C++ Equivalent of C# Yield?

Question

public void Consumer()
{
    foreach(int i in Integers())
    {
        Console.WriteLine(i.ToString());
    }
}

public IEnumerable<int> Integers()
{
    yield return 1;
    yield return 2;
    yield return 4;
    yield return 8;
    yield return 16;
    yield return 16777216;
}

Is there a way with template trick (or other) to get the same syntax in c++?

Answer 1

Take a look at boost::Coroutine. It does what you want. http://www.crystalclearsoftware.com/soc/coroutine/index.html#coroutine.intro

Example from tutorial

http://www.crystalclearsoftware.com/soc/coroutine/coroutine/tutorial.html

int range_generator(generator_type::self& self, int min, int max) 
{
     while(min < max)
         self.yield(min++);
     self.exit();
}

Answer 2

Coroutines are in the standard library since C++20 and uses co_yield instead of yield.

See also: What are coroutines in C++20?

There are some example usages in the first link: (the second one is probably what you're looking for)

• uses the co_await operator to suspend execution until resumed

  task<> tcp_echo_server() {
     char data[1024];
     while (true) {
        size_t n = co_await socket.async_read_some(buffer(data));
        co_await async_write(socket, buffer(data, n));
     }
  }
  

• uses the keyword co_yield to suspend execution returning a value

  generator<int> iota(int n = 0) {
     while (true)
        co_yield n++;
  }
  

• uses the keyword co_return to complete execution returning a value

  lazy<int> f() {
     co_return 7;
  }
  

Answer 3

You can always code this by hand. Truthfully, yield really seems like sugar coating to me (and co-routines too).

What a coroutine is, really ? Some state bundled up together with:

• one function to create it (isn't it a constructor ?)
• one function to move to the next state (isn't it operator++, traditionally ?)

In C++, it's called an InputIterator, and can be arbitrarily fat.

So, it's true that the syntax won't be as pretty, but this should do, just with the Standard Library:

static std::array<int, 6> const Array = {{1, 2, 4, 8, 16, 16777216}};

class Integers: public std::iterator<std::input_iterator_tag,
                                      int, ptrdiff_t, int const*, int>
{
public:
  Integers(): _index(0) {}

  operator bool() const { return _index < Array.size(); }

  Integers& operator++() { assert(*this); ++_index; return *this; }
  Integers operator++(int) { Integers tmp = *this; ++*this; return tmp; }

  int operator*() const { assert(*this); return Array[_index]; }
  int const* operator->() const { assert(*this); return &Array[_index]; }

private:
  size_t _index;
}; // class Integers

And obviously, since you decide exactly what state is stored, you decide if all is pre-computed or if part (or whole of it) is lazily computed, and possibly cached, and possibly multi-threaded, and ... you got the idea :)

Answer 4

In C++14, you can mimic yield this way:

auto&& function = []() { 
    int i = 0; 
    return [=]() mutable { 
        int arr[] = { 1, 2, 4, 8, 16, 16777216}; 
        if (i < 6) 
            return arr[i++]; 
        return 0; 
    }; 
}();

A live example is available at http://ideone.com/SQZ1qZ

Answer 5

Here is ASM "roll your own" version : http://www.flipcode.com/archives/Yield_in_C.shtml

#include <stdio.h
#include <conio.h
#include <iostream.h


//
// marks a location in the program for resume
// does not return control, exits function from inside macro
//
// yield( x, ret )
//      x : the 'name' of the yield, cannot be ambiguous in the
//          function namespace
//    ret : the return value for when yield() exits the function;

//          must match function return type (leave blank for no return type)

#define yield(x,ret)                            \
    {                                           \
        /* store the resume location */         \
        __asm {                                 \
            mov _myStaticMkr,offset label_##x   \
        }                                       \
                                                \
        /* return the supplied value */         \
        return ret;                             \
    }                                           \
    /* our offset in the function */            \
    label_##x:



//
// resumes function from the stored offset, or
// continues without notice if there's not one
// stored
//
// resume()
//   <void

#define resume()                        \
    /* our stored offset */             \
    static _myStaticMkr=0;              \
                                        \
    /* test for no offset */            \
    if( _myStaticMkr )                  \
    {                                   \
        /* resume from offset */        \
        __asm                           \
        {                               \
            jmp _myStaticMkr            \
        }                               \
    }


// example demonstrating a function with an int return type
// using the yield() and resume() macros
//
// myFunc()
//   <void

int myFunc()
{
    resume();

    cout << "1\n";

    yield(1,1);

    cout << "2\n";

    yield(2,1);

    cout << "3\n";

    yield(3,1);

    cout << "4\n";

    return 0;
}



// main function
//
// main()
//   <void

void main( void )
{
    cout << "Yield in C++\n";
    cout << "Chris Pergrossi\n\n";

    myFunc();

    do

    {
        cout << "main()\n";
        cout.flush();
    } while( myFunc() );

    cout.flush();

    getch();
}


/*

// example demonstrating a function with no return type
// using the yield() and resume() macros
//
// myFunc()
//   <void

void myFunc()
{
    resume();

    cout << "1\n";

    yield(1);

    cout << "2\n";

    yield(2);

    cout << "3\n";

    yield(3);

    cout << "4\n";

    return;
}



// main function
//
// main()
//   <void

void main( void )
{
    cout << "Yield in C++\n";
    cout << "Chris Pergrossi\n\n";

    myFunc();

    for( int k = 0; k < 4; k ++ )
    {
        cout << "main()\n";
        cout.flush();

        myFunc();
    }

    cout.flush();

    getch();
}

*/  

Answer 6

If all what you need is just foreach-like stuff, then following syntax is available in C++:

#define GENERATOR(name) \
struct name \
{ \
    template<typename F> \
    void operator()(F yield) \
/**/
#define _ };

template<typename Gen>
struct Adaptor
{
    Gen f;
    template<typename C>
    void operator*(C cont)
    {
        f(cont);
    }
};

template<typename Gen>
Adaptor<Gen> make_adaptor(Gen gen)
{
    return {gen};
}

#define FOREACH(arg, gen) make_adaptor(gen) * [&](arg)

---

#include <iostream>
using namespace std;

GENERATOR(integers)
{
    yield(1);
    yield(2);
    yield(4);
    yield(8);
    yield(16777216);
}_

int main()
{
    FOREACH(int i, integers())
    {
        cout << i << endl;
    };
}

Live Demo

If you need a little bit of coroutine "power", then you can try stackless coroutines.

Or if you need full power - then go with stackful coroutines. There is Boost.Coroutine library which implements stackful coroutines for different platforms.

Answer 7

An try to implement yield in c++ coroutine

Answer 8

If you write static unsigned int checkpoint = 0;, make all your variables static, switch (checkpoint), set each case: goto to some label, above each return set checkpoint to unique value, and below define label, and at the end of the function set checkpoint to zero, and all static variables to their default value, and at last return the end value of the function. If you do all this then the function becomes enumerable and iterative. The two lines you add above and below each return line, makes the return command to behave like yield return. goto allows you to continue and resume where you left off, and static integer variable, like checkpoint, help you to remember where you stopped, from where to continue/resume and where to go. You test it's values with switch case statements. Making all other variables static, is to save their value to the next call, so in the next call, their value won't be reset!

Here for example:

#define PowerEnd INT_MIN
int Power(int number, int exponent)
{
    static unsigned int checkpoint = 0;
    static int result = 1, i = 0;
    switch (checkpoint)
    {
        case 1: goto _1;
    }
    for (i = 0; i < exponent; i++)
    {
        result *= number;
        checkpoint = 1;
        return result;
        _1:;
    }
    checkpoint = 0;
    result = 1;
    i = 0;
    return PowerEnd;
}
void main()
{
    while (true)
    {
        int result = Power(2, 8);
        if (result == PowerEnd)
            break;
        cout << result << endl;
    }
    //to print only the first 4 results (if there are at least 4 results) then
    for (int i = 0; i < 4; i++)
    {
        int result = Power(2, 8);
        if (result == PowerEnd)
            break;
        cout << result << endl;
    }
}

The above program produces the following output:

2 4 8 16 32 64 128 256 2 4 8 16

Answer 9

Something similar is proposed for C++17 and there is already an experimental implementation in Visual C++ 2015. Here's a good overview talk from Gor Nishanov, one of the main authors of the proposal.

Answer 10

#include <setjmp.h>

class superclass
{
public:
    jmp_buf jbuf;
public:
    virtual int enumerate(void) { return -1; }
};

class subclass: public superclass
{
public:
    int enumerate()
    {
        static int i;
        static bool b = false;

        if(b) 
            longjmp(jbuf, 1);

        for(b = true, i = 0; i < 5; (i)++)
        {
            printf("\ndoing stuff: i = %d\n", i);

            if(setjmp(jbuf) != 1) 
                return i;    
        }
        return -1;
    }
};

To use the code...

int iret; 
subclass *sc;

sc = new subclass();
while((iret = sc->enumerate()) != -1)
{
    printf("\nsc->enumerate() returned: %d\n", iret);
}

Just got this working; it seems quite simple now, although I had a few false starts with it :)

Answer 11

You can of course always write your own iterators and return from them whatever you desire, but why would you want to? In the given example, why not simply put your values into a container like vector and iterate over that?