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I am trying to compile the following code using clang but got the following error.

I am wondering why using sort from the list class would work, but not std::sort.

#include <list>
#include <iostream>

int main(){
    std::string strings[] = {"hello", "nihao", "byebye", "yo"};
    std::list<std::string> cars(strings, strings+sizeof(strings) / sizeof(char **));

    // cars.sort(std::less<std::string>()); // compiles fine and produce a sorted list

    std::sort(cars.rbegin(), cars.rend(), std::less<std::string>() ); // this one won't compile

    for (std::list<std::string>::iterator it = cars.begin(); it != cars.end(); ++it)
        std::cout << *it << " - ";

    std::cout << std::endl;
    return 0;
}

/usr/include/c++/4.2.1/bits/stl_iterator.h:320:25: error: invalid operands to binary expression ('iterator_type' (aka 'std::_List_iterator >') and 'iterator_type') { return __y.base() - __x.base(); }

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possible duplicate of Sort list using stl sort function –  Christian Rau Nov 5 '11 at 0:23
    
Mostly that std::sort won't work on std::list. –  K-ballo Nov 5 '11 at 0:55

1 Answer 1

up vote 7 down vote accepted

std::sort requires random access iterators, which std::list does not provide. Consequently, std::list and std::forward_list implement their own member functions for sorting which work with their weaker iterators. The complexity guarantees of those member functions are worse than those of the more efficient general algorithm.[Whoops: see comments.]

Moreover, the member functions can take advantage of the special nature of the list data structure by simply relinking the list nodes, while the standard algorithm has to perform something like swap (or something to that effect), which requires object construction, assignment and deletion.

Note that remove() is a similar case: The standard algorithm is merely some iterator-returning rearrangement, while the list member function performs the lookup and actual removal all in one go; again thanks to being able to take advantage of the knowledge of the list's internal structure.

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The complexity guarantees are not worse. The member functions are "approximately N log N comparisons", whereas the algorithm is "O(N log N) comparisons". This is as you'd expect considering that the member functions are going to use merge sort, and std::sort is likely to use some kind of intro-sort, falling back to heapsort. –  Steve Jessop Nov 5 '11 at 0:35
    
@Steve: Ah, indeed, a flat-out misconception on my part. The standard does say though that the list function uses N log N comparisons, while the standard algorithm is "O(N log N)". Same asymptotics, but I suppose the constants are worse for the list version. –  Kerrek SB Nov 5 '11 at 0:51
    
Maybe the constants are worse, but remember that the standard complexity guarantees only care about number of comparisons, whereas one of the major performance factors when comparing merge/quick/heapsorts is locality of reference. So the constants applied to the comparison part of it aren't necessarily the major performance issue. I don't know what the worst-case number of comparisons is for heapsort, whether it's more or less than N log N, but N log N is the worst case for mergesort. And of course the expected case of introsort is overall faster runtime than the expected case of heapsort. –  Steve Jessop Nov 5 '11 at 1:02
    
@SteveJessop: I'd imagine that simply because you need to walk the iterators one by one you'll have a greater overall overhead factor, no matter which specific algorithm -- though perhaps I'm now confusing binary searching with sorting. Maybe the advantage of random access iterators isn't actually that great after all... –  Kerrek SB Nov 5 '11 at 1:04
    
Merge sort also does approximately N log N iterator increment operations (in fact, it does one increment per comparison, for fairly simple reasons), which is fine, although the locality depends entirely on how the list was constructed and vagaries of the allocator. The reason merge sort is so terrific for linked lists is just that it requires no extra memory, whereas merging arrays does. As with any sorting algorithm, to get a feel for it perform it manually on a deck of cards - you don't feel that you're missing random-access iterators :-) –  Steve Jessop Nov 5 '11 at 1:10

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