As Wikipedia states:

Green threads emulate multi-threaded environments without relying on any native OS capabilities, and they are managed in user space instead of kernel space, enabling them to work in environments that do not have native thread support.

Python's threads are implemented as pthreads (kernel threads), and because of the global interpreter lock (GIL), a Python process only runs one thread at a time.

[QUESTION] But in the case of Green-threads (or so-called greenlet or tasklets),

  1. Does the GIL affect them? Can there be more than one greenlet running at a time?
  2. What are the pitfalls of using greenlets or tasklets?
  3. If I use greenlets, how many of them can a process can handle? (I am wondering because in a single process you can open threads up to ulimit(-s, -v) set in your *ix system.)

I need a little insight, and it would help if someone could share their experience, or guide me to the right path.

  • 1
    The answer to all three is "it depends on the greenlet implementation".
    – millimoose
    Oct 6, 2012 at 11:12
  • 1
    Stackless Python gets into a lot of these concepts. I recommend getting a version and doing the tutorial on the official site. It has a lot of explination about the sorts of questions you are asking.
    – yurisich
    Oct 6, 2012 at 13:02

2 Answers 2


You can think of greenlets more like cooperative threads. What this means is that there is no scheduler pre-emptively switching between your threads at any given moment - instead your greenlets voluntarily/explicitly give up control to one another at specified points in your code.

Does the GIL affect them? Can there be more than one greenlet running at a time?

Only one code path is running at a time - the advantage is you have ultimate control over which one that is.

What are the pitfalls of using greenlets or tasklets?

You need to be more careful - a badly written greenlet will not yield control to other greenlets. On the other hand, since you know when a greenlet will context switch, you may be able to get away with not creating locks for shared data-structures.

If I use greenlets, how many of them can a process can handle? (I am wondering because in a single process you can open threads up to umask limit set in your *ix system.)

With regular threads, the more you have the more scheduler overhead you have. Also regular threads still have a relatively high context-switch overhead. Greenlets do not have this overhead associated with them. From the bottle documentation:

Most servers limit the size of their worker pools to a relatively low number of concurrent threads, due to the high overhead involved in switching between and creating new threads. While threads are cheap compared to processes (forks), they are still expensive to create for each new connection.

The gevent module adds greenlets to the mix. Greenlets behave similar to traditional threads, but are very cheap to create. A gevent-based server can spawn thousands of greenlets (one for each connection) with almost no overhead. Blocking individual greenlets has no impact on the servers ability to accept new requests. The number of concurrent connections is virtually unlimited.

There's also some further reading here if you're interested: http://sdiehl.github.io/gevent-tutorial/

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  • Thanks for putting all the info together, I think with information provided here one can move ahead quickly. Thanks @Martin Apr 27, 2015 at 7:09
  • @MartinKonecny this might not be the best place to ask but, is the statement "Only one code path is running at a time" valid for all user threads (this is same as greenlets, right?) or is it just valid for python? Oct 7, 2016 at 19:47
  • upvoted! so lets say i had 10 green threads performing 10 different joins between the same 2 sqlite tables A and B, you are saying they will run sequentially?
    – PirateApp
    May 12, 2018 at 8:15
  • They will run sequentially, yes. As long as you are yielding each greenlet after each query May 12, 2018 at 16:32

I assume you're talking about evenlet/gevent greenlets

1) There can be only one greenlet running

2) It's cooperative multithreading, which means that if a greenlet is stuck in an infinite loop, your entire program is stuck, typically greenlets are scheduled either explicitly or during I/O

3) A lot more than threads, it depends of the amount of RAM available

  • So you are saying that only advantage of using greenlet is you can have more "threads" than real threads. Oct 6, 2012 at 12:31
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    I'm not sure, but I think it's faster to switch between greenlets than it is to switch OS threads because they are lighter but don't quote me on that Oct 6, 2012 at 12:36
  • Green-threads have about the same cost as calling a function, while multi-threading need context switching (saving the whole thread state in memory, load the context of a new thread until looping over). These two method don't belong to the same scale of overhead (and processes are even worse).
    – Tim
    Oct 26, 2015 at 14:30
  • @Tim I believe you are conflating a process context switch with a thread context switch. Threads do not write them selves to memory or need to load when switching between threads of the same process -- they exist inside and share the same process memory space.
    – gbtimmon
    May 4, 2018 at 13:36
  • @Tim all that get switched for threads is the program counter, processor registers and the stack pointer. Thats much smaller then the full memory address space. That's one of the primary reasons the concept of threads exist instead of everything just being processes.
    – gbtimmon
    May 4, 2018 at 13:43

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