How do LISPs or MLs implement tail-call optimization?
I can't speak on the exact implementation details different compilers/interpreters, however generally speaking tail-call optimization operates like this:
Normally a function call involves something like this:
However when a function is in tail position, which pretty much means you are returning the result of the function you are about to call, you can be tricky and do
Note that #1 and #2 don't actually involve any work, #3 can be tricky or simple depending on your implementation, and 4-7 don't involve anything special from the function you are calling. Also note that all of this results in a 0 stack growth with respect to your call stack, so this allows for infinte recursion and generally speeding things up a little.
Also note that this kind of optimization can be applied not only to directly recursive functions, but co-recursive functions and in fact all calls that are in tail position.
It's CPU-architecture and/or operating system dependent what kind of functions can be tail-call optimized. That's because calling conventions (for passing function arguments and/or transferring control between functions) differ between CPUs and/or operating systems. It usually boils down to whether anything passed in the tail call must come from the stack or not. Take, for example, a function like:
If you compile this, even with high optimization (
i.e. a classical function, with stackframe setup/teardown (
In 64bit x86 (Linux), this looks like:
so it got tail-optimized.
On an entirely different type of CPU architecture (SPARC), this looks like (I've left the compiler's comment in):
Yet another one ... ARM (Linux EABI):
The differences here are the way arguments are passed, and control is transferred:
In all architectures where at least some argument passing can happen in registers, tail call optimization can be applied by the compiler on a large variety of functions.