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I just finished Programming in Scala, and I've been looking into the changes between Scala 2.7 and 2.8. The one that seems to be the most important is the continuations plugin, but I don't understand what it's useful for or how it works. I've seen that it's good for asynchronous I/O, but I haven't been able to find out why. Some of the more popular resources on the subject are these:

And this question on Stack Overflow:

Unfortunately, none of these references try to define what continuations are for or what the shift/reset functions are supposed to do, and I haven't found any references that do. I haven't been able to guess how any of the examples in the linked articles work (or what they do), so one way to help me out could be to go line-by-line through one of those samples. Even this simple one from the third article:

reset {
    ...
    shift { k: (Int=>Int) =>  // The continuation k will be the '_ + 1' below.
        k(7)
    } + 1
}
// Result: 8

Why is the result 8? That would probably help me to get started.

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scala-lang.org/api/current/… –  Vadzim Dec 4 '13 at 7:21

4 Answers 4

up vote 27 down vote accepted

My blog does explain what reset and shift do, so you may want to read that again.

Another good source, which I also point in my blog, is the Wikipedia entry on continuation passing style. That one is, by far, the most clear on the subject, though it does not use Scala syntax, and the continuation is explicitly passed.

The paper on delimited continuations, which I link to in my blog but seems to have become broken, gives many examples of usage.

But I think the best example of the concept of delimited continuations is Scala Swarm. In it, the library stops the execution of your code at one point, and the remaining computation becomes the continuation. The library then does something -- in this case, transferring the computation to another host, and returns the result (the value of the variable which was accessed) to the computation that was stopped.

Now, you don't understand even the simple example on the Scala page, so do read my blog. In it I'm only concerned with explaining these basics, of why the result is 8.

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I re-read your blog entry and this time I stuck with it -- I think I have a better idea of what is going on. I didn't get much from the Wikipedia page (I already know Lisp continuations) but the reset/shift deferred style or whatever its called had me stumped. For the impatient (ie myself) your description was ok but people will have to make sure to stick with it up to the "The result of reset is the result of the code inside shift." paragraph... I was hopelessly lost until that point but it does get clearer! I will have a look at Swarm because I'm still curious what this is for. Thx! –  Dave Oct 3 '09 at 20:52
    
Yes, it does take time until things start making sense. I didn't feel I could get away making the explanation any faster. –  Daniel C. Sobral Oct 4 '09 at 1:27
    
It all came together for my when I came to the realization that "reset delimits the scope of the continuation. (ie: the variables and statements to be included.) –  JeffV Oct 4 '09 at 14:02
1  
Your explanation was verbose and did not get to the essence of the understanding. The examples were long, I didn't get enough understanding in first paragraphs to inspire me to read it all. So I voted it down. SO displays a msg after I vote, asking me to add a comment, so I am complying. Apologies for my frankness. –  Shelby Moore III Nov 5 '12 at 13:04
1  
I've blogged about this with a focus on understanding control flow (without discussing the details of the implementation). wherenullpoints.com/2014/04/scala-continuations.html –  Alexandros Apr 9 at 1:32

I found the existing explanations to be less effective at explaining the concept than I would hope. I hope this one is clear (and correct.) I have not used continuations yet.

When a continuation function cf is called:

  1. Execution skips over the rest of the shift block and begins again at the end of it
    • the parameter passed to cf is what the shift block "evaluates" to as execution continues. this can be different for every call to cf
  2. Execution continues until the end of the reset block (or until a call to reset if there is no block)
    • the result of the reset block (or the parameter to reset() if there is no block) is what cf returns
  3. Execution continues after cf until the end of the shift block
  4. Execution skips until the end of the reset block (or a call to reset?)

So in this example, follow the letters from A to Z

reset {
  // A
  shift { cf: (Int=>Int) =>
    // B
    val eleven = cf(10)
    // E
    println(eleven)
    val oneHundredOne = cf(100)
    // H
    println(oneHundredOne)
    oneHundredOne
  }
  // C execution continues here with the 10 as the context
  // F execution continues here with 100
  + 1
  // D 10.+(1) has been executed - 11 is returned from cf which gets assigned to eleven
  // G 100.+(1) has been executed and 101 is returned and assigned to oneHundredOne
}
// I

This prints:

11
101
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2  
i've got an error saying "cannot compute type for CPS-transformed function result" when i tried to compile it.. i'm not sure what it is neither how to fix it –  Fabio Veronez Mar 29 '11 at 18:06
    
@Fabio Veronez Add a return statement to the end of the shift: change println(oneHundredOne) } to, say, println(oneHundredOne); oneHundredOne }. –  folone Jun 23 '11 at 6:37
    
Nice explanation for a horrible syntax. The declaration of the continuation function is strangely detached from its body. I would be reluctant to share such head-scratching code with others. –  joeytwiddle Jun 9 '12 at 20:31

Continuation capture the state of a computation, to be invoked later.

Think of the computation between leaving the shift expression and leaving the reset expression as a function. Inside the shift expression this function is called k, it is the continuation. You can pass it around, invoke it later, even more than once.

I think the value returned by the reset expression is the value of the expression inside the shift expression after the =>, but about this I'm not quite sure.

So with continuations you can wrap up a rather arbitrary and non-local piece of code in a function. This can be used to implement non-standard control flow, such as coroutining or backtracking.

So continuations should be used on a system level. Sprinkling them through your application code would be a sure recipe for nightmares, much worse than the worst spaghetti code using goto could ever be.

Disclaimer: I have no in depth understanding of continuations in Scala, I just inferred it from looking at the examples and knowing continuations from Scheme.

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Given the canonical example from the research paper for Scala's delimited continuations, modified slightly so the function input to shift is given the name f and thus is no longer anonymous.

def f(k: Int => Int): Int = k(k(k(7)))
reset(
  shift(f) + 1   // replace from here down with `f(k)` and move to `k`
) * 2

The Scala plugin transforms this example such that the computation (within the input argument of reset) starting from each shift to the invocation of reset is replaced with the function (e.g. f) input to shift.

The replaced computation is shifted (i.e. moved) into a function k. The function f inputs the function k, where k contains the replaced computation, k inputs x: Int, and the computation in k replaces shift(f) with x.

f(k) * 2
def k(x: Int): Int = x + 1

Which has the same effect as:

k(k(k(7))) * 2
def k(x: Int): Int = x + 1

Note the type Int of the input parameter x (i.e. the type signature of k) was given by the type signature of the input parameter of f.

Another borrowed example with the conceptually equivalent abstraction, i.e. read is the function input to shift:

def read(callback: Byte => Unit): Unit = myCallback = callback
reset {
  val byte = "byte"

  val byte1 = shift(read)   // replace from here with `read(callback)` and move to `callback`
  println(byte + "1 = " + byte1)
  val byte2 = shift(read)   // replace from here with `read(callback)` and move to `callback`
  println(byte + "2 = " + byte2)
}

I believe this would be translated to the logical equivalent of:

val byte = "byte"

read(callback)
def callback(x: Byte): Unit {
  val byte1 = x
  println(byte + "1 = " + byte1)
  read(callback2)
  def callback2(x: Byte): Unit {
    val byte2 = x
    println(byte + "2 = " + byte1)
  }
}

I hope this elucidates the coherent common abstraction which was somewhat obfuscated by prior presentation of these two examples. For example, the canonical first example was presented in the research paper as an anonymous function, instead of my named f, thus it was not immediately clear to some readers that it was abstractly analogous to the read in the borrowed second example.

Thus delimited continuations create the illusion of an inversion-of-control from "you call me from outside of reset" to "I call you inside reset".

Note the return type of f is, but k is not, required to be the same as the return type of reset, i.e. f has the freedom to declare any return type for k as long as f returns the same type as reset. Ditto for read and capture (see also ENV below).


Delimited continuations do not implicitly invert the control of state, e.g. read and callback are not pure functions. Thus the caller can not create referentially transparent expressions and thus does not have declarative (a.k.a. transparent) control over intended imperative semantics.

We can explicitly achieve pure functions with delimited continuations.

def aread(env: ENV): Tuple2[Byte,ENV] {
  def read(callback: Tuple2[Byte,ENV] => ENV): ENV = env.myCallback(callback)
  shift(read)
}
def pure(val env: ENV): ENV {
  reset {
    val (byte1, env) = aread(env)
    val env = env.println("byte1 = " + byte1)
    val (byte2, env) = aread(env)
    val env = env.println("byte2 = " + byte2)
  }
}

I believe this would be translated to the logical equivalent of:

def read(callback: Tuple2[Byte,ENV] => ENV, env: ENV): ENV =
  env.myCallback(callback)
def pure(val env: ENV): ENV {
  read(callback,env)
  def callback(x: Tuple2[Byte,ENV]): ENV {
    val (byte1, env) = x
    val env = env.println("byte1 = " + byte1)
    read(callback2,env)
    def callback2(x: Tuple2[Byte,ENV]): ENV {
      val (byte2, env) = x
      val env = env.println("byte2 = " + byte2)
    }
  }
}

This is getting noisy, because of the explicit environment.

Tangentially note, Scala does not have Haskell's global type inference and thus as far as I know couldn't support implicit lifting to a state monad's unit (as one possible strategy for hiding the explicit environment), because Haskell's global (Hindley-Milner) type inference depends on not supporting diamond multiple virtual inheritance.

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I am proposing that reset/shift be changed to delimit/replace. And by convention, that f and read be with, and k and callback be replaced, captured, continuation, or callback. –  Shelby Moore III Nov 6 '12 at 3:48
    
with is a keyword. P.S. Some of your resets have () which should be {} Anyway great writeup! –  nafg Nov 6 '12 at 4:10
    
@nafg thank you, so I will propose replacement instead of with. Afaik, () is also allowed? Afaik, {} is "Scala's lightweight syntax for closures", which is hiding an underlying function call. For example, see how I rewrote Daniel's sequence (note that code was never compiled or tested, so please feel free to correct me). –  Shelby Moore III Nov 6 '12 at 5:04
1  
A block -- that is, an expression containing multiple statements -- requires curly braces. –  nafg Nov 6 '12 at 6:30
    
@nafg, correct. Afaik shift reset are library functions, not keywords. Thus {} or () can be used when the function expects only one parameter. Scala has By-name parameters (see section "9.5 Control Abstractions" of Programming in Scala, 2nd ed. pg. 218), where if the parameter is of type () => ... the () => can be eliminated. I assume Unit and not by-name because the block should evaluate before reset is invoked, but I need {} for multiple statements. My usage for shift is correct, because it obviously inputs a function type. –  Shelby Moore III Nov 6 '12 at 9:14

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