Ok, an index normally tells you what the nth sorted element of a vector is. But this is going to do the reverse, thus it will tell you that the nth element in your vector is the mth in sorted order.

This is being done by creating a vector of indices on your non-sorted vector. You can still create a sorted copy or an index, of course.

We start off with a predicate for which a < b if v[a] < v[b]

```
template< typename T >
class PredByIndex
{
private:
std::vector< T > const & theColl;
public:
PredByIndex( std::vector<T> const& coll ) : theColl( coll )
{
}
bool operator()( size_t i, size_t j ) const
{
return theColl[i] < theColl[j];
}
};
template< typename T >
void makeOrdered( std::vector< T > const& input, std::vector< size_t > & order )
{
order.clear();
size_t len = input.size();
order.reserve( len );
for( size_t i = 0; i < len; ++i )
{
order.push_back( i );
}
PredByIndex<T> pred( input );
std::sort( order.begin(), order.end(), pred );
}
```

And now "order" will have the ordinal position in the ordered collection.

Of course in C++11 the predicate could be written as a lambda expression rather than having to create the class PredByIndex.

We are not done yet though. We now have an index, not a "find me in the sorted vector". However we can `transpose`

our index as follows:

```
void transpose_index( std::vector< size_t > const & index,
std::vector< size_t > & trans )
{
// for this to work, index must contain each value from 0 to N-1 exactly once.
size_t size = index.size();
trans.resize( index.size() );
for( size_t i = 0; i < size; ++i )
{
assert( index[i] < size );
// for further assert, you could initialize all values of trans to size
// then as we go along, ensure they still hold that value before
// assigning
trans[ index[i] ] = i;
}
```

}

Now our transposed index gives you what you want, and the transpose itself is `O(N)`

In a slightly different example of data, if the inputs are `[ 5, 3, 11, 7, 2 ]`

The "sorted" order is `[ 2, 3, 5, 7, 11 ]`

The "index" order is `[4, 1, 0, 3, 2]`

i.e. element 4 is the smallest, then element 1 etc.

The "transpose" order, as we fill it in

```
[ _, _, _, _, _ ]
[ _, _, _, _, 0 ]
[ _, 1, _, _, 0 ]
[ 2, 1, _, _, 0 ]
[ 2, 1, _, 3, 0 ]
[ 2, 1, 4, 3, 0 ]
```

This looks like what we want. Our original data 5 is position 2, 3 is position 1, 11 is position 4 etc in the sorted data.