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I tried to write a short function to invert an std::map<K, V> (I know about boost.bimap, this is for self-education), and found, to my surprise, that the code that GCC 4.4 accepted with -pedantic -ansi settings was rejected as const-incorrect by SunCC (5.8, from 2005).

Since value_type is std::pair<const K, V>, SunCC insisted that I const-qualify my K type in the arguments to functions that are passed to transform() and for_each(), and in the type of the return value to be passed to std::inserter, as far as I can tell, it might be right? Which compiler was standards-compliant?

#include <iostream>
#include <iterator>
#include <map>
#include <string>
#include <algorithm>
template<typename K, typename V>
std::pair<V, K> flip_pair(const std::pair<K, V>& p) // GCC/MSVC
//std::pair<const V, K> flip_pair(const std::pair<const K, V>& p) // SunCC
     return std::make_pair(p.second, p.first); // GCC/MSVC
//     return std::pair<const V, K>(p.second, p.first); // SunCC
template<typename K, typename V>
std::multimap<V, K> invert_map(const std::map<K, V>& in)
     std::multimap<V, K> out;
     transform(in.begin(), in.end(), std::inserter(out, out.begin()),
               flip_pair<K, V>);
     return out;
void print_pair(const std::pair<int, std::string>& p) // GCC/MSVC
//void print_pair(const std::pair<const int, std::string>& p) // SunCC
        std::cout << p.first << '\t' << p.second << '\n';
int main()
     std::map<std::string, int> map;
     map["foo"] = 1; map["bar"] = 2; map["baz"] = 3;
     std::multimap<int, std::string> revmap = invert_map(map);
     for_each(revmap.begin(), revmap.end(), print_pair);
share|improve this question
Does that version of Sun's compiler support member template functions? If not, that might explain the absence of implicit conversion constructors template<typename A,typename B> template<typename C,typename D> std::pair<A,B>::pair(const std::pair<C,D>&);. – aschepler Oct 4 '10 at 17:55
@aschepler: That constructor is #defined out with _RWSTD_NO_MEMBER_TEMPLATES on my system, it turns out. But the same program compiles with -library=stlport4, which picks up a different set of includes. The compiler itself is not to blame, after all. – Cubbi Oct 4 '10 at 18:09
up vote 3 down vote accepted

Visual C++ and g++ are correct; this code (with flip_pair<K, V>() taking a const std::pair<K, V>&) is okay.

Inside of transform, flip_pair<K, V> is being called. Since the object being passed to that function is a pair<const K, V>, a temporary object of type pair<K, V> is created (pair has a converting constructor that allows you to convert one pair type to another if the .first and .second types are convertible).

This temporary is passed to flip_pair<K, V>(), taking advantage of the fact that a const reference can be bound to a temporary.

share|improve this answer
Doesn't creating a temporary pair<K,V> discard const qualifiers? Wouldn't it be more appropriate to just qualify the type as pair<const K, V> in those functions? – JoshD Oct 4 '10 at 17:51
@JoshD, the compiler would not discard qualifiers in the type. And the types in flip_pair<K, V> would be: flip_pair<std::map<K, V>::value_type::first_type, std::map<K, V>::value_type::second_type> which would expand out to: flip_pair<const std::map<K, V>::key_type, std::map<K, V>::mapped_type>. In other words, K is const K in the instantiation of flip_pair in invert_map, so the additional const qualifier is unnecessary. – MSN Oct 4 '10 at 17:56
Simple as always! Forgot all about that constructor, confused by the 'wrong type while instantiating' errors. – Cubbi Oct 4 '10 at 18:01
Ah, OK. Thanks for clearing up my confusion. – JoshD Oct 4 '10 at 18:06

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