What is a coroutine? How are they related to concurrency?

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    Concurrent code does not have necessarily have to run in "parallel" (let's not introduce new terms). – lucid_dreamer Jan 30 '18 at 20:35
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    I've written one coroutine library with standard C, supporting select/poll/eplll/kqueue/iocp/Win GUI messages for Linux, BSD and Windows. It's a open-source project in github.com/acl-dev/libfiber. Advice will be wellcome. – ShuXin Zheng Feb 24 '18 at 15:38
  • More interesting info here: stackoverflow.com/q/16951904/14357 – spender Dec 7 '18 at 14:00
  • I can imagine this question will be downvoted if it's asked at this current era. Not sure why is there such vast difference of community perception as compared to before? – tnkh May 23 at 7:29

Coroutines and concurrency are largely orthogonal. Coroutines are a general control structure whereby flow control is cooperatively passed between two different routines without returning.

The 'yield' statement in Python is a good example. It creates a coroutine. When the 'yield ' is encountered the current state of the function is saved and control is returned to the calling function. The calling function can then transfer execution back to the yielding function and its state will be restored to the point where the 'yield' was encountered and execution will continue.

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    What is the difference between calling a function directly and yielding from a coroutine with wrapping this function into this coroutine? – Ming Li Aug 4 '14 at 10:44
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    It might be better to explain that these two concepts are not really 'orthogonal' in this context then. You can definitely draw how the two concepts are similar to each other. The idea of passing control between two or more things is very similar. – steviejay Aug 8 '17 at 17:44
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    Coroutines are a general control structure whereby flow control is cooperatively passed between two different routines without returning. <-- This is concurrency. The word you are looking for is parallelism. – Adam Arold Dec 10 '18 at 12:37

From Programming in Lua, "Coroutines" section:

A coroutine is similar to a thread (in the sense of multithreading): it is a line of execution, with its own stack, its own local variables, and its own instruction pointer; but it shares global variables and mostly anything else with other coroutines. The main difference between threads and coroutines is that, conceptually (or literally, in a multiprocessor machine), a program with threads runs several threads in parallel. Coroutines, on the other hand, are collaborative: at any given time, a program with coroutines is running only one of its coroutines, and this running coroutine suspends its execution only when it explicitly requests to be suspended.

So the point is: Coroutines are "collaborative". Even in multi-core system, there is only one coroutine running at any given time (but multiple threads can run in parallel). There is non-preemptive between coroutines, the running coroutine must relinquish the execution explicitly.

For "concurrency", you can refer Rob Pike's slide:

Concurrency is the composition of independently executing computations.

So during coroutine A's execution, it passes control to coroutine B. Then after some time, the coroutine B passes control back to coroutine A. Since there is dependency between coroutines, and they must run in tandem, so the two coroutines are not concurrency.

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    Coroutines do not execute independently. They take turns, each waiting for the other to do some part of the work. They actively coordinate with each other. That's the opposite of Rob Pikes definition of concurrency. – Erick G. Hagstrom Jun 22 '16 at 12:09
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    @ErickG.Hagstrom: Although they don't execute independently, the logic of every coroutine can be independent, right? If it is right, it is just like an un-preemptive OS running on one-core CPU, one process must relinquish CPU to let other tasks run. – Nan Xiao Jun 22 '16 at 12:18
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    There's a difference between relinquishing the CPU to let some other task run, and telling some specific other process that it's time to execute. Coroutines do the latter. That's not independent in any sense. – Erick G. Hagstrom Jun 22 '16 at 12:19
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    @ChrisClark I agree with you. Coroutines are concurrency. Here is some quote from wikipedia: Coroutines are very similar to threads. However, coroutines are cooperatively multitasked, whereas threads are typically preemptively multitasked. This means that they provide concurrency but not parallelism. – smwikipedia Oct 5 '18 at 4:00
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    And: Cooperative multitasking, also known as non-preemptive multitasking, is a style of computer multitasking in which the operating system never initiates a context switch from a running process to another process. Instead, processes voluntarily yield control periodically or when idle or logically blocked in order to enable multiple applications to be run concurrently. – smwikipedia Oct 5 '18 at 4:02

I find most of the answers too technical even though it is a technical question. I had a hard time trying to understand the coroutine process. I kind of get it but then I don't get it at the same time.

I found this answer here very helpful:


To quote from Idan Arye:

To build on your story, I'd put it something like this:

You start watching the cartoon, but it's the intro. Instead of watching the intro you switch to the game and enter the online lobby - but it needs 3 players and only you and your sister are in it. Instead of waiting for another player to join you switch to your homework, and answer the first question. The second question has a link to a YouTube video you need to watch. You open it - and it starts loading. Instead of waiting for it to load, you switch back to the cartoon. The intro is over, so you can watch. Now there are commercials - but meanwhile a third player has joined so you switch to the game And so on...

The idea is that you don't just switch the tasks really fast to make it look like you are doing everything at once. You utilize the time you are waiting for something to happen(IO) to do other things that do require your direct attention.

Definitely check the link, there are much more that I cannot quote everything.

  • 2
    Very simple and straight-forward illustration. +1 for this. – Taslim Oseni Jan 2 at 17:01
  • great illustration. I built a similar story - with standing in line waiting to collect a package. but for today, yours is much more realistic, who stands in line when there are door2door deliveries? Lol – apolak Apr 18 at 14:36
  • That's awesome explanation. From quote itself, it is super clear. – Farruh Habibullaev Jun 19 at 18:40

Coroutine is similar to subroutine/threads. The difference is once a caller invoked a subroutine/threads, it will never return back to the caller function. But a coroutine can return back to the caller after executing a few piece of code allowing the caller to execute some of its own code and get back to the coroutine point where it stopped execution and continue from there. ie. A coroutine has more than one entry and exit points

  • Coroutines are great features available in Kotlin Language
  • Coroutines are a new way of writing asynchronous, non-blocking code (and much more)
  • Coroutine are light-weight threads. A light weight thread means it doesn’t map on native thread, so it doesn’t require context switching on processor, so they are faster.
  • it doesn’t map on native thread
  • Coroutines and the threads both are multitasking. But the difference is that threads are managed by the OS and coroutines by the users.

Basically, there are two types of Coroutines:

  1. Stackless
  2. Stackful

Kotlin implements stackless coroutines — it’s mean that the coroutines don’t have own stack, so they don’t map on native thread.

These are the functions to start the coroutine:



You can learn more from here :




On a different note, in python gevent library is a coroutine based networking library which gives you threadlike features like async network requests, without the overhead of creating and destroying threads. The coroutine library used is greenlet.


From Python Coroutine:

Execution of Python coroutines can be suspended and resumed at many points (see coroutine). Inside the body of a coroutine function, await and async identifiers become reserved keywords; await expressions, async for and async with can only be used in coroutine function bodies.

From Coroutines (C++20)

A coroutine is a function that can suspend execution to be resumed later. Coroutines are stackless: they suspend execution by returning to the caller. This allows for sequential code that executes asynchronously (e.g. to handle non-blocking I/O without explicit callbacks), and also supports algorithms on lazy-computed infinite sequences and other uses.

Compare with other's answer:

In my opinion, the resumed later part is a core difference, just like @Twinkle's.
Although many fields of the document are still work in progress, however, this part is similar to most answer, except @Nan Xiao 's

Coroutines, on the other hand, are collaborative: at any given time, a program with coroutines is running only one of its coroutines, and this running coroutine suspends its execution only when it explicitly requests to be suspended.

Since it's quoted from Program in Lua, maybe it's language related(not familiar with Lua currently), not all document mentioned the only one part.

The relation with concurrent:
There is an "Execution" part of the Coroutines (C++20).Too long to quote here.
Besides the detail, there are several states.

When a coroutine begins execution  
When a coroutine reaches a suspension point  
When a coroutine reaches the co_return statement  
If the coroutine ends with an uncaught exception  
When the coroutine state is destroyed either because it terminated via co_return or uncaught exception, or because it was destroyed via its handle 

as the comment from @Adam Arold under @user217714's answer. It's concurrency.
But it's different from multithreading. from std::thread

Threads allow multiple functions to execute concurrently. Threads begin execution immediately upon construction of the associated thread object (pending any OS scheduling delays), starting at the top-level function provided as a constructor argument. The return value of the top-level function is ignored and if it terminates by throwing an exception, std::terminate is called. The top-level function may communicate its return value or an exception to the caller via std::promise or by modifying shared variables (which may require synchronization, see std::mutex and std::atomic)

Since it's concurrency, it works like multithreading especially when waiting is unavoidable(from the OS perspective), that's also why it's confusing.

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