doc/quickbook/algorithms.qbk - RealtimeRoboticsGroup/test - Gitiles

 [section:algorithms Algorithms]

 [section:advance Function template `advance()`]

 The `boost::iterators::advance` function template is an adapted version of `std::advance` for the Boost iterator [link iterator.concepts.traversal traversal concepts].

 [heading Header]

     <boost/iterator/advance.hpp>

 [heading Synopsis]

     template <typename Iterator, typename Distance>
     constexpr void advance(Iterator& it, Distance n);


 [heading Description]

 Moves `it` forward by `n` increments (or backward by `|n|` decrements if `n` is negative).

 [heading Requirements]

 `Iterator` should model Incrementable Iterator.

 [heading Preconditions]

 Let `it`[sub `i`] be the iterator obtained by incrementing (or decrementing if `n` is negative) `it` by `i`. All the iterators `it`[sub `i`] for `i` = 0, 1, 2, ..., `|n|` should be valid.

 If `Iterator` does not model [link iterator.concepts.traversal.bidirectional Bidirectional Traversal Iterator], `n` should be non-negative.

 [heading Complexity]

 If `Iterator` models [link iterator.concepts.traversal.random_access Random Access Traversal Iterator], it takes constant time; otherwise it takes linear time.

 [heading Notes]

 * This function is not a customization point and is protected against being found by argument-dependent lookup (ADL).
 * This function is `constexpr` only in C++14 or later.

 [heading Acknowledgements]

 Contributed by Michel Morin.

 [endsect]

 [section:distance Function template `distance()`]

 The `boost::iterators::distance` function template is an adapted version of `std::distance` for the Boost iterator [link iterator.concepts.traversal traversal concepts].

 [heading Header]

     <boost/iterator/distance.hpp>

 [heading Synopsis]

     template <typename Iterator>
     constexpr typename iterator_difference<Iterator>::type
     distance(Iterator first, Iterator last);

 [heading Description]

 Computes the (signed) distance from `first` to `last`.

 [heading Requirements]

 `Iterator` should model [link iterator.concepts.traversal.single_pass Single Pass Iterator].

 [heading Preconditions]

 If `Iterator` models [link iterator.concepts.traversal.random_access Random Access Traversal Iterator], `[first, last)` or `[last, first)` should be valid; otherwise `[first, last)` should be valid.

 [heading Complexity]

 If `Iterator` models [link iterator.concepts.traversal.random_access Random Access Traversal Iterator], it takes constant time; otherwise it takes linear time.

 [heading Notes]

 * This function is not a customization point and is protected against being found by argument-dependent lookup (ADL).
 * This function is `constexpr` only in C++14 or later.

 [heading Acknowledgements]

 Contributed by Michel Morin.

 [endsect]

 [section:next_prior Function templates `next()` and `prior()`]

 Certain data types, such as the C++ Standard Library's forward and bidirectional iterators, do not provide addition and subtraction via `operator+()` or `operator-()`. This means that non-modifying computation of the next or prior value requires a temporary, even though `operator++()` or `operator--()` is provided. It also means that writing code like `itr+1` inside a template restricts the iterator category to random access iterators.

 The `next()` and `prior()` functions defined in `boost/next_prior.hpp` provide a simple way around these problems.

 [heading Synopsis]

     template <class T>
     T next(T x)
     {
         return ++x;
     }

     template <class T, class Distance>
     T next(T x, Distance n)
     {
         std::advance(x, n);
         return x;
     }

     template <class T>
     T prior(T x)
     {
         return --x;
     }

     template <class T, class Distance>
     T prior(T x, Distance n)
     {
         std::advance(x, -n);
         return x;
     }

 [note Function implementations above are given for exposition only. The actual implementation has the same effect for iterators, but has different properties, as documented later.]

 [heading Usage]

 Usage is simple:

     const std::list<T>::iterator p = get_some_iterator();
     const std::list<T>::iterator prev = boost::prior(p);
     const std::list<T>::iterator next = boost::next(prev, 2);

 The distance from the given iterator should be supplied as an absolute value. For example, the iterator four iterators prior to the given iterator `p` may be obtained by `prior(p, 4)`.

 With C++11, the Standard Library provides `std::next()` and `std::prev()` function templates, which serve the same purpose. However, there are advantages to `boost::next()` and `boost::prior()`.

 First, `boost::next()` and `boost::prior()` are compatible not only with iterators but with any type that provides arithmetic operators `operator++()`, `operator--()`, `operator+()`, `operator-()`, `operator+=()` or `operator-=()`. For example, this is possible:

     int x = 10;
     int y = boost::next(x, 5);
     assert(y == 15);

 Second, `boost::next()` and `boost::prior()` use [link iterator.concepts.traversal traversal categories] to select the most efficient implementation. For some kinds of iterators, such as [link iterator.specialized.transform transform iterators], the standard iterator category does not reflect the traversal category correctly and therefore `std::next()` and `std::prev()` will fall back to linear complexity.

 [heading Acknowledgements]

 Contributed by [@http://www.boost.org/people/dave_abrahams.htm Dave Abrahams]. Two-argument versions by Daniel Walker.

 [endsect]

 [endsect]
	[section:algorithms Algorithms]

	[section:advance Function template `advance()`]

	The `boost::iterators::advance` function template is an adapted version of `std::advance` for the Boost iterator [link iterator.concepts.traversal traversal concepts].

	[heading Header]

	<boost/iterator/advance.hpp>

	[heading Synopsis]

	template <typename Iterator, typename Distance>
	constexpr void advance(Iterator& it, Distance n);


	[heading Description]

	Moves `it` forward by `n` increments (or backward by `\|n\|` decrements if `n` is negative).

	[heading Requirements]

	`Iterator` should model Incrementable Iterator.

	[heading Preconditions]

	Let `it`[sub `i`] be the iterator obtained by incrementing (or decrementing if `n` is negative) `it` by `i`. All the iterators `it`[sub `i`] for `i` = 0, 1, 2, ..., `\|n\|` should be valid.

	If `Iterator` does not model [link iterator.concepts.traversal.bidirectional Bidirectional Traversal Iterator], `n` should be non-negative.

	[heading Complexity]

	If `Iterator` models [link iterator.concepts.traversal.random_access Random Access Traversal Iterator], it takes constant time; otherwise it takes linear time.

	[heading Notes]

	* This function is not a customization point and is protected against being found by argument-dependent lookup (ADL).
	* This function is `constexpr` only in C++14 or later.

	[heading Acknowledgements]

	Contributed by Michel Morin.

	[endsect]

	[section:distance Function template `distance()`]

	The `boost::iterators::distance` function template is an adapted version of `std::distance` for the Boost iterator [link iterator.concepts.traversal traversal concepts].

	[heading Header]

	<boost/iterator/distance.hpp>

	[heading Synopsis]

	template <typename Iterator>
	constexpr typename iterator_difference<Iterator>::type
	distance(Iterator first, Iterator last);

	[heading Description]

	Computes the (signed) distance from `first` to `last`.

	[heading Requirements]

	`Iterator` should model [link iterator.concepts.traversal.single_pass Single Pass Iterator].

	[heading Preconditions]

	If `Iterator` models [link iterator.concepts.traversal.random_access Random Access Traversal Iterator], `[first, last)` or `[last, first)` should be valid; otherwise `[first, last)` should be valid.

	[heading Complexity]

	If `Iterator` models [link iterator.concepts.traversal.random_access Random Access Traversal Iterator], it takes constant time; otherwise it takes linear time.

	[heading Notes]

	* This function is not a customization point and is protected against being found by argument-dependent lookup (ADL).
	* This function is `constexpr` only in C++14 or later.

	[heading Acknowledgements]

	Contributed by Michel Morin.

	[endsect]

	[section:next_prior Function templates `next()` and `prior()`]

	Certain data types, such as the C++ Standard Library's forward and bidirectional iterators, do not provide addition and subtraction via `operator+()` or `operator-()`. This means that non-modifying computation of the next or prior value requires a temporary, even though `operator++()` or `operator--()` is provided. It also means that writing code like `itr+1` inside a template restricts the iterator category to random access iterators.

	The `next()` and `prior()` functions defined in `boost/next_prior.hpp` provide a simple way around these problems.

	[heading Synopsis]

	template <class T>
	T next(T x)
	{
	return ++x;
	}

	template <class T, class Distance>
	T next(T x, Distance n)
	{
	std::advance(x, n);
	return x;
	}

	template <class T>
	T prior(T x)
	{
	return --x;
	}

	template <class T, class Distance>
	T prior(T x, Distance n)
	{
	std::advance(x, -n);
	return x;
	}

	[note Function implementations above are given for exposition only. The actual implementation has the same effect for iterators, but has different properties, as documented later.]

	[heading Usage]

	Usage is simple:

	const std::list<T>::iterator p = get_some_iterator();
	const std::list<T>::iterator prev = boost::prior(p);
	const std::list<T>::iterator next = boost::next(prev, 2);

	The distance from the given iterator should be supplied as an absolute value. For example, the iterator four iterators prior to the given iterator `p` may be obtained by `prior(p, 4)`.

	With C++11, the Standard Library provides `std::next()` and `std::prev()` function templates, which serve the same purpose. However, there are advantages to `boost::next()` and `boost::prior()`.

	First, `boost::next()` and `boost::prior()` are compatible not only with iterators but with any type that provides arithmetic operators `operator++()`, `operator--()`, `operator+()`, `operator-()`, `operator+=()` or `operator-=()`. For example, this is possible:

	int x = 10;
	int y = boost::next(x, 5);
	assert(y == 15);

	Second, `boost::next()` and `boost::prior()` use [link iterator.concepts.traversal traversal categories] to select the most efficient implementation. For some kinds of iterators, such as [link iterator.specialized.transform transform iterators], the standard iterator category does not reflect the traversal category correctly and therefore `std::next()` and `std::prev()` will fall back to linear complexity.

	[heading Acknowledgements]

	Contributed by [@http://www.boost.org/people/dave_abrahams.htm Dave Abrahams]. Two-argument versions by Daniel Walker.

	[endsect]

	[endsect]