coroutine , a built-in Tcl command, creates a new coroutine context and an associated command.
coroutine creates a coroutine context and an associated coroutine command named name. It then evaluates cmd in the coroutine context, passing it any given arg values. In the coroutine context, yield pauses the evaluation and returns a value to the caller, and yieldto pauses the evaluation to tailcall another command. If yield paused the coroutine, then name may be called again with zero or one arguments, at which point the coroutine becomes active and the same yield returns that single argument. Similarly, if yieldto paused the coroutine, then name maybe be called with any number of arguments, and yieldto returns those arguments as a list. If cmd returns, the coroutine context is deleted and name is also deleted.
cmd is the first thing evaluted in the coroutine context, all additional levels of evaluation are also part of the context, and yield or yieldto can be called at any level. A coroutine context is essentially a separate flow of control that can be paused at any point, even with while or for loops, and can be used to model objects, generators, actors, and other agents in concurrent systems.
Apart from yield and yieldto, evaluation within a coroutine context proceeds exactly as evaluation of a script outside a coroutine context. At any given moment only one evalutaion context has control of its interpreter. Since a script being evaluated with a coroutine context may call yield or yieldto to pause the evaluation, coroutines are considered to implement non-preemptive multitasking. Coroutine can be used in conjunction with an event loop to provide asynchronous operation that appears to be synchronous from within each evaluation context. For example, a coroutine could be used in the handler for a channel event, allowing the coroutine to pause in the middle of a loop that handles the event each time it occurs.
Coroutines can be used to invert the traditional callback style. For example, without coroutines, something like fileutil::traverse that walks a filesystem hierarchy uses callbacks to process the files it encounters, making the traverser the client and the callback the server. A coroutine would instead yield a pathname each time it was called, making the caller the client, and the traverser the server.
yieldto allows peer-to-peer style, with coroutines yielding to each other.
Coroutines were introduced in Tcl8.6. At first these commands were in the tcl::unsupported namespace.
NRE made the implementation of coroutines possible.
MS added yieldto as Tcl 8.6 was about to be released, when it became clear that yieldto was a more general treatment than yieldm.
An implementation of asymmetric stackful coroutines (see Lua's team survey (pdf!) [L1 ] and tutorial [L2 ], and/or the Wikipedia article [L3 ]).
(DKF: Seems to be actually a "generator" according to the definitions referred to on Wikipedia.) (NEM: The definition on wikipedia seems wrong to me. The difference between a generator and a coroutine is that the former can only produce values, whereas the latter can be both a producer and a consumer. In practical terms, this means that yield can both generate a value and receive a value to return: set y [yield $x]. C.f. Python which extended its generators to full coroutines in version 2.5 by adding exactly this capability.)
aspect: Andy Wingo wrote a great survey of coroutine-like things in various languages as he was developing continuations and generators in Guile Scheme. The referenced notes and papers from Oleg Kiselyov are deep: after doing crazy things with call/cc for a long while, Oleg eventually argues strongly and convincingly that call/cc is too powerful .
This opinion was once neatly echoed by kbk in the chat: coroutines, closures, continuations, green threads, all have attributes in common. Scheme tries to distill them down to an irreducible minimum as 'call/cc'. But every time I want to work with 'call/cc', I have to spend a week meditating upon Continuation Passing Style before I can make sense of it.
jima 2009-11-11 notices goroutines in [L4 ] (and, incidentally, the use of UTF-8 in go language).
From c.l.t.[L5 ]
Just stating what I understand and where I stand. - A - Experimental coroutines are in HEAD and 8.6a2 * they do allow new and simpler ways to express things * what's in there is experimental infrastructure * please play with code and concept, help us make it better - B - Some design decisions I consider necessary, where the alternatives I saw fall in one or more of the following categories: (a) semantics not clear (to me and/or generally) (b) no hope in hell to have it in 8.6 (compat) (c) no hope in hell to have it in 8.6 (time) Among these: * the coroutine bodies run in [uplevel #0] * coroutines are not serializable * coroutines are like one-shot continuations, not restartable - C - Some design decisions where made with possibly insufficient info: (0a) [coroutine] creates a command and not a special object with subcommands Justification: (a) provides all that is needed (b) does not require new (sub)commands to resume, delete, ... (c) leverages Tcl's command management code (for instance, automatic cleanup on namespace deletion) (d) implementation simplicity (0b) [coroutine] runs the body up to the first [yield] instead of just creating the command Justification: (a) this is not really restrictive (b) it does not create commands that take different arguments at first and successive calls (c) implementation simplicity (1) coroutines are self-cleaning (2) [coroutine] requires a command name ([cmd] in the rest of this post] (3) [cmd] takes a single argument: [yield]'s inside return value (4) [yield] takes a single argument: the outside return value (5) [yield] always return an "ok" code, both inside and outside Of these, only (5) restricts functionality; it was taken because *I* can not see how to make the alternative (a) useful, (b) semantically clear, (c) play nicely with (1). I may be wrong, eager to learn. (1) I think is valuable: when the coroutine is exhausted there's nothing else that can be done with it, so let the command disappear instead of burdening the caller to clean up. The other three are ... irrelevant at this stage! Simple script wrappers can provide alternative syntax at minimal perf cost. They do not constrain experimentation in any way. Should we want more than one available, standard wrappers could be in tcllib or TIPped and "builtin". Should the perf penalty be too large, they can at any time be coded in C (or even bytecompiled!) as solving perf bugs. - D - I am eager to get help making this better (a) Looking mostly for "mental bugs", things that are stopping me from writing a TIP right away: * does it make sense? are there inconsistencies and semantic snafus? * are there B-type restrictions that could be lifted in time for 8.6? * is there more C-type stuff that I am missing, and that is losing generality? (b) Looking for arguments that would tip C-decisions one way or the other; this includes primarily real use cases. Mainly interested in (1) and (5), and possibly other decisions that I may have made unconsciously (help me find them!).
AMG: According to MS's documentation, "a yield is only allowed if the C stack is at the same level as it was when the coroutine is invoked." Does this mean that yield cannot be used as the SQLite progress callback?
DKF: In theory, it could. In practice, not with the current code because it recursively calls the interpreter rather than using the NRE evaluation mechanism. The tdbc version might work though (it's founded on NRE-enabled stuff).
PYK 2017-05-25: I think that at some point the progress callback became NRE-enabled, and can now yield.
AMG: yield doesn't work across multiple interps.
% coroutine foo [interp create] eval yield yield can only be called in a coroutine % coroutine foo info coroutine ::foo % coroutine foo [interp create] eval info coroutine % # returns empty string
I was considering a design where a script run in a safe interp repeatedly yields to the invoking interp, but I guess I can't do this.
MS Your example is designed to illustrate that you cannot directly yield across interps, which is true. Trying to guess the real aim of the exercise, I suggest something like
You can now call foo from the main interp and have the coroutine named foo run in the slave; when the coroutine yields, you are back in the main interp. Is this somehow related to what you really wanted to do?
AMG: Very interesting! I'm not entirely sure I can use this on my current project (I was just casting about for ideas), but I'm sure this will come in handy at some point. Thank you for explaining how to use coroutines across interpreters and for writing NRE/coroutine in the first place.
AMG, much later: Here's more code that mixes coroutines and interps. Unfortunately, it doesn't work, at least not in Tcl 8.6b1. TclExecuteByteCode() fails with "C stack busy".
proc splitscript input { set slave [interp create -safe] $slave eval {unset {*}[info vars]} foreach command [$slave eval {info commands}] { $slave hide $command } $slave alias unknown apply {args {yield $args}} coroutine nextline apply {{slave input} { yield $slave eval $input }} $slave $input set result {} while 1 { set line [nextline] if {$line ne {}} { lappend result $line } else { interp delete $slave return $result } } }
Is this by design, am I up against an unimplemented feature, is this a Tcl bug, or is there a mistake in my code or my understanding?
MS: same as above: you cannot yield across interp boundaries; more concretely, cross-interp aliases are not nre-enabled, they consume stack ("C stack busy") and block yield. I know I thought of some security risk in allowing this, but that is not the only reason: enabling this would have meant bigger changes in the core which I thought were unwarranted for a first version.
AMG: This is not quite the same as before, as indicated by the different error message. The yield happens in the same interpreter as the coroutine, which is the requirement not met by the code I posted long ago. Inside unknown, info coroutine returns nextline. But between the invocation of the coroutine and the yield, there are two interpreter switches: the coroutine calls into the slave interpreter, which then calls back into the master, which yields. And as you say, cross-interp aliases are not NRE-enabled. I can't think of any security problems with this, since all the coroutine stuff is done inside a single interpreter. However, I certainly do understand your second concern. You can't NRE-enable the world, not all at once anyway. :^)
AMG: By the way, here's a non-coroutine version of the above:
proc splitscript {input} { set slave [interp create -safe] $slave eval {unset {*}[info vars]} foreach command [$slave eval {info commands}] { $slave hide $command } $slave expose lappend lappend* $slave invokehidden proc unknown* {args} { lappend* ::script* $args } $slave invokehidden namespace unknown unknown* $slave invokehidden set script* {} $slave eval $input set script [$slave invokehidden set script*] interp delete $slave return $script }
AMG: See Config file using slave interp for another variation on the above script, plus discussion on its use.
AMG, nine years later: I ran into this problem again, came here to report it, and found I was the one who reported it to begin with. I'm running user code in a slave interpreter with various commands aliased back to the master interpreter, but some of those commands need to be able to [yield] back to the event loop (so the GUI stays alive) while they wait for an external event to occur (timeout, child process readability, incoming network data, and so on).
My current implementation uses separate threads, mostly because coroutines aren't available in the old version of Tcl I was targeting, but I've since changed all GUI usage of my program to 8.6. I want to get away from threads because they are complicated and don't do anything to let me use Tkcon to inspect and edit live code and data. With threads, I have an interpreter that's unresponsive to events while it waits for [after] or [read] or whatever to complete. Coroutines solve this problem, but it looks like it does so at the expense of slave interpreters.
Unless anyone has any better ideas, I'm afraid I must downgrade from running the user code in slave interpreters to running it in a namespace. This is especially frustrating because the majority of times my program will be used will be non-GUI (hence no requirement for Tkcon) and with Tcl 8.5.8 (hence no coroutine capability in the first place), so I'll be losing functionality everywhere for the sake of a nice feature used in rare (but important) circumstances.
DKF: You can do a "global coroutine" like this:
But that doesn't mean that I think it is a good idea. For example, you don't get nice variable handling this way.
NEM: Or, using a lambda:
DKF: Yes, but with lambdas you get that nice variable handling. That's because it comes from the local variable context that gets pushed as part of the apply (or the procedure if you're using a "traditional" coroutine).
Unconditionally terminate the currently running coroutine:
Terminating the currently running coroutine, catchable within the coroutine:
LV: In an environment which supports threads and safe interps, what questions should a new developer ask when determining the appropriate technology? And are there situations where one might want/need to combine these in ways?
DKF: This example (from the Tcl docs) shows how to generate primes with the sieve of eratosthenes in Tcl using coroutines...
proc filterByFactor {source n} { yield [info coroutine] while 1 { set x [$source] if {$x % $n} { yield $x } } } coroutine allNumbers apply {{} {while 1 {yield [incr x]}}} coroutine eratosthenes apply {c { yield while 1 { set n [$c] yield $n set c [coroutine prime$n filterByFactor $c $n] } }} allNumbers for {set i 1} {$i <= 20} {incr i} { puts "prime#$i = [eratosthenes]" }
It might be interesting if someone (TM) attempted a translation of A Curious Course on Coroutines and Concurrency .
SW: Here you go .
2015-12-02 sometimes I have code segments that can only run in a coroutine context (typically: sending a message, waiting for the reply, ...). I usually mark the entry point with a call to "coroutine::required":
namespace eval ::coroutine {} proc ::coroutine::required {} { if {![coroutine?]} { return -code error "coroutine required" } } proc ::coroutine? {} { expr {[info coroutine] ne ""} }
PYK 2016-04-23: Here's a trick to make sure the current context is a coroutine context. It's a essentially a no-op in the coroutine context, and an error otherwise:
jbr 2010-05-05:
Coroutine names don't appear in the info procs list? Is this by design? Below I can call "xxx" but I cannot see if its currently defined by asking info.
Output does not contain xxx:
auto_load_index unknown auto_import throw auto_execok clock auto_qualify auto_load yield-once try tclLog
AMG PYK: A coroutine isnt a proc but it is a command.
yield-once is a proc, but yield-once is not a coroutine. The coroutine command is created by yield, not coroutine. In this case yield calls the coroutine "xxx", since that's the name provided to it by coroutine.
jbr: Thanks - the documentation is correct and makes sense now that you point is out, coroutine creates a command just like the man page says.
AMG: Is there a way to clone a coroutine? I'm not talking about making a new coroutine that has the same command and arguments as an existing coroutine. Cloning a coroutine would produce a new command whose only difference from the original coroutine command is return value of [info coroutine]. The two coroutine commands would not be linked, they'd just have the same state at the moment of cloning.
% coroutine keaton apply {{} { yield foreach i {0 1 2 3} { puts "$i [info coroutine]" if {$i == 1} { yield } } }} % keaton 0 keaton 1 keaton % CloneCoroutine -old keaton -new kid_a % kid_a 2 kid_a 3 kid_a % keaton 2 keaton 3 keaton
DKF 2012-02-01: As things stand, no.
AMG: Basically this would establish a means to checkpoint a coroutine and resume execution at any old saved checkpoint, independent of what that coroutine has done (or what has been done to that coroutine) since the time the checkpoint was created.
I wonder what would come of coroutines cloning themselves. I'm afraid that with that kind of power they might try to take over the world. ;^) The CloneCoroutine command would return empty string when it is (initially) called, but when the newly created coroutine commands are called with an argument, they would see CloneCoroutine return that argument, similar to yield. That way, they could tell themselves apart without having to rely on [info coroutine], plus they could be passed arbitrary data. Why would it be advantageous to not depend on [info coroutine]? A coroutine could be cloned, then later that clone could be renamed on top of the original. In this situation, [info coroutine] would not be sufficient to distinguish between the original and the cloned invocations, though a global variable could also be used for this purpose. I don't know if this would be useful, I'm just playing with the idea.
AMG: Are there fundamental technical restrictions preventing the implementation of coroutine cloning? I can understand there being a lack of interest, since the subject hasn't come up before. But is that the only real obstacle?
MS: The real obstacle is that each coroutine has its own tcl stack, which stores (among other things) pointers to itself. Making a copy of that stack implies fixing those autorefs, which in turn implies storing the nature of each entry in the stack to know if it has to be fixed or not (and how), which in turn implies a redesign of the tcl stack.
AMG: Coroutine invocations form a stack separate from the normal call stack, with the limitation that coroutines are expressly non-reentrant (may not simultaneously appear more than once on the stack). When a coroutine yields, execution returns to whichever coroutine called it, if in fact it was called by a coroutine. The info coroutine command returns the name of the current coroutine, but there is no direct way to identify the calling coroutine or its callers.
That's not to say it can't be done. yieldto can be used to ask the caller to run [info coroutine], then to report the result back to the current coroutine. Like so:
proc parentCoroutine {} { lindex [yieldto apply {{resume} { $resume [info coroutine] }} [info coroutine]] 0 }
How about getting the caller's caller? Or the entire coroutine stack? The above can be extended to traverse the entire stack:
proc coroutineStack {} { if {[set self [info coroutine]] ne {}} { list {*}[yieldto apply {{resume} { $resume {*}[coroutineStack] }} $self] $self } }
For example:
% coroutineStack % coroutine coro1 coroutineStack ::coro1 % coroutine coro1 coroutine coro2 coroutine coro3 coroutineStack ::coro1 ::coro2 ::coro3 % coroutine coro1 apply {{} {apply {{} { coroutine coro2 apply {{} {apply {{} { coroutine coro3 apply {{} {apply {{} { coroutineStack }}}} }}}} }}}} ::coro1 ::coro2 ::coro3
The last example above demonstrates that [coroutineStack] still works even when there are many normal call stack layers present.
To just get the top-level coroutine, try:
proc coroutineTop {{resume return}} { set self [info coroutine] if {$self eq {} || [set top [lindex [yieldto coroutineTop $self] 0]] eq {}} { $resume $self } else { $resume $top } }
Take a moment to appreciate how bizarre all this is. The traditional call stack is flipped on its head. Execution proceeds down the coroutine stack and the call stack within each coroutine, then when [coroutineStack] or [coroutineTop] is invoked, execution proceeds backwards up the coroutine stack, with each coroutine being instructed to call the coroutine that originally called it, then to relay the result back to the coroutine that most recently called it. The coroutine stack unwinds and then rewinds, all the while preserving the call stacks within each coroutine.
Here's a lambda version using apply, ready to be used inline if there's only one place in your program that needs to know the toplevel coroutine:
apply {{next} { set self [info coroutine] set command [list yieldto apply [lindex [info level 0] 1] $self] if {$self eq {} || [set top [lindex [{*}$command] 0]] eq {}} { $next $self } else { $next $top } }} return
DKF: Sometimes, we need to see inside a coroutine to find out what it is up to. This is a very tricky thing to be doing, but is ever so useful for debugging. For example, it's great to be able to read the local variables of that coroutine, and check that it's behaving as expected after all. How might we do that? tcl::unsupported::inject.
proc c-body {} { set val [info coroutine] set l {} while {[set val [yield $val]] ne ""} { lappend l $val } puts [join $l ,] } coroutine c c-body # Send some data in c "abc def" c "123 456" c "the quick brown fox" # What's in the accumulator variable? Let's look! # Here's the code to get the goods. Mostly a simple procedure except that it finishes by tailcall yield proc probe var { upvar 1 $var v # We use tailcall so that we clear this procedure out of the way afterwards tailcall yield $v } # Insert our code into the (stopped) coroutine tcl::unsupported::inject c probe l # Fire it off to smuggle the data out and leave everything in the same state as before puts "l = [c]"; # l = {abc def} {123 456} {the quick brown fox} # Show that we didn't break anything by continuing as before c "Erie Huron Superior" c; # abc def,123 456,the quick brown fox,Erie Huron Superior
This works well for poking around with info level and info frame too. Indeed, the only tricky bit is that if the coroutine was stopped with yieldto then you want to finish the probe procedure with that too (often tailcall yieldto string cat $theValueToSmuggleOut) so that the multiple-arg-receiving capability of yieldto isn't disturbed.