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I have always assumed that std::lower_bound() runs in logarithmic time if I pass a pair of red-black tree iterators (set::iterator or map::iterator) to it. I had to burn myself twice to notice that std::lower_bound() runs in O(n) time in this case, at least with the libstdc++ implementation. I understand that the standard doesn't have the concept of red-black tree iterators; std::lower_bound() will treat them as bidirectional iterators and advance them in linear time. I still don't see any reason why the implementation couldn't create an implementation specific iterator tag for red-black tree iterators and call a specialized lower_bound() if the passed in iterators happen to be red-black tree iterators.

Is there any technical reason why std::lower_bound() is not specialized for red-black tree iterators?


UPDATE: Yes, I am aware of the find member functions but it is so not the point. (In a templated code I may not have access to the container or work only on a part of container.)


After the bounty has expired: I find Mehrdad's and Yakk's answers the most convincing. I couldn't decide between the too; I am giving the bounty to Mehrdad and accepting Yakk's answer.

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Tried the container method instead? –  Yakk Jan 5 at 14:30
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Not the point. Beside, in templated code you may not work access the container / work on the whole container. –  Ali Jan 5 at 14:31
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I think it's possible to supply a predicate that is not equivalent to the one supplied to std::set and still fulfil the requirement of partially sorted (for special sets). So you can only replace the lower_bound algorithm by a special red-black version if the predicate is equivalent to the std::set ordering. –  dyp Jan 5 at 14:34
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@dyp technically it just needs to agree on the elements in the given range. –  Yakk Jan 5 at 14:49
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+1 You have gained enough upvotes - so we approve you: go and patch the library! :-) Because the only real reason is that nobody did it yet. –  TMS Jan 7 at 16:17

5 Answers 5

up vote 5 down vote accepted

There is no technical reason why this could not be implemented.

To demonstrate, I will sketch out a way to implement this.

We add a new Iterator category, SkipableIterator. It is a subtype of BiDirectionalIterator and a supertype of RandomAccessIterator.

SkipableIterators guarantee that the function between done in a context where std::between is visible works.

template<typeanme SkipableIterator>
SkipableIterator between( SkipableIterator begin, SkipableIterator end )

between returns an iterator between begin and end. It returns end if and only if ++begin == end (end is right after begin).

Conceptually, between should efficiently find an element "about half way between" begin and end, but we should be careful to allow a randomized skip list or a balanced red black tree to both work.

Random access iterators have a really simple implementation of between -- return (begin + ((end-begin)+1)/2;

Adding a new tag is also easy. Derivation makes existing code work well so long as they properly used tag dispatching (and did not explicitly specialize), but there is a small concern of breakage here. We could have "tag versions" where iterator_category_2 is a refinement of iterator_category (or soemthing less hacky), or we could use a completely different mechanism to talk about skipable iterators (an independent iterator trait?).

Once we have this ability, we can write a fast ordered searching algorithms that works on map/set and multi. It would also work on a skip list container like QList. It might be even the same implementation as the random access version!

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What asymptotic runtime does between have for tree iterators? (And how is it used to implement a binary search? Is is just a replacement for distance+advance?) –  dyp Jan 6 at 12:42
    
@DyP: Probably amortized or expected O(log(distance(begin, end))). –  Mehrdad Jan 6 at 19:23
    
@DyP All that matters is that between is faster than distance+advance amortized, which should be easy in O notation scale for a balanced binary bidirectional iterable tree. Ideally, you'd mimic set::lower_bound's search order. The point is that sometimes between is much faster than advance, as advance says "I want to move exactly so far", when all we want to do is move about half way to the end. (Note that if the tree was fast indexable (each node tracked count of children, say), a log-speed advance could be implemented) –  Yakk Jan 6 at 19:32
    
Hmm... To me that sounds like lower_bound with SkipableIterators is still asymptotically slower than set::find, something like O(logN * logN), as each step in the binary search requires a between, which is O(logN) (that N is halfed for each step, but that seems not to matter asymptotically). That's better than lower_bound with a O(N) advance, but still wouldn't make the member function obsolete. Or did you have a different algorithm in mind? –  dyp Jan 6 at 20:08
    
@DyP you might be able to reach amortized constant time on recursive calls to zero size: track how you'd walk a (somewhat) balanced binary tree. There may be a constant factor that a member could pull off (because it knows it starts with the entire tree). (The note about log-speed advance was a side note, not how I'd expect between to be implemented: between explicitly does not care about where it ends up exactly, while advance may have to descend needlessly down the tree to find the exact spot it wants to be) –  Yakk Jan 6 at 20:40

There are multiple reasons:

  1. When using the non-member version a different predicate can be used. In fact, a different predicate has to be used when using, e.g., a std::map<K, V> as the map predicate operates on Ks while the range operates on pairs of K and V.
  2. Even if the predicate is compatible, the function has an interface using a pair of nodes somewhere in the tree rather than the root node which would be needed for an efficient search. Although it is likely that there are parent pointers, requiring so for the tree seems inappropriate.
  3. The iterators provided to the algorithm are not required to be the t.begin() and the t.end() of the tree. They can be somewhere in the tree, making the use of the tree structure potentially inefficient.
  4. The standard library doesn't have a tree abstraction or algorithms operating on trees. Although the associative ordered containers are [probably] implemented using trees the corresponding algorithms are not exposed for general use.

The part I consider questionable is the use of a generic name for an algorithm which has linear complexity with bidirectional iterators and logarithmic complexity with random access iterators (I understand that the number of comparisons has logarithmic complexity in both cases and that the movements are considered to be fast).

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"The part I consider questionable" -- even worse, std::advance uses the same name for an algorithm that has linear complexity with bidirectional iterators and constant complexity with random-access ;-p –  Steve Jessop Jan 5 at 16:57
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@SteveJessop std::advance() is not confusing for me: It is always as fast as possible. std::lower_bound() is different as it is possible to implement it in logarithmic time with red-black tree iterators, yet it runs in linear time. Ouch! –  Ali Jan 5 at 17:09
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@Ali: Not really, std::advance is not "always as fast as possible". If you used ADL to call it (i.e. using std::advance; advance(i, d);) then it might have been. But at the moment, std::advance does not use operator+= unless the iterator is random-access. That's inefficient: consider a concat_iterator, which iterators over the concatenation of a bunch of ranges. operator++ would be much slower there than operator+= because the latter can skip entire ranges, but the iterator could not possibly offer the random-access guarantee so std::advance would be inefficient. –  Mehrdad Jan 5 at 22:22
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@Ali: I personally think ADL should be used for calling all C++ algorithms for reasons like this one -- but I feel like I'm the only one who believe this is necessary or a good idea, so I don't actually end up doing it in practice either. :( I think C++ would provide much better abstractions if ADL was used properly for algorithms, though. –  Mehrdad Jan 5 at 22:24
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@SteveJessop: I don't think considering algorithms customization points is the right approach. There are a couple of customization pointers, e.g., the operators, swap(), advance(), distance(), and maybe a handful of others. Not everything which is a function template is a suitable customization point, though. In fact, I'd rather go the opposite way and nail certain algorithms to not be candidates looked up via ADL by making them function objects (which would have the added advantage that you could easily bind them even if you don't know the arguments, yet). –  Dietmar Kühl Jan 6 at 23:46

Great question. I honestly think there's no good/convincing/objective reason for this.

Almost all the reasons I see here (e.g. the predicate requirement) are non-issues to me. They might be inconvenient to solve, but they're perfectly solvable (e.g. just require a typedef to distinguish predicates).

The most convincing reason I see in the topmost answer is:

Although it is likely that there are parent pointers, requiring so for the tree seems inappropriate.

However, I think it's perfectly reasonable to assume parent pointers are implemented.

Why? Because the time complexity of set::insert(iterator, value) is guaranteed to be amortized constant time if the iterator points to the correct location.

Consider that:

  1. The tree must stay self-balancing.
  2. Keeping a tree balanced requires looking at the parent node at every modification.

How can you possibly avoid storing parent pointers here?

Without parent pointers, in order to ensure the tree is balanced after the insertion, the tree must be traversed starting from the root every single time, which is certainly not amortized constant time.

I obviously can't mathematically prove there exists no data structure that can provide this guarantee, so there's clearly the possibility that I'm wrong and this is possible.
However, in the absence of such data structures, what I'm saying is that this is a reasonable assumption, given by the fact that all the implementations of set and map I've seen are in fact red-black trees.


Side note, but note that we simply couldn't partially-specialize functions (like lower_bound) in C++03.
But that's not really a problem because we could have just specialized a type instead, and forwarded the call to a member function of that type.

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A quick google search shows that there are RB trees out there without parent pointer but their superiority is questionable, see for example Left-Leaning Red-Black Trees Considered Harmful. So assuming parent pointers is quite reasonable. OK, so the only real issue I see is the case when the predicate has data members: DyP says that in this case we need access to the container. Any thoughts on that? –  Ali Jan 6 at 0:01
    
@Ali: Oh I certainly did not mean that all RB trees I'd seen use parent pointers! That's certainly not the case -- in fact, I've seen that link before. What I meant was that all implementations of std::map or std::sets I had seen use parent pointers because they need to provide the O(1) amortized time complexity guarantee when the iterator is given, and I don't think they can do so otherwise. A generic RB tree need not satisfy this. Regarding the predicate -- yes, that requires the nodes to hold pointers back to their containers, but there's nothing (?) preventing that is there? –  Mehrdad Jan 6 at 0:39
    
@Ali: Alternatively the comparator could be stored elsewhere on the heap to avoid issues when containers are swapped, if necessary. –  Mehrdad Jan 6 at 0:41
    
It can be done otherwise; the iterator itself could maintain a store of the nodes it's already gone through, similar to a naive recursive tree walk. I've seen this method used several times when the tree is large and the number of iterators is small. I would not be surprised to see such an implementation in a high performance STL-like library, as it makes lock-free implementations easier and optimizes for the normal case of low iterators. –  Alice Jan 8 at 20:30
    
@Alice: Wait what do you mean? Doesn't that require O(n) storage inside each iterator which is pretty expensive? Also, doesn't that mean the iterators will get invalidated once the parent of a right-child node is erased? –  Mehrdad Jan 10 at 19:00

(Elaborating on a comment)

I think it's possible to supply a predicate that is not equivalent to the one supplied to std::set and still fulfil the requirement of partially sorted (for special sets). So you can only replace the lower_bound algorithm by a special red-black version if the predicate is equivalent to the std::set ordering.

Example:

#include <utility>
#include <algorithm>
#include <set>
#include <iostream>

struct ipair : std::pair<int,int>
{
    using pair::pair;
};

bool operator<(ipair const& l, ipair const& r)
{  return l.first < r.first;  }

struct comp2nd
{
    bool operator()(ipair const& l, ipair const& r) const
    {  return l.second > r.second; /* note the > */ }
};

std::ostream& operator<<(std::ostream& o, ipair const& e)
{  return o << "[" << e.first << "," << e.second << "]";  }

int main()
{
    std::set<ipair, comp2nd> my_set = {{0,4}, {1,3}, {2,2}, {3,1}, {4,0}};
    for(auto const& e : my_set) std::cout << e << ", ";

    std::cout << "\n\n";

    // my_set is sorted wrt ::operator<(ipair const&, ipair const&)
    //        and       wrt comp2nd
    std::cout << std::is_sorted(my_set.cbegin(), my_set.cend()) << "\n";
    std::cout << std::is_sorted(my_set.cbegin(), my_set.cend(),
                                comp2nd()) << "\n";

    std::cout << "\n\n";

    // implicitly using operator<
    auto res = std::lower_bound(my_set.cbegin(), my_set.cend(), ipair{3, -1});
    std::cout << *res;

    std::cout << "\n\n";

    auto res2 = std::lower_bound(my_set.cbegin(), my_set.cend(), ipair{-1, 3},
                                 comp2nd());
    std::cout << *res2;
}

Output:

[0,4], [1,3], [2,2], [3,1], [4,0], 

1
1

[3,1]

[1,3]
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Of course, you can still provide some mechanism to dispatch the lower_bound to a red-black version if the used predicate is equivalent to the std::set::key_comp() –  dyp Jan 5 at 14:52
    
Thanks. I should have made it clear in the question that I assume that the lower_bound() and the set use the same predicate. –  Ali Jan 5 at 14:53
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@Ali You'd still had to check that, I think. So you can't just use a general tag-dispatch for red-black iterators (in my edited example, you'll see that the default predicate chosen by lower_bound can be different from the predicate of the set as well; even if you don't supply a non-default predicate to set, name lookup might differ). –  dyp Jan 5 at 14:57
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I think it is the user's responsibility to provide lower_bound with the correct predicate. If the user messes up, there is nothing we can do. I simply can't decide whether your example isn't an example of a user's mistake. –  Ali Jan 5 at 15:01
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@Ali As Dietmar Kühl says, it might be possible to get O(logN) runtime if there are parent pointers. Checking the equivalence of the predicate does require access to the container if the comparison is non-trivial (imagine a predicate function object with data members). The type of the predicate can be embedded in the type of iterator, though (that should be sufficient for std::less and other stateless predicates). It might also be impossible to check for equivalence (predicate needed to be EqualityComparable). –  dyp Jan 5 at 23:35

Here's a very simple non-technical reason: It's not required by the standard, and any future change will break backwards compatibility with existing compiled code for no reason.

Wind the clock back to the early 2000's, during the transition between GCC and GCC 3, and later, during minor revisions of GCC 3. Many of the projects I worked on were meant to be binary compatible; we could not require the user to recompile our programs or plugins, and neither could we be certain of the version of GCC they were compiled on or the version of the STL they were compiled against.

The solution: don't use the STL. We had in-house strings, vectors, and tries rather than using the STL. The solution to the dependency hell introduced by an ostensibly standard part of the language was so great, that we abandoned it. Not in just one or two projects either.

This problem has largely gone away, thankfully, and libraries such as boost have stepped in to provide include only versions of the STL containers. In GCC 4, I would see no issue with using standard STL containers, and indeed, binary compatibility is much easier, largely due to standardization efforts.

But your change would introduce a new, unspoken, dependency

Suppose tomorrow, a new data structure comes out, which substantially beats red black trees, but does not provide the guarantee that some specialized iterators are available. One such implementation that was very popular just a few years ago was the skip list, which offered the same guarantees at a possibly substantially smaller memory footprint. The skip list didn't seem to pan out, but another data structure very well could. My personal preference is to use tries, which offer substantially better cache performance and more robust algorithmic performance; their iterators would be substantially different from a red black trees, should someone in the libstdc++ decide that these structures offer better all around performance for most usages.

By following the standard strictly, binary backwards compatibility can be maintained even in the face of data structure changes. This is a Good Thing (TM) for a library meant to be used dynamically. For one that would be used statically, such as the Boost Container library, I would not bat an eye if such optimizations were both well implemented and well used.

But for a dynamic library such as libstdc++, binary backwards compatibility is much more important.

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Would a change in an algorithm (template) make binaries incompatible? –  dyp Jan 8 at 20:58
    
It depends on the implementation of the dynamic link. Some parts of the library (the template, for example) will be in the linking program, while others (the implementation of the underlying structure) will not be. Suppose the template is a wrapper, which wraps generic calls to an underlying datastructure that uses void*'s in the shared library (a common way to reduce bloat allowed by the standard). If the compiled in template refers to iterators that are now not used in the shared library, we have a breaking change. The standard is policy, not implementation, for this very reason. –  Alice Jan 8 at 21:22
    
I should point out, this is a fundamental conflict between generics and objects, which is solved through a primitive form of type erasure; either vector<int> and vector<string> are fundamentally different classes and thus no code can be shared between them, or some form of type erasure must occur and "vector" of any instantiate can share code. The first is clearly what happens in a header include only static library (like boost container), and the second is what we would prefer in a dynamic library, like libstdc++. –  Alice Jan 8 at 21:30

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