Preamble with plenty of Standardese
The call to
swap() in the example entails a dependent name because its arguments
begin depend on the template parameter
T of the surrounding
algorithm() function template. Two-phase name lookup for such dependent names is defined in the Standard as follows:
184.108.40.206 Candidate functions [temp.dep.candidate]
1 For a function call where the postﬁx-expression is a dependent name,
the candidate functions are found using the usual lookup rules (3.4.1,
3.4.2) except that:
— For the part of the lookup using unqualiﬁed name lookup (3.4.1), only function declarations from the template deﬁnition
context are found.
— For the part of the lookup using associated
namespaces (3.4.2), only function declarations found in either the
template deﬁnition context or the template instantiation context are
Unqualified lookup is defined by
3.4.1 Unqualiﬁed name lookup [basic.lookup.unqual]
1 In all the cases listed in 3.4.1, the scopes are searched for a
declaration in the order listed in each of the respective categories;
name lookup ends as soon as a declaration is found for the name. If no
declaration is found, the program is ill-formed.
and argument-dependent lookup (ADL) as
3.4.2 Argument-dependent name lookup [basic.lookup.argdep]
1 When the postfix-expression in a function call (5.2.2) is an
unqualified-id, other namespaces not considered during the usual
unqualified lookup (3.4.1) may be searched, and in those namespaces,
namespace-scope friend function or function template declarations
(11.3) not otherwise visible may be found. These modifications to the
search depend on the types of the arguments (and for template template
arguments, the namespace of the template argument).
Applying the Standard to the example
The first example calls
exp::swap(). This is not a dependent name and does not require two-phase name lookup. Because the call to swap is qualified, ordinary lookup takes place which finds only the generic
swap(T&, T&) function template.
The second example (what @HowardHinnant calls "the modern solution") calls
swap() and also has an overload
swap(A&, A&) in the same namespace as where
class A lives (the global namespace in this case). Because the call to swap is unqualified, both ordinary lookup and ADL take place at the point of definition (again only finding the generic
swap(T&, T&)) but another ADL takes place at the point of instantiation (i.e where
exp::algorithm() is being called in
main()) and this picks up
swap(A&, A&) which is a better match during overload resolution.
So far so good. Now for the encore: the third example calls
swap() and has a specialization
template<> swap(A&, A&) inside
namespace exp. The lookup is the same as in the second example, but now ADL does not pick up the template specialization because it is not in an associated namespace of
class A. However, even though the specialization
template<> swap(A&, A&) does not play a role during overload resolution, it is still instantiated at the point of use.
Finally, the fourth example calls
swap() and has an overload
template<class T> swap(A<T>&, A<T>&) inside
namespace exp for
template<class T> class A living in the global namespace. The lookup is the same as in the third example, and again ADL does not pick up the overload
swap(A<T>&, A<T>&) because it is not in an associated namespace of the class template
A<T>. And in this case, there is also no specialization that has to be instantiated at the point of use, so the generic
swap(T&, T&) is being callled here.
Even though you are not allowed to add new overloads to
namespace std, and only explicit specializations, it would not even work because of the various intricacies of two-phase name lookup.