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I've got some example Python code that I need to mimic in C++. I do not require any specific solution (such as co-routine based yield solutions, although they would be acceptable answers as well), I simply need to reproduce the semantics in some manner.


This is a basic sequence generator, clearly too large to store a materialized version.

def pair_sequence():
    for i in range(2**32):
        for j in range(2**32):
            yield (i, j)

The goal is to maintain two instances of the sequence above, and iterate over them in semi-lockstep, but in chunks. In the example below the first_pass uses the sequence of pairs to initialize the buffer, and the second_pass regenerates the same exact sequence and processes the buffer again.

def run():
    seq1 = pair_sequence()
    seq2 = pair_sequence()

    buffer = [0] * 1000
    first_pass(seq1, buffer)
    second_pass(seq2, buffer)
    ... repeat ...


The only thing I can find for a solution in C++ is to mimic yield with C++ coroutines, but I haven't found any good reference on how to do this. I'm also interested in alternative (non general) solutions for this problem. I do not have enough memory budget to keep a copy of the sequence between passes.

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As you can see from here stackoverflow.com/questions/3864410/… coroutine is not good idea to implement. Can't you do it with buffered reading? stackoverflow.com/questions/4685862/… –  batbaatar Jan 30 '12 at 4:11
C++ iterators should support something like this. –  Lalaland Jan 30 '12 at 5:28
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6 Answers

up vote 13 down vote accepted

Generators exist in C++, just under another name: Input Iterators. For example, reading from std::cin is similar to having a generator of char.

You simply need to understand what a generator does:

  • there is a blob of data: the local variables define a state
  • there is an init method
  • there is a "next" method
  • there is a way to signal termination

In your trivial example, it's easy enough. Conceptually:

struct State { unsigned i, j; };

State make();

void next(State&);

bool isDone(State const&);

Of course, we wrap this as a proper class:

class PairSequence {
  typedef void (PairSequence::*BoolLike)();
  void non_comparable();
  typedef std::input_iterator_tag iterator_category;
  typedef std::pair<unsigned, unsigned> value_type;
  typedef value_type const& reference;
  typedef value_type const* pointer;
  typedef ptrdiff_t difference_type;

  PairSequence(): done(false) {}

  // Safe Bool idiom
  operator BoolLike() const {
    return done ? nullptr : &PairSequence::non_comparable;

  reference operator*() const { return ij; }
  pointer operator->() const { return &ij; }

  PairSequence& operator++() {
    static unsigned const Max = std::numeric_limts<unsigned>::max();


    if (ij.second != Max) { ++ij.second; return *this; }
    if (ij.first != Max) { ij.second = 0; ++ij.first; return *this; }

    done = true;
    return *this;

  PairSequence operator++(int) {
    PairSequence const tmp(*this);
    return tmp;

  bool done;
  value_type ij;

So hum yeah... might be that C++ is a tad more verbose :)

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I accepted your answer (thanks!) because it is technically correct for the question i gave. Do you have any pointers for techniques in cases where the sequence that needs to be generated is more complex, or am I just beating a dead horse here with C++ and really coroutines are the only way for generality? –  Noah Watkins Jan 30 '12 at 15:31
@NoahWatkins: coroutines make for an easy implementation when languages support them. Unfortunately C++ does not, so iteration is easier. If you really need coroutines, you actually need a full-blown thread to hold the "stack" of your function call on the side. It's definitely overkill to open such a can of worms just for that in this example, but your mileage may vary depending on your actual needs. –  Matthieu M. Jan 30 '12 at 15:46
Thanks for the note. I think I can cobble something together with your iterator approach! –  Noah Watkins Jan 30 '12 at 15:49
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In C++ there are iterators, but implementing an iterator isn't straightforward: one has to consult the iterator concepts and carefully design the new iterator class to implement them. Thankfully, Boost has an iterator_facade template which should help implementing the iterators and iterator-compatible generators.

Sometimes a stackless coroutine can be used to implement an iterator.

P.S. See also this article which mentions both a switch hack by Christopher M. Kohlhoff and Boost.Coroutine by Oliver Kowalke. Oliver Kowalke's work is a followup on Boost.Coroutine by Giovanni P. Deretta.

P.S. I think you can also write a kind of generator with lambdas:

std::function<int()> generator = []{
  int i = 0;
  return [=]() mutable {
    return i < 10 ? i++ : -1;
int ret = 0; while ((ret = generator()) != -1) std::cout << "generator: " << ret << std::endl;

Or with a functor:

struct generator_t {
  int i = 0;
  int operator() () {
    return i < 10 ? i++ : -1;
} generator;
int ret = 0; while ((ret = generator()) != -1) std::cout << "generator: " << ret << std::endl;

P.S. Here's a generator implemented with the Mordor coroutines:

#include <iostream>
using std::cout; using std::endl;
#include <mordor/coroutine.h>
using Mordor::Coroutine; using Mordor::Fiber;

void testMordor() {
  Coroutine<int> coro ([](Coroutine<int>& self) {
    int i = 0; while (i < 9) self.yield (i++);
  for (int i = coro.call(); coro.state() != Fiber::TERM; i = coro.call()) cout << i << endl;
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And here is my implementation: http://www.codeproject.com/Articles/29524/Generators-in-C

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If you only need to do this for a relatively small number of specific generators, you can implement each as a class, where the member data is equivalent to the local variables of the Python generator function. Then you have a next function that returns the next thing the generator would yield, updating the internal state as it does so.

This is basically similar to how Python generators are implemented, I believe. The major difference being they can remember an offset into the bytecode for the generator function as part of the "internal state", which means the generators can be written as loops containing yields. You would have to instead calculate the next value from the previous. In the case of your pair_sequence, that's pretty trivial. It may not be for complex generators.

You also need some way of indicating termination. If what you're returning is "pointer-like", and NULL should not be a valid yieldable value you could use a NULL pointer as a termination indicator. Otherwise you need an out-of-band signal.

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Something like this is very similar:

struct pair_sequence
    typedef pair<unsigned int, unsigned int> result_type;
    static const unsigned int limit = numeric_limits<unsigned int>::max()

    pair_sequence() : i(0), j(0) {}

    result_type operator()()
        result_type r(i, j);
        if(j < limit) j++;
        else if(i < limit)
          j = 0;
        else throw out_of_range("end of iteration");

        unsigned int i;
        unsigned int j;

Using the operator() is only a question of what you want to do with this generator, you could also build it as a stream and make sure it adapts to an istream_iterator, for example.

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