If you want to use a type
T as an iterator, you must ensure that
std::iterator_traits can be specialized for that type. That means you either need to provide the five nested typedefs that it defers to by default, or you need to specialize
std::iterator_traits yourself. The five nested typedefs it requires are
difference_type, which is some type that can represent the distance between two iterators (e.g., as would be returned by
value_type, which is the type of the object pointed to by the iterator
pointer, which is the return type of the iterator type's
operator->. This doesn't necessarily need to be a pointer type and it doesn't necessarily need to be
value_type const*. For example, if you have an iterator that generates elements, you may not have an object to which you can return a pointer. In that case, you might return an object that wraps the returned element and overloads
reference, which is the return type of the iterator type's
operator*. This doesn't necessarily need to be a reference type and it doesn't necessarily need to be
value_type const&). For example, If you're iterating over an immutable range of integers, you might just return the element by value, for performance reasons.
iterator_category, which must be one of the iterator category tags or a type derived from one of those tags:
random_access_iterator_tag (all in namespace
std). Algorithms can use these to select an optimal algorithm based on the iterator category.
You can't omit any of these; they all have to be defined. That said, sometimes one or more of the typedefs may not make sense. For example, if you have an iterator that generates
char elements on the fly, your iterator may not implement
char is not a class type). In this case, you might consider just using
void for the
pointer type, since it should never be used anyway.