The hashtable and map is hashtable is implemented as a hash function but map is implemented as a tree.
My question is, in what situation, hashtable can not be used but a map is a must?
The hashtable and map is hashtable is implemented as a hash function but map is implemented as a tree. My question is, in what situation, hashtable can not be used but a map is a must? 


One motivation for choosing to use a map over a hashtable is the constraints which each one places on the key type used in the template instantiation. As described in the documentation for hash_map in the SGI implementation of STL, an instantiation hash_map requires provision of a functor which hashes K. The STL includes a functor, std::hash, which does this, but it is only implemented for a limited set of types T. Instantiation of std::map on the other hand only requires a functor which compares objects of type K to generate a weak ordering. The standard functor std::less will work for any T which defines an operator<. This means that, for many userdefined types, adding the support necessary to use the type as a key in a std::map is much less than that required to use it in a std::hash_map. Aside from the question of overhead,



There are a number of potential reasons.



The runtime characteristics are different: A treebased map always has a runtime (worst case, average case) in the order of O(log n), i.e. the height of the (balanced) binary search tree. Hash maps, on the other hand, have a much more complicated runtime behaviour. But in the usual case, a hash table has an expected runtime of O(1), i.e. constant overhead. In general, the worst case is O(n), which sounds bad. However, it can be shown that for a good choice of parameters, this worst case gets so rare as to not play a role in practice. “Rare” here means really rare, as in winning the lottery ten times in a row and then being killed by a comet. In practice, a bad choice of parameters (hashing technique, load factor …) can raise this probability considerably. 


When you depends on that the keys are sorted. 


I'm going to answer with regard to std::unordered_map (hashtable) and std::map (tree). Note that neither of these actually specify implementation mechanisms. Basically, you use map when you need to access the keys in sorted order, and unordered_map otherwise. 


If you need to find the 'next' item in the data structure, a hashtable cannot be used because it doesn't keep items in a traversable order. 

