# Turn a multimap into set of sets

I have a multimap and I would like to get a set of sets - which would group together all the items of type A in the multimap that share the same key. Is there a built-in way to do this in STL?

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No easy way, not even using STL algorithms. You need to code it manually. – Let_Me_Be Nov 9 '10 at 11:13
Why not trying a `std::map<key, std::vector<value>>` first ? `set` can be difficult to use because its elements are necessarily `const`... – Matthieu M. Nov 9 '10 at 13:10
You probably mean a map of sets. A set element has to be comparable with operator< and can you really say one set is less than another? – CashCow Nov 9 '10 at 15:10
@CashCow isn't set an unordered group of elements? – Amir Rachum Nov 9 '10 at 15:11
No, std::set is ordered. The difference between set and map is that map has unique keys with an associated value whereas in set the key and value are one and the same. – CashCow Nov 10 '10 at 9:27

I don't think there is a built-in way. However it is easy to do manually:

``````std::multimap<key, value> mm;
// ...
std::multimap<key, value>::const_iterator i = mm.begin();
while (i != mm.end())
{
std::multimap<key, value>::const_iterator end = mm.upper_bound(i->first);
// construct a set from the values in [i, end)
i = end;
}
``````

Or something like that.

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This solution works well if you have few unique values in you original multi-map. This is O(M log N) where M is the number of unique values and N is the whole size of the multimap. So if you have 1,048,576 values and 1024 unique ones (thus we are going to create 1024 entries of 1024 each) this is 20K comparisons compared to O(N) you get traversing the original list (although you still need to traverse all entries for insertion into your std::sets) – CashCow Nov 10 '10 at 11:01

You could use a set on a pair.

First you define the pair. The pair needs the key as first element and your instance as second element.

E.g. suppose we have a collection of books and we want to group them by author:

``````typedef std::pair<Author *,Book *> AuthorBookPair;
``````

Then you define a set on this pair:

``````typedef set<AuthorBookPair> BooksGroupedByAuthor;
``````

Filling the set can be done like this:

``````BooksGroupedByAuthor books;
books.insert (std::make_pair(book1->getAuthor(),book1));
books.insert (std::make_pair(book2->getAuthor(),book2));
books.insert (std::make_pair(book3->getAuthor(),book3));
books.insert (std::make_pair(book4->getAuthor(),book4));
``````

You can now simply look up books of an author using the lower_bound and upper_bound methods:

``````#define POINTER_SMALLEST 0x00000000
#define POINTER_LARGEST  0xffffffff

BooksGroupedByAuthor::const_iterator lowerbound = books.lower_bound(std::make_pair(myFavoriteAuthor,POINTER_POINTER));
BooksGroupedByAuthor::const_iterator upperbound = books.upper_bound(std::make_pair(myFavoriteAuthor,POINTER_POINTER));
``````

Now simply iterate between lowerbound and upperbound to get all the books from this author.

This trick relies on the fact that I chose to store pointers to books, and that I know what the smallest and the largest pointer is (for 64-bit apps you will have to change this !). I must admit this is not the nicest trick.

A slightly better alternative would be to store the books themselves (if it is allowed in your application to make copies of these instances) and make 2 specific instances of Book that represent the 'smallest book' and the 'largest book' respectively.

The nice thing about this trick is that it allows adding more dimensions if needed. E.g. you could add the year as a second dimension, and then choose to look up books from an author only, or looking up books from an author in a specific year. When using more dimensions, the tuples from the new C++0x may become handy.

This trick also has the advantage that it protects you from adding a book twice. If a book is added twice, it will still be once in the collection (if we assume that the author of the book never changes). If you would use a multi_map, you could add the same book twice, which is probably not wanted.

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You could do something along the lines of (but with more appropriate names) the following. Note that the output structure is actually a map of sets rather than a set of set because that way you retain the keys.

``````#include <map>
#include <set>

template <class key_t, class value_t>
struct transform_fn {
typedef std::multimap<key_t, value_t> src_t;
typedef std::map<key_t, std::set<value_t> > dest_t;

dest_t operator()(src_t const& src) const
{
dest_t dest;
typedef typename src_t::const_iterator iter_t;
for (iter_t i = src.begin(), e = src.end(); i != e; ++i) {
dest[i->first].insert(i->second);
}
return dest;
}
};

#include <string>

int
main()
{
typedef std::multimap<std::string, int> some_map_t;
typedef std::map<std::string, std::set<int> > tr_some_map_t;

some_map_t src;
transform_fn<std::string, int> tr;
tr_some_map_t dest = tr(src);

return 0;
}
``````
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This creates a map of sets. Set of sets doesn't really make sense.

for each element in your set you can do:

``````our_map[iter->first].insert(iter->second);
``````

if you have iterators or

``````our_map[p.first].insert(p.second);
``````

with value_type pairs.

Either way, operator[] on outer_set will create an empty inner set if iter->first is not found and will retrieve the existing one if the key already exists.

This will work but will not be the most efficient way to do it. The reason is that we know that p.first either matches the last key we saw or we must insert at the end, but the above is doing a lookup every time. Thus a more efficient way is to hold on to our set iterator. value_type here is the value type of our multimap

``````BOOST_FOREACH( elt, our_multimap )
{
if( our_map.empty() || elt.key != last_key )
{
last_key = elt.key;
map_iter = our_map.insert(
std::make_pair<elt.key, std::set<value_type>(),
our_map.end() ).first;
}
our_iter->insert( elt.value );
}
``````

Note we are capturing the iterator as we insert, it is the first of the pair returned by std::map.

If you don't want to work with iterators you can use a pointer to a std::set like this.

``````std::set<value_type> *p_set = NULL;
key_type last_key;
BOOST_FOREACH( elt, our_multimap )
{
if( !p_set || elt.key != last_key )
{
last_key = elt.key;
p_set = &our_map[elt.key];
}
p_set->insert( elt.value );
}
``````

This still has the advantage of not having to look up when we hit a duplicate key, but has the disadvantage that we can't pass a "hint" to operator[] like we could to insert.

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