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This section contains snippets that were automatically translated from C++ to Python and may contain errors.

The <QtAlgorithms> header includes the generic, template-based algorithms.

Qt provides a number of global template functions in <QtAlgorithms> that work on containers and perform small tasks to make life easier, such as qDeleteAll() , which invokes operator delete on all items in a given container or in a given range. You can use these algorithms with any container class that provides STL-style iterators, including Qt’s QList , QMap , and QHash classes.

Most algorithms take STL-style iterators as parameters. The algorithms are generic in the sense that they aren’t bound to a specific iterator class; you can use them with any iterators that meet a certain set of requirements.

Different algorithms can have different requirements for the iterators they accept. The iterator types required are specified for each algorithm. If an iterator of the wrong type is passed (for example, if QList::ConstIterator is passed as an output iterator ), you will always get a compiler error, although not necessarily a very informative one.

Some algorithms have special requirements on the value type stored in the containers. For example, qDeleteAll() requires that the value type is a non-const pointer type (for example, QWidget *). The value type requirements are specified for each algorithm, and the compiler will produce an error if a requirement isn’t met.

The generic algorithms can be used on other container classes than those provided by Qt and STL. The syntax of STL-style iterators is modeled after C++ pointers, so it’s possible to use plain arrays as containers and plain pointers as iterators.

Types of Iterators#

The algorithms have certain requirements on the iterator types they accept, and these are specified individually for each function. The compiler will produce an error if a requirement isn’t met.

Input Iterators#

An input iterator is an iterator that can be used for reading data sequentially from a container. It must provide the following operators: == and != for comparing two iterators, unary * for retrieving the value stored in the item, and prefix ++ for advancing to the next item.

The Qt containers’ iterator types (const and non-const) are all input iterators.

Output Iterators#

An output iterator is an iterator that can be used for writing data sequentially to a container or to some output stream. It must provide the following operators: unary * for writing a value (i.e., *it = val) and prefix ++ for advancing to the next item.

The Qt containers’ non-const iterator types are all output iterators.

Forward Iterators#

A forward iterator is an iterator that meets the requirements of both input iterators and output iterators.

The Qt containers’ non-const iterator types are all forward iterators.

Bidirectional Iterators#

A bidirectional iterator is an iterator that meets the requirements of forward iterators but that in addition supports prefix -- for iterating backward.

The Qt containers’ non-const iterator types are all bidirectional iterators.

Random Access Iterators#

The last category, random access iterators, is the most powerful type of iterator. It supports all the requirements of a bidirectional iterator, and supports the following operations:

i += n

advances iterator i by n positions

i -= n

moves iterator i back by n positions

i + n or n + i

returns the iterator for the item n positions ahead of iterator i

i - n

returns the iterator for the item n positions behind of iterator i

i - j

returns the number of items between iterators i and j

i[n]

same as *(i + n)

i < j

returns true if iterator j comes after iterator i

QList ‘s non-const iterator type is random access iterator.

Returns the number of consecutive zero bits in v, when searching from the MSB. For example, qCountLeadingZeroBits(quint8(1)) returns 7 and qCountLeadingZeroBits(quint8(8)) returns 4.

Returns the number of consecutive zero bits in v, when searching from the MSB. For example, qCountLeadingZeroBits (quint16(1)) returns 15 and qCountLeadingZeroBits (quint16(8)) returns 12.

Returns the number of consecutive zero bits in v, when searching from the MSB. For example, qCountLeadingZeroBits (quint32(1)) returns 31 and qCountLeadingZeroBits (quint32(8)) returns 28.

Returns the number of consecutive zero bits in v, when searching from the MSB. For example, qCountLeadingZeroBits (quint64(1)) returns 63 and qCountLeadingZeroBits (quint64(8)) returns 60.

Returns the number of consecutive zero bits in v, when searching from the LSB. For example, qCountTrailingZeroBits(1) returns 0 and qCountTrailingZeroBits(8) returns 3.

This is an overloaded function.

This is an overloaded function.

This is an overloaded function.

Deletes all the items in the range [begin, end) using the C++ delete operator. The item type must be a pointer type (for example, QWidget *).

Example:

*> = QList<Employee()
list.append(Employee("Blackpool", "Stephen"))
list.append(Employee("Twist", "Oliver"))
qDeleteAll(list.begin(), list.end())
list.clear()

Notice that qDeleteAll() doesn’t remove the items from the container; it merely calls delete on them. In the example above, we call clear() on the container to remove the items.

This function can also be used to delete items stored in associative containers, such as QMap and QHash . Only the objects stored in each container will be deleted by this function; objects used as keys will not be deleted.

This is an overloaded function.

This is the same as qDeleteAll (c.begin(), c.end()).

Returns the number of bits set in v. This number is also called the Hamming Weight of v.

This is an overloaded function.

This is an overloaded function.

This is an overloaded function.