;
}
size = size % 16;
}
#endif
while (size--)
*dst++ = (uchar)*str++;
}
return d;
}
QString::Data *QString::fromAscii_helper(const char *str, int size)
{
#ifndef QT_NO_TEXTCODEC
if (codecForCStrings) {
Data *d;
if (!str) {
d = &shared_null;
d->ref.ref();
} else if (size == 0 || (!*str && size < 0)) {
d = &shared_empty;
d->ref.ref();
} else {
if (size < 0)
size = qstrlen(str);
QString s = codecForCStrings->toUnicode(str, size);
d = s.d;
d->ref.ref();
}
return d;
}
#endif
return fromLatin1_helper(str, size);
}
/*!
Returns a QString initialized with the first \a size characters
of the Latin-1 string \a str.
If \a size is -1 (default), it is taken to be qstrlen(\a
str).
\sa toLatin1(), fromAscii(), fromUtf8(), fromLocal8Bit()
*/
QString QString::fromLatin1(const char *str, int size)
{
return QString(fromLatin1_helper(str, size), 0);
}
#ifdef QT3_SUPPORT
/*!
\internal
*/
const char *QString::ascii_helper() const
{
if (!asciiCache)
asciiCache = new QHash<void *, QByteArray>();
d->asciiCache = true;
QByteArray ascii = toAscii();
QByteArray old = asciiCache->value(d);
if (old == ascii)
return old.constData();
asciiCache->insert(d, ascii);
return ascii.constData();
}
/*!
\internal
*/
const char *QString::latin1_helper() const
{
if (!asciiCache)
asciiCache = new QHash<void *, QByteArray>();
d->asciiCache = true;
QByteArray ascii = toLatin1();
QByteArray old = asciiCache->value(d);
if (old == ascii)
return old.constData();
asciiCache->insert(d, ascii);
return ascii.constData();
}
#endif
/*!
Returns a QString initialized with the first \a size characters
of the 8-bit string \a str.
If \a size is -1 (default), it is taken to be qstrlen(\a
str).
QTextCodec::codecForLocale() is used to perform the conversion
from Unicode.
\sa toLocal8Bit(), fromAscii(), fromLatin1(), fromUtf8()
*/
QString QString::fromLocal8Bit(const char *str, int size)
{
if (!str)
return QString();
if (size == 0 || (!*str && size < 0))
return QLatin1String("");
#if !defined(QT_NO_TEXTCODEC)
if (size < 0)
size = qstrlen(str);
QTextCodec *codec = QTextCodec::codecForLocale();
if (codec)
return codec->toUnicode(str, size);
#endif // !QT_NO_TEXTCODEC
return fromLatin1(str, size);
}
/*!
Returns a QString initialized with the first \a size characters
of the 8-bit string \a str.
If \a size is -1 (default), it is taken to be qstrlen(\a
str).
Note that, despite the name, this function actually uses the codec
defined by QTextCodec::setCodecForCStrings() to convert \a str to
Unicode. Depending on the codec, it may not accept valid US-ASCII (ANSI
X3.4-1986) input. If no codec has been set, this function does the same
as fromLatin1().
\sa toAscii(), fromLatin1(), fromUtf8(), fromLocal8Bit()
*/
QString QString::fromAscii(const char *str, int size)
{
return QString(fromAscii_helper(str, size), 0);
}
/*!
Returns a QString initialized with the first \a size bytes
of the UTF-8 string \a str.
If \a size is -1 (default), it is taken to be qstrlen(\a
str).
UTF-8 is a Unicode codec and can represent all characters in a Unicode
string like QString. However, invalid sequences are possible with UTF-8
and, if any such are found, they will be replaced with one or more
"replacement characters", or suppressed. These include non-Unicode
sequences, non-characters, overlong sequences or surrogate codepoints
encoded into UTF-8.
Non-characters are codepoints that the Unicode standard reserves and must
not be used in text interchange. They are the last two codepoints in each
Unicode Plane (U+FFFE, U+FFFF, U+1FFFE, U+1FFFF, U+2FFFE, etc.), as well
as 16 codepoints in the range U+FDD0..U+FDDF, inclusive.
\sa toUtf8(), fromAscii(), fromLatin1(), fromLocal8Bit()
*/
QString QString::fromUtf8(const char *str, int size)
{
if (!str)
return QString();
if (size < 0)
size = qstrlen(str);
return QUtf8::convertToUnicode(str, size, 0);
}
/*!
Returns a QString initialized with the first \a size characters
of the Unicode string \a unicode (ISO-10646-UTF-16 encoded).
If \a size is -1 (default), \a unicode must be terminated
with a 0.
This function checks for a Byte Order Mark (BOM). If it is missing,
host byte order is assumed.
This function is slow compared to the other Unicode conversions.
Use QString(const QChar *, int) or QString(const QChar *) if possible.
QString makes a deep copy of the Unicode data.
\sa utf16(), setUtf16()
*/
QString QString::fromUtf16(const ushort *unicode, int size)
{
if (!unicode)
return QString();
if (size < 0) {
size = 0;
while (unicode[size] != 0)
++size;
}
return QUtf16::convertToUnicode((const char *)unicode, size*2, 0);
}
/*!
\since 4.2
Returns a QString initialized with the first \a size characters
of the Unicode string \a unicode (ISO-10646-UCS-4 encoded).
If \a size is -1 (default), \a unicode must be terminated
with a 0.
\sa toUcs4(), fromUtf16(), utf16(), setUtf16(), fromWCharArray()
*/
QString QString::fromUcs4(const uint *unicode, int size)
{
if (!unicode)
return QString();
if (size < 0) {
size = 0;
while (unicode[size] != 0)
++size;
}
return QUtf32::convertToUnicode((const char *)unicode, size*4, 0);
}
/*!
Resizes the string to \a size characters and copies \a unicode
into the string.
If \a unicode is 0, nothing is copied, but the string is still
resized to \a size.
\sa unicode(), setUtf16()
*/
QString& QString::setUnicode(const QChar *unicode, int size)
{
resize(size);
if (unicode && size)
memcpy(d->data, unicode, size * sizeof(QChar));
return *this;
}
/*!
\fn QString &QString::setUtf16(const ushort *unicode, int size)
Resizes the string to \a size characters and copies \a unicode
into the string.
If \a unicode is 0, nothing is copied, but the string is still
resized to \a size.
Note that unlike fromUtf16(), this function does not consider BOMs and
possibly differing byte ordering.
\sa utf16(), setUnicode()
*/
/*!
Returns a string that has whitespace removed from the start
and the end, and that has each sequence of internal whitespace
replaced with a single space.
Whitespace means any character for which QChar::isSpace() returns
true. This includes the ASCII characters '\\t', '\\n', '\\v',
'\\f', '\\r', and ' '.
Example:
\snippet doc/src/snippets/qstring/main.cpp 57
\sa trimmed()
*/
QString QString::simplified() const
{
if (d->size == 0)
return *this;
const QChar * const start = reinterpret_cast<QChar *>(d->data);
const QChar *from = start;
const QChar *fromEnd = start + d->size;
forever {
QChar ch = *from;
if (!ch.isSpace())
break;
if (++from == fromEnd) {
// All-whitespace string
shared_empty.ref.ref();
return QString(&shared_empty, 0);
}
}
// This loop needs no underflow check, as we already determined that
// the string contains non-whitespace. If the string has exactly one
// non-whitespace, it will be checked twice - we can live with that.
while (fromEnd[-1].isSpace())
fromEnd--;
// The rest of the function depends on the fact that we already know
// that the last character in the source is no whitespace.
const QChar *copyFrom = from;
int copyCount;
forever {
if (++from == fromEnd) {
// Only leading and/or trailing whitespace, if any at all
return mid(copyFrom - start, from - copyFrom);
}
QChar ch = *from;
if (!ch.isSpace())
continue;
if (ch != QLatin1Char(' ')) {
copyCount = from - copyFrom;
break;
}
ch = *++from;
if (ch.isSpace()) {
copyCount = from - copyFrom - 1;
break;
}
}
// 'from' now points at the non-trailing whitespace which made the
// string not simplified in the first place. 'copyCount' is the number
// of already simplified characters - at least one, obviously -
// without a trailing space.
QString result((fromEnd - from) + copyCount, Qt::Uninitialized);
QChar *to = reinterpret_cast<QChar *>(result.d->data);
::memcpy(to, copyFrom, copyCount * 2);
to += copyCount;
fromEnd--;
QChar ch;
forever {
*to++ = QLatin1Char(' ');
do {
ch = *++from;
} while (ch.isSpace());
if (from == fromEnd)
break;
do {
*to++ = ch;
ch = *++from;
if (from == fromEnd)
goto done;
} while (!ch.isSpace());
}
done:
*to++ = ch;
result.truncate(to - reinterpret_cast<QChar *>(result.d->data));
return result;
}
/*!
Returns a string that has whitespace removed from the start and
the end.
Whitespace means any character for which QChar::isSpace() returns
true. This includes the ASCII characters '\\t', '\\n', '\\v',
'\\f', '\\r', and ' '.
Example:
\snippet doc/src/snippets/qstring/main.cpp 82
Unlike simplified(), trimmed() leaves internal whitespace alone.
\sa simplified()
*/
QString QString::trimmed() const
{
if (d->size == 0)
return *this;
const QChar *s = (const QChar*)d->data;
if (!s->isSpace() && !s[d->size-1].isSpace())
return *this;
int start = 0;
int end = d->size - 1;
while (start<=end && s[start].isSpace()) // skip white space from start
start++;
if (start <= end) { // only white space
while (end && s[end].isSpace()) // skip white space from end
end--;
}
int l = end - start + 1;
if (l <= 0) {
shared_empty.ref.ref();
return QString(&shared_empty, 0);
}
return QString(s + start, l);
}
/*! \fn const QChar QString::at(int position) const
Returns the character at the given index \a position in the
string.
The \a position must be a valid index position in the string
(i.e., 0 <= \a position < size()).
\sa operator[]()
*/
/*!
\fn QCharRef QString::operator[](int position)
Returns the character at the specified \a position in the string as a
modifiable reference.
Example:
\snippet doc/src/snippets/qstring/main.cpp 85
The return value is of type QCharRef, a helper class for QString.
When you get an object of type QCharRef, you can use it as if it
were a QChar &. If you assign to it, the assignment will apply to
the character in the QString from which you got the reference.
\sa at()
*/
/*!
\fn const QChar QString::operator[](int position) const
\overload operator[]()
*/
/*! \fn QCharRef QString::operator[](uint position)
\overload operator[]()
Returns the character at the specified \a position in the string as a
modifiable reference. Equivalent to \c at(position).
*/
/*! \fn const QChar QString::operator[](uint position) const
\overload operator[]()
*/
/*!
\fn void QString::truncate(int position)
Truncates the string at the given \a position index.
If the specified \a position index is beyond the end of the
string, nothing happens.
Example:
\snippet doc/src/snippets/qstring/main.cpp 83
If \a position is negative, it is equivalent to passing zero.
\sa chop(), resize(), left()
*/
void QString::truncate(int pos)
{
if (pos < d->size)
resize(pos);
}
/*!
Removes \a n characters from the end of the string.
If \a n is greater than size(), the result is an empty string.
Example:
\snippet doc/src/snippets/qstring/main.cpp 15
If you want to remove characters from the \e beginning of the
string, use remove() instead.
\sa truncate(), resize(), remove()
*/
void QString::chop(int n)
{
if (n > 0)
resize(d->size - n);
}
/*!
Sets every character in the string to character \a ch. If \a size
is different from -1 (default), the string is resized to \a
size beforehand.
Example:
\snippet doc/src/snippets/qstring/main.cpp 21
\sa resize()
*/
QString& QString::fill(QChar ch, int size)
{
resize(size < 0 ? d->size : size);
if (d->size) {
QChar *i = (QChar*)d->data + d->size;
QChar *b = (QChar*)d->data;
while (i != b)
*--i = ch;
}
return *this;
}
/*!
\fn int QString::length() const
Returns the number of characters in this string. Equivalent to
size().
\sa setLength()
*/
/*!
\fn int QString::size() const
Returns the number of characters in this string.
The last character in the string is at position size() - 1. In
addition, QString ensures that the character at position size()
is always '\\0', so that you can use the return value of data()
and constData() as arguments to functions that expect
'\\0'-terminated strings.
Example:
\snippet doc/src/snippets/qstring/main.cpp 58
\sa isEmpty(), resize()
*/
/*! \fn bool QString::isNull() const
Returns true if this string is null; otherwise returns false.
Example:
\snippet doc/src/snippets/qstring/main.cpp 28
Qt makes a distinction between null strings and empty strings for
historical reasons. For most applications, what matters is
whether or not a string contains any data, and this can be
determined using the isEmpty() function.
\sa isEmpty()
*/
/*! \fn bool QString::isEmpty() const
Returns true if the string has no characters; otherwise returns
false.
Example:
\snippet doc/src/snippets/qstring/main.cpp 27
\sa size()
*/
/*! \fn QString &QString::operator+=(const QString &other)
Appends the string \a other onto the end of this string and
returns a reference to this string.
Example:
\snippet doc/src/snippets/qstring/main.cpp 84
This operation is typically very fast (\l{constant time}),
because QString preallocates extra space at the end of the string
data so it can grow without reallocating the entire string each
time.
\sa append(), prepend()
*/
/*! \fn QString &QString::operator+=(const QLatin1String &str)
\overload operator+=()
Appends the Latin-1 string \a str to this string.
*/
/*! \fn QString &QString::operator+=(const QByteArray &ba)
\overload operator+=()
Appends the byte array \a ba to this string. The byte array is converted
to Unicode using the fromAscii() function. If any NUL characters ('\0')
are embedded in the \a ba byte array, they will be included in the
transformation.
You can disable this function by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*! \fn QString &QString::operator+=(const char *str)
\overload operator+=()
Appends the string \a str to this string. The const char pointer
is converted to Unicode using the fromAscii() function.
You can disable this function by defining \c QT_NO_CAST_FROM_ASCII
when you compile your applications. This can be useful if you want
to ensure that all user-visible strings go through QObject::tr(),
for example.
*/
/*! \fn QString &QString::operator+=(const QStringRef &str)
\overload operator+=()
Appends the string section referenced by \a str to this string.
*/
/*! \fn QString &QString::operator+=(char ch)
\overload operator+=()
Appends the character \a ch to this string. The character is
converted to Unicode using the fromAscii() function.
You can disable this function by defining \c QT_NO_CAST_FROM_ASCII
when you compile your applications. This can be useful if you want
to ensure that all user-visible strings go through QObject::tr(),
for example.
*/
/*! \fn QString &QString::operator+=(QChar ch)
\overload operator+=()
Appends the character \a ch to the string.
*/
/*! \fn QString &QString::operator+=(QChar::SpecialCharacter c)
\overload operator+=()
\internal
*/
/*!
\fn bool operator==(const char *s1, const QString &s2)
\overload operator==()
\relates QString
Returns true if \a s1 is equal to \a s2; otherwise returns false.
Note that no string is equal to \a s1 being 0.
Equivalent to \c {s1 != 0 && compare(s1, s2) == 0}.
\sa QString::compare()
*/
/*!
\fn bool operator!=(const char *s1, const QString &s2)
\relates QString
Returns true if \a s1 is not equal to \a s2; otherwise returns
false.
For \a s1 != 0, this is equivalent to \c {compare(} \a s1, \a s2
\c {) != 0}. Note that no string is equal to \a s1 being 0.
\sa QString::compare()
*/
/*!
\fn bool operator<(const char *s1, const QString &s2)
\relates QString
Returns true if \a s1 is lexically less than \a s2; otherwise
returns false. For \a s1 != 0, this is equivalent to \c
{compare(s1, s2) < 0}.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings using the
QString::localeAwareCompare() function.
\sa QString::compare()
*/
/*!
\fn bool operator<=(const char *s1, const QString &s2)
\relates QString
Returns true if \a s1 is lexically less than or equal to \a s2;
otherwise returns false. For \a s1 != 0, this is equivalent to \c
{compare(s1, s2) <= 0}.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings with
QString::localeAwareCompare().
\sa QString::compare()
*/
/*!
\fn bool operator>(const char *s1, const QString &s2)
\relates QString
Returns true if \a s1 is lexically greater than \a s2; otherwise
returns false. Equivalent to \c {compare(s1, s2) > 0}.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings using the
QString::localeAwareCompare() function.
\sa QString::compare()
*/
/*!
\fn bool operator>=(const char *s1, const QString &s2)
\relates QString
Returns true if \a s1 is lexically greater than or equal to \a s2;
otherwise returns false. For \a s1 != 0, this is equivalent to \c
{compare(s1, s2) >= 0}.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings using the
QString::localeAwareCompare() function.
*/
/*!
\fn const QString operator+(const QString &s1, const QString &s2)
\relates QString
Returns a string which is the result of concatenating \a s1 and \a
s2.
*/
/*!
\fn const QString operator+(const QString &s1, const char *s2)
\relates QString
Returns a string which is the result of concatenating \a s1 and \a
s2 (\a s2 is converted to Unicode using the QString::fromAscii()
function).
\sa QString::fromAscii()
*/
/*!
\fn const QString operator+(const char *s1, const QString &s2)
\relates QString
Returns a string which is the result of concatenating \a s1 and \a
s2 (\a s1 is converted to Unicode using the QString::fromAscii()
function).
\sa QString::fromAscii()
*/
/*!
\fn const QString operator+(const QString &s, char ch)
\relates QString
Returns a string which is the result of concatenating the string
\a s and the character \a ch.
*/
/*!
\fn const QString operator+(char ch, const QString &s)
\relates QString
Returns a string which is the result of concatenating the
character \a ch and the string \a s.
*/
/*!
\fn int QString::compare(const QString &s1, const QString &s2, Qt::CaseSensitivity cs)
\since 4.2
Compares \a s1 with \a s2 and returns an integer less than, equal
to, or greater than zero if \a s1 is less than, equal to, or
greater than \a s2.
If \a cs is Qt::CaseSensitive, the comparison is case sensitive;
otherwise the comparison is case insensitive.
Case sensitive comparison is based exclusively on the numeric
Unicode values of the characters and is very fast, but is not what
a human would expect. Consider sorting user-visible strings with
localeAwareCompare().
\snippet doc/src/snippets/qstring/main.cpp 16
\sa operator==(), operator<(), operator>()
*/
/*!
\fn int QString::compare(const QString & s1, const QString & s2)
\overload compare()
Performs a case sensitive compare of \a s1 and \a s2.
*/
/*!
\fn int QString::compare(const QString &s1, const QLatin1String &s2, Qt::CaseSensitivity cs)
\since 4.2
\overload compare()
Performs a comparison of \a s1 and \a s2, using the case
sensitivity setting \a cs.
*/
/*!
\fn int QString::compare(const QLatin1String &s1, const QString &s2, Qt::CaseSensitivity cs = Qt::CaseSensitive)
\since 4.2
\overload compare()
Performs a comparison of \a s1 and \a s2, using the case
sensitivity setting \a cs.
*/
/*!
\overload compare()
Lexically compares this string with the \a other string and
returns an integer less than, equal to, or greater than zero if
this string is less than, equal to, or greater than the other
string.
Equivalent to \c {compare(*this, other)}.
*/
int QString::compare(const QString &other) const
{
return ucstrcmp(constData(), length(), other.constData(), other.length());
}
/*!
\overload compare()
\since 4.2
Same as compare(*this, \a other, \a cs).
*/
int QString::compare(const QString &other, Qt::CaseSensitivity cs) const
{
if (cs == Qt::CaseSensitive)
return ucstrcmp(constData(), length(), other.constData(), other.length());
return ucstricmp(d->data, d->data + d->size, other.d->data, other.d->data + other.d->size);
}
/*!
\internal
\since 4.5
*/
int QString::compare_helper(const QChar *data1, int length1, const QChar *data2, int length2,
Qt::CaseSensitivity cs)
{
if (cs == Qt::CaseSensitive)
return ucstrcmp(data1, length1, data2, length2);
register const ushort *s1 = reinterpret_cast<const ushort *>(data1);
register const ushort *s2 = reinterpret_cast<const ushort *>(data2);
return ucstricmp(s1, s1 + length1, s2, s2 + length2);
}
/*!
\overload compare()
\since 4.2
Same as compare(*this, \a other, \a cs).
*/
int QString::compare(const QLatin1String &other, Qt::CaseSensitivity cs) const
{
return compare_helper(unicode(), length(), other, cs);
}
/*!
\fn int QString::compare(const QStringRef &ref, Qt::CaseSensitivity cs = Qt::CaseSensitive) const
\overload compare()
Compares the string reference, \a ref, with the string and returns
an integer less than, equal to, or greater than zero if the string
is less than, equal to, or greater than \a ref.
*/
/*!
\fn int QString::compare(const QString &s1, const QStringRef &s2, Qt::CaseSensitivity cs = Qt::CaseSensitive)
\overload compare()
*/
/*!
\internal
\since 4.5
*/
int QString::compare_helper(const QChar *data1, int length1, QLatin1String s2,
Qt::CaseSensitivity cs)
{
const ushort *uc = reinterpret_cast<const ushort *>(data1);
const ushort *e = uc + length1;
const uchar *c = (uchar *)s2.latin1();
if (!c)
return length1;
if (cs == Qt::CaseSensitive) {
while (uc < e && *c && *uc == *c)
uc++, c++;
if (uc == e)
return -*c;
return *uc - *c;
} else {
return ucstricmp(uc, e, c);
}
}
/*!
\fn int QString::localeAwareCompare(const QString & s1, const QString & s2)
Compares \a s1 with \a s2 and returns an integer less than, equal
to, or greater than zero if \a s1 is less than, equal to, or
greater than \a s2.
The comparison is performed in a locale- and also
platform-dependent manner. Use this function to present sorted
lists of strings to the user.
On Mac OS X since Qt 4.3, this function compares according the
"Order for sorted lists" setting in the International prefereces panel.
\sa compare(), QTextCodec::locale()
*/
/*!
\fn int QString::localeAwareCompare(const QStringRef &other) const
\since 4.5
\overload localeAwareCompare()
Compares this string with the \a other string and returns an
integer less than, equal to, or greater than zero if this string
is less than, equal to, or greater than the \a other string.
The comparison is performed in a locale- and also
platform-dependent manner. Use this function to present sorted
lists of strings to the user.
Same as \c {localeAwareCompare(*this, other)}.
*/
/*!
\fn int QString::localeAwareCompare(const QString &s1, const QStringRef &s2)
\since 4.5
\overload localeAwareCompare()
Compares \a s1 with \a s2 and returns an integer less than, equal
to, or greater than zero if \a s1 is less than, equal to, or
greater than \a s2.
The comparison is performed in a locale- and also
platform-dependent manner. Use this function to present sorted
lists of strings to the user.
*/
#if !defined(CSTR_LESS_THAN)
#define CSTR_LESS_THAN 1
#define CSTR_EQUAL 2
#define CSTR_GREATER_THAN 3
#endif
/*!
\overload localeAwareCompare()
Compares this string with the \a other string and returns an
integer less than, equal to, or greater than zero if this string
is less than, equal to, or greater than the \a other string.
The comparison is performed in a locale- and also
platform-dependent manner. Use this function to present sorted
lists of strings to the user.
Same as \c {localeAwareCompare(*this, other)}.
*/
int QString::localeAwareCompare(const QString &other) const
{
return localeAwareCompare_helper(constData(), length(), other.constData(), other.length());
}
#if defined(Q_OS_WIN32) || defined(Q_OS_WINCE)
QT_END_NAMESPACE
#include "qt_windows.h"
QT_BEGIN_NAMESPACE
#endif
/*!
\internal
\since 4.5
*/
int QString::localeAwareCompare_helper(const QChar *data1, int length1,
const QChar *data2, int length2)
{
// do the right thing for null and empty
if (length1 == 0 || length2 == 0)
return ucstrcmp(data1, length1, data2, length2);
#if defined(Q_OS_WIN32) || defined(Q_OS_WINCE)
int res = CompareString(GetUserDefaultLCID(), 0, (wchar_t*)data1, length1, (wchar_t*)data2, length2);
switch (res) {
case CSTR_LESS_THAN:
return -1;
case CSTR_GREATER_THAN:
return 1;
default:
return 0;
}
#elif defined (Q_OS_MAC)
// Use CFStringCompare for comparing strings on Mac. This makes Qt order
// strings the same way as native applications do, and also respects
// the "Order for sorted lists" setting in the International preferences
// panel.
const CFStringRef thisString =
CFStringCreateWithCharactersNoCopy(kCFAllocatorDefault,
reinterpret_cast<const UniChar *>(data1), length1, kCFAllocatorNull);
const CFStringRef otherString =
CFStringCreateWithCharactersNoCopy(kCFAllocatorDefault,
reinterpret_cast<const UniChar *>(data2), length2, kCFAllocatorNull);
const int result = CFStringCompare(thisString, otherString, kCFCompareLocalized);
CFRelease(thisString);
CFRelease(otherString);
return result;
#elif defined(Q_OS_SYMBIAN)
TPtrC p1 = TPtrC16(reinterpret_cast<const TUint16 *>(data1), length1);
TPtrC p2 = TPtrC16(reinterpret_cast<const TUint16 *>(data2), length2);
return p1.CompareC(p2);
#elif defined(Q_OS_UNIX)
// declared in <string.h>
int delta = strcoll(toLocal8Bit_helper(data1, length1), toLocal8Bit_helper(data2, length2));
if (delta == 0)
delta = ucstrcmp(data1, length1, data2, length2);
return delta;
#else
return ucstrcmp(data1, length1, data2, length2);
#endif
}
/*!
\fn const QChar *QString::unicode() const
Returns a '\\0'-terminated Unicode representation of the string.
The result remains valid until the string is modified.
\sa utf16()
*/
/*!
\fn const ushort *QString::utf16() const
Returns the QString as a '\\0\'-terminated array of unsigned
shorts. The result remains valid until the string is modified.
The returned string is in host byte order.
\sa unicode()
*/
const ushort *QString::utf16() const
{
if (d->data != d->array) {
QString *that = const_cast<QString*>(this);
that->realloc(); // ensure '\\0'-termination for ::fromRawData strings
return that->d->data;
}
return d->array;
}
/*!
Returns a string of size \a width that contains this string
padded by the \a fill character.
If \a truncate is false and the size() of the string is more than
\a width, then the returned string is a copy of the string.
\snippet doc/src/snippets/qstring/main.cpp 32
If \a truncate is true and the size() of the string is more than
\a width, then any characters in a copy of the string after
position \a width are removed, and the copy is returned.
\snippet doc/src/snippets/qstring/main.cpp 33
\sa rightJustified()
*/
QString QString::leftJustified(int width, QChar fill, bool truncate) const
{
QString result;
int len = length();
int padlen = width - len;
if (padlen > 0) {
result.resize(len+padlen);
if (len)
memcpy(result.d->data, d->data, sizeof(QChar)*len);
QChar *uc = (QChar*)result.d->data + len;
while (padlen--)
* uc++ = fill;
} else {
if (truncate)
result = left(width);
else
result = *this;
}
return result;
}
/*!
Returns a string of size() \a width that contains the \a fill
character followed by the string. For example:
\snippet doc/src/snippets/qstring/main.cpp 49
If \a truncate is false and the size() of the string is more than
\a width, then the returned string is a copy of the string.
If \a truncate is true and the size() of the string is more than
\a width, then the resulting string is truncated at position \a
width.
\snippet doc/src/snippets/qstring/main.cpp 50
\sa leftJustified()
*/
QString QString::rightJustified(int width, QChar fill, bool truncate) const
{
QString result;
int len = length();
int padlen = width - len;
if (padlen > 0) {
result.resize(len+padlen);
QChar *uc = (QChar*)result.d->data;
while (padlen--)
* uc++ = fill;
if (len)
memcpy(uc, d->data, sizeof(QChar)*len);
} else {
if (truncate)
result = left(width);
else
result = *this;
}
return result;
}
/*!
Returns a lowercase copy of the string.
\snippet doc/src/snippets/qstring/main.cpp 75
\sa toUpper()
*/
QString QString::toLower() const
{
const ushort *p = d->data;
if (!p)
return *this;
if (!d->size)
return *this;
const ushort *e = d->data + d->size;
// this avoids one out of bounds check in the loop
if (QChar(*p).isLowSurrogate())
++p;
while (p != e) {
uint c = *p;
if (QChar(c).isLowSurrogate() && QChar(*(p - 1)).isHighSurrogate())
c = QChar::surrogateToUcs4(*(p - 1), c);
const QUnicodeTables::Properties *prop = qGetProp(c);
if (prop->lowerCaseDiff || prop->lowerCaseSpecial) {
QString s(d->size, Qt::Uninitialized);
memcpy(s.d->data, d->data, (p - d->data)*sizeof(ushort));
ushort *pp = s.d->data + (p - d->data);
while (p < e) {
uint c = *p;
if (QChar(c).isLowSurrogate() && QChar(*(p - 1)).isHighSurrogate())
c = QChar::surrogateToUcs4(*(p - 1), c);
prop = qGetProp(c);
if (prop->lowerCaseSpecial) {
int pos = pp - s.d->data;
s.resize(s.d->size + SPECIAL_CASE_MAX_LEN);
pp = s.d->data + pos;
const ushort *specialCase = specialCaseMap + prop->lowerCaseDiff;
while (*specialCase)
*pp++ = *specialCase++;
} else {
*pp++ = *p + prop->lowerCaseDiff;
}
++p;
}
s.truncate(pp - s.d->data);
return s;
}
++p;
}
return *this;
}
/*!
Returns the case folded equivalent of the string. For most Unicode
characters this is the same as toLower().
*/
QString QString::toCaseFolded() const
{
if (!d->size)
return *this;
const ushort *p = d->data;
if (!p)
return *this;
const ushort *e = d->data + d->size;
uint last = 0;
while (p < e) {
ushort folded = foldCase(*p, last);
if (folded != *p) {
QString s(*this);
s.detach();
ushort *pp = s.d->data + (p - d->data);
const ushort *ppe = s.d->data + s.d->size;
last = pp > s.d->data ? *(pp - 1) : 0;
while (pp < ppe) {
*pp = foldCase(*pp, last);
++pp;
}
return s;
}
p++;
}
return *this;
}
/*!
Returns an uppercase copy of the string.
\snippet doc/src/snippets/qstring/main.cpp 81
\sa toLower()
*/
QString QString::toUpper() const
{
const ushort *p = d->data;
if (!p)
return *this;
if (!d->size)
return *this;
const ushort *e = d->data + d->size;
// this avoids one out of bounds check in the loop
if (QChar(*p).isLowSurrogate())
++p;
while (p != e) {
uint c = *p;
if (QChar(c).isLowSurrogate() && QChar(*(p - 1)).isHighSurrogate())
c = QChar::surrogateToUcs4(*(p - 1), c);
const QUnicodeTables::Properties *prop = qGetProp(c);
if (prop->upperCaseDiff || prop->upperCaseSpecial) {
QString s(d->size, Qt::Uninitialized);
memcpy(s.d->data, d->data, (p - d->data)*sizeof(ushort));
ushort *pp = s.d->data + (p - d->data);
while (p < e) {
uint c = *p;
if (QChar(c).isLowSurrogate() && QChar(*(p - 1)).isHighSurrogate())
c = QChar::surrogateToUcs4(*(p - 1), c);
prop = qGetProp(c);
if (prop->upperCaseSpecial) {
int pos = pp - s.d->data;
s.resize(s.d->size + SPECIAL_CASE_MAX_LEN);
pp = s.d->data + pos;
const ushort *specialCase = specialCaseMap + prop->upperCaseDiff;
while (*specialCase)
*pp++ = *specialCase++;
} else {
*pp++ = *p + prop->upperCaseDiff;
}
++p;
}
s.truncate(pp - s.d->data);
return s;
}
++p;
}
return *this;
}
// ### Qt 5: Consider whether this function shouldn't be removed See task 202871.
/*!
Safely builds a formatted string from the format string \a cformat
and an arbitrary list of arguments.
The %lc escape sequence expects a unicode character of type ushort
(as returned by QChar::unicode()). The %ls escape sequence expects
a pointer to a zero-terminated array of unicode characters of type
ushort (as returned by QString::utf16()).
\note This function expects a UTF-8 string for %s and Latin-1 for
the format string.
The format string supports most of the conversion specifiers
provided by printf() in the standard C++ library. It doesn't
honor the length modifiers (e.g. \c h for \c short, \c ll for
\c{long long}). If you need those, use the standard snprintf()
function instead:
\snippet doc/src/snippets/qstring/main.cpp 63
\warning We do not recommend using QString::sprintf() in new Qt
code. Instead, consider using QTextStream or arg(), both of
which support Unicode strings seamlessly and are type-safe.
Here's an example that uses QTextStream:
\snippet doc/src/snippets/qstring/main.cpp 64
For \l {QObject::tr()}{translations}, especially if the strings
contains more than one escape sequence, you should consider using
the arg() function instead. This allows the order of the
replacements to be controlled by the translator.
\sa arg()
*/
QString &QString::sprintf(const char *cformat, ...)
{
va_list ap;
va_start(ap, cformat);
QString &s = vsprintf(cformat, ap);
va_end(ap);
return s;
}
/*!
Equivalent method to sprintf(), but takes a va_list \a ap
instead a list of variable arguments. See the sprintf()
documentation for an explanation of \a cformat.
This method does not call the va_end macro, the caller
is responsible to call va_end on \a ap.
\sa sprintf()
*/
QString &QString::vsprintf(const char* cformat, va_list ap)
{
QLocale locale(QLocale::C);
if (!cformat || !*cformat) {
// Qt 1.x compat
*this = fromLatin1("");
return *this;
}
// Parse cformat
QString result;
const char *c = cformat;
for (;;) {
// Copy non-escape chars to result
#ifndef QT_NO_TEXTCODEC
int i = 0;
while (*(c + i) != '\0' && *(c + i) != '%')
++i;
if (codecForCStrings)
result.append(codecForCStrings->toUnicode(c, i));
else
result.append(fromLatin1(c, i));
c += i;
#else
while (*c != '\0' && *c != '%')
result.append(QLatin1Char(*c++));
#endif
if (*c == '\0')
break;
// Found '%'
const char *escape_start = c;
++c;
if (*c == '\0') {
result.append(QLatin1Char('%')); // a % at the end of the string - treat as non-escape text
break;
}
if (*c == '%') {
result.append(QLatin1Char('%')); // %%
++c;
continue;
}
// Parse flag characters
uint flags = 0;
bool no_more_flags = false;
do {
switch (*c) {
case '#': flags |= QLocalePrivate::Alternate; break;
case '0': flags |= QLocalePrivate::ZeroPadded; break;
case '-': flags |= QLocalePrivate::LeftAdjusted; break;
case ' ': flags |= QLocalePrivate::BlankBeforePositive; break;
case '+': flags |= QLocalePrivate::AlwaysShowSign; break;
case '\'': flags |= QLocalePrivate::ThousandsGroup; break;
default: no_more_flags = true; break;
}
if (!no_more_flags)
++c;
} while (!no_more_flags);
if (*c == '\0') {
result.append(QLatin1String(escape_start)); // incomplete escape, treat as non-escape text
break;
}
// Parse field width
int width = -1; // -1 means unspecified
if (qIsDigit(*c)) {
QString width_str;
while (*c != '\0' && qIsDigit(*c))
width_str.append(QLatin1Char(*c++));
// can't be negative - started with a digit
// contains at least one digit
width = width_str.toInt();
}
else if (*c == '*') {
width = va_arg(ap, int);
if (width < 0)
width = -1; // treat all negative numbers as unspecified
++c;
}
if (*c == '\0') {
result.append(QLatin1String(escape_start)); // incomplete escape, treat as non-escape text
break;
}
// Parse precision
int precision = -1; // -1 means unspecified
if (*c == '.') {
++c;
if (qIsDigit(*c)) {
QString precision_str;
while (*c != '\0' && qIsDigit(*c))
precision_str.append(QLatin1Char(*c++));
// can't be negative - started with a digit
// contains at least one digit
precision = precision_str.toInt();
}
else if (*c == '*') {
precision = va_arg(ap, int);
if (precision < 0)
precision = -1; // treat all negative numbers as unspecified
++c;
}
}
if (*c == '\0') {
result.append(QLatin1String(escape_start)); // incomplete escape, treat as non-escape text
break;
}
// Parse the length modifier
enum LengthMod { lm_none, lm_hh, lm_h, lm_l, lm_ll, lm_L, lm_j, lm_z, lm_t };
LengthMod length_mod = lm_none;
switch (*c) {
case 'h':
++c;
if (*c == 'h') {
length_mod = lm_hh;
++c;
}
else
length_mod = lm_h;
break;
case 'l':
++c;
if (*c == 'l') {
length_mod = lm_ll;
++c;
}
else
length_mod = lm_l;
break;
case 'L':
++c;
length_mod = lm_L;
break;
case 'j':
++c;
length_mod = lm_j;
break;
case 'z':
case 'Z':
++c;
length_mod = lm_z;
break;
case 't':
++c;
length_mod = lm_t;
break;
default: break;
}
if (*c == '\0') {
result.append(QLatin1String(escape_start)); // incomplete escape, treat as non-escape text
break;
}
// Parse the conversion specifier and do the conversion
QString subst;
switch (*c) {
case 'd':
case 'i': {
qint64 i;
switch (length_mod) {
case lm_none: i = va_arg(ap, int); break;
case lm_hh: i = va_arg(ap, int); break;
case lm_h: i = va_arg(ap, int); break;
case lm_l: i = va_arg(ap, long int); break;
case lm_ll: i = va_arg(ap, qint64); break;
case lm_j: i = va_arg(ap, long int); break;
case lm_z: i = va_arg(ap, size_t); break;
case lm_t: i = va_arg(ap, int); break;
default: i = 0; break;
}
subst = locale.d()->longLongToString(i, precision, 10, width, flags);
++c;
break;
}
case 'o':
case 'u':
case 'x':
case 'X': {
quint64 u;
switch (length_mod) {
case lm_none: u = va_arg(ap, uint); break;
case lm_hh: u = va_arg(ap, uint); break;
case lm_h: u = va_arg(ap, uint); break;
case lm_l: u = va_arg(ap, ulong); break;
case lm_ll: u = va_arg(ap, quint64); break;
case lm_z: u = va_arg(ap, size_t); break;
default: u = 0; break;
}
if (qIsUpper(*c))
flags |= QLocalePrivate::CapitalEorX;
int base = 10;
switch (qToLower(*c)) {
case 'o':
base = 8; break;
case 'u':
base = 10; break;
case 'x':
base = 16; break;
default: break;
}
subst = locale.d()->unsLongLongToString(u, precision, base, width, flags);
++c;
break;
}
case 'E':
case 'e':
case 'F':
case 'f':
case 'G':
case 'g':
case 'A':
case 'a': {
double d;
if (length_mod == lm_L)
d = va_arg(ap, long double); // not supported - converted to a double
else
d = va_arg(ap, double);
if (qIsUpper(*c))
flags |= QLocalePrivate::CapitalEorX;
QLocalePrivate::DoubleForm form = QLocalePrivate::DFDecimal;
switch (qToLower(*c)) {
case 'e': form = QLocalePrivate::DFExponent; break;
case 'a': // not supported - decimal form used instead
case 'f': form = QLocalePrivate::DFDecimal; break;
case 'g': form = QLocalePrivate::DFSignificantDigits; break;
default: break;
}
subst = locale.d()->doubleToString(d, precision, form, width, flags);
++c;
break;
}
case 'c': {
if (length_mod == lm_l)
subst = QChar((ushort) va_arg(ap, int));
else
subst = QLatin1Char((uchar) va_arg(ap, int));
++c;
break;
}
case 's': {
if (length_mod == lm_l) {
const ushort *buff = va_arg(ap, const ushort*);
const ushort *ch = buff;
while (*ch != 0)
++ch;
subst.setUtf16(buff, ch - buff);
} else
subst = QString::fromUtf8(va_arg(ap, const char*));
if (precision != -1)
subst.truncate(precision);
++c;
break;
}
case 'p': {
void *arg = va_arg(ap, void*);
#ifdef Q_OS_WIN64
quint64 i = reinterpret_cast<quint64>(arg);
#else
quint64 i = reinterpret_cast<unsigned long>(arg);
#endif
flags |= QLocalePrivate::Alternate;
subst = locale.d()->unsLongLongToString(i, precision, 16, width, flags);
++c;
break;
}
case 'n':
switch (length_mod) {
case lm_hh: {
signed char *n = va_arg(ap, signed char*);
*n = result.length();
break;
}
case lm_h: {
short int *n = va_arg(ap, short int*);
*n = result.length();
break;
}
case lm_l: {
long int *n = va_arg(ap, long int*);
*n = result.length();
break;
}
case lm_ll: {
qint64 *n = va_arg(ap, qint64*);
volatile uint tmp = result.length(); // egcs-2.91.66 gets internal
*n = tmp; // compiler error without volatile
break;
}
default: {
int *n = va_arg(ap, int*);
*n = result.length();
break;
}
}
++c;
break;
default: // bad escape, treat as non-escape text
for (const char *cc = escape_start; cc != c; ++cc)
result.append(QLatin1Char(*cc));
continue;
}
if (flags & QLocalePrivate::LeftAdjusted)
result.append(subst.leftJustified(width));
else
result.append(subst.rightJustified(width));
}
*this = result;
return *this;
}
/*!
Returns the string converted to a \c{long long} using base \a
base, which is 10 by default and must be between 2 and 36, or 0.
Returns 0 if the conversion fails.
If a conversion error occurs, *\a{ok} is set to false; otherwise
*\a{ok} is set to true.
If \a base is 0, the C language convention is used: If the string
begins with "0x", base 16 is used; if the string begins with "0",
base 8 is used; otherwise, base 10 is used.
Example:
\snippet doc/src/snippets/qstring/main.cpp 74
\sa number(), toULongLong(), toInt()
*/
qint64 QString::toLongLong(bool *ok, int base) const
{
#if defined(QT_CHECK_RANGE)
if (base != 0 && (base < 2 || base > 36)) {
qWarning("QString::toLongLong: Invalid base (%d)", base);
base = 10;
}
#endif
bool my_ok;
QLocale def_locale;
qint64 result = def_locale.d()->stringToLongLong(*this, base, &my_ok, QLocalePrivate::FailOnGroupSeparators);
if (my_ok) {
if (ok != 0)
*ok = true;
return result;
}
QLocale c_locale(QLocale::C);
return c_locale.d()->stringToLongLong(*this, base, ok, QLocalePrivate::FailOnGroupSeparators);
}
/*!
Returns the string converted to an \c{unsigned long long} using base \a
base, which is 10 by default and must be between 2 and 36, or 0.
Returns 0 if the conversion fails.
If a conversion error occurs, *\a{ok} is set to false; otherwise
*\a{ok} is set to true.
If \a base is 0, the C language convention is used: If the string
begins with "0x", base 16 is used; if the string begins with "0",
base 8 is used; otherwise, base 10 is used.
Example:
\snippet doc/src/snippets/qstring/main.cpp 79
\sa number(), toLongLong()
*/
quint64 QString::toULongLong(bool *ok, int base) const
{
#if defined(QT_CHECK_RANGE)
if (base != 0 && (base < 2 || base > 36)) {
qWarning("QString::toULongLong: Invalid base (%d)", base);
base = 10;
}
#endif
bool my_ok;
QLocale def_locale;
quint64 result = def_locale.d()->stringToUnsLongLong(*this, base, &my_ok, QLocalePrivate::FailOnGroupSeparators);
if (my_ok) {
if (ok != 0)
*ok = true;
return result;
}
QLocale c_locale(QLocale::C);
return c_locale.d()->stringToUnsLongLong(*this, base, ok, QLocalePrivate::FailOnGroupSeparators);
}
/*!
\fn long QString::toLong(bool *ok, int base) const
Returns the string converted to a \c long using base \a
base, which is 10 by default and must be between 2 and 36, or 0.
Returns 0 if the conversion fails.
If a conversion error occurs, *\a{ok} is set to false; otherwise
*\a{ok} is set to true.
If \a base is 0, the C language convention is used: If the string
begins with "0x", base 16 is used; if the string begins with "0",
base 8 is used; otherwise, base 10 is used.
Example:
\snippet doc/src/snippets/qstring/main.cpp 73
\sa number(), toULong(), toInt()
*/
long QString::toLong(bool *ok, int base) const
{
qint64 v = toLongLong(ok, base);
if (v < LONG_MIN || v > LONG_MAX) {
if (ok)
*ok = false;
v = 0;
}
return (long)v;
}
/*!
\fn ulong QString::toULong(bool *ok, int base) const
Returns the string converted to an \c{unsigned long} using base \a
base, which is 10 by default and must be between 2 and 36, or 0.
Returns 0 if the conversion fails.
If a conversion error occurs, *\a{ok} is set to false; otherwise
*\a{ok} is set to true.
If \a base is 0, the C language convention is used: If the string
begins with "0x", base 16 is used; if the string begins with "0",
base 8 is used; otherwise, base 10 is used.
Example:
\snippet doc/src/snippets/qstring/main.cpp 78
\sa number()
*/
ulong QString::toULong(bool *ok, int base) const
{
quint64 v = toULongLong(ok, base);
if (v > ULONG_MAX) {
if (ok)
*ok = false;
v = 0;
}
return (ulong)v;
}
/*!
Returns the string converted to an \c int using base \a
base, which is 10 by default and must be between 2 and 36, or 0.
Returns 0 if the conversion fails.
If a conversion error occurs, *\a{ok} is set to false; otherwise
*\a{ok} is set to true.
If \a base is 0, the C language convention is used: If the string
begins with "0x", base 16 is used; if the string begins with "0",
base 8 is used; otherwise, base 10 is used.
Example:
\snippet doc/src/snippets/qstring/main.cpp 72
\sa number(), toUInt(), toDouble()
*/
int QString::toInt(bool *ok, int base) const
{
qint64 v = toLongLong(ok, base);
if (v < INT_MIN || v > INT_MAX) {
if (ok)
*ok = false;
v = 0;
}
return v;
}
/*!
Returns the string converted to an \c{unsigned int} using base \a
base, which is 10 by default and must be between 2 and 36, or 0.
Returns 0 if the conversion fails.
If a conversion error occurs, *\a{ok} is set to false; otherwise
*\a{ok} is set to true.
If \a base is 0, the C language convention is used: If the string
begins with "0x", base 16 is used; if the string begins with "0",
base 8 is used; otherwise, base 10 is used.
Example:
\snippet doc/src/snippets/qstring/main.cpp 77
\sa number(), toInt()
*/
uint QString::toUInt(bool *ok, int base) const
{
quint64 v = toULongLong(ok, base);
if (v > UINT_MAX) {
if (ok)
*ok = false;
v = 0;
}
return (uint)v;
}
/*!
Returns the string converted to a \c short using base \a
base, which is 10 by default and must be between 2 and 36, or 0.
Returns 0 if the conversion fails.
If a conversion error occurs, *\a{ok} is set to false; otherwise
*\a{ok} is set to true.
If \a base is 0, the C language convention is used: If the string
begins with "0x", base 16 is used; if the string begins with "0",
base 8 is used; otherwise, base 10 is used.
Example:
\snippet doc/src/snippets/qstring/main.cpp 76
\sa number(), toUShort(), toInt()
*/
short QString::toShort(bool *ok, int base) const
{
long v = toLongLong(ok, base);
if (v < SHRT_MIN || v > SHRT_MAX) {
if (ok)
*ok = false;
v = 0;
}
return (short)v;
}
/*!
Returns the string converted to an \c{unsigned short} using base \a
base, which is 10 by default and must be between 2 and 36, or 0.
Returns 0 if the conversion fails.
If a conversion error occurs, *\a{ok} is set to false; otherwise
*\a{ok} is set to true.
If \a base is 0, the C language convention is used: If the string
begins with "0x", base 16 is used; if the string begins with "0",
base 8 is used; otherwise, base 10 is used.
Example:
\snippet doc/src/snippets/qstring/main.cpp 80
\sa number(), toShort()
*/
ushort QString::toUShort(bool *ok, int base) const
{
ulong v = toULongLong(ok, base);
if (v > USHRT_MAX) {
if (ok)
*ok = false;
v = 0;
}
return (ushort)v;
}
/*!
Returns the string converted to a \c double value.
Returns 0.0 if the conversion fails.
If a conversion error occurs, \c{*}\a{ok} is set to false;
otherwise \c{*}\a{ok} is set to true.
\snippet doc/src/snippets/qstring/main.cpp 66
Various string formats for floating point numbers can be converted
to double values:
\snippet doc/src/snippets/qstring/main.cpp 67
This function tries to interpret the string according to the
current locale. The current locale is determined from the
system at application startup and can be changed by calling
QLocale::setDefault(). If the string cannot be interpreted
according to the current locale, this function falls back
on the "C" locale.
\snippet doc/src/snippets/qstring/main.cpp 69
\snippet doc/src/snippets/qstring/main.cpp 70
Due to the ambiguity between the decimal point and thousands group
separator in various locales, this function does not handle
thousands group separators. If you need to convert such numbers,
see QLocale::toDouble().
\snippet doc/src/snippets/qstring/main.cpp 68
\sa number() QLocale::setDefault() QLocale::toDouble() trimmed()
*/
double QString::toDouble(bool *ok) const
{
bool my_ok;
QLocale def_locale;
double result = def_locale.d()->stringToDouble(*this, &my_ok, QLocalePrivate::FailOnGroupSeparators);
if (my_ok) {
if (ok != 0)
*ok = true;
return result;
}
QLocale c_locale(QLocale::C);
return c_locale.d()->stringToDouble(*this, ok, QLocalePrivate::FailOnGroupSeparators);
}
/*!
Returns the string converted to a \c float value.
If a conversion error occurs, *\a{ok} is set to false; otherwise
*\a{ok} is set to true. Returns 0.0 if the conversion fails.
Example:
\snippet doc/src/snippets/qstring/main.cpp 71
\sa number(), toDouble(), toInt()
*/
#define QT_MAX_FLOAT 3.4028234663852886e+38
float QString::toFloat(bool *ok) const
{
bool myOk;
double d = toDouble(&myOk);
if (!myOk || d > QT_MAX_FLOAT || d < -QT_MAX_FLOAT) {
if (ok != 0)
*ok = false;
return 0.0;
}
if (ok != 0)
*ok = true;
return (float) d;
}
/*! \fn QString &QString::setNum(int n, int base)
Sets the string to the printed value of \a n in the specified \a
base, and returns a reference to the string.
The base is 10 by default and must be between 2 and 36. For bases
other than 10, \a n is treated as an unsigned integer.
\snippet doc/src/snippets/qstring/main.cpp 56
The formatting always uses QLocale::C, i.e., English/UnitedStates.
To get a localized string representation of a number, use
QLocale::toString() with the appropriate locale.
*/
/*! \fn QString &QString::setNum(uint n, int base)
\overload
*/
/*! \fn QString &QString::setNum(long n, int base)
\overload
*/
/*! \fn QString &QString::setNum(ulong n, int base)
\overload
*/
/*!
\overload
*/
QString &QString::setNum(qlonglong n, int base)
{
#if defined(QT_CHECK_RANGE)
if (base < 2 || base > 36) {
qWarning("QString::setNum: Invalid base (%d)", base);
base = 10;
}
#endif
QLocale locale(QLocale::C);
*this = locale.d()->longLongToString(n, -1, base);
return *this;
}
/*!
\overload
*/
QString &QString::setNum(qulonglong n, int base)
{
#if defined(QT_CHECK_RANGE)
if (base < 2 || base > 36) {
qWarning("QString::setNum: Invalid base (%d)", base);
base = 10;
}
#endif
QLocale locale(QLocale::C);
*this = locale.d()->unsLongLongToString(n, -1, base);
return *this;
}
/*! \fn QString &QString::setNum(short n, int base)
\overload
*/
/*! \fn QString &QString::setNum(ushort n, int base)
\overload
*/
/*!
\fn QString &QString::setNum(double n, char format, int precision)
\overload
Sets the string to the printed value of \a n, formatted according
to the given \a format and \a precision, and returns a reference
to the string.
The \a format can be 'f', 'F', 'e', 'E', 'g' or 'G' (see the
arg() function documentation for an explanation of the formats).
Unlike QLocale::toString(), this function doesn't honor the
user's locale settings.
*/
QString &QString::setNum(double n, char f, int prec)
{
QLocalePrivate::DoubleForm form = QLocalePrivate::DFDecimal;
uint flags = 0;
if (qIsUpper(f))
flags = QLocalePrivate::CapitalEorX;
f = qToLower(f);
switch (f) {
case 'f':
form = QLocalePrivate::DFDecimal;
break;
case 'e':
form = QLocalePrivate::DFExponent;
break;
case 'g':
form = QLocalePrivate::DFSignificantDigits;
break;
default:
#if defined(QT_CHECK_RANGE)
qWarning("QString::setNum: Invalid format char '%c'", f);
#endif
break;
}
QLocale locale(QLocale::C);
*this = locale.d()->doubleToString(n, prec, form, -1, flags);
return *this;
}
/*!
\fn QString &QString::setNum(float n, char format, int precision)
\overload
Sets the string to the printed value of \a n, formatted according
to the given \a format and \a precision, and returns a reference
to the string.
*/
/*!
\fn QString QString::number(long n, int base)
Returns a string equivalent of the number \a n according to the
specified \a base.
The base is 10 by default and must be between 2
and 36. For bases other than 10, \a n is treated as an
unsigned integer.
\snippet doc/src/snippets/qstring/main.cpp 35
\sa setNum()
*/
QString QString::number(long n, int base)
{
QString s;
s.setNum(n, base);
return s;
}
/*!
\fn QString QString::number(ulong n, int base)
\overload
*/
QString QString::number(ulong n, int base)
{
QString s;
s.setNum(n, base);
return s;
}
/*!
\overload
*/
QString QString::number(int n, int base)
{
QString s;
s.setNum(n, base);
return s;
}
/*!
\overload
*/
QString QString::number(uint n, int base)
{
QString s;
s.setNum(n, base);
return s;
}
/*!
\overload
*/
QString QString::number(qlonglong n, int base)
{
QString s;
s.setNum(n, base);
return s;
}
/*!
\overload
*/
QString QString::number(qulonglong n, int base)
{
QString s;
s.setNum(n, base);
return s;
}
/*!
\fn QString QString::number(double n, char format, int precision)
Returns a string equivalent of the number \a n, formatted
according to the specified \a format and \a precision. See
\l{Argument Formats} for details.
Unlike QLocale::toString(), this function does not honor the
user's locale settings.
\sa setNum(), QLocale::toString()
*/
QString QString::number(double n, char f, int prec)
{
QString s;
s.setNum(n, f, prec);
return s;
}
/*!
Splits the string into substrings wherever \a sep occurs, and
returns the list of those strings. If \a sep does not match
anywhere in the string, split() returns a single-element list
containing this string.
\a cs specifies whether \a sep should be matched case
sensitively or case insensitively.
If \a behavior is QString::SkipEmptyParts, empty entries don't
appear in the result. By default, empty entries are kept.
Example:
\snippet doc/src/snippets/qstring/main.cpp 62
\sa QStringList::join(), section()
*/
QStringList QString::split(const QString &sep, SplitBehavior behavior, Qt::CaseSensitivity cs) const
{
QStringList list;
int start = 0;
int extra = 0;
int end;
while ((end = indexOf(sep, start + extra, cs)) != -1) {
if (start != end || behavior == KeepEmptyParts)
list.append(mid(start, end - start));
start = end + sep.size();
extra = (sep.size() == 0 ? 1 : 0);
}
if (start != size() || behavior == KeepEmptyParts)
list.append(mid(start));
return list;
}
/*!
\overload
*/
QStringList QString::split(const QChar &sep, SplitBehavior behavior, Qt::CaseSensitivity cs) const
{
QStringList list;
int start = 0;
int end;
while ((end = indexOf(sep, start, cs)) != -1) {
if (start != end || behavior == KeepEmptyParts)
list.append(mid(start, end - start));
start = end + 1;
}
if (start != size() || behavior == KeepEmptyParts)
list.append(mid(start));
return list;
}
#ifndef QT_NO_REGEXP
/*!
\overload
Splits the string into substrings wherever the regular expression
\a rx matches, and returns the list of those strings. If \a rx
does not match anywhere in the string, split() returns a
single-element list containing this string.
Here's an example where we extract the words in a sentence
using one or more whitespace characters as the separator:
\snippet doc/src/snippets/qstring/main.cpp 59
Here's a similar example, but this time we use any sequence of
non-word characters as the separator:
\snippet doc/src/snippets/qstring/main.cpp 60
Here's a third example where we use a zero-length assertion,
\bold{\\b} (word boundary), to split the string into an
alternating sequence of non-word and word tokens:
\snippet doc/src/snippets/qstring/main.cpp 61
\sa QStringList::join(), section()
*/
QStringList QString::split(const QRegExp &rx, SplitBehavior behavior) const
{
QRegExp rx2(rx);
QStringList list;
int start = 0;
int extra = 0;
int end;
while ((end = rx2.indexIn(*this, start + extra)) != -1) {
int matchedLen = rx2.matchedLength();
if (start != end || behavior == KeepEmptyParts)
list.append(mid(start, end - start));
start = end + matchedLen;
extra = (matchedLen == 0) ? 1 : 0;
}
if (start != size() || behavior == KeepEmptyParts)
list.append(mid(start));
return list;
}
#endif
/*!
\enum QString::NormalizationForm
This enum describes the various normalized forms of Unicode text.
\value NormalizationForm_D Canonical Decomposition
\value NormalizationForm_C Canonical Decomposition followed by Canonical Composition
\value NormalizationForm_KD Compatibility Decomposition
\value NormalizationForm_KC Compatibility Decomposition followed by Canonical Composition
\sa normalized(),
{http://www.unicode.org/reports/tr15/}{Unicode Standard Annex #15}
*/
/*!
\fn QString QString::normalized(NormalizationForm mode) const
Returns the string in the given Unicode normalization \a mode.
*/
QString QString::normalized(QString::NormalizationForm mode) const
{
return normalized(mode, UNICODE_DATA_VERSION);
}
/*!
\since 4.5
Returns a copy of this string repeated the specified number of \a times.
If \a times is less than 1, an empty string is returned.
Example:
\code
QString str("ab");
str.repeated(4); // returns "abababab"
\endcode
*/
QString QString::repeated(int times) const
{
if (d->size == 0)
return *this;
if (times <= 1) {
if (times == 1)
return *this;
return QString();
}
const int resultSize = times * d->size;
QString result;
result.reserve(resultSize);
if (result.d->alloc != resultSize)
return QString(); // not enough memory
memcpy(result.d->data, d->data, d->size * sizeof(ushort));
int sizeSoFar = d->size;
ushort *end = result.d->data + sizeSoFar;
const int halfResultSize = resultSize >> 1;
while (sizeSoFar <= halfResultSize) {
memcpy(end, result.d->data, sizeSoFar * sizeof(ushort));
end += sizeSoFar;
sizeSoFar <<= 1;
}
memcpy(end, result.d->data, (resultSize - sizeSoFar) * sizeof(ushort));
result.d->data[resultSize] = '\0';
result.d->size = resultSize;
return result;
}
void qt_string_normalize(QString *data, QString::NormalizationForm mode, QChar::UnicodeVersion version, int from);
/*!
\overload
\fn QString QString::normalized(NormalizationForm mode, QChar::UnicodeVersion version) const
Returns the string in the given Unicode normalization \a mode,
according to the given \a version of the Unicode standard.
*/
QString QString::normalized(QString::NormalizationForm mode, QChar::UnicodeVersion version) const
{
QString copy = *this;
qt_string_normalize(©, mode, version, 0);
return copy;
}
void qt_string_normalize(QString *data, QString::NormalizationForm mode, QChar::UnicodeVersion version, int from)
{
bool simple = true;
const QChar *p = data->constData();
int len = data->length();
for (int i = from; i < len; ++i) {
if (p[i].unicode() >= 0x80) {
simple = false;
break;
}
}
if (simple)
return;
if (version == QChar::Unicode_Unassigned) {
version = UNICODE_DATA_VERSION;
} else if (version != UNICODE_DATA_VERSION) {
QString &s = *data;
for (int i = 0; i < NumNormalizationCorrections; ++i) {
const NormalizationCorrection &n = uc_normalization_corrections[i];
if (n.version > version) {
int pos = from;
if (n.ucs4 > 0xffff) {
ushort ucs4High = QChar::highSurrogate(n.ucs4);
ushort ucs4Low = QChar::lowSurrogate(n.ucs4);
ushort oldHigh = QChar::highSurrogate(n.old_mapping);
ushort oldLow = QChar::lowSurrogate(n.old_mapping);
while (pos < s.length() - 1) {
if (s.at(pos).unicode() == ucs4High && s.at(pos + 1).unicode() == ucs4Low) {
s[pos] = oldHigh;
s[pos + 1] = oldLow;
++pos;
}
++pos;
}
} else {
while (pos < s.length()) {
if (s.at(pos).unicode() == n.ucs4) {
s[pos] = n.old_mapping;
}
++pos;
}
}
}
}
}
decomposeHelper(data, mode < QString::NormalizationForm_KD, version, from);
canonicalOrderHelper(data, version, from);
if (mode == QString::NormalizationForm_D || mode == QString::NormalizationForm_KD)
return;
composeHelper(data, from);
}
struct ArgEscapeData
{
int min_escape; // lowest escape sequence number
int occurrences; // number of occurrences of the lowest escape sequence number
int locale_occurrences; // number of occurrences of the lowest escape sequence number that
// contain 'L'
int escape_len; // total length of escape sequences which will be replaced
};
static ArgEscapeData findArgEscapes(const QString &s)
{
const QChar *uc_begin = s.unicode();
const QChar *uc_end = uc_begin + s.length();
ArgEscapeData d;
d.min_escape = INT_MAX;
d.occurrences = 0;
d.escape_len = 0;
d.locale_occurrences = 0;
const QChar *c = uc_begin;
while (c != uc_end) {
while (c != uc_end && c->unicode() != '%')
++c;
if (c == uc_end)
break;
const QChar *escape_start = c;
if (++c == uc_end)
break;
bool locale_arg = false;
if (c->unicode() == 'L') {
locale_arg = true;
if (++c == uc_end)
break;
}
if (c->digitValue() == -1)
continue;
int escape = c->digitValue();
++c;
if (c != uc_end && c->digitValue() != -1) {
escape = (10 * escape) + c->digitValue();
++c;
}
if (escape > d.min_escape)
continue;
if (escape < d.min_escape) {
d.min_escape = escape;
d.occurrences = 0;
d.escape_len = 0;
d.locale_occurrences = 0;
}
++d.occurrences;
if (locale_arg)
++d.locale_occurrences;
d.escape_len += c - escape_start;
}
return d;
}
static QString replaceArgEscapes(const QString &s, const ArgEscapeData &d, int field_width,
const QString &arg, const QString &larg, const QChar &fillChar = QLatin1Char(' '))
{
const QChar *uc_begin = s.unicode();
const QChar *uc_end = uc_begin + s.length();
int abs_field_width = qAbs(field_width);
int result_len = s.length()
- d.escape_len
+ (d.occurrences - d.locale_occurrences)
*qMax(abs_field_width, arg.length())
+ d.locale_occurrences
*qMax(abs_field_width, larg.length());
QString result(result_len, Qt::Uninitialized);
QChar *result_buff = (QChar*) result.unicode();
QChar *rc = result_buff;
const QChar *c = uc_begin;
int repl_cnt = 0;
while (c != uc_end) {
/* We don't have to check if we run off the end of the string with c,
because as long as d.occurrences > 0 we KNOW there are valid escape
sequences. */
const QChar *text_start = c;
while (c->unicode() != '%')
++c;
const QChar *escape_start = c++;
bool locale_arg = false;
if (c->unicode() == 'L') {
locale_arg = true;
++c;
}
int escape = c->digitValue();
if (escape != -1) {
if (c + 1 != uc_end && (c + 1)->digitValue() != -1) {
escape = (10 * escape) + (c + 1)->digitValue();
++c;
}
}
if (escape != d.min_escape) {
memcpy(rc, text_start, (c - text_start)*sizeof(QChar));
rc += c - text_start;
}
else {
++c;
memcpy(rc, text_start, (escape_start - text_start)*sizeof(QChar));
rc += escape_start - text_start;
uint pad_chars;
if (locale_arg)
pad_chars = qMax(abs_field_width, larg.length()) - larg.length();
else
pad_chars = qMax(abs_field_width, arg.length()) - arg.length();
if (field_width > 0) { // left padded
for (uint i = 0; i < pad_chars; ++i)
(rc++)->unicode() = fillChar.unicode();
}
if (locale_arg) {
memcpy(rc, larg.unicode(), larg.length()*sizeof(QChar));
rc += larg.length();
}
else {
memcpy(rc, arg.unicode(), arg.length()*sizeof(QChar));
rc += arg.length();
}
if (field_width < 0) { // right padded
for (uint i = 0; i < pad_chars; ++i)
(rc++)->unicode() = fillChar.unicode();
}
if (++repl_cnt == d.occurrences) {
memcpy(rc, c, (uc_end - c)*sizeof(QChar));
rc += uc_end - c;
Q_ASSERT(rc - result_buff == result_len);
c = uc_end;
}
}
}
Q_ASSERT(rc == result_buff + result_len);
return result;
}
/*!
Returns a copy of this string with the lowest numbered place marker
replaced by string \a a, i.e., \c %1, \c %2, ..., \c %99.
\a fieldWidth specifies the minimum amount of space that argument \a
a shall occupy. If \a a requires less space than \a fieldWidth, it
is padded to \a fieldWidth with character \a fillChar. A positive
\a fieldWidth produces right-aligned text. A negative \a fieldWidth
produces left-aligned text.
This example shows how we might create a \c status string for
reporting progress while processing a list of files:
\snippet doc/src/snippets/qstring/main.cpp 11
First, \c arg(i) replaces \c %1. Then \c arg(total) replaces \c
%2. Finally, \c arg(fileName) replaces \c %3.
One advantage of using arg() over sprintf() is that the order of the
numbered place markers can change, if the application's strings are
translated into other languages, but each arg() will still replace
the lowest numbered unreplaced place marker, no matter where it
appears. Also, if place marker \c %i appears more than once in the
string, the arg() replaces all of them.
If there is no unreplaced place marker remaining, a warning message
is output and the result is undefined. Place marker numbers must be
in the range 1 to 99.
*/
QString QString::arg(const QString &a, int fieldWidth, const QChar &fillChar) const
{
ArgEscapeData d = findArgEscapes(*this);
if (d.occurrences == 0) {
qWarning("QString::arg: Argument missing: %s, %s", toLocal8Bit().data(),
a.toLocal8Bit().data());
return *this;
}
return replaceArgEscapes(*this, d, fieldWidth, a, a, fillChar);
}
/*!
\fn QString QString::arg(const QString& a1, const QString& a2) const
\overload arg()
This is the same as \c {str.arg(a1).arg(a2)}, except that the
strings \a a1 and \a a2 are replaced in one pass. This can make a
difference if \a a1 contains e.g. \c{%1}:
\snippet doc/src/snippets/qstring/main.cpp 13
*/
/*!
\fn QString QString::arg(const QString& a1, const QString& a2, const QString& a3) const
\overload arg()
This is the same as calling \c str.arg(a1).arg(a2).arg(a3), except
that the strings \a a1, \a a2 and \a a3 are replaced in one pass.
*/
/*!
\fn QString QString::arg(const QString& a1, const QString& a2, const QString& a3, const QString& a4) const
\overload arg()
This is the same as calling \c
{str.arg(a1).arg(a2).arg(a3).arg(a4)}, except that the strings \a
a1, \a a2, \a a3 and \a a4 are replaced in one pass.
*/
/*!
\fn QString QString::arg(const QString& a1, const QString& a2, const QString& a3, const QString& a4, const QString& a5) const
\overload arg()
This is the same as calling \c
{str.arg(a1).arg(a2).arg(a3).arg(a4).arg(a5)}, except that the strings
\a a1, \a a2, \a a3, \a a4, and \a a5 are replaced in one pass.
*/
/*!
\fn QString QString::arg(const QString& a1, const QString& a2, const QString& a3, const QString& a4, const QString& a5, const QString& a6) const
\overload arg()
This is the same as calling \c
{str.arg(a1).arg(a2).arg(a3).arg(a4).arg(a5).arg(a6))}, except that
the strings \a a1, \a a2, \a a3, \a a4, \a a5, and \a a6 are
replaced in one pass.
*/
/*!
\fn QString QString::arg(const QString& a1, const QString& a2, const QString& a3, const QString& a4, const QString& a5, const QString& a6, const QString& a7) const
\overload arg()
This is the same as calling \c
{str.arg(a1).arg(a2).arg(a3).arg(a4).arg(a5).arg(a6).arg(a7)},
except that the strings \a a1, \a a2, \a a3, \a a4, \a a5, \a a6,
and \a a7 are replaced in one pass.
*/
/*!
\fn QString QString::arg(const QString& a1, const QString& a2, const QString& a3, const QString& a4, const QString& a5, const QString& a6, const QString& a7, const QString& a8) const
\overload arg()
This is the same as calling \c
{str.arg(a1).arg(a2).arg(a3).arg(a4).arg(a5).arg(a6).arg(a7).arg(a8)},
except that the strings \a a1, \a a2, \a a3, \a a4, \a a5, \a a6, \a
a7, and \a a8 are replaced in one pass.
*/
/*!
\fn QString QString::arg(const QString& a1, const QString& a2, const QString& a3, const QString& a4, const QString& a5, const QString& a6, const QString& a7, const QString& a8, const QString& a9) const
\overload arg()
This is the same as calling \c
{str.arg(a1).arg(a2).arg(a3).arg(a4).arg(a5).arg(a6).arg(a7).arg(a8).arg(a9)},
except that the strings \a a1, \a a2, \a a3, \a a4, \a a5, \a a6, \a
a7, \a a8, and \a a9 are replaced in one pass.
*/
/*! \fn QString QString::arg(int a, int fieldWidth, int base, const QChar &fillChar) const
\overload arg()
The \a a argument is expressed in base \a base, which is 10 by
default and must be between 2 and 36. For bases other than 10, \a a
is treated as an unsigned integer.
\a fieldWidth specifies the minimum amount of space that \a a is
padded to and filled with the character \a fillChar. A positive
value produces right-aligned text; a negative value produces
left-aligned text.
The '%' can be followed by an 'L', in which case the sequence is
replaced with a localized representation of \a a. The conversion
uses the default locale, set by QLocale::setDefault(). If no default
locale was specified, the "C" locale is used. The 'L' flag is
ignored if \a base is not 10.
\snippet doc/src/snippets/qstring/main.cpp 12
\snippet doc/src/snippets/qstring/main.cpp 14
If \a fillChar is '0' (the number 0, ASCII 48), the locale's zero is
used. For negative numbers, zero padding might appear before the
minus sign.
*/
/*! \fn QString QString::arg(uint a, int fieldWidth, int base, const QChar &fillChar) const
\overload arg()
The \a base argument specifies the base to use when converting the
integer \a a into a string. The base must be between 2 and 36.
If \a fillChar is '0' (the number 0, ASCII 48), the locale's zero is
used. For negative numbers, zero padding might appear before the
minus sign.
*/
/*! \fn QString QString::arg(long a, int fieldWidth, int base, const QChar &fillChar) const
\overload arg()
\a fieldWidth specifies the minimum amount of space that \a a is
padded to and filled with the character \a fillChar. A positive
value produces right-aligned text; a negative value produces
left-aligned text.
The \a a argument is expressed in the given \a base, which is 10 by
default and must be between 2 and 36.
The '%' can be followed by an 'L', in which case the sequence is
replaced with a localized representation of \a a. The conversion
uses the default locale. The default locale is determined from the
system's locale settings at application startup. It can be changed
using QLocale::setDefault(). The 'L' flag is ignored if \a base is
not 10.
\snippet doc/src/snippets/qstring/main.cpp 12
\snippet doc/src/snippets/qstring/main.cpp 14
If \a fillChar is '0' (the number 0, ASCII 48), the locale's zero is
used. For negative numbers, zero padding might appear before the
minus sign.
*/
/*! \fn QString QString::arg(ulong a, int fieldWidth, int base, const QChar &fillChar) const
\overload arg()
\a fieldWidth specifies the minimum amount of space that \a a is
padded to and filled with the character \a fillChar. A positive
value produces right-aligned text; a negative value produces
left-aligned text.
The \a base argument specifies the base to use when converting the
integer \a a to a string. The base must be between 2 and 36, with 8
giving octal, 10 decimal, and 16 hexadecimal numbers.
If \a fillChar is '0' (the number 0, ASCII 48), the locale's zero is
used. For negative numbers, zero padding might appear before the
minus sign.
*/
/*!
\overload arg()
\a fieldWidth specifies the minimum amount of space that \a a is
padded to and filled with the character \a fillChar. A positive
value produces right-aligned text; a negative value produces
left-aligned text.
The \a base argument specifies the base to use when converting the
integer \a a into a string. The base must be between 2 and 36, with
8 giving octal, 10 decimal, and 16 hexadecimal numbers.
If \a fillChar is '0' (the number 0, ASCII 48), the locale's zero is
used. For negative numbers, zero padding might appear before the
minus sign.
*/
QString QString::arg(qlonglong a, int fieldWidth, int base, const QChar &fillChar) const
{
ArgEscapeData d = findArgEscapes(*this);
if (d.occurrences == 0) {
qWarning() << "QString::arg: Argument missing:" << *this << ',' << a;
return *this;
}
unsigned flags = QLocalePrivate::NoFlags;
if (fillChar == QLatin1Char('0'))
flags = QLocalePrivate::ZeroPadded;
QString arg;
if (d.occurrences > d.locale_occurrences)
arg = QLocale::c().d()->longLongToString(a, -1, base, fieldWidth, flags);
QString locale_arg;
if (d.locale_occurrences > 0) {
QLocale locale;
if (!locale.numberOptions() & QLocale::OmitGroupSeparator)
flags |= QLocalePrivate::ThousandsGroup;
locale_arg = locale.d()->longLongToString(a, -1, base, fieldWidth, flags);
}
return replaceArgEscapes(*this, d, fieldWidth, arg, locale_arg, fillChar);
}
/*!
\overload arg()
\a fieldWidth specifies the minimum amount of space that \a a is
padded to and filled with the character \a fillChar. A positive
value produces right-aligned text; a negative value produces
left-aligned text.
The \a base argument specifies the base to use when converting the
integer \a a into a string. \a base must be between 2 and 36, with 8
giving octal, 10 decimal, and 16 hexadecimal numbers.
If \a fillChar is '0' (the number 0, ASCII 48), the locale's zero is
used. For negative numbers, zero padding might appear before the
minus sign.
*/
QString QString::arg(qulonglong a, int fieldWidth, int base, const QChar &fillChar) const
{
ArgEscapeData d = findArgEscapes(*this);
if (d.occurrences == 0) {
qWarning() << "QString::arg: Argument missing:" << *this << ',' << a;
return *this;
}
unsigned flags = QLocalePrivate::NoFlags;
if (fillChar == QLatin1Char('0'))
flags = QLocalePrivate::ZeroPadded;
QString arg;
if (d.occurrences > d.locale_occurrences)
arg = QLocale::c().d()->unsLongLongToString(a, -1, base, fieldWidth, flags);
QString locale_arg;
if (d.locale_occurrences > 0) {
QLocale locale;
if (!locale.numberOptions() & QLocale::OmitGroupSeparator)
flags |= QLocalePrivate::ThousandsGroup;
locale_arg = locale.d()->unsLongLongToString(a, -1, base, fieldWidth, flags);
}
return replaceArgEscapes(*this, d, fieldWidth, arg, locale_arg, fillChar);
}
/*!
\overload arg()
\fn QString QString::arg(short a, int fieldWidth, int base, const QChar &fillChar) const
\a fieldWidth specifies the minimum amount of space that \a a is
padded to and filled with the character \a fillChar. A positive
value produces right-aligned text; a negative value produces
left-aligned text.
The \a base argument specifies the base to use when converting the
integer \a a into a string. The base must be between 2 and 36, with
8 giving octal, 10 decimal, and 16 hexadecimal numbers.
If \a fillChar is '0' (the number 0, ASCII 48), the locale's zero is
used. For negative numbers, zero padding might appear before the
minus sign.
*/
/*!
\fn QString QString::arg(ushort a, int fieldWidth, int base, const QChar &fillChar) const
\overload arg()
\a fieldWidth specifies the minimum amount of space that \a a is
padded to and filled with the character \a fillChar. A positive
value produces right-aligned text; a negative value produces
left-aligned text.
The \a base argument specifies the base to use when converting the
integer \a a into a string. The base must be between 2 and 36, with
8 giving octal, 10 decimal, and 16 hexadecimal numbers.
If \a fillChar is '0' (the number 0, ASCII 48), the locale's zero is
used. For negative numbers, zero padding might appear before the
minus sign.
*/
/*!
\overload arg()
*/
QString QString::arg(QChar a, int fieldWidth, const QChar &fillChar) const
{
QString c;
c += a;
return arg(c, fieldWidth, fillChar);
}
/*!
\overload arg()
The \a a argument is interpreted as a Latin-1 character.
*/
QString QString::arg(char a, int fieldWidth, const QChar &fillChar) const
{
QString c;
c += QLatin1Char(a);
return arg(c, fieldWidth, fillChar);
}
/*!
\fn QString QString::arg(double a, int fieldWidth, char format, int precision, const QChar &fillChar) const
\overload arg()
Argument \a a is formatted according to the specified \a format and
\a precision. See \l{Argument Formats} for details.
\a fieldWidth specifies the minimum amount of space that \a a is
padded to and filled with the character \a fillChar. A positive
value produces right-aligned text; a negative value produces
left-aligned text.
\snippet doc/src/snippets/code/src_corelib_tools_qstring.cpp 2
The '%' can be followed by an 'L', in which case the sequence is
replaced with a localized representation of \a a. The conversion
uses the default locale, set by QLocale::setDefaultLocale(). If no
default locale was specified, the "C" locale is used.
If \a fillChar is '0' (the number 0, ASCII 48), this function will
use the locale's zero to pad. For negative numbers, the zero padding
will probably appear before the minus sign.
\sa QLocale::toString()
*/
QString QString::arg(double a, int fieldWidth, char fmt, int prec, const QChar &fillChar) const
{
ArgEscapeData d = findArgEscapes(*this);
if (d.occurrences == 0) {
qWarning("QString::arg: Argument missing: %s, %g", toLocal8Bit().data(), a);
return *this;
}
unsigned flags = QLocalePrivate::NoFlags;
if (fillChar == QLatin1Char('0'))
flags = QLocalePrivate::ZeroPadded;
if (qIsUpper(fmt))
flags |= QLocalePrivate::CapitalEorX;
fmt = qToLower(fmt);
QLocalePrivate::DoubleForm form = QLocalePrivate::DFDecimal;
switch (fmt) {
case 'f':
form = QLocalePrivate::DFDecimal;
break;
case 'e':
form = QLocalePrivate::DFExponent;
break;
case 'g':
form = QLocalePrivate::DFSignificantDigits;
break;
default:
#if defined(QT_CHECK_RANGE)
qWarning("QString::arg: Invalid format char '%c'", fmt);
#endif
break;
}
QString arg;
if (d.occurrences > d.locale_occurrences)
arg = QLocale::c().d()->doubleToString(a, prec, form, fieldWidth, flags);
QString locale_arg;
if (d.locale_occurrences > 0) {
QLocale locale;
if (!locale.numberOptions() & QLocale::OmitGroupSeparator)
flags |= QLocalePrivate::ThousandsGroup;
locale_arg = locale.d()->doubleToString(a, prec, form, fieldWidth, flags);
}
return replaceArgEscapes(*this, d, fieldWidth, arg, locale_arg, fillChar);
}
static int getEscape(const QChar *uc, int *pos, int len, int maxNumber = 999)
{
int i = *pos;
++i;
if (i < len && uc[i] == QLatin1Char('L'))
++i;
if (i < len) {
int escape = uc[i].unicode() - '0';
if (uint(escape) >= 10U)
return -1;
++i;
while (i < len) {
int digit = uc[i].unicode() - '0';
if (uint(digit) >= 10U)
break;
escape = (escape * 10) + digit;
++i;
}
if (escape <= maxNumber) {
*pos = i;
return escape;
}
}
return -1;
}
QString QString::multiArg(int numArgs, const QString **args) const
{
QString result;
QMap<int, int> numbersUsed;
const QChar *uc = (const QChar *) d->data;
const int len = d->size;
const int end = len - 1;
int lastNumber = -1;
int i = 0;
// populate the numbersUsed map with the %n's that actually occur in the string
while (i < end) {
if (uc[i] == QLatin1Char('%')) {
int number = getEscape(uc, &i, len);
if (number != -1) {
numbersUsed.insert(number, -1);
continue;
}
}
++i;
}
// assign an argument number to each of the %n's
QMap<int, int>::iterator j = numbersUsed.begin();
QMap<int, int>::iterator jend = numbersUsed.end();
int arg = 0;
while (j != jend && arg < numArgs) {
*j = arg++;
lastNumber = j.key();
++j;
}
// sanity
if (numArgs > arg) {
qWarning("QString::arg: %d argument(s) missing in %s", numArgs - arg, toLocal8Bit().data());
numArgs = arg;
}
i = 0;
while (i < len) {
if (uc[i] == QLatin1Char('%') && i != end) {
int number = getEscape(uc, &i, len, lastNumber);
int arg = numbersUsed[number];
if (number != -1 && arg != -1) {
result += *args[arg];
continue;
}
}
result += uc[i++];
}
return result;
}
static bool isStringRightToLeft(const ushort *p, const ushort *end)
{
bool righttoleft = false;
while (p < end) {
switch(QChar::direction(*p))
{
case QChar::DirL:
goto end;
case QChar::DirR:
case QChar::DirAL:
righttoleft = true;
goto end;
default:
break;
}
++p;
}
end:
return righttoleft;
}
/*! \internal
*/
void QString::updateProperties() const
{
ushort *p = d->data;
ushort *end = p + d->size;
d->simpletext = true;
while (p < end) {
ushort uc = *p;
// sort out regions of complex text formatting
if (uc > 0x058f && (uc < 0x1100 || uc > 0xfb0f)) {
d->simpletext = false;
}
p++;
}
d->righttoleft = isStringRightToLeft(d->data, d->data + d->size);
d->clean = true;
}
bool QString::isRightToLeft() const
{
return isStringRightToLeft(d->data, d->data + d->size);
}
/*! \fn bool QString::isSimpleText() const
\internal
*/
/*! \fn bool QString::isRightToLeft() const
Returns true if the string is read right to left.
*/
/*! \fn QChar *QString::data()
Returns a pointer to the data stored in the QString. The pointer
can be used to access and modify the characters that compose the
string. For convenience, the data is '\\0'-terminated.
Example:
\snippet doc/src/snippets/qstring/main.cpp 19
Note that the pointer remains valid only as long as the string is
not modified by other means. For read-only access, constData() is
faster because it never causes a \l{deep copy} to occur.
\sa constData(), operator[]()
*/
/*! \fn const QChar *QString::data() const
\overload
*/
/*! \fn const QChar *QString::constData() const
Returns a pointer to the data stored in the QString. The pointer
can be used to access the characters that compose the string. For
convenience, the data is '\\0'-terminated.
Note that the pointer remains valid only as long as the string is
not modified.
\sa data(), operator[]()
*/
/*! \fn void QString::push_front(const QString &other)
This function is provided for STL compatibility, prepending the
given \a other string to the beginning of this string. It is
equivalent to \c prepend(other).
\sa prepend()
*/
/*! \fn void QString::push_front(QChar ch)
\overload
Prepends the given \a ch character to the beginning of this string.
*/
/*! \fn void QString::push_back(const QString &other)
This function is provided for STL compatibility, appending the
given \a other string onto the end of this string. It is
equivalent to \c append(other).
\sa append()
*/
/*! \fn void QString::push_back(QChar ch)
\overload
Appends the given \a ch character onto the end of this string.
*/
/*!
\fn std::string QString::toStdString() const
Returns a std::string object with the data contained in this
QString. The Unicode data is converted into 8-bit characters using
the toAscii() function.
This operator is mostly useful to pass a QString to a function
that accepts a std::string object.
If the QString contains Unicode characters that the
QTextCodec::codecForCStrings() codec cannot handle, using this operator
can lead to loss of information.
This operator is only available if Qt is configured with STL
compatibility enabled.
\sa toAscii(), toLatin1(), toUtf8(), toLocal8Bit()
*/
/*!
Constructs a QString that uses the first \a size Unicode characters
in the array \a unicode. The data in \a unicode is \e not
copied. The caller must be able to guarantee that \a unicode will
not be deleted or modified as long as the QString (or an
unmodified copy of it) exists.
Any attempts to modify the QString or copies of it will cause it
to create a deep copy of the data, ensuring that the raw data
isn't modified.
Here's an example of how we can use a QRegExp on raw data in
memory without requiring to copy the data into a QString:
\snippet doc/src/snippets/qstring/main.cpp 22
\snippet doc/src/snippets/qstring/main.cpp 23
\warning A string created with fromRawData() is \e not
'\\0'-terminated, unless the raw data contains a '\\0' character
at position \a size. This means unicode() will \e not return a
'\\0'-terminated string (although utf16() does, at the cost of
copying the raw data).
\sa fromUtf16(), setRawData()
*/
QString QString::fromRawData(const QChar *unicode, int size)
{
Data *x = static_cast<Data *>(qMalloc(sizeof(Data)));
Q_CHECK_PTR(x);
if (unicode) {
x->data = (ushort *)unicode;
} else {
x->data = x->array;
size = 0;
}
x->ref = 1;
x->alloc = x->size = size;
*x->array = '\0';
x->clean = x->asciiCache = x->simpletext = x->righttoleft = x->capacity = 0;
return QString(x, 0);
}
/*!
\since 4.7
Resets the QString to use the first \a size Unicode characters
in the array \a unicode. The data in \a unicode is \e not
copied. The caller must be able to guarantee that \a unicode will
not be deleted or modified as long as the QString (or an
unmodified copy of it) exists.
This function can be used instead of fromRawData() to re-use
existings QString objects to save memory re-allocations.
\sa fromRawData()
*/
QString &QString::setRawData(const QChar *unicode, int size)
{
if (d->ref != 1 || (d->data == d->array && d->alloc)) {
*this = fromRawData(unicode, size);
} else {
#ifdef QT3_SUPPORT
if (d->asciiCache) {
Q_ASSERT(asciiCache);
asciiCache->remove(d);
}
#endif
if (unicode) {
d->data = (ushort *)unicode;
} else {
d->data = d->array;
size = 0;
}
d->alloc = d->size = size;
*d->array = '\0';
d->clean = d->asciiCache = d->simpletext = d->righttoleft = d->capacity = 0;
}
return *this;
}
/*! \class QLatin1String
\brief The QLatin1String class provides a thin wrapper around an US-ASCII/Latin-1 encoded string literal.
\ingroup string-processing
\reentrant
Many of QString's member functions are overloaded to accept
\c{const char *} instead of QString. This includes the copy
constructor, the assignment operator, the comparison operators,
and various other functions such as \link QString::insert()
insert() \endlink, \link QString::replace() replace()\endlink,
and \link QString::indexOf() indexOf()\endlink. These functions
are usually optimized to avoid constructing a QString object for
the \c{const char *} data. For example, assuming \c str is a
QString,
\snippet doc/src/snippets/code/src_corelib_tools_qstring.cpp 3
is much faster than
\snippet doc/src/snippets/code/src_corelib_tools_qstring.cpp 4
because it doesn't construct four temporary QString objects and
make a deep copy of the character data.
Applications that define \c QT_NO_CAST_FROM_ASCII (as explained
in the QString documentation) don't have access to QString's
\c{const char *} API. To provide an efficient way of specifying
constant Latin-1 strings, Qt provides the QLatin1String, which is
just a very thin wrapper around a \c{const char *}. Using
QLatin1String, the example code above becomes
\snippet doc/src/snippets/code/src_corelib_tools_qstring.cpp 5
This is a bit longer to type, but it provides exactly the same
benefits as the first version of the code, and is faster than
converting the Latin-1 strings using QString::fromLatin1().
Thanks to the QString(const QLatin1String &) constructor,
QLatin1String can be used everywhere a QString is expected. For
example:
\snippet doc/src/snippets/code/src_corelib_tools_qstring.cpp 6
\sa QString, QLatin1Char
*/
/*! \fn QLatin1String::QLatin1String(const char *str)
Constructs a QLatin1String object that stores \a str. Note that if
\a str is 0, an empty string is created; this case is handled by
QString.
The string data is \e not copied. The caller must be able to
guarantee that \a str will not be deleted or modified as long as
the QLatin1String object exists.
\sa latin1()
*/
/*!
\since 4.1
\fn QLatin1String &QLatin1String::operator=(const QLatin1String &other)
Constructs a copy of \a other.
*/
/*! \fn const char *QLatin1String::latin1() const
Returns the Latin-1 string stored in this object.
*/
/*! \fn bool QLatin1String::operator==(const QString &other) const
Returns true if this string is equal to string \a other;
otherwise returns false.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings with
QString::localeAwareCompare().
*/
/*!
\fn bool QLatin1String::operator==(const char *other) const
\since 4.3
\overload
The \a other const char pointer is converted to a QString using
the QString::fromAscii() function.
You can disable this operator by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*! \fn bool QLatin1String::operator!=(const QString &other) const
Returns true if this string is not equal to string \a other;
otherwise returns false.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings with
QString::localeAwareCompare().
*/
/*!
\fn bool QLatin1String::operator!=(const char *other) const
\since 4.3
\overload operator!=()
The \a other const char pointer is converted to a QString using
the QString::fromAscii() function.
You can disable this operator by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*!
\fn bool QLatin1String::operator>(const QString &other) const
Returns true if this string is lexically greater than string \a
other; otherwise returns false.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings with
QString::localeAwareCompare().
*/
/*!
\fn bool QLatin1String::operator>(const char *other) const
\since 4.3
\overload
The \a other const char pointer is converted to a QString using
the QString::fromAscii() function.
You can disable this operator by defining \c QT_NO_CAST_FROM_ASCII
when you compile your applications. This can be useful if you want
to ensure that all user-visible strings go through QObject::tr(),
for example.
*/
/*!
\fn bool QLatin1String::operator<(const QString &other) const
Returns true if this string is lexically less than the \a other
string; otherwise returns false.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings using the
QString::localeAwareCompare() function.
*/
/*!
\fn bool QLatin1String::operator<(const char *other) const
\since 4.3
\overload
The \a other const char pointer is converted to a QString using
the QString::fromAscii() function.
You can disable this operator by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*!
\fn bool QLatin1String::operator>=(const QString &other) const
Returns true if this string is lexically greater than or equal
to string \a other; otherwise returns false.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings with
QString::localeAwareCompare().
*/
/*!
\fn bool QLatin1String::operator>=(const char *other) const
\since 4.3
\overload
The \a other const char pointer is converted to a QString using
the QString::fromAscii() function.
You can disable this operator by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/*! \fn bool QLatin1String::operator<=(const QString &other) const
Returns true if this string is lexically less than or equal
to string \a other; otherwise returns false.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings with
QString::localeAwareCompare().
*/
/*!
\fn bool QLatin1String::operator<=(const char *other) const
\since 4.3
\overload
The \a other const char pointer is converted to a QString using
the QString::fromAscii() function.
You can disable this operator by defining \c
QT_NO_CAST_FROM_ASCII when you compile your applications. This
can be useful if you want to ensure that all user-visible strings
go through QObject::tr(), for example.
*/
/* \fn bool operator==(const QLatin1String &s1, const QLatin1String &s2)
\relates QLatin1String
Returns true if string \a s1 is lexically equal to string \a s2; otherwise
returns false.
*/
/* \fn bool operator!=(const QLatin1String &s1, const QLatin1String &s2)
\relates QLatin1String
Returns true if string \a s1 is lexically unequal to string \a s2; otherwise
returns false.
*/
/* \fn bool operator<(const QLatin1String &s1, const QLatin1String &s2)
\relates QLatin1String
Returns true if string \a s1 is lexically smaller than string \a s2; otherwise
returns false.
*/
/* \fn bool operator<=(const QLatin1String &s1, const QLatin1String &s2)
\relates QLatin1String
Returns true if string \a s1 is lexically smaller than or equal to string \a s2; otherwise
returns false.
*/
/* \fn bool operator>(const QLatin1String &s1, const QLatin1String &s2)
\relates QLatin1String
Returns true if string \a s1 is lexically greater than string \a s2; otherwise
returns false.
*/
/* \fn bool operator>=(const QLatin1String &s1, const QLatin1String &s2)
\relates QLatin1String
Returns true if string \a s1 is lexically greater than or equal to
string \a s2; otherwise returns false.
*/
#if !defined(QT_NO_DATASTREAM) || (defined(QT_BOOTSTRAPPED) && !defined(QT_BUILD_QMAKE))
/*!
\fn QDataStream &operator<<(QDataStream &stream, const QString &string)
\relates QString
Writes the given \a string to the specified \a stream.
\sa {Serializing Qt Data Types}
*/
QDataStream &operator<<(QDataStream &out, const QString &str)
{
if (out.version() == 1) {
out << str.toLatin1();
} else {
if (!str.isNull() || out.version() < 3) {
int byteOrder = out.byteOrder();
const QChar* ub = str.unicode();
static const uint auto_size = 1024;
char t[auto_size];
char *b;
if (str.length()*sizeof(QChar) > auto_size) {
b = new char[str.length()*sizeof(QChar)];
} else {
b = t;
}
int l = str.length();
char *c=b;
while (l--) {
if (byteOrder == QDataStream::BigEndian) {
*c++ = (char)ub->row();
*c++ = (char)ub->cell();
} else {
*c++ = (char)ub->cell();
*c++ = (char)ub->row();
}
ub++;
}
out.writeBytes(b, sizeof(QChar)*str.length());
if (str.length()*sizeof(QChar) > auto_size)
delete [] b;
} else {
// write null marker
out << (quint32)0xffffffff;
}
}
return out;
}
/*!
\fn QDataStream &operator>>(QDataStream &stream, QString &string)
\relates QString
Reads a string from the specified \a stream into the given \a string.
\sa {Serializing Qt Data Types}
*/
QDataStream &operator>>(QDataStream &in, QString &str)
{
#ifdef QT_QSTRING_UCS_4
#if defined(Q_CC_GNU)
#warning "operator>> not working properly"
#endif
#endif
if (in.version() == 1) {
QByteArray l;
in >> l;
str = QString::fromLatin1(l);
} else {
quint32 bytes = 0;
in >> bytes; // read size of string
if (bytes == 0xffffffff) { // null string
str.clear();
} else if (bytes > 0) { // not empty
if (bytes & 0x1) {
str.clear();
in.setStatus(QDataStream::ReadCorruptData);
return in;
}
const quint32 Step = 1024 * 1024;
quint32 len = bytes / 2;
quint32 allocated = 0;
while (allocated < len) {
int blockSize = qMin(Step, len - allocated);
str.resize(allocated + blockSize);
if (in.readRawData(reinterpret_cast<char *>(str.data()) + allocated * 2,
blockSize * 2) != blockSize * 2) {
str.clear();
in.setStatus(QDataStream::ReadPastEnd);
return in;
}
allocated += blockSize;
}
if ((in.byteOrder() == QDataStream::BigEndian)
!= (QSysInfo::ByteOrder == QSysInfo::BigEndian)) {
ushort *data = reinterpret_cast<ushort *>(str.data());
while (len--) {
*data = qbswap(*data);
++data;
}
}
} else {
str = QLatin1String("");
}
}
return in;
}
#endif // QT_NO_DATASTREAM
/*!
\fn void QString::setLength(int nl)
Use resize() instead.
*/
/*!
\fn QString QString::copy() const
Use simple assignment instead. QString is implicitly shared so if
a copy is modified only the copy is changed.
*/
/*!
\fn QString &QString::remove(QChar c, bool cs)
Use the remove(QChar, Qt::CaseSensitive) overload instead.
*/
/*!
\fn QString &QString::remove(const QString &s, bool cs)
Use the remove(QString, Qt::CaseSensitive) overload instead.
*/
/*!
\fn QString &QString::replace(QChar c, const QString &after, bool cs)
Use the replace(QChar, QString, Qt::CaseSensitive) overload instead.
*/
/*!
\fn QString &QString::replace(const QString &before, const QString &after, bool cs)
Use the replace(QString, QString, Qt::CaseSensitive) overload instead.
*/
/*!
\fn QString &QString::replace(char c, const QString &after, bool cs)
Use the replace(QChar, QString, Qt::CaseSensitive) overload instead.
*/
/*!
\fn QString &QString::replace(char c, const QString &after, Qt::CaseSensitivity cs)
Use the replace(QChar, QString, Qt::CaseSensitive) overload instead.
*/
/*!
\fn int QString::find(QChar c, int i = 0, bool cs = true) const
Use indexOf() instead.
*/
/*!
\fn int QString::find(const QString &s, int i = 0, bool cs = true) const
Use indexOf() instead.
*/
/*!
\fn int QString::findRev(QChar c, int i = -1, bool cs = true) const
Use lastIndexOf() instead.
*/
/*!
\fn int QString::findRev(const QString &s, int i = -1, bool cs = true) const
Use lastIndexOf() instead.
*/
/*!
\fn int QString::find(const QRegExp &rx, int i=0) const
Use indexOf() instead.
*/
/*!
\fn int QString::find(QRegExp &rx, int i=0) const
\internal
\since 4.5
Use indexOf() instead.
*/
/*!
\fn int QString::findRev(const QRegExp &rx, int i=-1) const
Use lastIndexOf() instead.
*/
/*!
\fn int QString::findRev(QRegExp &rx, int i=0) const
\internal
\since 4.5
Use lastIndexOf() instead.
*/
/*!
\fn QBool QString::contains(QChar c, bool cs) const
Use the contains(QChar, Qt::CaseSensitive) overload instead.
*/
/*!
\fn QBool QString::contains(const QString &s, bool cs) const
Use the contains(QString, Qt::CaseSensitive) overload instead.
*/
/*!
\fn bool QString::startsWith(const QString &s, bool cs) const
Use the startsWith(QString, Qt::CaseSensitive) overload instead.
*/
/*!
\fn bool QString::endsWith(const QString &s, bool cs) const
Use the endsWith(QString, Qt::CaseSensitive) overload instead.
*/
/*!
\fn QString QString::leftJustify(int width, QChar fill = QLatin1Char(' '), bool trunc=false) const
Use leftJustified() instead.
*/
/*!
\fn QString QString::rightJustify(int width, QChar fill = QLatin1Char(' '), bool trunc=false) const
Use rightJustified() instead.
*/
/*!
\fn QString QString::lower() const
Use toLower() instead.
*/
/*!
\fn QString QString::upper() const
Use toUpper() instead.
*/
/*!
\fn QString QString::stripWhiteSpace() const
Use trimmed() instead.
*/
/*!
\fn QString QString::simplifyWhiteSpace() const
Use simplified() instead.
*/
/*!
\fn QString &QString::setUnicodeCodes(const ushort *unicode_as_ushorts, int size)
Use setUtf16() instead.
*/
/*!
\fn ushort *QString::ucs2() const
Use utf16() instead.
*/
/*!
\fn QString QString::fromUcs2(const ushort *unicode, int size = -1)
Use fromUtf16() instead.
*/
/*!
\fn QString &QString::setAscii(const char *str, int len = -1)
Use fromAscii() instead.
*/
/*!
\fn QString &QString::setLatin1(const char *str, int len = -1)
Use fromLatin1() instead.
*/
/*!
\fn QChar QString::constref(uint i) const
Use at() instead.
*/
/*!
\fn QChar &QString::ref(uint i);
Use operator[]() instead.
*/
/*!
\fn QString::operator const char *() const
Use toAscii().constData() instead.
*/
/*!
\class QConstString
\brief The QConstString class is a wrapper for constant Unicode string data.
\compat
In Qt 4, QConstString is replaced by QString::fromRawData(), a
static function that constructs a QString object based on Unicode
string data.
Because QString::fromRawData() has slightly more stringent
constraints than QConstString had in Qt 3, the new QConstString
class takes a deep copy of the string data.
\sa QString::fromRawData()
*/
/*!
\fn QConstString::QConstString(const QChar *unicode, int size)
Use QString(\a unicode, \a size) or
QString::fromRawData(\a unicode, \a size) instead.
*/
/*!
\fn const QString &QConstString::string() const
Returns \c *this. Not necessary in Qt 4.
*/
/*!
\class QStringRef
\since 4.3
\brief The QStringRef class provides a thin wrapper around QString substrings.
\reentrant
\ingroup tools
\ingroup string-processing
QStringRef provides a read-only subset of the QString API.
A string reference explicitly references a portion of a string()
with a given size(), starting at a specific position(). Calling
toString() returns a copy of the data as a real QString instance.
This class is designed to improve the performance of substring
handling when manipulating substrings obtained from existing QString
instances. QStringRef avoids the memory allocation and reference
counting overhead of a standard QString by simply referencing a
part of the original string. This can prove to be advantageous in
low level code, such as that used in a parser, at the expense of
potentially more complex code.
For most users, there are no semantic benefits to using QStringRef
instead of QString since QStringRef requires attention to be paid
to memory management issues, potentially making code more complex
to write and maintain.
\warning A QStringRef is only valid as long as the referenced
string exists. If the original string is deleted, the string
reference points to an invalid memory location.
We suggest that you only use this class in stable code where profiling
has clearly identified that performance improvements can be made by
replacing standard string operations with the optimized substring
handling provided by this class.
\sa {Implicitly Shared Classes}
*/
/*!
\fn QStringRef::QStringRef()
Constructs an empty string reference.
*/
/*! \fn QStringRef::QStringRef(const QString *string, int position, int length)
Constructs a string reference to the range of characters in the given
\a string specified by the starting \a position and \a length in characters.
\warning This function exists to improve performance as much as possible,
and performs no bounds checking. For program correctness, \a position and
\a length must describe a valid substring of \a string.
This means that the starting \a position must be positive or 0 and smaller
than \a string's length, and \a length must be positive or 0 but smaller than
the string's length minus the starting \a position;
i.e, 0 <= position < string->length() and
0 <= length <= string->length() - position must both be satisfied.
*/
/*! \fn QStringRef::QStringRef(const QString *string)
Constructs a string reference to the given \a string.
*/
/*! \fn QStringRef::QStringRef(const QStringRef &other)
Constructs a copy of the \a other string reference.
*/
/*!
\fn QStringRef::~QStringRef()
Destroys the string reference.
Since this class is only used to refer to string data, and does not take
ownership of it, no memory is freed when instances are destroyed.
*/
/*!
\fn int QStringRef::position() const
Returns the starting position in the referenced string that is referred to
by the string reference.
\sa size(), string()
*/
/*!
\fn int QStringRef::size() const
Returns the number of characters referred to by the string reference.
Equivalent to length() and count().
\sa position(), string()
*/
/*!
\fn int QStringRef::count() const
Returns the number of characters referred to by the string reference.
Equivalent to size() and length().
\sa position(), string()
*/
/*!
\fn int QStringRef::length() const
Returns the number of characters referred to by the string reference.
Equivalent to size() and count().
\sa position(), string()
*/
/*!
\fn bool QStringRef::isEmpty() const
Returns true if the string reference has no characters; otherwise returns
false.
A string reference is empty if its size is zero.
\sa size()
*/
/*!
\fn bool QStringRef::isNull() const
Returns true if string() returns a null pointer or a pointer to a
null string; otherwise returns true.
\sa size()
*/
/*!
\fn const QString *QStringRef::string() const
Returns a pointer to the string referred to by the string reference, or
0 if it does not reference a string.
\sa unicode()
*/
/*!
\fn const QChar *QStringRef::unicode() const
Returns a Unicode representation of the string reference. Since
the data stems directly from the referenced string, it is not
null-terminated unless the string reference includes the string's
null terminator.
\sa string()
*/
/*!
\fn const QChar *QStringRef::data() const
Same as unicode().
*/
/*!
\fn const QChar *QStringRef::constData() const
Same as unicode().
*/
/*!
Returns a copy of the string reference as a QString object.
If the string reference is not a complete reference of the string
(meaning that position() is 0 and size() equals string()->size()),
this function will allocate a new string to return.
\sa string()
*/
QString QStringRef::toString() const {
if (!m_string)
return QString();
if (m_size && m_position == 0 && m_size == m_string->size())
return *m_string;
return QString(m_string->unicode() + m_position, m_size);
}
/*! \relates QStringRef
Returns true if string reference \a s1 is lexically equal to string reference \a s2; otherwise
returns false.
*/
bool operator==(const QStringRef &s1,const QStringRef &s2)
{ return (s1.size() == s2.size() &&
qMemEquals((const ushort *)s1.unicode(), (const ushort *)s2.unicode(), s1.size()));
}
/*! \relates QStringRef
Returns true if string \a s1 is lexically equal to string reference \a s2; otherwise
returns false.
*/
bool operator==(const QString &s1,const QStringRef &s2)
{ return (s1.size() == s2.size() &&
qMemEquals((const ushort *)s1.unicode(), (const ushort *)s2.unicode(), s1.size()));
}
/*! \relates QStringRef
Returns true if string \a s1 is lexically equal to string reference \a s2; otherwise
returns false.
*/
bool operator==(const QLatin1String &s1, const QStringRef &s2)
{
const ushort *uc = reinterpret_cast<const ushort *>(s2.unicode());
const ushort *e = uc + s2.size();
const uchar *c = reinterpret_cast<const uchar *>(s1.latin1());
if (!c)
return s2.isEmpty();
while (*c) {
if (uc == e || *uc != *c)
return false;
++uc;
++c;
}
return (uc == e);
}
/*!
\relates QStringRef
Returns true if string reference \a s1 is lexically less than
string reference \a s2; otherwise returns false.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings using the
QString::localeAwareCompare() function.
*/
bool operator<(const QStringRef &s1,const QStringRef &s2)
{
return ucstrcmp(s1.constData(), s1.length(), s2.constData(), s2.length()) < 0;
}
/*!\fn bool operator<=(const QStringRef &s1,const QStringRef &s2)
\relates QStringRef
Returns true if string reference \a s1 is lexically less than
or equal to string reference \a s2; otherwise returns false.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings using the
QString::localeAwareCompare() function.
*/
/*!\fn bool operator>=(const QStringRef &s1,const QStringRef &s2)
\relates QStringRef
Returns true if string reference \a s1 is lexically greater than
or equal to string reference \a s2; otherwise returns false.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings using the
QString::localeAwareCompare() function.
*/
/*!\fn bool operator>(const QStringRef &s1,const QStringRef &s2)
\relates QStringRef
Returns true if string reference \a s1 is lexically greater than
string reference \a s2; otherwise returns false.
The comparison is based exclusively on the numeric Unicode values
of the characters and is very fast, but is not what a human would
expect. Consider sorting user-interface strings using the
QString::localeAwareCompare() function.
*/
/*!
\fn const QChar QStringRef::at(int position) const
Returns the character at the given index \a position in the
string reference.
The \a position must be a valid index position in the string
(i.e., 0 <= \a position < size()).
*/
/*!
\fn void QStringRef::clear()
Clears the contents of the string reference by making it null and empty.
\sa isEmpty(), isNull()
*/
/*!
\fn QStringRef &QStringRef::operator=(const QStringRef &other)
Assigns the \a other string reference to this string reference, and
returns the result.
*/
/*!
\fn QStringRef &QStringRef::operator=(const QString *string)
Constructs a string reference to the given \a string and assigns it to
this string reference, returning the result.
*/
/*!
\typedef QString::DataPtr
\internal
*/
/*!
\fn DataPtr & QString::data_ptr()
\internal
*/
/*! Appends the string reference to \a string, and returns a new
reference to the combined string data.
*/
QStringRef QStringRef::appendTo(QString *string) const
{
if (!string)
return QStringRef();
int pos = string->size();
string->insert(pos, unicode(), size());
return QStringRef(string, pos, size());
}
/*!
\fn int QStringRef::compare(const QStringRef &s1, const QString &s2, Qt::CaseSensitivity cs = Qt::CaseSensitive)
\since 4.5
Compares the string \a s1 with the string \a s2 and returns an
integer less than, equal to, or greater than zero if \a s1
is less than, equal to, or greater than \a s2.
If \a cs is Qt::CaseSensitive, the comparison is case sensitive;
otherwise the comparison is case insensitive.
*/
/*!
\fn int QStringRef::compare(const QStringRef &s1, const QStringRef &s2, Qt::CaseSensitivity cs = Qt::CaseSensitive)
\since 4.5
\overload
Compares the string \a s1 with the string \a s2 and returns an
integer less than, equal to, or greater than zero if \a s1
is less than, equal to, or greater than \a s2.
If \a cs is Qt::CaseSensitive, the comparison is case sensitive;
otherwise the comparison is case insensitive.
*/
/*!
\fn int QStringRef::compare(const QStringRef &s1, QLatin1String s2, Qt::CaseSensitivity cs = Qt::CaseSensitive)
\since 4.5
\overload
Compares the string \a s1 with the string \a s2 and returns an
integer less than, equal to, or greater than zero if \a s1
is less than, equal to, or greater than \a s2.
If \a cs is Qt::CaseSensitive, the comparison is case sensitive;
otherwise the comparison is case insensitive.
*/
/*!
\overload
\fn int QStringRef::compare(const QString &other, Qt::CaseSensitivity cs = Qt::CaseSensitive) const
\since 4.5
Compares this string with the \a other string and returns an
integer less than, equal to, or greater than zero if this string
is less than, equal to, or greater than the \a other string.
If \a cs is Qt::CaseSensitive, the comparison is case sensitive;
otherwise the comparison is case insensitive.
Equivalent to \c {compare(*this, other, cs)}.
\sa QString::compare()
*/
/*!
\overload
\fn int QStringRef::compare(const QStringRef &other, Qt::CaseSensitivity cs = Qt::CaseSensitive) const
\since 4.5
Compares this string with the \a other string and returns an
integer less than, equal to, or greater than zero if this string
is less than, equal to, or greater than the \a other string.
If \a cs is Qt::CaseSensitive, the comparison is case sensitive;
otherwise the comparison is case insensitive.
Equivalent to \c {compare(*this, other, cs)}.
\sa QString::compare()
*/
/*!
\overload
\fn int QStringRef::compare(QLatin1String other, Qt::CaseSensitivity cs = Qt::CaseSensitive) const
\since 4.5
Compares this string with the \a other string and returns an
integer less than, equal to, or greater than zero if this string
is less than, equal to, or greater than the \a other string.
If \a cs is Qt::CaseSensitive, the comparison is case sensitive;
otherwise the comparison is case insensitive.
Equivalent to \c {compare(*this, other, cs)}.
\sa QString::compare()
*/
/*!
\fn int QStringRef::localeAwareCompare(const QStringRef &s1, const QString & s2)
\since 4.5
Compares \a s1 with \a s2 and returns an integer less than, equal
to, or greater than zero if \a s1 is less than, equal to, or
greater than \a s2.
The comparison is performed in a locale- and also
platform-dependent manner. Use this function to present sorted
lists of strings to the user.
On Mac OS X, this function compares according the
"Order for sorted lists" setting in the International prefereces panel.
\sa compare(), QTextCodec::locale()
*/
/*!
\fn int QStringRef::localeAwareCompare(const QStringRef &s1, const QStringRef & s2)
\since 4.5
\overload
Compares \a s1 with \a s2 and returns an integer less than, equal
to, or greater than zero if \a s1 is less than, equal to, or
greater than \a s2.
The comparison is performed in a locale- and also
platform-dependent manner. Use this function to present sorted
lists of strings to the user.
*/
/*!
\fn int QStringRef::localeAwareCompare(const QString &other) const
\since 4.5
\overload
Compares this string with the \a other string and returns an
integer less than, equal to, or greater than zero if this string
is less than, equal to, or greater than the \a other string.
The comparison is performed in a locale- and also
platform-dependent manner. Use this function to present sorted
lists of strings to the user.
*/
/*!
\fn int QStringRef::localeAwareCompare(const QStringRef &other) const
\since 4.5
\overload
Compares this string with the \a other string and returns an
integer less than, equal to, or greater than zero if this string
is less than, equal to, or greater than the \a other string.
The comparison is performed in a locale- and also
platform-dependent manner. Use this function to present sorted
lists of strings to the user.
*/
/*!
\fn QString &QString::append(const QStringRef &reference)
\since 4.4
Appends the given string \a reference to this string and returns the result.
*/
QString &QString::append(const QStringRef &str)
{
if (str.string() == this) {
str.appendTo(this);
} else if (str.string()) {
int oldSize = size();
resize(oldSize + str.size());
memcpy(data() + oldSize, str.unicode(), str.size() * sizeof(QChar));
}
return *this;
}
/*!
\since 4.4
Returns a substring reference to the \a n leftmost characters
of the string.
If \a n is greater than size() or less than zero, a reference to the entire
string is returned.
\snippet doc/src/snippets/qstring/main.cpp leftRef
\sa left(), rightRef(), midRef(), startsWith()
*/
QStringRef QString::leftRef(int n) const
{
if (n >= d->size || n < 0)
n = d->size;
return QStringRef(this, 0, n);
}
/*!
\since 4.4
Returns a substring reference to the \a n rightmost characters
of the string.
If \a n is greater than size() or less than zero, a reference to the entire
string is returned.
\snippet doc/src/snippets/qstring/main.cpp rightRef
\sa right(), leftRef(), midRef(), endsWith()
*/
QStringRef QString::rightRef(int n) const
{
if (n >= d->size || n < 0)
n = d->size;
return QStringRef(this, d->size - n, n);
}
/*!
\since 4.4
Returns a substring reference to \a n characters of this string,
starting at the specified \a position.
If the \a position exceeds the length of the string, an empty
reference is returned.
If there are less than \a n characters available in the string,
starting at the given \a position, or if \a n is -1 (default), the
function returns all characters from the specified \a position
onwards.
Example:
\snippet doc/src/snippets/qstring/main.cpp midRef
\sa mid(), leftRef(), rightRef()
*/
QStringRef QString::midRef(int position, int n) const
{
if (d == &shared_null || position >= d->size)
return QStringRef();
if (n < 0)
n = d->size - position;
if (position < 0) {
n += position;
position = 0;
}
if (n + position > d->size)
n = d->size - position;
return QStringRef(this, position, n);
}
QT_END_NAMESPACE
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