boost_1_45_0/libs/range/doc/reference/algorithm/next_permutation.qbk - nest-learning-thermostat/5.0/boost - Git at Google

 [section:next_permutation next_permutation]

 [heading Prototype]

 ``
 template<class BidirectionalRange>
 bool next_permutation(BidirectionalRange& rng);

 template<class BidirectionalRange>
 bool next_permutation(const BidirectionalRange& rng);

 template<class BidirectionalRange, class Compare>
 bool next_permutation(BidirectionalRange& rng, Compare pred);

 template<class BidirectionalRange, class Compare>
 bool next_permutation(const BidirectionalRange& rng, Compare pred);
 ``

 [heading Description]

 `next_permutation` transforms the range of elements `rng` into the lexicographically next greater permutation of the elements if such a permutation exists. If one does not exist then the range is transformed into the lexicographically smallest permutation and `false` is returned. `true` is returned when the next greater permutation is successfully generated.

 The ordering relationship is determined by using `operator<` in the non-predicate versions, and by evaluating `pred` in the predicate versions.

 [heading Definition]

 Defined in the header file `boost/range/algorithm/permutation.hpp`

 [heading Requirements]

 [*For the non-predicate versions:]

 * `BidirectionalRange` is a model of the __bidirectional_range__ Concept.
 * `BidirectionalRange` is mutable.
 * `BidirectionalRange`'s value type is a model of the `LessThanComparableConcept`.
 * The ordering of objects of type `BidirectionalRange`'s value type is a [*/strict weak ordering/], as defined in the `LessThanComparableConcept` requirements.

 [*For the predicate versions:]

 * `BidirectionalRange` is a model of the __bidirectional_range__ Concept.
 * `BidirectionalRange` is mutable.
 * `Compare` is a model of the `StrictWeakOrderingConcept`.
 * `BidirectionalRange`'s value type is convertible to both of `Compare`'s argument types.

 [heading Complexity]

 Linear. At most `distance(rng) / 2` swaps.

 [endsect]
	[section:next_permutation next_permutation]

	[heading Prototype]

	``
	template<class BidirectionalRange>
	bool next_permutation(BidirectionalRange& rng);

	template<class BidirectionalRange>
	bool next_permutation(const BidirectionalRange& rng);

	template<class BidirectionalRange, class Compare>
	bool next_permutation(BidirectionalRange& rng, Compare pred);

	template<class BidirectionalRange, class Compare>
	bool next_permutation(const BidirectionalRange& rng, Compare pred);
	``

	[heading Description]

	`next_permutation` transforms the range of elements `rng` into the lexicographically next greater permutation of the elements if such a permutation exists. If one does not exist then the range is transformed into the lexicographically smallest permutation and `false` is returned. `true` is returned when the next greater permutation is successfully generated.

	The ordering relationship is determined by using `operator<` in the non-predicate versions, and by evaluating `pred` in the predicate versions.

	[heading Definition]

	Defined in the header file `boost/range/algorithm/permutation.hpp`

	[heading Requirements]

	[*For the non-predicate versions:]

	* `BidirectionalRange` is a model of the __bidirectional_range__ Concept.
	* `BidirectionalRange` is mutable.
	* `BidirectionalRange`'s value type is a model of the `LessThanComparableConcept`.
	* The ordering of objects of type `BidirectionalRange`'s value type is a [*/strict weak ordering/], as defined in the `LessThanComparableConcept` requirements.

	[*For the predicate versions:]

	* `BidirectionalRange` is a model of the __bidirectional_range__ Concept.
	* `BidirectionalRange` is mutable.
	* `Compare` is a model of the `StrictWeakOrderingConcept`.
	* `BidirectionalRange`'s value type is convertible to both of `Compare`'s argument types.

	[heading Complexity]

	Linear. At most `distance(rng) / 2` swaps.

	[endsect]