|
I'm working on a Scheme interpreter written in C. Currently it uses the C runtime stack as its own stack, which is presenting a minor problem with implementing continuations. My current solution is manual copying of the C stack to the heap then copying it back when needed. Aside from not being standard C, this solution is hardly ideal. What is the simplest way to implement continuations for Scheme in C? |
||||
|
|
|
I remember reading an article that may be of help to you: Cheney on the M.T.A. :-) Some implementations of Scheme I know of, such as SISC, allocate their call frames on the heap. @ollie: You don't need to do the hoisting if all your call frames are on the heap. There's a tradeoff in performance, of course: the time to hoist, versus the overhead required to allocate all frames on the heap. Maybe it should be a tunable runtime parameter in the interpreter. :-P |
||||
|
|
|
A good summary is available in Implementation Strategies for First-Class Continuations, an article by Clinger, Hartheimer, and Ost. I recommend looking at Chez Scheme's implementation in particular. Stack copying isn't that complex and there are a number of well-understood techniques available to improve performance. Using heap-allocated frames is also fairly simple, but you make a tradeoff of creating overhead for "normal" situation where you aren't using explicit continuations. If you convert input code to continuation passing style (CPS) then you can get away with eliminating the stack altogether. However, while CPS is elegant it adds another processing step in the front end and requires additional optimization to overcome certain performance implications. |
||||
|
|
|
The traditional way is to use setjmp and longjmp, though there are caveats. Here's a reasonably good explanation |
|||
|
|
|
If you are starting from scratch, you really should look in to Continuation Passing Style (CPS) transformation. Good sources include "LISP in small pieces" and Marc Feeley's scheme in 90 minutes presentation: http://www.iro.umontreal.ca/~boucherd/mslug/meetings/20041020/minutes-en.html . |
|||
|
|
|
Examples that you can look at are: Chicken (a Scheme implementation, written in C that support continuations); Paul Graham's On Lisp - where he creates a CPS transformer to implement a subset of continuations in Common Lisp; and Weblocks - a continuation based web framework, which also implements a limited form of continuations in Common Lisp. |
|||
|
|
|
Continuations aren't the problem: you can implement those with regular higher-order functions using CPS. The issue with naive stack allocation is that tail calls are never optimised, which means you can't be scheme. The best current approach to mapping scheme's spaghetti stack onto the stack is using trampolines: essentially extra infrastructure to handle non-C-like calls and exits from procedures. See Trampolined Style (ps). There's some code illustrating both of these ideas. |
|||
|
|
|
It seems Dybvig's thesis is unmentioned so far. It is a delight to read. The heap based model is the easiest to implement, but the stack based is more efficient. Ignore the string based model. R. Kent Dybvig. "Three Implementation Models for Scheme". http://www.cs.indiana.edu/~dyb/papers/3imp.pdf Also check out the implementation papers on ReadScheme.org. http://library.readscheme.org/page8.html The abstract is as follows:
|
|||
|
|
|
Besides the nice answers you've got so far, I recommend Andrew Appel's Compiling with Continuations. It's very well written and while not dealing directly with C, it is a source of really nice ideas for compiler writers. The Chicken Wiki also has pages that you'll find very interesting, such as internal structure and compilation process (where CPS is explained with an actual example of compilation). |
||||
|
|
|
Continuations basically consist of the saved state of the stack and CPU registers at the point of context switches. At the very least you don't have to copy the entire stack to the heap when switching, you could only redirect the stack pointer. Continuations are trivially implemented using fibers. http://en.wikipedia.org/wiki/Fiber_%28computer_science%29 . The only thing that needs careful encapsulation is parameter passing and return values. In Windows fibers are done using the CreateFiber/SwitchToFiber family of calls. in Posix-compliant systems it can be done with makecontext/swapcontext. boost::coroutine has a working implementation of coroutines for C++ that can serve as a reference point for implementation. |
|||||
|
|
Use an explicit stack instead. |
|||||
|
|
Patrick is correct, the only way you can really do this is to use an explicit stack in your interpreter, and hoist the appropriate segment of stack into the heap when you need to convert to a continuation. This is basically the same as what is needed to support closures in languages that support them (closures and continuations being somewhat related). |
|||
|
|
