Lets take Haskell as our inspiration - it being lazy to the core.
Also, let's keep in mind how Linq in C# uses Enumerators in a monadic (urgh - here is the word - sorry) way.
Last not least, lets keep in mind, what coroutines are supposed to provide to programmers. Namely the decoupling of computational steps (e.g. producer consumer) from each other.
And lets try to think about how coroutines relate to lazy evaluation.

All of the above appears to be somehow related.

Next, lets try to extract our personal definition of what "lazy" comes down to.

One interpretation is: We want to state our computation in a composable way, *before* executing it. Some of those parts we use to compose our complete solution might very well draw upon huge (sometimes infinite) data sources, with our full computation also either producing a finite or infinite result.

Lets get concrete and into some code. We need an example for that! Here, I choose the fizzbuzz "problem" as an example, just for the reason that there is some nice, lazy solution to it.

In Haskell, it looks like this:

```
module FizzBuzz
( fb
)
where
fb n =
fmap merge fizzBuzzAndNumbers
where
fizz = cycle ["","","fizz"]
buzz = cycle ["","","","","buzz"]
fizzBuzz = zipWith (++) fizz buzz
fizzBuzzAndNumbers = zip [1..n] fizzBuzz
merge (x,s) = if length s == 0 then show x else s
```

The Haskell function `cycle`

creates an infinite list (lazy, of course!) from a finite list by simply repeating the values in the finite list forever. In an eager programming style, writing something like that would ring alarm bells (memory overflow, endless loops!). But not so in a lazy language. The trick is, that lazy lists are not computed right away. Maybe never. Normally only as much as subsequent code requires it.

The third line in the `where`

block above creates another lazy!! list, by means of combining the infinite lists `fizz`

and `buzz`

by means of the single two elements recipe "concatenate a string element from either input list into a single string". Again, if this were to be immediately evaluated, we would have to wait for our computer to run out of resources.

In the 4th line, we create tuples of the members of a finite lazy list `[1..n]`

with our infinite lazy list `fizzbuzz`

. The result is still lazy.

Even in the main body of our `fb`

function, there is no need to get eager. The whole function returns a list with the solution, which itself is -again- lazy. You could as well think of the result of `fb 50`

as a computation which you can (partially) evaluate later. Or combine with other stuff, leading to an even larger (lazy) evaluation.

So, in order to get started with our C++ version of "fizzbuzz", we need to think of ways how to combine partial steps of our computation into larger bits of computations, each drawing data from previous steps as required.

You can see the full story in a gist of mine.

Here the basic ideas behind the code:

Borrowing from C# and Linq, we "invent" a stateful, generic type `Enumerator`

, which holds

- The current value of the partial computation

- The state of a partial computation (so we can produce subsequent values)

- The worker function, which produces the next state, the next value and a bool which states if there is more data or if the enumeration has come to an end.

In order to be able to compose `Enumerator<T,S>`

instance by means of the power of the `.`

(dot), this class also contains functions, borrowed from Haskell type classes such as `Functor`

and `Applicative`

.

The worker function for enumerator is always of the form: `S -> std::tuple<bool,S,T`

where `S`

is the generic type variable representing the state and `T`

is the generic type variable representing a value - the result of a computation step.

All this is already visible in the first lines of the `Enumerator`

class definition.

```
template <class T, class S>
class Enumerator
{
public:
typedef typename S State_t;
typedef typename T Value_t;
typedef std::function<
std::tuple<bool, State_t, Value_t>
(const State_t&
)
> Worker_t;
Enumerator(Worker_t worker, State_t s0)
: m_worker(worker)
, m_state(s0)
, m_value{}
{
}
// ...
};
```

So, all we need to create a specific enumerator instance, we need to create a worker function, have the initial state and create an instance of `Enumerator`

with those two arguments.

Here an example - function `range(first,last)`

creates a finite range of values. This corresponds to a lazy list in the Haskell world.

```
template <class T>
Enumerator<T, T> range(const T& first, const T& last)
{
auto finiteRange =
[first, last](const T& state)
{
T v = state;
T s1 = (state < last) ? (state + 1) : state;
bool active = state != s1;
return std::make_tuple(active, s1, v);
};
return Enumerator<T,T>(finiteRange, first);
}
```

And we can make use of this function, for example like this: `auto r1 = range(size_t{1},10);`

- We have created ourselves a lazy list with 10 elements!

Now, all is missing for our "wow" experience, is to see how we can compose enumerators.
Coming back to Haskells `cycle`

function, which is kind of cool. How would it look in our C++ world? Here it is:

```
template <class T, class S>
auto
cycle
( Enumerator<T, S> values
) -> Enumerator<T, S>
{
auto eternally =
[values](const S& state) -> std::tuple<bool, S, T>
{
auto[active, s1, v] = values.step(state);
if (active)
{
return std::make_tuple(active, s1, v);
}
else
{
return std::make_tuple(true, values.state(), v);
}
};
return Enumerator<T, S>(eternally, values.state());
}
```

It takes an enumerator as input and returns an enumerator. Local (lambda) function `eternally`

simply resets the input enumeration to its start value whenever it runs out of values and voilà - we have an infinite, ever repeating version of the list we gave as an argument:: `auto foo = cycle(range(size_t{1},3));`

And we can already shamelessly compose our lazy "computations".

`zip`

is a good example, showing that we can also create a new enumerator from two input enumerators. The resulting enumerator yields as many values as the smaller of either of the input enumerators (tuples with 2 element, one for each input enumerator). I have implemented `zip`

inside `class Enumerator`

itself. Here is how it looks like:

```
// member function of class Enumerator<S,T>
template <class T1, class S1>
auto
zip
( Enumerator<T1, S1> other
) -> Enumerator<std::tuple<T, T1>, std::tuple<S, S1> >
{
auto worker0 = this->m_worker;
auto worker1 = other.worker();
auto combine =
[worker0,worker1](std::tuple<S, S1> state) ->
std::tuple<bool, std::tuple<S, S1>, std::tuple<T, T1> >
{
auto[s0, s1] = state;
auto[active0, newS0, v0] = worker0(s0);
auto[active1, newS1, v1] = worker1(s1);
return std::make_tuple
( active0 && active1
, std::make_tuple(newS0, newS1)
, std::make_tuple(v0, v1)
);
};
return Enumerator<std::tuple<T, T1>, std::tuple<S, S1> >
( combine
, std::make_tuple(m_state, other.state())
);
}
```

Please note, how the "combining" also ends up in combining the state of both sources and the values of both sources.

As this post is already TL;DR; for many, here the...

**Summary**

Yes, lazy evaluation can be implemented in C++. Here, I did it by borrowing the function names from haskell and the paradigm from C# enumerators and Linq. There might be similarities to pythons itertools, btw. I think they followed a similar approach.

My implementation (see the gist link above) is just a prototype - not production code, btw. So no warranties whatsoever from my side. It serves well as demo code to get the general idea across, though.

And what would this answer be without the final C++ version of fizzbuz, eh? Here it is:

```
std::string fizzbuzz(size_t n)
{
typedef std::vector<std::string> SVec;
// merge (x,s) = if length s == 0 then show x else s
auto merge =
[](const std::tuple<size_t, std::string> & value)
-> std::string
{
auto[x, s] = value;
if (s.length() > 0) return s;
else return std::to_string(x);
};
SVec fizzes{ "","","fizz" };
SVec buzzes{ "","","","","buzz" };
return
range(size_t{ 1 }, n)
.zip
( cycle(iterRange(fizzes.cbegin(), fizzes.cend()))
.zipWith
( std::function(concatStrings)
, cycle(iterRange(buzzes.cbegin(), buzzes.cend()))
)
)
.map<std::string>(merge)
.statefulFold<std::ostringstream&>
(
[](std::ostringstream& oss, const std::string& s)
{
if (0 == oss.tellp())
{
oss << s;
}
else
{
oss << "," << s;
}
}
, std::ostringstream()
)
.str();
}
```

And... to drive the point home even further - here a variation of fizzbuzz which returns an "infinite list" to the caller:

```
typedef std::vector<std::string> SVec;
static const SVec fizzes{ "","","fizz" };
static const SVec buzzes{ "","","","","buzz" };
auto fizzbuzzInfinite() -> decltype(auto)
{
// merge (x,s) = if length s == 0 then show x else s
auto merge =
[](const std::tuple<size_t, std::string> & value)
-> std::string
{
auto[x, s] = value;
if (s.length() > 0) return s;
else return std::to_string(x);
};
auto result =
range(size_t{ 1 })
.zip
(cycle(iterRange(fizzes.cbegin(), fizzes.cend()))
.zipWith
(std::function(concatStrings)
, cycle(iterRange(buzzes.cbegin(), buzzes.cend()))
)
)
.map<std::string>(merge)
;
return result;
}
```

It is worth showing, since you can learn from it how to dodge the question what the exact return type of that function is (as it depends on the implementation of the function alone, namely how the code combines the enumerators).

Also it demonstrates that we had to move the vectors `fizzes`

and `buzzes`

outside the scope of the function so they are still around when eventually on the outside, the lazy mechanism produces values. If we had not done that, the `iterRange(..)`

code would have stored iterators to the vectors which are long gone.