The QByteArray class provides an array of bytes. More...
#include <QByteArray>
Inherited by: Q3CString.
Note: All functions in this class are reentrant.
QByteArray () | |
QByteArray ( const char * str ) | |
QByteArray ( const char * data, int size ) | |
QByteArray ( int size, char ch ) | |
QByteArray ( const QByteArray & other ) | |
~QByteArray () | |
QByteArray & | append ( const QByteArray & ba ) |
QByteArray & | append ( const QString & str ) |
QByteArray & | append ( const char * str ) |
QByteArray & | append ( const char * str, int len ) |
QByteArray & | append ( char ch ) |
char | at ( int i ) const |
int | capacity () const |
void | chop ( int n ) |
void | clear () |
const char * | constData () const |
bool | contains ( const QByteArray & ba ) const |
bool | contains ( const char * str ) const |
bool | contains ( char ch ) const |
int | count ( const QByteArray & ba ) const |
int | count ( const char * str ) const |
int | count ( char ch ) const |
int | count () const |
char * | data () |
const char * | data () const |
bool | endsWith ( const QByteArray & ba ) const |
bool | endsWith ( const char * str ) const |
bool | endsWith ( char ch ) const |
QByteArray & | fill ( char ch, int size = -1 ) |
int | indexOf ( const QByteArray & ba, int from = 0 ) const |
int | indexOf ( const QString & str, int from = 0 ) const |
int | indexOf ( const char * str, int from = 0 ) const |
int | indexOf ( char ch, int from = 0 ) const |
QByteArray & | insert ( int i, const QByteArray & ba ) |
QByteArray & | insert ( int i, const QString & str ) |
QByteArray & | insert ( int i, const char * str ) |
QByteArray & | insert ( int i, const char * str, int len ) |
QByteArray & | insert ( int i, char ch ) |
bool | isEmpty () const |
bool | isNull () const |
int | lastIndexOf ( const QByteArray & ba, int from = -1 ) const |
int | lastIndexOf ( const QString & str, int from = -1 ) const |
int | lastIndexOf ( const char * str, int from = -1 ) const |
int | lastIndexOf ( char ch, int from = -1 ) const |
QByteArray | left ( int len ) const |
QByteArray | leftJustified ( int width, char fill = ' ', bool truncate = false ) const |
int | length () const |
QByteArray | mid ( int pos, int len = -1 ) const |
QByteArray & | prepend ( const QByteArray & ba ) |
QByteArray & | prepend ( const char * str ) |
QByteArray & | prepend ( const char * str, int len ) |
QByteArray & | prepend ( char ch ) |
void | push_back ( const QByteArray & other ) |
void | push_back ( const char * str ) |
void | push_back ( char ch ) |
void | push_front ( const QByteArray & other ) |
void | push_front ( const char * str ) |
void | push_front ( char ch ) |
QByteArray & | remove ( int pos, int len ) |
QByteArray | repeated ( int times ) const |
QByteArray & | replace ( int pos, int len, const QByteArray & after ) |
QByteArray & | replace ( int pos, int len, const char * after ) |
QByteArray & | replace ( int pos, int len, const char * after, int alen ) |
QByteArray & | replace ( const QByteArray & before, const QByteArray & after ) |
QByteArray & | replace ( const char * before, const QByteArray & after ) |
QByteArray & | replace ( const char * before, int bsize, const char * after, int asize ) |
QByteArray & | replace ( const QByteArray & before, const char * after ) |
QByteArray & | replace ( const QString & before, const QByteArray & after ) |
QByteArray & | replace ( const QString & before, const char * after ) |
QByteArray & | replace ( const char * before, const char * after ) |
QByteArray & | replace ( char before, const QByteArray & after ) |
QByteArray & | replace ( char before, const QString & after ) |
QByteArray & | replace ( char before, const char * after ) |
QByteArray & | replace ( char before, char after ) |
void | reserve ( int size ) |
void | resize ( int size ) |
QByteArray | right ( int len ) const |
QByteArray | rightJustified ( int width, char fill = ' ', bool truncate = false ) const |
QByteArray & | setNum ( int n, int base = 10 ) |
QByteArray & | setNum ( uint n, int base = 10 ) |
QByteArray & | setNum ( short n, int base = 10 ) |
QByteArray & | setNum ( ushort n, int base = 10 ) |
QByteArray & | setNum ( qlonglong n, int base = 10 ) |
QByteArray & | setNum ( qulonglong n, int base = 10 ) |
QByteArray & | setNum ( double n, char f = 'g', int prec = 6 ) |
QByteArray & | setNum ( float n, char f = 'g', int prec = 6 ) |
QByteArray & | setRawData ( const char * data, uint size ) |
QByteArray | simplified () const |
int | size () const |
QList<QByteArray> | split ( char sep ) const |
void | squeeze () |
bool | startsWith ( const QByteArray & ba ) const |
bool | startsWith ( const char * str ) const |
bool | startsWith ( char ch ) const |
void | swap ( QByteArray & other ) |
QByteArray | toBase64 () const |
double | toDouble ( bool * ok = 0 ) const |
float | toFloat ( bool * ok = 0 ) const |
QByteArray | toHex () const |
int | toInt ( bool * ok = 0, int base = 10 ) const |
long | toLong ( bool * ok = 0, int base = 10 ) const |
qlonglong | toLongLong ( bool * ok = 0, int base = 10 ) const |
QByteArray | toLower () const |
QByteArray | toPercentEncoding ( const QByteArray & exclude = QByteArray(), const QByteArray & include = QByteArray(), char percent = '%' ) const |
short | toShort ( bool * ok = 0, int base = 10 ) const |
uint | toUInt ( bool * ok = 0, int base = 10 ) const |
ulong | toULong ( bool * ok = 0, int base = 10 ) const |
qulonglong | toULongLong ( bool * ok = 0, int base = 10 ) const |
ushort | toUShort ( bool * ok = 0, int base = 10 ) const |
QByteArray | toUpper () const |
QByteArray | trimmed () const |
void | truncate ( int pos ) |
operator const char * () const | |
operator const void * () const | |
bool | operator!= ( const QString & str ) const |
QByteArray & | operator+= ( const QByteArray & ba ) |
QByteArray & | operator+= ( const QString & str ) |
QByteArray & | operator+= ( const char * str ) |
QByteArray & | operator+= ( char ch ) |
bool | operator< ( const QString & str ) const |
bool | operator<= ( const QString & str ) const |
QByteArray & | operator= ( const QByteArray & other ) |
QByteArray & | operator= ( const char * str ) |
bool | operator== ( const QString & str ) const |
bool | operator> ( const QString & str ) const |
bool | operator>= ( const QString & str ) const |
QByteRef | operator[] ( int i ) |
char | operator[] ( int i ) const |
QByteRef | operator[] ( uint i ) |
char | operator[] ( uint i ) const |
QByteArray | fromBase64 ( const QByteArray & base64 ) |
QByteArray | fromHex ( const QByteArray & hexEncoded ) |
QByteArray | fromPercentEncoding ( const QByteArray & input, char percent = '%' ) |
QByteArray | fromRawData ( const char * data, int size ) |
QByteArray | number ( int n, int base = 10 ) |
QByteArray | number ( uint n, int base = 10 ) |
QByteArray | number ( qlonglong n, int base = 10 ) |
QByteArray | number ( qulonglong n, int base = 10 ) |
QByteArray | number ( double n, char f = 'g', int prec = 6 ) |
quint16 | qChecksum ( const char * data, uint len ) |
QByteArray | qCompress ( const QByteArray & data, int compressionLevel = -1 ) |
QByteArray | qCompress ( const uchar * data, int nbytes, int compressionLevel = -1 ) |
QByteArray | qUncompress ( const QByteArray & data ) |
QByteArray | qUncompress ( const uchar * data, int nbytes ) |
int | qsnprintf ( char * str, size_t n, const char * fmt, ... ) |
int | qstrcmp ( const char * str1, const char * str2 ) |
char * | qstrcpy ( char * dst, const char * src ) |
char * | qstrdup ( const char * src ) |
int | qstricmp ( const char * str1, const char * str2 ) |
uint | qstrlen ( const char * str ) |
int | qstrncmp ( const char * str1, const char * str2, uint len ) |
char * | qstrncpy ( char * dst, const char * src, uint len ) |
int | qstrnicmp ( const char * str1, const char * str2, uint len ) |
uint | qstrnlen ( const char * str, uint maxlen ) |
int | qvsnprintf ( char * str, size_t n, const char * fmt, va_list ap ) |
bool | operator!= ( const QByteArray & a1, const QByteArray & a2 ) |
bool | operator!= ( const QByteArray & a1, const char * a2 ) |
bool | operator!= ( const char * a1, const QByteArray & a2 ) |
const QByteArray | operator+ ( const QByteArray & a1, const QByteArray & a2 ) |
const QByteArray | operator+ ( const QByteArray & a1, const char * a2 ) |
const QByteArray | operator+ ( const QByteArray & a1, char a2 ) |
const QByteArray | operator+ ( const char * a1, const QByteArray & a2 ) |
const QByteArray | operator+ ( char a1, const QByteArray & a2 ) |
bool | operator< ( const QByteArray & a1, const QByteArray & a2 ) |
bool | operator< ( const QByteArray & a1, const char * a2 ) |
bool | operator< ( const char * a1, const QByteArray & a2 ) |
QDataStream & | operator<< ( QDataStream & out, const QByteArray & ba ) |
bool | operator<= ( const QByteArray & a1, const QByteArray & a2 ) |
bool | operator<= ( const QByteArray & a1, const char * a2 ) |
bool | operator<= ( const char * a1, const QByteArray & a2 ) |
bool | operator== ( const QByteArray & a1, const QByteArray & a2 ) |
bool | operator== ( const QByteArray & a1, const char * a2 ) |
bool | operator== ( const char * a1, const QByteArray & a2 ) |
bool | operator> ( const QByteArray & a1, const QByteArray & a2 ) |
bool | operator> ( const QByteArray & a1, const char * a2 ) |
bool | operator> ( const char * a1, const QByteArray & a2 ) |
bool | operator>= ( const QByteArray & a1, const QByteArray & a2 ) |
bool | operator>= ( const QByteArray & a1, const char * a2 ) |
bool | operator>= ( const char * a1, const QByteArray & a2 ) |
QDataStream & | operator>> ( QDataStream & in, QByteArray & ba ) |
QT_NO_CAST_FROM_BYTEARRAY |
The QByteArray class provides an array of bytes.
QByteArray can be used to store both raw bytes (including '\0's) and traditional 8-bit '\0'-terminated strings. Using QByteArray is much more convenient than using const char *. Behind the scenes, it always ensures that the data is followed by a '\0' terminator, and uses implicit sharing (copy-on-write) to reduce memory usage and avoid needless copying of data.
In addition to QByteArray, Qt also provides the QString class to store string data. For most purposes, QString is the class you want to use. It stores 16-bit Unicode characters, making it easy to store non-ASCII/non-Latin-1 characters in your application. Furthermore, QString is used throughout in the Qt API. 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 Qt for Embedded Linux).
One way to initialize a QByteArray is simply to pass a const char * to its constructor. For example, the following code creates a byte array of size 5 containing the data "Hello":
QByteArray ba("Hello");
Although the size() is 5, the byte array also maintains an extra '\0' character at the end so that if a function is used that asks for a pointer to the underlying data (e.g. a call to data()), the data pointed to is guaranteed to be '\0'-terminated.
QByteArray makes a deep copy of the const char * 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 QByteArray::fromRawData() instead.)
Another approach is to set the size of the array using resize() and to initialize the data byte per byte. QByteArray uses 0-based indexes, just like C++ arrays. To access the byte at a particular index position, you can use operator[](). On non-const byte arrays, operator[]() returns a reference to a byte that can be used on the left side of an assignment. For example:
QByteArray ba; ba.resize(5); ba[0] = 0x3c; ba[1] = 0xb8; ba[2] = 0x64; ba[3] = 0x18; ba[4] = 0xca;
For read-only access, an alternative syntax is to use at():
for (int i = 0; i < ba.size(); ++i) { if (ba.at(i) >= 'a' && ba.at(i) <= 'f') cout << "Found character in range [a-f]" << endl; }
at() can be faster than operator[](), because it never causes a deep copy to occur.
To extract many bytes at a time, use left(), right(), or mid().
A QByteArray can embed '\0' bytes. The size() function always returns the size of the whole array, including embedded '\0' bytes. If you want to obtain the length of the data up to and excluding the first '\0' character, call qstrlen() on the byte array.
After a call to resize(), newly allocated bytes have undefined values. To set all the bytes to a particular value, call fill().
To obtain a pointer to the actual character data, call data() or constData(). These functions return a pointer to the beginning of the data. The pointer is guaranteed to remain valid until a non-const function is called on the QByteArray. It is also guaranteed that the data ends with a '\0' byte unless the QByteArray was created from a raw data. This '\0' byte is automatically provided by QByteArray and is not counted in size().
QByteArray provides the following basic functions for modifying the byte data: append(), prepend(), insert(), replace(), and remove(). For example:
QByteArray x("and"); x.prepend("rock "); // x == "rock and" x.append(" roll"); // x == "rock and roll" x.replace(5, 3, "&"); // x == "rock & roll"
The replace() and remove() functions' first two arguments are the position from which to start erasing and the number of bytes that should be erased.
When you append() data to a non-empty array, the array will be reallocated and the new data copied to it. You can avoid this behavior by calling reserve(), which preallocates a certain amount of memory. You can also call capacity() to find out how much memory QByteArray actually allocated. Data appended to an empty array is not copied.
A frequent requirement is to remove whitespace characters from a byte array ('\n', '\t', ' ', etc.). If you want to remove whitespace from both ends of a QByteArray, use trimmed(). If you want to remove whitespace from both ends and replace multiple consecutive whitespaces with a single space character within the byte array, use simplified().
If you want to find all occurrences of a particular character or substring in a QByteArray, use indexOf() or lastIndexOf(). 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:
QByteArray ba("We must be <b>bold</b>, very <b>bold</b>"); int j = 0; while ((j = ba.indexOf("<b>", j)) != -1) { cout << "Found <b> tag at index position " << j << endl; ++j; }
If you simply want to check whether a QByteArray contains a particular character or substring, use contains(). If you want to find out how many times a particular character or substring occurs in the byte array, use count(). If you want to replace all occurrences of a particular value with another, use one of the two-parameter replace() overloads.
QByteArrays can be compared using overloaded operators such as operator<(), operator<=(), operator==(), operator>=(), and so on. The comparison is based exclusively on the numeric values of the characters and is very fast, but is not what a human would expect. QString::localeAwareCompare() is a better choice for sorting user-interface strings.
For historical reasons, QByteArray distinguishes between a null byte array and an empty byte array. A null byte array is a byte array that is initialized using QByteArray's default constructor or by passing (const char *)0 to the constructor. An empty byte array is any byte array with size 0. A null byte array is always empty, but an empty byte array isn't necessarily null:
QByteArray().isNull(); // returns true QByteArray().isEmpty(); // returns true QByteArray("").isNull(); // returns false QByteArray("").isEmpty(); // returns true QByteArray("abc").isNull(); // returns false QByteArray("abc").isEmpty(); // returns false
All functions except isNull() treat null byte arrays the same as empty byte arrays. For example, data() returns a pointer to a '\0' character for a null byte array (not a null pointer), and QByteArray() compares equal to QByteArray(""). We recommend that you always use isEmpty() and avoid isNull().
Functions that perform conversions between numeric data types and strings are performed in the C locale, irrespective of the user's locale settings. Use QString to perform locale-aware conversions between numbers and strings.
In QByteArray, the notion of uppercase and lowercase and of which character is greater than or less than another character is locale dependent. This affects functions that support a case insensitive option or that compare or lowercase or uppercase their arguments. Case insensitive operations and comparisons will be accurate if both strings contain only ASCII characters. (If $LC_CTYPE is set, most Unix systems do "the right thing".) Functions that this affects include contains(), indexOf(), lastIndexOf(), operator<(), operator<=(), operator>(), operator>=(), toLower() and toUpper().
This issue does not apply to QStrings since they represent characters using Unicode.
See also QString and QBitArray.
Constructs an empty byte array.
See also isEmpty().
Constructs a byte array initialized with the string str.
QByteArray makes a deep copy of the string data.
Constructs a byte array containing the first size bytes of array data.
If data is 0, a null byte array is constructed.
QByteArray makes a deep copy of the string data.
See also fromRawData().
Constructs a byte array of size size with every byte set to character ch.
See also fill().
Constructs a copy of other.
This operation takes constant time, because QByteArray is implicitly shared. This makes returning a QByteArray from a function very fast. If a shared instance is modified, it will be copied (copy-on-write), taking linear time.
See also operator=().
Destroys the byte array.
Appends the byte array ba onto the end of this byte array.
Example:
QByteArray x("free"); QByteArray y("dom"); x.append(y); // x == "freedom"
This is the same as insert(size(), ba).
Note: QByteArray is an implicitly shared class. Consequently, if this is an empty QByteArray, then this will just share the data held in ba. In this case, no copying of data is done, taking constant time. If a shared instance is modified, it will be copied (copy-on-write), taking linear time.
If this is not an empty QByteArray, a deep copy of the data is performed, taking linear time.
This operation typically does not suffer from allocation overhead, because QByteArray preallocates extra space at the end of the data so that it may grow without reallocating for each append operation.
See also operator+=(), prepend(), and insert().
This is an overloaded function.
Appends the string str to this byte array. The Unicode data is converted into 8-bit characters using QString::toAscii().
If the QString contains non-ASCII Unicode characters, using this function can lead to loss of information. You can disable this function by defining QT_NO_CAST_TO_ASCII when you compile your applications. You then need to call QString::toAscii() (or QString::toLatin1() or QString::toUtf8() or QString::toLocal8Bit()) explicitly if you want to convert the data to const char *.
This is an overloaded function.
Appends the string str to this byte array.
This function overloads append().
Appends the first len characters of the string str to this byte array and returns a reference to this byte array.
If len is negative, the length of the string will be determined automatically using qstrlen(). If len is zero or str is null, nothing is appended to the byte array. Ensure that len is not longer than str.
This is an overloaded function.
Appends the character ch to this byte array.
Returns the character at index position i in the byte array.
i must be a valid index position in the byte array (i.e., 0 <= i < size()).
See also operator[]().
Returns the maximum number of bytes that can be stored in the byte array without forcing a reallocation.
The sole purpose of this function is to provide a means of fine tuning QByteArray's memory usage. In general, you will rarely ever need to call this function. If you want to know how many bytes are in the byte array, call size().
See also reserve() and squeeze().
Removes n bytes from the end of the byte array.
If n is greater than size(), the result is an empty byte array.
Example:
QByteArray ba("STARTTLS\r\n"); ba.chop(2); // ba == "STARTTLS"
See also truncate(), resize(), and left().
Clears the contents of the byte array and makes it empty.
See also resize() and isEmpty().
Returns a pointer to the data stored in the byte array. The pointer can be used to access the bytes that compose the array. The data is '\0'-terminated unless the QByteArray object was created from raw data. The pointer remains valid as long as the byte array isn't reallocated or destroyed.
This function is mostly useful to pass a byte array to a function that accepts a const char *.
Note: A QByteArray can store any byte values including '\0's, but most functions that take char * arguments assume that the data ends at the first '\0' they encounter.
See also data(), operator[](), and fromRawData().
Returns true if the byte array contains an occurrence of the byte array ba; otherwise returns false.
See also indexOf() and count().
This is an overloaded function.
Returns true if the byte array contains the string str; otherwise returns false.
This is an overloaded function.
Returns true if the byte array contains the character ch; otherwise returns false.
Returns the number of (potentially overlapping) occurrences of byte array ba in this byte array.
See also contains() and indexOf().
This is an overloaded function.
Returns the number of (potentially overlapping) occurrences of string str in the byte array.
This is an overloaded function.
Returns the number of occurrences of character ch in the byte array.
See also contains() and indexOf().
This is an overloaded function.
Same as size().
Returns a pointer to the data stored in the byte array. The pointer can be used to access and modify the bytes that compose the array. The data is '\0'-terminated, i.e. the number of bytes in the returned character string is size() + 1 for the '\0' terminator.
Example:
QByteArray ba("Hello world"); char *data = ba.data(); while (*data) { cout << "[" << *data << "]" << endl; ++data; }
The pointer remains valid as long as the byte array isn't reallocated or destroyed. For read-only access, constData() is faster because it never causes a deep copy to occur.
This function is mostly useful to pass a byte array to a function that accepts a const char *.
The following example makes a copy of the char* returned by data(), but it will corrupt the heap and cause a crash because it does not allocate a byte for the '\0' at the end:
QString tmp = "test"; QByteArray text = tmp.toLocal8Bit(); char *data = new char[text.size()] strcpy(data, text.data()); delete [] data;
This one allocates the correct amount of space:
QString tmp = "test"; QByteArray text = tmp.toLocal8Bit(); char *data = new char[text.size() + 1] strcpy(data, text.data()); delete [] data;
Note: A QByteArray can store any byte values including '\0's, but most functions that take char * arguments assume that the data ends at the first '\0' they encounter.
See also constData() and operator[]().
This is an overloaded function.
Returns true if this byte array ends with byte array ba; otherwise returns false.
Example:
QByteArray url("http://qt.nokia.com/index.html"); if (url.endsWith(".html")) ...
See also startsWith() and right().
This is an overloaded function.
Returns true if this byte array ends with string str; otherwise returns false.
This is an overloaded function.
Returns true if this byte array ends with character ch; otherwise returns false.
Sets every byte in the byte array to character ch. If size is different from -1 (the default), the byte array is resized to size size beforehand.
Example:
QByteArray ba("Istambul"); ba.fill('o'); // ba == "oooooooo" ba.fill('X', 2); // ba == "XX"
See also resize().
Returns a decoded copy of the Base64 array base64. Input is not checked for validity; invalid characters in the input are skipped, enabling the decoding process to continue with subsequent characters.
For example:
QByteArray text = QByteArray::fromBase64("UXQgaXMgZ3JlYXQh"); text.data(); // returns "Qt is great!"
The algorithm used to decode Base64-encoded data is defined in RFC 2045.
See also toBase64().
Returns a decoded copy of the hex encoded array hexEncoded. Input is not checked for validity; invalid characters in the input are skipped, enabling the decoding process to continue with subsequent characters.
For example:
QByteArray text = QByteArray::fromHex("517420697320677265617421"); text.data(); // returns "Qt is great!"
See also toHex().
Returns a decoded copy of the URI/URL-style percent-encoded input. The percent parameter allows you to replace the '%' character for another (for instance, '_' or '=').
For example:
QByteArray text = QByteArray::fromPercentEncoding("Qt%20is%20great%33"); text.data(); // returns "Qt is great!"
This function was introduced in Qt 4.4.
See also toPercentEncoding() and QUrl::fromPercentEncoding().
Constructs a QByteArray that uses the first size bytes of the data array. The bytes are not copied. The QByteArray will contain the data pointer. The caller guarantees that data will not be deleted or modified as long as this QByteArray and any copies of it exist that have not been modified. In other words, because QByteArray is an implicitly shared class and the instance returned by this function contains the data pointer, the caller must not delete data or modify it directly as long as the returned QByteArray and any copies exist. However, QByteArray does not take ownership of data, so the QByteArray destructor will never delete the raw data, even when the last QByteArray referring to data is destroyed.
A subsequent attempt to modify the contents of the returned QByteArray or any copy made from it will cause it to create a deep copy of the data array before doing the modification. This ensures that the raw data array itself will never be modified by QByteArray.
Here is an example of how to read data using a QDataStream on raw data in memory without copying the raw data into a QByteArray:
static const char mydata[] = { 0x00, 0x00, 0x03, 0x84, 0x78, 0x9c, 0x3b, 0x76, 0xec, 0x18, 0xc3, 0x31, 0x0a, 0xf1, 0xcc, 0x99, ... 0x6d, 0x5b }; QByteArray data = QByteArray::fromRawData(mydata, sizeof(mydata)); QDataStream in(&data, QIODevice::ReadOnly); ...
Warning: A byte array created with fromRawData() is not null-terminated, unless the raw data contains a 0 character at position size. While that does not matter for QDataStream or functions like indexOf(), passing the byte array to a function accepting a const char * expected to be '\0'-terminated will fail.
See also setRawData(), data(), and constData().
Returns the index position of the first occurrence of the byte array ba in this byte array, searching forward from index position from. Returns -1 if ba could not be found.
Example:
QByteArray x("sticky question"); QByteArray y("sti"); x.indexOf(y); // returns 0 x.indexOf(y, 1); // returns 10 x.indexOf(y, 10); // returns 10 x.indexOf(y, 11); // returns -1
See also lastIndexOf(), contains(), and count().
This is an overloaded function.
Returns the index position of the first occurrence of the string str in the byte array, searching forward from index position from. Returns -1 if str could not be found.
The Unicode data is converted into 8-bit characters using QString::toAscii().
If the QString contains non-ASCII Unicode characters, using this function can lead to loss of information. You can disable this function by defining QT_NO_CAST_TO_ASCII when you compile your applications. You then need to call QString::toAscii() (or QString::toLatin1() or QString::toUtf8() or QString::toLocal8Bit()) explicitly if you want to convert the data to const char *.
This is an overloaded function.
Returns the index position of the first occurrence of the string str in the byte array, searching forward from index position from. Returns -1 if str could not be found.
This is an overloaded function.
Returns the index position of the first occurrence of the character ch in the byte array, searching forward from index position from. Returns -1 if ch could not be found.
Example:
QByteArray ba("ABCBA"); ba.indexOf("B"); // returns 1 ba.indexOf("B", 1); // returns 1 ba.indexOf("B", 2); // returns 3 ba.indexOf("X"); // returns -1
See also lastIndexOf() and contains().
Inserts the byte array ba at index position i and returns a reference to this byte array.
Example:
QByteArray ba("Meal"); ba.insert(1, QByteArray("ontr")); // ba == "Montreal"
See also append(), prepend(), replace(), and remove().
This is an overloaded function.
Inserts the string str at index position i in the byte array. The Unicode data is converted into 8-bit characters using QString::toAscii().
If i is greater than size(), the array is first extended using resize().
If the QString contains non-ASCII Unicode characters, using this function can lead to loss of information. You can disable this function by defining QT_NO_CAST_TO_ASCII when you compile your applications. You then need to call QString::toAscii() (or QString::toLatin1() or QString::toUtf8() or QString::toLocal8Bit()) explicitly if you want to convert the data to const char *.
This is an overloaded function.
Inserts the string str at position i in the byte array.
If i is greater than size(), the array is first extended using resize().
This is an overloaded function.
Inserts len bytes of the string str at position i in the byte array.
If i is greater than size(), the array is first extended using resize().
This function was introduced in Qt 4.6.
This is an overloaded function.
Inserts character ch at index position i in the byte array. If i is greater than size(), the array is first extended using resize().
Returns true if the byte array has size 0; otherwise returns false.
Example:
QByteArray().isEmpty(); // returns true QByteArray("").isEmpty(); // returns true QByteArray("abc").isEmpty(); // returns false
See also size().
Returns true if this byte array is null; otherwise returns false.
Example:
QByteArray().isNull(); // returns true QByteArray("").isNull(); // returns false QByteArray("abc").isNull(); // returns false
Qt makes a distinction between null byte arrays and empty byte arrays for historical reasons. For most applications, what matters is whether or not a byte array contains any data, and this can be determined using isEmpty().
See also isEmpty().
Returns the index position of the last occurrence of the byte array ba in this byte array, searching backward from index position from. If from is -1 (the default), the search starts at the last byte. Returns -1 if ba could not be found.
Example:
QByteArray x("crazy azimuths"); QByteArray y("az"); x.lastIndexOf(y); // returns 6 x.lastIndexOf(y, 6); // returns 6 x.lastIndexOf(y, 5); // returns 2 x.lastIndexOf(y, 1); // returns -1
See also indexOf(), contains(), and count().
This is an overloaded function.
Returns the index position of the last occurrence of the string str in the byte array, searching backward from index position from. If from is -1 (the default), the search starts at the last (size() - 1) byte. Returns -1 if str could not be found.
The Unicode data is converted into 8-bit characters using QString::toAscii().
If the QString contains non-ASCII Unicode characters, using this function can lead to loss of information. You can disable this function by defining QT_NO_CAST_TO_ASCII when you compile your applications. You then need to call QString::toAscii() (or QString::toLatin1() or QString::toUtf8() or QString::toLocal8Bit()) explicitly if you want to convert the data to const char *.
This is an overloaded function.
Returns the index position of the last occurrence of the string str in the byte array, searching backward from index position from. If from is -1 (the default), the search starts at the last (size() - 1) byte. Returns -1 if str could not be found.
This is an overloaded function.
Returns the index position of the last occurrence of character ch in the byte array, searching backward from index position from. If from is -1 (the default), the search starts at the last (size() - 1) byte. Returns -1 if ch could not be found.
Example:
QByteArray ba("ABCBA"); ba.lastIndexOf("B"); // returns 3 ba.lastIndexOf("B", 3); // returns 3 ba.lastIndexOf("B", 2); // returns 1 ba.lastIndexOf("X"); // returns -1
See also indexOf() and contains().
Returns a byte array that contains the leftmost len bytes of this byte array.
The entire byte array is returned if len is greater than size().
Example:
QByteArray x("Pineapple"); QByteArray y = x.left(4); // y == "Pine"
See also right(), mid(), startsWith(), and truncate().
Returns a byte array of size width that contains this byte array padded by the fill character.
If truncate is false and the size() of the byte array is more than width, then the returned byte array is a copy of this byte array.
If truncate is true and the size() of the byte array is more than width, then any bytes in a copy of the byte array after position width are removed, and the copy is returned.
Example:
QByteArray x("apple"); QByteArray y = x.leftJustified(8, '.'); // y == "apple..."
See also rightJustified().
Same as size().
Returns a byte array containing len bytes from this byte array, starting at position pos.
If len is -1 (the default), or pos + len >= size(), returns a byte array containing all bytes starting at position pos until the end of the byte array.
Example:
QByteArray x("Five pineapples"); QByteArray y = x.mid(5, 4); // y == "pine" QByteArray z = x.mid(5); // z == "pineapples"
Returns a byte array containing the string equivalent of the number n to base base (10 by default). The base can be any value between 2 and 36.
Example:
int n = 63; QByteArray::number(n); // returns "63" QByteArray::number(n, 16); // returns "3f" QByteArray::number(n, 16).toUpper(); // returns "3F"
Note: The format of the number is not localized; the default C locale is used irrespective of the user's locale.
See also setNum() and toInt().
This is an overloaded function.
See also toUInt().
This is an overloaded function.
See also toLongLong().
This is an overloaded function.
See also toULongLong().
This is an overloaded function.
Returns a byte array that contains the printed value of n, formatted in format f with precision prec.
Argument n is formatted according to the f format specified, which is g by default, and can be any of the following:
Format | Meaning |
---|---|
e | format as [-]9.9e[+|-]999 |
E | format as [-]9.9E[+|-]999 |
f | format as [-]9.9 |
g | use e or f format, whichever is the most concise |
G | use E or f format, whichever is the most concise |
With 'e', 'E', and 'f', prec is the number of digits after the decimal point. With 'g' and 'G', prec is the maximum number of significant digits (trailing zeroes are omitted).
QByteArray ba = QByteArray::number(12.3456, 'E', 3); // ba == 1.235E+01
Note: The format of the number is not localized; the default C locale is used irrespective of the user's locale.
See also toDouble().
Prepends the byte array ba to this byte array and returns a reference to this byte array.
Example:
QByteArray x("ship"); QByteArray y("air"); x.prepend(y); // x == "airship"
This is the same as insert(0, ba).
Note: QByteArray is an implicitly shared class. Consequently, if this is an empty QByteArray, then this will just share the data held in ba. In this case, no copying of data is done, taking constant time. If a shared instance is modified, it will be copied (copy-on-write), taking linear time.
If this is not an empty QByteArray, a deep copy of the data is performed, taking linear time.
See also append() and insert().
This is an overloaded function.
Prepends the string str to this byte array.
This is an overloaded function.
Prepends len bytes of the string str to this byte array.
This function was introduced in Qt 4.6.
This is an overloaded function.
Prepends the character ch to this byte array.
This function is provided for STL compatibility. It is equivalent to append(other).
This is an overloaded function.
Same as append(str).
This is an overloaded function.
Same as append(ch).
This function is provided for STL compatibility. It is equivalent to prepend(other).
This is an overloaded function.
Same as prepend(str).
This is an overloaded function.
Same as prepend(ch).
Removes len bytes from the array, starting at index position pos, and returns a reference to the array.
If pos is out of range, nothing happens. If pos is valid, but pos + len is larger than the size of the array, the array is truncated at position pos.
Example:
QByteArray ba("Montreal"); ba.remove(1, 4); // ba == "Meal"
See also insert() and replace().
Returns a copy of this byte array repeated the specified number of times.
If times is less than 1, an empty byte array is returned.
Example:
QByteArray ba("ab"); ba.repeated(4); // returns "abababab"
This function was introduced in Qt 4.5.
Replaces len bytes from index position pos with the byte array after, and returns a reference to this byte array.
Example:
QByteArray x("Say yes!"); QByteArray y("no"); x.replace(4, 3, y); // x == "Say no!"
See also insert() and remove().
This is an overloaded function.
Replaces len bytes from index position pos with the zero terminated string after.
Notice: this can change the length of the byte array.
This is an overloaded function.
Replaces len bytes from index position pos with alen bytes from the string after. after is allowed to have '\0' characters.
This function was introduced in Qt 4.7.
This is an overloaded function.
Replaces every occurrence of the byte array before with the byte array after.
Example:
QByteArray ba("colour behaviour flavour neighbour"); ba.replace(QByteArray("ou"), QByteArray("o")); // ba == "color behavior flavor neighbor"
This is an overloaded function.
Replaces every occurrence of the string before with the byte array after.
This is an overloaded function.
Replaces every occurrence of the string before with the string after. Since the sizes of the strings are given by bsize and asize, they may contain zero characters and do not need to be zero-terminated.
This is an overloaded function.
Replaces every occurrence of the byte array before with the string after.
This is an overloaded function.
Replaces every occurrence of the string before with the byte array after. The Unicode data is converted into 8-bit characters using QString::toAscii().
If the QString contains non-ASCII Unicode characters, using this function can lead to loss of information. You can disable this function by defining QT_NO_CAST_TO_ASCII when you compile your applications. You then need to call QString::toAscii() (or QString::toLatin1() or QString::toUtf8() or QString::toLocal8Bit()) explicitly if you want to convert the data to const char *.
This is an overloaded function.
Replaces every occurrence of the string before with the string after.
This is an overloaded function.
Replaces every occurrence of the string before with the string after.
This is an overloaded function.
Replaces every occurrence of the character before with the byte array after.
This is an overloaded function.
Replaces every occurrence of the character before with the string after. The Unicode data is converted into 8-bit characters using QString::toAscii().
If the QString contains non-ASCII Unicode characters, using this function can lead to loss of information. You can disable this function by defining QT_NO_CAST_TO_ASCII when you compile your applications. You then need to call QString::toAscii() (or QString::toLatin1() or QString::toUtf8() or QString::toLocal8Bit()) explicitly if you want to convert the data to const char *.
This is an overloaded function.
Replaces every occurrence of the character before with the string after.
This is an overloaded function.
Replaces every occurrence of the character before with the character after.
Attempts to allocate memory for at least size bytes. If you know in advance how large the byte array will be, you can call this function, and if you call resize() often you are likely to get better performance. If size is an underestimate, the worst that will happen is that the QByteArray will be a bit slower.
The sole purpose of this function is to provide a means of fine tuning QByteArray's memory usage. In general, you will rarely ever need to call this function. If you want to change the size of the byte array, call resize().
See also squeeze() and capacity().
Sets the size of the byte array to size bytes.
If size is greater than the current size, the byte array is extended to make it size bytes with the extra bytes added to the end. The new bytes are uninitialized.
If size is less than the current size, bytes are removed from the end.
See also size() and truncate().
Returns a byte array that contains the rightmost len bytes of this byte array.
The entire byte array is returned if len is greater than size().
Example:
QByteArray x("Pineapple"); QByteArray y = x.right(5); // y == "apple"
See also endsWith(), left(), and mid().
Returns a byte array of size width that contains the fill character followed by this byte array.
If truncate is false and the size of the byte array is more than width, then the returned byte array is a copy of this byte array.
If truncate is true and the size of the byte array is more than width, then the resulting byte array is truncated at position width.
Example:
QByteArray x("apple"); QByteArray y = x.rightJustified(8, '.'); // y == "...apple"
See also leftJustified().
Sets the byte array to the printed value of n in base base (10 by default) and returns a reference to the byte array. The base can be any value between 2 and 36.
Example:
QByteArray ba; int n = 63; ba.setNum(n); // ba == "63" ba.setNum(n, 16); // ba == "3f"
Note: The format of the number is not localized; the default C locale is used irrespective of the user's locale.
See also number() and toInt().
This is an overloaded function.
See also toUInt().
This is an overloaded function.
See also toShort().
This is an overloaded function.
See also toUShort().
This is an overloaded function.
See also toLongLong().
This is an overloaded function.
See also toULongLong().
This is an overloaded function.
Sets the byte array to the printed value of n, formatted in format f with precision prec, and returns a reference to the byte array.
The format f can be any of the following:
Format | Meaning |
---|---|
e | format as [-]9.9e[+|-]999 |
E | format as [-]9.9E[+|-]999 |
f | format as [-]9.9 |
g | use e or f format, whichever is the most concise |
G | use E or f format, whichever is the most concise |
With 'e', 'E', and 'f', prec is the number of digits after the decimal point. With 'g' and 'G', prec is the maximum number of significant digits (trailing zeroes are omitted).
Note: The format of the number is not localized; the default C locale is used irrespective of the user's locale.
See also toDouble().
This is an overloaded function.
Sets the byte array to the printed value of n, formatted in format f with precision prec, and returns a reference to the byte array.
Note: The format of the number is not localized; the default C locale is used irrespective of the user's locale.
See also toFloat().
Resets the QByteArray to use the first size bytes of the data array. The bytes are not copied. The QByteArray will contain the data pointer. The caller guarantees that data will not be deleted or modified as long as this QByteArray and any copies of it exist that have not been modified.
This function can be used instead of fromRawData() to re-use existings QByteArray objects to save memory re-allocations.
This function was introduced in Qt 4.7.
See also fromRawData(), data(), and constData().
Returns a byte array that has whitespace removed from the start and the end, and which has each sequence of internal whitespace replaced with a single space.
Whitespace means any character for which the standard C++ isspace() function returns true. This includes the ASCII characters '\t', '\n', '\v', '\f', '\r', and ' '.
Example:
QByteArray ba(" lots\t of\nwhitespace\r\n "); ba = ba.simplified(); // ba == "lots of whitespace";
See also trimmed().
Returns the number of bytes in this byte array.
The last byte in the byte array is at position size() - 1. In addition, QByteArray ensures that the byte 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. If the QByteArray object was created from a raw data that didn't include the trailing null-termination character then QByteArray doesn't add it automaticall unless the deep copy is created.
Example:
QByteArray ba("Hello"); int n = ba.size(); // n == 5 ba.data()[0]; // returns 'H' ba.data()[4]; // returns 'o' ba.data()[5]; // returns '\0'
See also isEmpty() and resize().
Splits the byte array into subarrays wherever sep occurs, and returns the list of those arrays. If sep does not match anywhere in the byte array, split() returns a single-element list containing this byte array.
Releases any memory not required to store the array's data.
The sole purpose of this function is to provide a means of fine tuning QByteArray's memory usage. In general, you will rarely ever need to call this function.
See also reserve() and capacity().
Returns true if this byte array starts with byte array ba; otherwise returns false.
Example:
QByteArray url("ftp://ftp.qt.nokia.com/"); if (url.startsWith("ftp:")) ...
See also endsWith() and left().
This is an overloaded function.
Returns true if this byte array starts with string str; otherwise returns false.
This is an overloaded function.
Returns true if this byte array starts with character ch; otherwise returns false.
Swaps byte array other with this byte array. This operation is very fast and never fails.
This function was introduced in Qt 4.8.
Returns a copy of the byte array, encoded as Base64.
QByteArray text("Qt is great!"); text.toBase64(); // returns "UXQgaXMgZ3JlYXQh"
The algorithm used to encode Base64-encoded data is defined in RFC 2045.
See also fromBase64().
Returns the byte array converted to a double value.
Returns 0.0 if the conversion fails.
If ok is not 0: if a conversion error occurs, *ok is set to false; otherwise *ok is set to true.
QByteArray string("1234.56"); double a = string.toDouble(); // a == 1234.56
Note: The conversion of the number is performed in the default C locale, irrespective of the user's locale.
See also number().
Returns the byte array converted to a float value.
Returns 0.0 if the conversion fails.
If ok is not 0: if a conversion error occurs, *ok is set to false; otherwise *ok is set to true.
Note: The conversion of the number is performed in the default C locale, irrespective of the user's locale.
See also number().
Returns a hex encoded copy of the byte array. The hex encoding uses the numbers 0-9 and the letters a-f.
See also fromHex().
Returns the byte array converted to an int using base base, which is 10 by default and must be between 2 and 36, or 0.
If base is 0, the base is determined automatically using the following rules: If the byte array begins with "0x", it is assumed to be hexadecimal; if it begins with "0", it is assumed to be octal; otherwise it is assumed to be decimal.
Returns 0 if the conversion fails.
If ok is not 0: if a conversion error occurs, *ok is set to false; otherwise *ok is set to true.
QByteArray str("FF"); bool ok; int hex = str.toInt(&ok, 16); // hex == 255, ok == true int dec = str.toInt(&ok, 10); // dec == 0, ok == false
Note: The conversion of the number is performed in the default C locale, irrespective of the user's locale.
See also number().
Returns the byte array converted to a long int using base base, which is 10 by default and must be between 2 and 36, or 0.
If base is 0, the base is determined automatically using the following rules: If the byte array begins with "0x", it is assumed to be hexadecimal; if it begins with "0", it is assumed to be octal; otherwise it is assumed to be decimal.
Returns 0 if the conversion fails.
If ok is not 0: if a conversion error occurs, *ok is set to false; otherwise *ok is set to true.
QByteArray str("FF"); bool ok; long hex = str.toLong(&ok, 16); // hex == 255, ok == true long dec = str.toLong(&ok, 10); // dec == 0, ok == false
Note: The conversion of the number is performed in the default C locale, irrespective of the user's locale.
This function was introduced in Qt 4.1.
See also number().
Returns the byte array converted to a long long using base base, which is 10 by default and must be between 2 and 36, or 0.
If base is 0, the base is determined automatically using the following rules: If the byte array begins with "0x", it is assumed to be hexadecimal; if it begins with "0", it is assumed to be octal; otherwise it is assumed to be decimal.
Returns 0 if the conversion fails.
If ok is not 0: if a conversion error occurs, *ok is set to false; otherwise *ok is set to true.
Note: The conversion of the number is performed in the default C locale, irrespective of the user's locale.
See also number().
Returns a lowercase copy of the byte array. The bytearray is interpreted as a Latin-1 encoded string.
Example:
QByteArray x("Qt by NOKIA"); QByteArray y = x.toLower(); // y == "qt by nokia"
See also toUpper() and 8-bit Character Comparisons.
Returns a URI/URL-style percent-encoded copy of this byte array. The percent parameter allows you to override the default '%' character for another.
By default, this function will encode all characters that are not one of the following:
ALPHA ("a" to "z" and "A" to "Z") / DIGIT (0 to 9) / "-" / "." / "_" / "~"
To prevent characters from being encoded pass them to exclude. To force characters to be encoded pass them to include. The percent character is always encoded.
Example:
QByteArray text = "{a fishy string?}"; QByteArray ba = text.toPercentEncoding("{}", "s"); qDebug(ba.constData()); // prints "{a fi%73hy %73tring%3F}"
The hex encoding uses the numbers 0-9 and the uppercase letters A-F.
This function was introduced in Qt 4.4.
See also fromPercentEncoding() and QUrl::toPercentEncoding().
Returns the byte array converted to a short using base base, which is 10 by default and must be between 2 and 36, or 0.
If base is 0, the base is determined automatically using the following rules: If the byte array begins with "0x", it is assumed to be hexadecimal; if it begins with "0", it is assumed to be octal; otherwise it is assumed to be decimal.
Returns 0 if the conversion fails.
If ok is not 0: if a conversion error occurs, *ok is set to false; otherwise *ok is set to true.
Note: The conversion of the number is performed in the default C locale, irrespective of the user's locale.
See also number().
Returns the byte array converted to an unsigned int using base base, which is 10 by default and must be between 2 and 36, or 0.
If base is 0, the base is determined automatically using the following rules: If the byte array begins with "0x", it is assumed to be hexadecimal; if it begins with "0", it is assumed to be octal; otherwise it is assumed to be decimal.
Returns 0 if the conversion fails.
If ok is not 0: if a conversion error occurs, *ok is set to false; otherwise *ok is set to true.
Note: The conversion of the number is performed in the default C locale, irrespective of the user's locale.
See also number().
Returns the byte array converted to an unsigned long int using base base, which is 10 by default and must be between 2 and 36, or 0.
If base is 0, the base is determined automatically using the following rules: If the byte array begins with "0x", it is assumed to be hexadecimal; if it begins with "0", it is assumed to be octal; otherwise it is assumed to be decimal.
Returns 0 if the conversion fails.
If ok is not 0: if a conversion error occurs, *ok is set to false; otherwise *ok is set to true.
Note: The conversion of the number is performed in the default C locale, irrespective of the user's locale.
This function was introduced in Qt 4.1.
See also number().
Returns the byte array converted to an unsigned long long using base base, which is 10 by default and must be between 2 and 36, or 0.
If base is 0, the base is determined automatically using the following rules: If the byte array begins with "0x", it is assumed to be hexadecimal; if it begins with "0", it is assumed to be octal; otherwise it is assumed to be decimal.
Returns 0 if the conversion fails.
If ok is not 0: if a conversion error occurs, *ok is set to false; otherwise *ok is set to true.
Note: The conversion of the number is performed in the default C locale, irrespective of the user's locale.
See also number().
Returns the byte array converted to an unsigned short using base base, which is 10 by default and must be between 2 and 36, or 0.
If base is 0, the base is determined automatically using the following rules: If the byte array begins with "0x", it is assumed to be hexadecimal; if it begins with "0", it is assumed to be octal; otherwise it is assumed to be decimal.
Returns 0 if the conversion fails.
If ok is not 0: if a conversion error occurs, *ok is set to false; otherwise *ok is set to true.
Note: The conversion of the number is performed in the default C locale, irrespective of the user's locale.
See also number().
Returns an uppercase copy of the byte array. The bytearray is interpreted as a Latin-1 encoded string.
Example:
QByteArray x("Qt by NOKIA"); QByteArray y = x.toUpper(); // y == "QT BY NOKIA"
See also toLower() and 8-bit Character Comparisons.
Returns a byte array that has whitespace removed from the start and the end.
Whitespace means any character for which the standard C++ isspace() function returns true. This includes the ASCII characters '\t', '\n', '\v', '\f', '\r', and ' '.
Example:
QByteArray ba(" lots\t of\nwhitespace\r\n "); ba = ba.trimmed(); // ba == "lots\t of\nwhitespace";
Unlike simplified(), trimmed() leaves internal whitespace alone.
See also simplified().
Truncates the byte array at index position pos.
If pos is beyond the end of the array, nothing happens.
Example:
QByteArray ba("Stockholm"); ba.truncate(5); // ba == "Stock"
See also chop(), resize(), and left().
Returns a pointer to the data stored in the byte array. The pointer can be used to access the bytes that compose the array. The data is '\0'-terminated. The pointer remains valid as long as the array isn't reallocated or destroyed.
This operator is mostly useful to pass a byte array to a function that accepts a const char *.
You can disable this operator by defining QT_NO_CAST_FROM_BYTEARRAY when you compile your applications.
Note: A QByteArray can store any byte values including '\0's, but most functions that take char * arguments assume that the data ends at the first '\0' they encounter.
See also constData().
Returns a pointer to the data stored in the byte array. The pointer can be used to access the bytes that compose the array. The data is '\0'-terminated. The pointer remains valid as long as the array isn't reallocated or destroyed.
This operator is mostly useful to pass a byte array to a function that accepts a const char *.
You can disable this operator by defining QT_NO_CAST_FROM_BYTEARRAY when you compile your applications.
Note: A QByteArray can store any byte values including '\0's, but most functions that take char * arguments assume that the data ends at the first '\0' they encounter.
See also constData().
Returns true if this byte array is not equal to string str; otherwise returns false.
The Unicode data is converted into 8-bit characters using QString::toAscii().
The comparison is case sensitive.
You can disable this operator by defining QT_NO_CAST_FROM_ASCII when you compile your applications. You then need to call QString::fromAscii(), QString::fromLatin1(), QString::fromUtf8(), or QString::fromLocal8Bit() explicitly if you want to convert the byte array to a QString before doing the comparison.
Appends the byte array ba onto the end of this byte array and returns a reference to this byte array.
Example:
QByteArray x("free"); QByteArray y("dom"); x += y; // x == "freedom"
Note: QByteArray is an implicitly shared class. Consequently, if this is an empty QByteArray, then this will just share the data held in ba. In this case, no copying of data is done, taking constant time. If a shared instance is modified, it will be copied (copy-on-write), taking linear time.
If this is not an empty QByteArray, a deep copy of the data is performed, taking linear time.
This operation typically does not suffer from allocation overhead, because QByteArray preallocates extra space at the end of the data so that it may grow without reallocating for each append operation.
See also append() and prepend().
This is an overloaded function.
Appends the string str onto the end of this byte array and returns a reference to this byte array. The Unicode data is converted into 8-bit characters using QString::toAscii().
If the QString contains non-ASCII Unicode characters, using this operator can lead to loss of information. You can disable this operator by defining QT_NO_CAST_TO_ASCII when you compile your applications. You then need to call QString::toAscii() (or QString::toLatin1() or QString::toUtf8() or QString::toLocal8Bit()) explicitly if you want to convert the data to const char *.
This is an overloaded function.
Appends the string str onto the end of this byte array and returns a reference to this byte array.
This is an overloaded function.
Appends the character ch onto the end of this byte array and returns a reference to this byte array.
Returns true if this byte array is lexically less than string str; otherwise returns false.
The Unicode data is converted into 8-bit characters using QString::toAscii().
The comparison is case sensitive.
You can disable this operator by defining QT_NO_CAST_FROM_ASCII when you compile your applications. You then need to call QString::fromAscii(), QString::fromLatin1(), QString::fromUtf8(), or QString::fromLocal8Bit() explicitly if you want to convert the byte array to a QString before doing the comparison.
Returns true if this byte array is lexically less than or equal to string str; otherwise returns false.
The Unicode data is converted into 8-bit characters using QString::toAscii().
The comparison is case sensitive.
You can disable this operator by defining QT_NO_CAST_FROM_ASCII when you compile your applications. You then need to call QString::fromAscii(), QString::fromLatin1(), QString::fromUtf8(), or QString::fromLocal8Bit() explicitly if you want to convert the byte array to a QString before doing the comparison.
Assigns other to this byte array and returns a reference to this byte array.
This is an overloaded function.
Assigns str to this byte array.
Returns true if this byte array is equal to string str; otherwise returns false.
The Unicode data is converted into 8-bit characters using QString::toAscii().
The comparison is case sensitive.
You can disable this operator by defining QT_NO_CAST_FROM_ASCII when you compile your applications. You then need to call QString::fromAscii(), QString::fromLatin1(), QString::fromUtf8(), or QString::fromLocal8Bit() explicitly if you want to convert the byte array to a QString before doing the comparison.
Returns true if this byte array is lexically greater than string str; otherwise returns false.
The Unicode data is converted into 8-bit characters using QString::toAscii().
The comparison is case sensitive.
You can disable this operator by defining QT_NO_CAST_FROM_ASCII when you compile your applications. You then need to call QString::fromAscii(), QString::fromLatin1(), QString::fromUtf8(), or QString::fromLocal8Bit() explicitly if you want to convert the byte array to a QString before doing the comparison.
Returns true if this byte array is greater than or equal to string str; otherwise returns false.
The Unicode data is converted into 8-bit characters using QString::toAscii().
The comparison is case sensitive.
You can disable this operator by defining QT_NO_CAST_FROM_ASCII when you compile your applications. You then need to call QString::fromAscii(), QString::fromLatin1(), QString::fromUtf8(), or QString::fromLocal8Bit() explicitly if you want to convert the byte array to a QString before doing the comparison.
Returns the byte at index position i as a modifiable reference.
If an assignment is made beyond the end of the byte array, the array is extended with resize() before the assignment takes place.
Example:
QByteArray ba; for (int i = 0; i < 10; ++i) ba[i] = 'A' + i; // ba == "ABCDEFGHIJ"
The return value is of type QByteRef, a helper class for QByteArray. When you get an object of type QByteRef, you can use it as if it were a char &. If you assign to it, the assignment will apply to the character in the QByteArray from which you got the reference.
See also at().
This is an overloaded function.
Same as at(i).
This is an overloaded function.
This is an overloaded function.
Returns the CRC-16 checksum of the first len bytes of data.
The checksum is independent of the byte order (endianness).
Note: This function is a 16-bit cache conserving (16 entry table) implementation of the CRC-16-CCITT algorithm.
Compresses the data byte array and returns the compressed data in a new byte array.
The compressionLevel parameter specifies how much compression should be used. Valid values are between 0 and 9, with 9 corresponding to the greatest compression (i.e. smaller compressed data) at the cost of using a slower algorithm. Smaller values (8, 7, ..., 1) provide successively less compression at slightly faster speeds. The value 0 corresponds to no compression at all. The default value is -1, which specifies zlib's default compression.
See also qUncompress().
This is an overloaded function.
Compresses the first nbytes of data and returns the compressed data in a new byte array.
Uncompresses the data byte array and returns a new byte array with the uncompressed data.
Returns an empty QByteArray if the input data was corrupt.
This function will uncompress data compressed with qCompress() from this and any earlier Qt version, back to Qt 3.1 when this feature was added.
Note: If you want to use this function to uncompress external data that was compressed using zlib, you first need to prepend a four byte header to the byte array containing the data. The header must contain the expected length (in bytes) of the uncompressed data, expressed as an unsigned, big-endian, 32-bit integer.
See also qCompress().
This is an overloaded function.
Uncompresses the first nbytes of data and returns a new byte array with the uncompressed data.
A portable snprintf() function, calls qvsnprintf.
fmt is the printf() format string. The result is put into str, which is a buffer of at least n bytes.
Warning: Call this function only when you know what you are doing since it shows different behavior on certain platforms. Use QString::sprintf() to format a string instead.
See also qvsnprintf() and QString::sprintf().
A safe strcmp() function.
Compares str1 and str2. Returns a negative value if str1 is less than str2, 0 if str1 is equal to str2 or a positive value if str1 is greater than str2.
Special case 1: Returns 0 if str1 and str2 are both 0.
Special case 2: Returns an arbitrary non-zero value if str1 is 0 or str2 is 0 (but not both).
See also qstrncmp(), qstricmp(), qstrnicmp(), and 8-bit Character Comparisons.
Copies all the characters up to and including the '\0' from src into dst and returns a pointer to dst. If src is 0, it immediately returns 0.
This function assumes that dst is large enough to hold the contents of src.
See also qstrncpy().
Returns a duplicate string.
Allocates space for a copy of src, copies it, and returns a pointer to the copy. If src is 0, it immediately returns 0.
Ownership is passed to the caller, so the returned string must be deleted using delete[].
A safe stricmp() function.
Compares str1 and str2 ignoring the case of the characters. The encoding of the strings is assumed to be Latin-1.
Returns a negative value if str1 is less than str2, 0 if str1 is equal to str2 or a positive value if str1 is greater than str2.
Special case 1: Returns 0 if str1 and str2 are both 0.
Special case 2: Returns a random non-zero value if str1 is 0 or str2 is 0 (but not both).
See also qstrcmp(), qstrncmp(), qstrnicmp(), and 8-bit Character Comparisons.
A safe strlen() function.
Returns the number of characters that precede the terminating '\0', or 0 if str is 0.
See also qstrnlen().
A safe strncmp() function.
Compares at most len bytes of str1 and str2.
Returns a negative value if str1 is less than str2, 0 if str1 is equal to str2 or a positive value if str1 is greater than str2.
Special case 1: Returns 0 if str1 and str2 are both 0.
Special case 2: Returns a random non-zero value if str1 is 0 or str2 is 0 (but not both).
See also qstrcmp(), qstricmp(), qstrnicmp(), and 8-bit Character Comparisons.
A safe strncpy() function.
Copies at most len bytes from src (stopping at len or the terminating '\0' whichever comes first) into dst and returns a pointer to dst. Guarantees that dst is '\0'-terminated. If src or dst is 0, returns 0 immediately.
This function assumes that dst is at least len characters long.
Note: When compiling with Visual C++ compiler version 14.00 (Visual C++ 2005) or later, internally the function strncpy_s will be used.
See also qstrcpy().
A safe strnicmp() function.
Compares at most len bytes of str1 and str2 ignoring the case of the characters. The encoding of the strings is assumed to be Latin-1.
Returns a negative value if str1 is less than str2, 0 if str1 is equal to str2 or a positive value if str1 is greater than str2.
Special case 1: Returns 0 if str1 and str2 are both 0.
Special case 2: Returns a random non-zero value if str1 is 0 or str2 is 0 (but not both).
See also qstrcmp(), qstrncmp(), qstricmp(), and 8-bit Character Comparisons.
A safe strnlen() function.
Returns the number of characters that precede the terminating '\0', but at most maxlen. If str is 0, returns 0.
This function was introduced in Qt 4.2.
See also qstrlen().
A portable vsnprintf() function. Will call ::vsnprintf(), ::_vsnprintf(), or ::vsnprintf_s depending on the system, or fall back to an internal version.
fmt is the printf() format string. The result is put into str, which is a buffer of at least n bytes.
The caller is responsible to call va_end() on ap.
Warning: Since vsnprintf() shows different behavior on certain platforms, you should not rely on the return value or on the fact that you will always get a 0 terminated string back.
Ideally, you should never call this function but use QString::sprintf() instead.
See also qsnprintf() and QString::sprintf().
This is an overloaded function.
Returns true if byte array a1 is not equal to byte array a2; otherwise returns false.
This is an overloaded function.
Returns true if byte array a1 is not equal to string a2; otherwise returns false.
This is an overloaded function.
Returns true if string a1 is not equal to byte array a2; otherwise returns false.
Returns a byte array that is the result of concatenating byte array a1 and byte array a2.
See also QByteArray::operator+=().
This is an overloaded function.
Returns a byte array that is the result of concatenating byte array a1 and string a2.
This is an overloaded function.
Returns a byte array that is the result of concatenating byte array a1 and character a2.
This is an overloaded function.
Returns a byte array that is the result of concatenating string a1 and byte array a2.
This is an overloaded function.
Returns a byte array that is the result of concatenating character a1 and byte array a2.
This is an overloaded function.
Returns true if byte array a1 is lexically less than byte array a2; otherwise returns false.
This is an overloaded function.
Returns true if byte array a1 is lexically less than string a2; otherwise returns false.
This is an overloaded function.
Returns true if string a1 is lexically less than byte array a2; otherwise returns false.
Writes byte array ba to the stream out and returns a reference to the stream.
See also Serializing Qt Data Types.
This is an overloaded function.
Returns true if byte array a1 is lexically less than or equal to byte array a2; otherwise returns false.
This is an overloaded function.
Returns true if byte array a1 is lexically less than or equal to string a2; otherwise returns false.
This is an overloaded function.
Returns true if string a1 is lexically less than or equal to byte array a2; otherwise returns false.
This is an overloaded function.
Returns true if byte array a1 is equal to byte array a2; otherwise returns false.
This is an overloaded function.
Returns true if byte array a1 is equal to string a2; otherwise returns false.
This is an overloaded function.
Returns true if string a1 is equal to byte array a2; otherwise returns false.
This is an overloaded function.
Returns true if byte array a1 is lexically greater than byte array a2; otherwise returns false.
This is an overloaded function.
Returns true if byte array a1 is lexically greater than string a2; otherwise returns false.
This is an overloaded function.
Returns true if string a1 is lexically greater than byte array a2; otherwise returns false.
This is an overloaded function.
Returns true if byte array a1 is lexically greater than or equal to byte array a2; otherwise returns false.
This is an overloaded function.
Returns true if byte array a1 is lexically greater than or equal to string a2; otherwise returns false.
This is an overloaded function.
Returns true if string a1 is lexically greater than or equal to byte array a2; otherwise returns false.
Reads a byte array into ba from the stream in and returns a reference to the stream.
See also Serializing Qt Data Types.
Disables automatic conversions from QByteArray to const char * or const void *.
See also QT_NO_CAST_TO_ASCII and QT_NO_CAST_FROM_ASCII.