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368 lines
12 KiB
368 lines
12 KiB
/****************************************************************************
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**
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** TQt Template Library classes documentation
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**
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** Copyright (C) 1992-2008 Trolltech ASA. All rights reserved.
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**
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** This file is part of the TQt GUI Toolkit.
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**
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** This file may be used under the terms of the GNU General
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** Public License versions 2.0 or 3.0 as published by the Free
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** Software Foundation and appearing in the files LICENSE.GPL2
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** and LICENSE.GPL3 included in the packaging of this file.
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** Alternatively you may (at your option) use any later version
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** of the GNU General Public License if such license has been
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** publicly approved by Trolltech ASA (or its successors, if any)
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** and the KDE Free TQt Foundation.
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**
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** Please review the following information to ensure GNU General
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** Public Licensing requirements will be met:
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** http://trolltech.com/products/qt/licenses/licensing/opensource/.
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** If you are unsure which license is appropriate for your use, please
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** review the following information:
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** http://trolltech.com/products/qt/licenses/licensing/licensingoverview
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** or contact the sales department at sales@trolltech.com.
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**
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** This file may be used under the terms of the Q Public License as
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** defined by Trolltech ASA and appearing in the file LICENSE.QPL
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** included in the packaging of this file. Licensees holding valid Qt
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** Commercial licenses may use this file in accordance with the Qt
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** Commercial License Agreement provided with the Software.
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**
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** This file is provided "AS IS" with NO WARRANTY OF ANY KIND,
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** INCLUDING THE WARRANTIES OF DESIGN, MERCHANTABILITY AND FITNESS FOR
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** A PARTICULAR PURPOSE. Trolltech reserves all rights not granted
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** herein.
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**
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**********************************************************************/
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/*!
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\page qt-template-lib.html
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\title TQt Template Library
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The TQt Template Library (TQTL) is a set of templates that provide
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object containers. If a suitable STL implementation is not available
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on all your target platforms, the TQTL can be used instead. It provides
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a list of objects, a vector (dynamic array) of objects, a map relating
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one type to another (also called a dictionary or associative array),
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and associated \link #Iterators iterators\endlink and \link
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#Algorithms algorithms\endlink. A container is an object which
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contains and manages other objects and provides iterators that allow
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the contained objects to be accessed.
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The TQTL classes' naming conventions are consistent with the other Qt
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classes (e.g., count(), isEmpty()). They also provide extra functions
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for compatibility with STL algorithms, such as size() and empty().
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Programmers already familiar with the STL \c map can use the
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STL-compatible functions if preferred.
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Compared to the STL, the TQTL only contains the most important features
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of the STL container API. Compared with the STL, TQTL has no platform
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differences, but is often a little slower and often expands to less
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object code.
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If you cannot make copies of the objects you want to store you should
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use TQPtrCollection and friends, all of which operate on pointers
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rather than values. This applies, for example, to all classes derived
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from \l TQObject. A TQObject does not have a copy constructor, so using
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it as value is impossible. You may choose to store pointers to
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TQObjects in a TQValueList, but using TQPtrList directly seems to be the
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better choice for this kind of application domain. TQPtrList, like all
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other TQPtrCollection based containers, provides far more sanity
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checking than a speed-optimized value based container.
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If you have objects that implement value semantics, and the STL is not
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available on your target platform, the TQt Template Library can be used
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instead. Value semantics require at least:
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\list
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\i a copy constructor;
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\i an assignment operator;
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\i a defaultconstructor, i.e. a constructor that does not take any arguments.
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\endlist
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Note that a fast copy constructor is absolutely crucial to achieve
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good overall performance of the container, since many copy operations
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will occur.
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If you intend sorting your data you must implement \c{operator<()} for
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your data's class.
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Good candidates for value based classes are TQRect, TQPoint, TQSize,
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TQString and all simple C++ types, such as int, bool or double.
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The TQt Template Library is designed for speed. Iterators are extremely
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fast. To achieve this performance, less error checking is done than in
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the TQPtrCollection based containers. A TQTL container, for example,
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does not track any associated iterators. This makes certain validity
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checks, for example when removing items, impossible to perform
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automatically, but does lead to extremely good performance.
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\target Iterators
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\section1 Iterators
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The TQt Template Library deals with value objects, not with pointers.
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For that reason, there is no other way of iterating over containers
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other than with iterators. This is no disadvantage as the size of an
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iterator matches the size of a normal pointer.
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To iterate over a container, use a loop like this:
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\code
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typedef TQValueList<int> List;
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List list;
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for( List::Iterator it = list.begin(); it != list.end(); ++it )
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printf( "Number is %i\n", *it );
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\endcode
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begin() returns the iterator pointing at the first element, while
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end() returns an iterator that points \e after the last element. end()
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marks an invalid position, so it can never be dereferenced. It's the
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break condition in any iteration, whether the start point is from
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begin() or fromLast(). For maximum speed, use increment or decrement
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iterators with the prefix operator (++it, --it) instead of the postfix
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operator (it++, it--), since the former is slightly faster.
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The same concept applies to the other container classes:
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\code
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typedef TQMap<TQString,TQString> Map;
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Map map;
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for( Map::iterator it = map.begin(); it != map.end(); ++it )
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printf( "Key=%s Data=%s\n", it.key().ascii(), it.data().ascii() );
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typedef TQValueVector<int> Vector;
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Vector vec;
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for( Vector::iterator it = vec.begin(); it != vec.end(); ++it )
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printf( "Data=%d\n", *it );
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\endcode
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There are two kind of iterators, the volatile iterator shown in the
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examples above and a version that returns a const reference to its
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current object, the ConstIterator. Const iterators are required
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whenever the container itself is const, such as a member variable
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inside a const function. Assigning a ConstIterator to a normal
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Iterator is not allowed as it would violate const semantics.
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\target Algorithms
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\section1 Algorithms
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The TQt Template Library defines a number of algorithms that operate on
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its containers. These algorithms are implemented as template functions
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and provide useful generic code which can be applied to any container
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that provides iterators (including your own containers).
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\section2 qHeapSort()
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qHeapSort() provides a well known sorting algorithm. You can use it
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like this:
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\code
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typedef TQValueList<int> List;
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List list;
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list << 42 << 100 << 1234 << 12 << 8;
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qHeapSort( list );
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List list2;
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list2 << 42 << 100 << 1234 << 12 << 8;
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List::Iterator b = list2.find( 100 );
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List::Iterator e = list2.find( 8 );
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qHeapSort( b, e );
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double arr[] = { 3.2, 5.6, 8.9 };
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qHeapSort( arr, arr + 3 );
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\endcode
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The first example sorts the entire list. The second example sorts only
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those elements that fall between the two iterators, i.e. 100, 1234 and
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12. The third example shows that iterators act like pointers and can
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be treated as such.
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If using your own data types you must implement \c{operator<()} for
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your data's class.
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Naturally, the sorting templates won't work with const iterators.
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\target tqSwap
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\section2 tqSwap()
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tqSwap() exchanges the values of two variables:
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\code
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TQString second( "Einstein" );
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TQString name( "Albert" );
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tqSwap( second, name );
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\endcode
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\target tqCount
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\section2 tqCount()
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The tqCount() template function counts the number of occurrences of a
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value within a container. For example:
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\code
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TQValueList<int> list;
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list.push_back( 1 );
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list.push_back( 1 );
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list.push_back( 1 );
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list.push_back( 2 );
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int c = 0;
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tqCount( list.begin(), list.end(), 1, c ); // c == 3
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\endcode
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\target tqFind
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\section2 tqFind()
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The tqFind() template function finds the first occurrence of a value
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within a container. For example:
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\code
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TQValueList<int> list;
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list.push_back( 1 );
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list.push_back( 1 );
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list.push_back( 1 );
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list.push_back( 2 );
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TQValueListIterator<int> it = tqFind( list.begin(), list.end(), 2 );
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\endcode
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\target tqFill
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\section2 tqFill()
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The tqFill() template function fills a range with copies of a value.
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For example:
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\code
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TQValueVector<int> vec(3);
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tqFill( vec.begin(), vec.end(), 99 ); // vec contains 99, 99, 99
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\endcode
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\target tqEqual
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\section2 tqEqual()
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The tqEqual() template function compares two ranges for equality of
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their elements. Note that the number of elements in each range is not
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considered, only if the elements in the first range are equal to the
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corresponding elements in the second range (consequently, both ranges
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must be valid). For example:
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\code
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TQValueVector<int> v1(3);
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v1[0] = 1;
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v1[2] = 2;
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v1[3] = 3;
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TQValueVector<int> v2(5);
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v2[0] = 1;
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v2[2] = 2;
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v2[3] = 3;
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v2[4] = 4;
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v2[5] = 5;
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bool b = tqEqual( v1.begin(), v2.end(), v2.begin() );
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// b == TRUE
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\endcode
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\target tqCopy
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\section2 tqCopy()
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The tqCopy() template function copies a range of elements to an
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OutputIterator, in this case a TQTextOStreamIterator:
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\code
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TQValueList<int> list;
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list.push_back( 100 );
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list.push_back( 200 );
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list.push_back( 300 );
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TQTextOStream str( stdout );
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tqCopy( list.begin(), list.end(), TQTextOStreamIterator(str) );
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\endcode
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\omit
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Here is another example which copies a range of elements from one
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container into another. It uses the qBackInserter() template function
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which creates a QBackInsertIterator<> whose job is to insert elements
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into the end of a container. For example:
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\code
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TQValueList<int> l;
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l.push_back( 100 );
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l.push_back( 200 );
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l.push_back( 300 );
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TQValueVector<int> v;
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tqCopy( l.begin(), l.end(), qBackInserter(v) );
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\endcode
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\endomit
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\target tqCopyBackward
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\section2 tqCopyBackward()
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The tqCopyBackward() template function copies a container or a slice of
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a container to an OutputIterator, but in reverse order, for example:
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\code
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TQValueVector<int> vec(3);
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vec.push_back( 100 );
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vec.push_back( 200 );
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vec.push_back( 300 );
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TQValueVector<int> another;
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tqCopyBackward( vec.begin(), vec.end(), another.begin() );
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// 'another' now contains 100, 200, 300
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// however the elements are copied one at a time
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// in reverse order (300, 200, then 100)
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\endcode
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\section2 TQTL Iterators
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You can use any TQt Template Library iterator as the OutputIterator.
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Just make sure that the right hand of the iterator has as many
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elements present as you want to insert. The following example
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illustrates this:
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\code
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TQStringList list1, list2;
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list1 << "Weis" << "Ettrich" << "Arnt" << "Sue";
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list2 << "Torben" << "Matthias";
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tqCopy( list2.begin(), list2.end(), list1.begin() );
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TQValueVector<TQString> vec( list1.size(), "Dave" );
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tqCopy( list2.begin(), list2.end(), vec.begin() );
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\endcode
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At the end of this code fragment, the list list1 contains "Torben",
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"Matthias", "Arnt" and "Sue", with the prior contents being
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overwritten. The vector vec contains "Torben", "Matthias", "Dave" and
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"Dave", also with the prior contents being overwritten.
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If you write new algorithms, consider writing them as template
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functions in order to make them usable with as many containers
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as possible. In the above example, you could just as easily print out
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a standard C++ array with tqCopy():
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\code
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int arr[] = { 100, 200, 300 };
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TQTextOStream str( stdout );
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tqCopy( arr, arr + 3, TQTextOStreamIterator( str ) );
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\endcode
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\section1 Streaming
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All the containers we've mentioned can be serialized with the
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appropriate streaming operators. Here is an example.
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\code
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TQDataStream str(...);
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TQValueList<TQRect> list;
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// ... fill the list here
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str << list;
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\endcode
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The container can be read in again with:
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\code
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TQValueList<TQRect> list;
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str >> list;
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\endcode
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The same applies to TQStringList, TQValueStack and TQMap.
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*/
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/*!
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\fn TQPair qMakePair(T1 t1, T2 t2)
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\relates TQPair
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This is a template convenience function. It is used to create a
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TQPair\<\> object that contains \a t1 and \a t2.
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*/
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