range/doc/reference/algorithm/find_end.qbk

[section:find_end find_end]

[heading Prototype]

``
template<class ForwardRange1, class ForwardRange2>
typename range_iterator<ForwardRange1>::type
find_end(ForwardRange1& rng1, const ForwardRange2& rng2);

template<
    class ForwardRange1,
    class ForwardRange2,
    class BinaryPredicate
    >
typename range_iterator<ForwardRange1>::type
find_end(ForwardRange1& rng1, const ForwardRange2& rng2, BinaryPredicate pred);

template<
    range_return_value re,
    class ForwardRange1,
    class ForwardRange2
    >
typename range_return<ForwardRange1, re>::type
find_end(ForwardRange1& rng1, const ForwardRange2& rng2);

template<
    range_return_value re,
    class ForwardRange1,
    class ForwardRange2,
    class BinaryPredicate
    >
typename range_return<ForwardRange1, re>::type
find_end(ForwardRange1& rng1, const ForwardRange2& rng2, BinaryPredicate pred);
``

[heading Description]

The versions of `find_end` that return an iterator, return an iterator to the beginning of the last sub-sequence equal to `rng2` within `rng1`.
Equality is determined by `operator==` for non-predicate versions of `find_end`, and by satisfying `pred` in the predicate versions. The versions of `find_end` that return a `range_return`, defines `found` in the same manner as the returned iterator described above.

[heading Definition]

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

[heading Requirements]

[*For the non-predicate versions:]

* `ForwardRange1` is a model of the __forward_range__ Concept.
* `ForwardRange2` is a model of the __forward_range__ Concept.
* `ForwardRange1`'s value type is a model of the `EqualityComparableConcept`.
* `ForwardRange2`'s value type is a model of the `EqualityComparableConcept`.
* Objects of `ForwardRange1`'s value type can be compared for equality with objects of `ForwardRange2`'s value type.

[*For the predicate versions:]

* `ForwardRange1` is a model of the __forward_range__ Concept.
* `ForwardRange2` is a model of the __forward_range__ Concept.
* `BinaryPredicate` is a model of the `BinaryPredicateConcept`.
* `ForwardRange1`'s value type is convertible to `BinaryPredicate`'s first argument type.
* `ForwardRange2`'s value type is convertible to `BinaryPredicate`'s second argument type.

[heading Complexity]

The number of comparisons is proportional to `distance(rng1) * distance(rng2)`. If both `ForwardRange1` and `ForwardRange2` are models of `BidirectionalRangeConcept` then the average complexity is linear and the worst case is `distance(rng1) * distance(rng2)`.

[endsect]
Boost.RangeEx merged into Boost.Range [SVN r60897] 2010-03-28 16:08:35 +00:00			`[section:find_end find_end]`

			`[heading Prototype]`

			``
			`template<class ForwardRange1, class ForwardRange2>`
			`typename range_iterator<ForwardRange1>::type`
			`find_end(ForwardRange1& rng1, const ForwardRange2& rng2);`

			`template<`
			`class ForwardRange1,`
			`class ForwardRange2,`
			`class BinaryPredicate`
			`>`
			`typename range_iterator<ForwardRange1>::type`
			`find_end(ForwardRange1& rng1, const ForwardRange2& rng2, BinaryPredicate pred);`

			`template<`
			`range_return_value re,`
			`class ForwardRange1,`
			`class ForwardRange2`
			`>`
			`typename range_return<ForwardRange1, re>::type`
			`find_end(ForwardRange1& rng1, const ForwardRange2& rng2);`

			`template<`
			`range_return_value re,`
			`class ForwardRange1,`
			`class ForwardRange2,`
			`class BinaryPredicate`
			`>`
			`typename range_return<ForwardRange1, re>::type`
			`find_end(ForwardRange1& rng1, const ForwardRange2& rng2, BinaryPredicate pred);`
			``

			`[heading Description]`

			The versions of `find_end` that return an iterator, return an iterator to the beginning of the last sub-sequence equal to `rng2` within `rng1`.
			Equality is determined by `operator==` for non-predicate versions of `find_end`, and by satisfying `pred` in the predicate versions. The versions of `find_end` that return a `range_return`, defines `found` in the same manner as the returned iterator described above.
Boost.Range fixes for compilers that were having problems picking between const and mutable range overloads of range algorithms. [SVN r61028] 2010-04-03 21:00:56 +00:00
Boost.RangeEx merged into Boost.Range [SVN r60897] 2010-03-28 16:08:35 +00:00			`[heading Definition]`

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

			`[heading Requirements]`

			`[*For the non-predicate versions:]`

			* `ForwardRange1` is a model of the __forward_range__ Concept.
			* `ForwardRange2` is a model of the __forward_range__ Concept.
			* `ForwardRange1`'s value type is a model of the `EqualityComparableConcept`.
			* `ForwardRange2`'s value type is a model of the `EqualityComparableConcept`.
			* Objects of `ForwardRange1`'s value type can be compared for equality with objects of `ForwardRange2`'s value type.

			`[*For the predicate versions:]`

			* `ForwardRange1` is a model of the __forward_range__ Concept.
			* `ForwardRange2` is a model of the __forward_range__ Concept.
			* `BinaryPredicate` is a model of the `BinaryPredicateConcept`.
			* `ForwardRange1`'s value type is convertible to `BinaryPredicate`'s first argument type.
			* `ForwardRange2`'s value type is convertible to `BinaryPredicate`'s second argument type.

			`[heading Complexity]`

			The number of comparisons is proportional to `distance(rng1) * distance(rng2)`. If both `ForwardRange1` and `ForwardRange2` are models of `BidirectionalRangeConcept` then the average complexity is linear and the worst case is `distance(rng1) * distance(rng2)`.

			`[endsect]`