61

What are coroutines in ?

In what ways it is different from "Parallelism2" or/and "Concurrency2" (look into below image)?

The below image is from ISOCPP.

https://isocpp.org/files/img/wg21-timeline-2017-03.png

enter image description here

  • 3
    To answer "In what way is the concept of coroutines different from parallelism and concurrency?" -- en.wikipedia.org/wiki/Coroutine – Ben Voigt Apr 19 '17 at 18:44
  • related: stackoverflow.com/q/35121078/103167 – Ben Voigt Apr 19 '17 at 18:49
  • 3
    A very good and easy-to-follow intro to coroutine is James McNellis's presentation “Introduction to C++ Coroutines" (Cppcon2016). – philsumuru Apr 19 '17 at 18:52
  • 1
    Finally it would also be good to cover "How are coroutines in C++ different from other languages' implementations of coroutines and resumable functions?" (which the above-linked wikipedia article, being language agnostic, doesn't address) – Ben Voigt Apr 19 '17 at 18:55
122

At an abstract level, Coroutines split the idea of having an execution state off of the idea of having a thread of execution.

SIMD (single instruction multiple data) has multiple "threads of execution" but only one execution state (it just works on multiple data). Arguably parallel algorithms are a bit like this, in that you have one "program" run on different data.

Threading has multiple "threads of execution" and multiple execution states. You have more than one program, and more than one thread of execution.

Coroutines has multiple execution states, but does not own a thread of execution. You have a program, and the program has state, but it has no thread of execution.


The easiest example of coroutines are generators or enumerables from other languages.

In pseudo code:

function Generator() {
  for (i = 0 to 100)
    produce i
}

The Generator is called, and the first time it is called it returns 0. Its state is remembered (how much state varies with implementation of coroutines), and the next time you call it it continues where it left off. So it returns 1 the next time. Then 2.

Finally it reaches the end of the loop and falls off the end of the function; the coroutine is finished. (What happens here varies based on language we are talking about; in python, it throws an exception).

Coroutines bring this capability to C++.

There are two kinds of coroutines; stackful and stackless.

A stackless coroutine only stores local variables in its state and its location of execution.

A stackful coroutine stores an entire stack (like a thread).

Stackless coroutines can be extremely light weight. The last proposal I read involved basically rewriting your function into something a bit like a lambda; all local variables go into the state of an object, and labels are used to jump to/from the location where the coroutine "produces" intermediate results.

The process of producing a value is called "yield", as coroutines are bit like cooperative multithreading; you are yielding the point of execution back to the caller.

Boost has an implementation of stackful coroutines; it lets you call a function to yield for you. Stackful coroutines are more powerful, but also more expensive.


There is more to coroutines than a simple generator. You can await a coroutine in a coroutine, which lets you compose coroutines in a useful manner.

Coroutines, like if, loops and function calls, are another kind of "structured goto" that lets you express certain useful patterns (like state machines) in a more natural way.


The specific implementation of Coroutines in C++ is a bit interesting.

At its most basic level, it adds a few keywords to C++: co_return co_await co_yield, together with some library types that work with them.

A function becomes a coroutine by having one of those in its body. So from their declaration they are indistinguishable from functions.

When one of those three keywords are used in a function body, some standard mandated examining of the return type and arguments occurs and the function is transformed into a coroutine. This examining tells the compiler where to store the function state when the function is suspended.

The simplest coroutine is a generator:

generator<int> get_integers( int start=0, int step=1 ) {
  for (int current=start; current+= step)
    co_yield current;
}

co_yield suspends the functions execution, stores that state in the generator<int>, then returns the value of current through the generator<int>.

You can loop over the integers returned.

co_await meanwhile lets you splice one coroutine onto another. If you are in one coroutine and you need the results of an awaitable thing (often a coroutine) before progressing, you co_await on it. If they are ready, you proceed immediately; if not, you suspend until the awaitable you are waiting on is ready.

std::future<std::expected<std::string>> load_data( std::string resource )
{
  auto handle = co_await open_resouce(resource);
  while( auto line = co_await read_line(handle)) {
    if (std::optional<std::string> r = parse_data_from_line( line ))
       co_return *r;
  }
  co_return std::unexpected( resource_lacks_data(resource) );
}

load_data is a coroutine that generates a std::future when the named resource is opened and we manage to parse to the point where we found the data requested.

open_resource and read_lines are probably async coroutines that open a file and read lines from it. The co_await connects the suspending and ready state of load_data to their progress.

C++ coroutines are much more flexible than this, as they were implemented as a minimal set of language features on top of user-space types. The user-space types effectively define what co_return co_await and co_yield mean -- I've seen people use it to implement monadic optional expressions such that a co_await on an empty optional automatically propogates the empty state to the outer optional:

modified_optional<int> add( modified_optional<int> a, modified_optional<int> b ) {
  return (co_await a) + (co_await b);
}

instead of

std::optional<int> add( std::optional<int> a, std::optional<int> b ) {
  if (!a) return std::nullopt;
  if (!b) return std::nullopt;
  return *a + *b;
}
  • 9
    This is one of the clearest explanations of what coroutines are that I've ever read. Comparing them to and distinguishing them from SIMD and classical threads was an excellent idea. – Omnifarious Feb 16 '18 at 15:30
  • 1
    I don't understand the add-optionals example. std::optional<int> is not an awaitable object. – Jive Dadson Apr 1 '18 at 1:28
  • @jive I think the actual code had an optional augmented to be awaitable. The effect was that if awaited on a not-"ready" optional it would suspend and return an empty optional, and would be ready if the optional was populated. This composes nicely and lets you express "if this optional is empty stop computing and return empty, otherwise continue on". It was a bit of a hack, and may have required heap allocation. – Yakk - Adam Nevraumont Apr 1 '18 at 1:35
  • Why is r co_return'd and not co_yield'd? Is that example really to only extract one line and then be done (as written), or should it be returning as many parsed lines as it contains, yielding each one until there are no more? – Mordachai Mar 26 at 12:36
  • 1
    @mord yes it is supposed to return 1 element. Might need polishing; if we want more than one line need a different control flow. – Yakk - Adam Nevraumont Mar 26 at 13:00
9

A coroutine is like a C function which has multiple return statements and when called a 2nd time does not start execution at the begin of the function but at the first instruction after the previous executed return. This execution location is saved together with all automatic variables that would live on the stack in non coroutine functions.

A previous experimental coroutine implementation from Microsoft did use copied stacks so you could even return from deep nested functions. But this version was rejected by the C++ committee. You can get this implementation for example with the Boosts fiber library.

1

coroutines are supposed to be (in C++) functions that are able to "wait" for some other routine to complete and to provide whatever is needed for the suspended, paused, waiting, routine to go on. the feature that is most interesting to C++ folks is that coroutines would ideally take no stack space...C# can already do something like this with await and yield but C++ might have to be rebuilt to get it in.

concurrency is heavily focused on the separation of concerns where a concern is a task that the program is supposed to complete. this separation of concerns may be accomplished by a number of means...usually be delegation of some sort. the idea of concurrency is that a number of processes could run independently (separation of concerns) and a 'listener' would direct whatever is produced by those separated concerns to wherever it is supposed to go. this is heavily dependent on some sort of asynchronous management. There are a number of approaches to concurrency including Aspect oriented programming and others. C# has the 'delegate' operator which works quite nicely.

parallelism sounds like concurrency and may be involved but is actually a physical construct involving many processors arranged in a more or less parallel fashion with software that is able to direct portions of code to different processors where it will be run and the results will be received back synchronously.

  • 8
    Concurrency and separation of concerns are totally unrelated. Coroutines aren't to provide information for the suspended routine, they are the resumable routines. – Ben Voigt Apr 19 '17 at 20:33

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.