The following members of class <QtAlgorithms> are obsolete. They are provided to keep old source code working. We strongly advise against using them in new code.
(obsolete) RandomAccessIterator |
qBinaryFind(RandomAccessIterator begin, RandomAccessIterator end, const T &value) |
(obsolete) RandomAccessIterator |
qBinaryFind(RandomAccessIterator begin, RandomAccessIterator end, const T &value, LessThan lessThan) |
(obsolete) typename Container::const_iterator |
qBinaryFind(const Container &container, const T &value) |
(obsolete) OutputIterator |
qCopy(InputIterator begin1, InputIterator end1, OutputIterator begin2) |
(obsolete) BiIterator2 |
qCopyBackward(BiIterator1 begin1, BiIterator1 end1, BiIterator2 end2) |
(obsolete) void |
qCount(InputIterator begin, InputIterator end, const T &value, Size &n) |
(obsolete) void |
qCount(const Container &container, const T &value, Size &n) |
(obsolete) bool |
qEqual(InputIterator1 begin1, InputIterator1 end1, InputIterator2 begin2) |
(obsolete) void |
qFill(ForwardIterator begin, ForwardIterator end, const T &value) |
(obsolete) void |
qFill(Container &container, const T &value) |
(obsolete) InputIterator |
qFind(InputIterator begin, InputIterator end, const T &value) |
(obsolete) typename Container::const_iterator |
qFind(const Container &container, const T &value) |
(obsolete) LessThan |
qGreater() |
(obsolete) LessThan |
qLess() |
(obsolete) RandomAccessIterator |
qLowerBound(RandomAccessIterator begin, RandomAccessIterator end, const T &value) |
(obsolete) RandomAccessIterator |
qLowerBound(RandomAccessIterator begin, RandomAccessIterator end, const T &value, LessThan lessThan) |
(obsolete) typename Container::const_iterator |
qLowerBound(const Container &container, const T &value) |
(obsolete) void |
qSort(RandomAccessIterator begin, RandomAccessIterator end) |
(obsolete) void |
qSort(RandomAccessIterator begin, RandomAccessIterator end, LessThan lessThan) |
(obsolete) void |
qSort(Container &container) |
(obsolete) void |
qStableSort(RandomAccessIterator begin, RandomAccessIterator end) |
(obsolete) void |
qStableSort(RandomAccessIterator begin, RandomAccessIterator end, LessThan lessThan) |
(obsolete) void |
qStableSort(Container &container) |
(obsolete) void |
qSwap(T &var1, T &var2) |
(obsolete) RandomAccessIterator |
qUpperBound(RandomAccessIterator begin, RandomAccessIterator end, const T &value) |
(obsolete) RandomAccessIterator |
qUpperBound(RandomAccessIterator begin, RandomAccessIterator end, const T &value, LessThan lessThan) |
(obsolete) typename Container::const_iterator |
qUpperBound(const Container &container, const T &value) |
Use std::binary_search
or std::lower_bound
instead.
Performs a binary search of the range [begin, end) and returns the position of an occurrence of value. If there are no occurrences of value, returns end.
The items in the range [begin, end) must be sorted in ascending order; see qSort().
If there are many occurrences of the same value, any one of them could be returned. Use qLowerBound() or qUpperBound() if you need finer control.
Example:
QVector<int> vect; vect << 3 << 3 << 6 << 6 << 6 << 8; QVector<int>::iterator i = qBinaryFind(vect.begin(), vect.end(), 6); // i == vect.begin() + 2 (or 3 or 4)
This function requires the item type (in the example above, QString) to implement operator<()
.
See also qLowerBound(), qUpperBound(), and random access iterators.
This is an overloaded function.
Use std::binary_search
or std::lower_bound
instead.
Uses the lessThan function instead of operator<()
to compare the items.
Note that the items in the range must be sorted according to the order specified by the lessThan object.
This is an overloaded function.
Use std::binary_search
or std::lower_bound
instead.
This is the same as qBinaryFind(container.begin(), container.end(), value);
Use std::copy
instead.
Copies the items from range [begin1, end1) to range [begin2, ...), in the order in which they appear.
The item at position begin1 is assigned to that at position begin2; the item at position begin1 + 1 is assigned to that at position begin2 + 1; and so on.
Example:
QStringList list; list << "one" << "two" << "three"; QVector<QString> vect1(3); qCopy(list.begin(), list.end(), vect1.begin()); // vect: [ "one", "two", "three" ] QVector<QString> vect2(8); qCopy(list.begin(), list.end(), vect2.begin() + 2); // vect: [ "", "", "one", "two", "three", "", "", "" ]
See also qCopyBackward(), input iterators, and output iterators.
Use std::copy_backward
instead.
Copies the items from range [begin1, end1) to range [..., end2).
The item at position end1 - 1 is assigned to that at position end2 - 1; the item at position end1 - 2 is assigned to that at position end2 - 2; and so on.
Example:
QStringList list; list << "one" << "two" << "three"; QVector<QString> vect(5); qCopyBackward(list.begin(), list.end(), vect.end()); // vect: [ "", "", "one", "two", "three" ]
See also qCopy() and bidirectional iterators.
Use std::count
instead.
Returns the number of occurrences of value in the range [begin, end), which is returned in n. n is never initialized, the count is added to n. It is the caller's responsibility to initialize n.
Example:
QList<int> list; list << 3 << 3 << 6 << 6 << 6 << 8; int countOf6 = 0; qCount(list.begin(), list.end(), 6, countOf6); // countOf6 == 3 int countOf7 = 0; qCount(list.begin(), list.end(), 7, countOf7); // countOf7 == 0
This function requires the item type (in the example above, int
) to implement operator==()
.
See also input iterators.
This is an overloaded function.
Use std::count
instead.
Instead of operating on iterators, as in the other overload, this function operates on the specified container to obtain the number of instances of value in the variable passed as a reference in argument n.
Use std::equal
instead.
Compares the items in the range [begin1, end1) with the items in the range [begin2, ...). Returns true
if all the items compare equal; otherwise returns false
.
Example:
QStringList list; list << "one" << "two" << "three"; QVector<QString> vect(3); vect[0] = "one"; vect[1] = "two"; vect[2] = "three"; bool ret1 = qEqual(list.begin(), list.end(), vect.begin()); // ret1 == true vect[2] = "seven"; bool ret2 = qEqual(list.begin(), list.end(), vect.begin()); // ret2 == false
This function requires the item type (in the example above, QString) to implement operator==()
.
See also input iterators.
Use std::fill
instead.
Fills the range [begin, end) with value.
Example:
QStringList list; list << "one" << "two" << "three"; qFill(list.begin(), list.end(), "eleven"); // list: [ "eleven", "eleven", "eleven" ] qFill(list.begin() + 1, list.end(), "six"); // list: [ "eleven", "six", "six" ]
See also qCopy() and forward iterators.
This is an overloaded function.
Use std::fill
instead.
This is the same as qFill(container.begin(), container.end(), value);
Use std::find
instead.
Returns an iterator to the first occurrence of value in a container in the range [begin, end). Returns end if value isn't found.
Example:
QStringList list; list << "one" << "two" << "three"; QStringList::iterator i1 = qFind(list.begin(), list.end(), "two"); // i1 == list.begin() + 1 QStringList::iterator i2 = qFind(list.begin(), list.end(), "seventy"); // i2 == list.end()
This function requires the item type (in the example above, QString) to implement operator==()
.
If the items in the range are in ascending order, you can get faster results by using qLowerBound() or qBinaryFind() instead of qFind().
See also qBinaryFind() and input iterators.
This is an overloaded function.
Use std::find
instead.
This is the same as qFind(container.constBegin(), container.constEnd(), value);
Use std::greater
instead.
Returns a functional object, or functor, that can be passed to qSort() or qStableSort().
Example:
QList<int> list; list << 33 << 12 << 68 << 6 << 12; qSort(list.begin(), list.end(), qGreater<int>()); // list: [ 68, 33, 12, 12, 6 ]
See also qLess<T>().
Use std::less
instead.
Returns a functional object, or functor, that can be passed to qSort() or qStableSort().
Example:
QList<int> list; list << 33 << 12 << 68 << 6 << 12; qSort(list.begin(), list.end(), qLess<int>()); // list: [ 6, 12, 12, 33, 68 ]
See also qGreater<T>().
Use std::lower_bound
instead.
Performs a binary search of the range [begin, end) and returns the position of the first occurrence of value. If no such item is found, returns the position where it should be inserted.
The items in the range [begin, end) must be sorted in ascending order; see qSort().
Example:
QList<int> list; list << 3 << 3 << 6 << 6 << 6 << 8; QList<int>::iterator i = qLowerBound(list.begin(), list.end(), 5); list.insert(i, 5); // list: [ 3, 3, 5, 6, 6, 6, 8 ] i = qLowerBound(list.begin(), list.end(), 12); list.insert(i, 12); // list: [ 3, 3, 5, 6, 6, 6, 8, 12 ]
This function requires the item type (in the example above, int
) to implement operator<()
.
qLowerBound() can be used in conjunction with qUpperBound() to iterate over all occurrences of the same value:
QVector<int> vect; vect << 3 << 3 << 6 << 6 << 6 << 8; QVector<int>::iterator begin6 = qLowerBound(vect.begin(), vect.end(), 6); QVector<int>::iterator end6 = qUpperBound(begin6, vect.end(), 6); QVector<int>::iterator i = begin6; while (i != end6) { *i = 7; ++i; } // vect: [ 3, 3, 7, 7, 7, 8 ]
See also qUpperBound() and qBinaryFind().
This is an overloaded function.
Use std::lower_bound
instead.
Uses the lessThan function instead of operator<()
to compare the items.
Note that the items in the range must be sorted according to the order specified by the lessThan object.
This is an overloaded function.
Use std::lower_bound
instead.
For read-only iteration over containers, this function is broadly equivalent to qLowerBound(container.begin(), container.end(), value). However, since it returns a const iterator, you cannot use it to modify the container; for example, to insert items.
Use std::sort
instead.
Sorts the items in range [begin, end) in ascending order using the quicksort algorithm.
Example:
QList<int> list; list << 33 << 12 << 68 << 6 << 12; qSort(list.begin(), list.end()); // list: [ 6, 12, 12, 33, 68 ]
The sort algorithm is efficient on large data sets. It operates in linear-logarithmic time, O(n log n).
This function requires the item type (in the example above, int
) to implement operator<()
.
If neither of the two items is "less than" the other, the items are taken to be equal. It is then undefined which one of the two items will appear before the other after the sort.
See also qStableSort() and random access iterators.
This is an overloaded function.
Use std::sort
instead.
Uses the lessThan function instead of operator<()
to compare the items.
For example, here's how to sort the strings in a QStringList in case-insensitive alphabetical order:
bool caseInsensitiveLessThan(const QString &s1, const QString &s2) { return s1.toLower() < s2.toLower(); } int doSomething() { QStringList list; list << "AlPha" << "beTA" << "gamma" << "DELTA"; qSort(list.begin(), list.end(), caseInsensitiveLessThan); // list: [ "AlPha", "beTA", "DELTA", "gamma" ] }
To sort values in reverse order, pass qGreater<T>() as the lessThan parameter. For example:
QList<int> list; list << 33 << 12 << 68 << 6 << 12; qSort(list.begin(), list.end(), qGreater<int>()); // list: [ 68, 33, 12, 12, 6 ]
If neither of the two items is "less than" the other, the items are taken to be equal. It is then undefined which one of the two items will appear before the other after the sort.
An alternative to using qSort() is to put the items to sort in a QMap, using the sort key as the QMap key. This is often more convenient than defining a lessThan function. For example, the following code shows how to sort a list of strings case insensitively using QMap:
QStringList list; list << "AlPha" << "beTA" << "gamma" << "DELTA"; QMap<QString, QString> map; foreach (const QString &str, list) map.insert(str.toLower(), str); list = map.values();
See also QMap.
This is an overloaded function.
Use std::sort
instead.
This is the same as qSort(container.begin(), container.end());
Use std::stable_sort
instead.
Sorts the items in range [begin, end) in ascending order using a stable sorting algorithm.
If neither of the two items is "less than" the other, the items are taken to be equal. The item that appeared before the other in the original container will still appear first after the sort. This property is often useful when sorting user-visible data.
Example:
QList<int> list; list << 33 << 12 << 68 << 6 << 12; qStableSort(list.begin(), list.end()); // list: [ 6, 12, 12, 33, 68 ]
The sort algorithm is efficient on large data sets. It operates in linear-logarithmic time, O(n log n).
This function requires the item type (in the example above, int
) to implement operator<()
.
See also qSort() and random access iterators.
This is an overloaded function.
Use std::stable_sort
instead.
Uses the lessThan function instead of operator<()
to compare the items.
For example, here's how to sort the strings in a QStringList in case-insensitive alphabetical order:
bool caseInsensitiveLessThan(const QString &s1, const QString &s2) { return s1.toLower() < s2.toLower(); } int doSomething() { QStringList list; list << "AlPha" << "beTA" << "gamma" << "DELTA"; qStableSort(list.begin(), list.end(), caseInsensitiveLessThan); // list: [ "AlPha", "beTA", "DELTA", "gamma" ] }
Note that earlier versions of Qt allowed using a lessThan function that took its arguments by non-const reference. From 4.3 and on this is no longer possible, the arguments has to be passed by const reference or value.
To sort values in reverse order, pass qGreater<T>() as the lessThan parameter. For example:
QList<int> list; list << 33 << 12 << 68 << 6 << 12; qStableSort(list.begin(), list.end(), qGreater<int>()); // list: [ 68, 33, 12, 12, 6 ]
If neither of the two items is "less than" the other, the items are taken to be equal. The item that appeared before the other in the original container will still appear first after the sort. This property is often useful when sorting user-visible data.
This is an overloaded function.
Use std::stable_sort
instead.
This is the same as qStableSort(container.begin(), container.end());
Use std::swap
instead.
Exchanges the values of variables var1 and var2.
Example:
double pi = 3.14; double e = 2.71; qSwap(pi, e); // pi == 2.71, e == 3.14
Use std::upper_bound
instead.
Performs a binary search of the range [begin, end) and returns the position of the one-past-the-last occurrence of value. If no such item is found, returns the position where the item should be inserted.
The items in the range [begin, end) must be sorted in ascending order; see qSort().
Example:
QList<int> list; list << 3 << 3 << 6 << 6 << 6 << 8; QList<int>::iterator i = qUpperBound(list.begin(), list.end(), 5); list.insert(i, 5); // list: [ 3, 3, 5, 6, 6, 6, 8 ] i = qUpperBound(list.begin(), list.end(), 12); list.insert(i, 12); // list: [ 3, 3, 5, 6, 6, 6, 8, 12 ]
This function requires the item type (in the example above, int
) to implement operator<()
.
qUpperBound() can be used in conjunction with qLowerBound() to iterate over all occurrences of the same value:
QVector<int> vect; vect << 3 << 3 << 6 << 6 << 6 << 8; QVector<int>::iterator begin6 = qLowerBound(vect.begin(), vect.end(), 6); QVector<int>::iterator end6 = qUpperBound(vect.begin(), vect.end(), 6); QVector<int>::iterator i = begin6; while (i != end6) { *i = 7; ++i; } // vect: [ 3, 3, 7, 7, 7, 8 ]
See also qLowerBound() and qBinaryFind().
This is an overloaded function.
Use std::upper_bound
instead.
Uses the lessThan function instead of operator<()
to compare the items.
Note that the items in the range must be sorted according to the order specified by the lessThan object.
This is an overloaded function.
Use std::upper_bound
instead.
This is the same as qUpperBound(container.begin(), container.end(), value);