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I've been frustrated by the unhandiness of stl iterators and am looking for something more usable. In particular, a concept that is easier to map and filter, and one that is easier to implement too: basically C#/python/ruby/everything-but-C++ style enumerations.

I came across Andrei Alexandrescu's Iterator's must go! boostcon keynote of 2009 in which he describes a range concept that pretty much is exactly what I'm looking for and much more.

Does anybody know if something like this was actually implemented? I know of boost::range, but that's not an ideal solution; it's implemented in terms of iterators (which is more confusing and complex, less efficient, less general, and makes writing your own one at least as messy as implementing an iterator). Still, it's better than nothing. Is there anything better out there?

Edit: there's been lot's of discussion as to why this is at all attractive. On iteration explains the motivation more clearly. I realize the link to D - but that shouldn't distract from the argument itself.

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I suggest you to be more skeptical about Andrei's presentation, he has his own motives. I agree that he makes some good points, but Stepanov had his good points too. Ranges are not always intuitive. Most of your claims regarding boost ranges are unbased. Also remember that you cannot model your complex world much simpler than it is. –  ybungalobill Dec 29 '10 at 23:29
@ybungalobill: perhaps, but I'm fed up enough with iterators to give something else a shot. And boost::range really isn't quite it (I don't know what you mean with unbased): it requires you to implement iterators and thus maintain code for both iterators and ranges - and I'm looking for something simpler, not more complex. Finally, the fact that so many other languages have succeeded using range-like concepts is a good hint that this isn't some far-out there impractical concept. I'm looking for C++ enumerators (not iterators), and andrei presented something even better: what's not to like? –  Eamon Nerbonne Dec 30 '10 at 11:58
@Eamon, why would ranges be simpler than iterators? Even if you don't implement them as 2 iterators they are still basically 2 const iterators. They could be more convenient to use in certain cases, but is there a reason why their non-iterator implementation would be simpler than an iterator-based one? –  Roman L Dec 30 '10 at 14:37
I don't agree with you all: iterators are flexible. –  Alexandre C. Dec 30 '10 at 15:57
@Eamon Nerbonne: iterator transforms (filtering, composing with a function, taking member pointers to the result...) and "special" output iterators (which forget all but last of what you give to them, or store a modified/filtered version) are precisely what makes them flexible. What is not flexible is the iterator classes of the standard: ie. no way to distinguish between rvalue/lvalue iterators. I found a C++0x proposal to address this issue though. With auto and lambda, they are a great tool to enhance C++ with runtime efficient expressive functional constructs. –  Alexandre C. Dec 30 '10 at 16:41

3 Answers 3

Seems pretty easy to do yourself -- assuming you don't mind a bit of work/typing

I haven't compiled this yet but something like this should move you a bit along

template< typename T>
class enumeration : boost::noncopyable {
virtual T& next() = 0;
virtual bool has_next() = 0;

template< typename T>
class editable_enumeration : public enumeration<T> {
virtual void remove() = 0;

//That was simple enough, now for adapting the std containers we
//will use the iterator interface already exposed. For new classes,
//we can implement iterators in any way we want. (e.g. copy python or java)

template < class C >
class const_std_enumeration : public enumeration<C::value_type>
C::const_iterator iter_;
C::const_iterator end_;

typedef C::value_type value_type;

const_std_enumeration( C const& c) :
iter_(c.begin()), end_(c.end()) { } //c++0x use std::begin(c), std::end(c) instead

virtual value_type& next() { if(iter_!=end_) return *iter_++; throw std::runtime_error("No more elements"); }
virtual bool has_next() { return iter_!=end_; }

template < class C>
class std_enumeration : public enumeration<C::value_type>
C& c_;
C::iterator iter_;
C::iterator end_;

typedef C::value_type value_type;

std_enumeration( C& c) :
c_(c), iter_(vector.begin()), end_(vector.end()) { }

virtual value_type& next() { if(v_!=end_) return *iter_++; throw std::runtime_error("No more elements"); }
virtual bool has_next() { return iter_!=end_; }
virtual remove() { iter_ = c_.erase(iter_); }

//Since we can't add methods to std containers, we will use an
//overloaded free-function `enumeration` to get enumerations from ANY container
//We could use `auto_ptr` or `unique_ptr`, but for simplicity's sake, I'm
//just using raw pointers

template < class C >
editable_enumeration<C::value_type>* enumeration( C&c ) { return new std_enumeration<C>(c); }

template < class C >
enumeration<C::value_type>* enumeration( C const& c ) { return new const_std_enumeration<C>(c); }

for all other containers, merely ensure that enumeration is defined and returns either an enumeration or editable_enumeration. If you other container already implements the iterator interface, then this should work

We can now write:

template<typename T>
bool contains( enumeration<T>* e, T const& t) {
  if ( t == e->next() )
    return true;
return false;
std::vector<int> v = getIntVector();
if( contains( enumeration(v), 10 ) ) std::cout<<"Enumeration contains 10\n";
std::list<int> l = getIntList();
if( contains( enumeration(l), 10 ) ) std::cout<<"Enumeration contains 10\n";

It should be noted one huge advantage the iterator concept holds over this is the case where the next element is requested when then has_next() would return false. For iterators, end()++ is (IIRC) undefined behavior. For teh enumeration, it is defined to throw std::runtime_error(...) which may be worse for some people.

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undefined behavior is not better than an exception: it's possibly an exception; or maybe an exception (or access violation) much later at nondeterministic time. –  Eamon Nerbonne Dec 30 '10 at 16:25
thanks for the implementation! This isn't what I'm looking for, however; such an undertaking would need to be part of a larger, tested, library. After all, large parts of algorithm need to be reimplemented, and high performance is not a given (in particularly, you're using virtual dispatch here). –  Eamon Nerbonne Dec 30 '10 at 17:53
Why are you returning enumerators by pointer instead of by value? That opens the door to memory leaks and unexpected behavior (contains isn't a read-only check, it modifies the range? highly counterintuitive!) –  Ben Voigt Dec 30 '10 at 19:00
@Eamon Nerbonne The reason I use virtual dispatch is to decouple the types (enumeration, editable_enumeration) from the containers they iterate over: Using OO design instead of generic algorithm design. IMO, if you want the high-efficiency, use iterators. –  KitsuneYMG Dec 30 '10 at 19:40
@Kitsune: I like your iterator-wrapper idea :-). You'd still want to reimplement the functions, even if it's just in terms of STL using the wrapper to clean up the api and tweak the semantics of a few functions to be more range-friendly. –  Eamon Nerbonne Dec 30 '10 at 21:24

May be this one will help you: .

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up vote 1 down vote accepted

It's been a few years, but it looks like there's a library out there that implements proper functional style sequences now: C++ Streams.

Code sample from the project's homepage:

Summing the first 10 squares:

int total = stream::MakeStream::counter(1)
    .map([] (int x) { return x * x; })
share|improve this answer
Although ranges like in D also forward random access and the other traits where possible, which guarantees better performance in some cases. –  Sebastian Mar 26 at 16:38

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