# adjacent_find

**Visual Studio 2010**

Searches for two adjacent elements that are either equal or satisfy a specified condition.

template<class ForwardIterator> ForwardIterator adjacent_find( ForwardIterator _First, ForwardIterator _Last ); template<class ForwardIterator , class BinaryPredicate> ForwardIterator adjacent_find( ForwardIterator _First, ForwardIterator _Last, BinaryPredicate _Comp );

A forward iterator to the first element of the adjacent pair that are either equal to each other (in the first version) or that satisfy the condition given by the binary predicate (in the second version), provided that such a pair of elements is found. Otherwise, an iterator pointing to _Last is returned.

The **adjacent_find** algorithm is a nonmutating sequence algorithm. The range to be searched must be valid; all pointers must be dereferenceable and the last position is reachable from the first by incrementation. The time complexity of the algorithm is linear in the number of elements contained in the range.

The **operator==** used to determine the match between elements must impose an equivalence relation between its operands.

// alg_adj_fnd.cpp // compile with: /EHsc #include <list> #include <algorithm> #include <iostream> // Returns whether second element is twice the first bool twice (int elem1, int elem2 ) { return elem1 * 2 == elem2; } int main( ) { using namespace std; list <int> L; list <int>::iterator Iter; list <int>::iterator result1, result2; L.push_back( 50 ); L.push_back( 40 ); L.push_back( 10 ); L.push_back( 20 ); L.push_back( 20 ); cout << "L = ( " ; for ( Iter = L.begin( ) ; Iter != L.end( ) ; Iter++ ) cout << *Iter << " "; cout << ")" << endl; result1 = adjacent_find( L.begin( ), L.end( ) ); if ( result1 == L.end( ) ) cout << "There are not two adjacent elements that are equal." << endl; else cout << "There are two adjacent elements that are equal." << "\n They have a value of " << *( result1 ) << "." << endl; result2 = adjacent_find( L.begin( ), L.end( ), twice ); if ( result2 == L.end( ) ) cout << "There are not two adjacent elements where the " << " second is twice the first." << endl; else cout << "There are two adjacent elements where " << "the second is twice the first." << "\n They have values of " << *(result2++); cout << " & " << *result2 << "." << endl; }

L = ( 50 40 10 20 20 ) There are two adjacent elements that are equal. They have a value of 20. There are two adjacent elements where the second is twice the first. They have values of 10 & 20.