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I realise the answer to this question could be different for different languages, and the language I am most interested in is C++. If the tag needs be changed because this can't be answered in a language-agnostic manner, feel free.

Is it possible to have a function be partially tail-recursive and still get any advantage that being tail-recursive would get you?

As I understand it, tail-recursion is where instead of doing a full function call, the compiler will optimise the function to just change the arguments in place to the new arguments and jump to the beginning of the function.

If you have a function like this:

def example(arg):
    if arg == 0:
        return 0 # base case

    if arg % 2 == 0:
        return example(arg - 1) # should be tail recursive

    return 3 + example(arg - 1) # isn't tail recursive because 3 is added to the result

When an optimiser encounters something like that (where the function is tail-recursive in some cases and not in others) will it turn the one into a jump and the other into a call, or will some fact of optimisation reality (if I knew it I wouldn't be asking) make it have to turn everything into a call and lose all the efficiency you would have had if the function were tail-recursive?

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2 Answers 2

up vote 1 down vote accepted

In Scheme, the first language that comes to mind when I think of tail calls, the second case is guaranteed to be a tail call by the language specification. (Terminology note: it is preferred to refer to such function calls as 'tail calls'.)

The Scheme specification defines exactly what tail calls are in Scheme and mandates that compilers support them specially. You can see the definition in 11.20. Tail calls and tail contexts of R6RS (source).

Note that in Scheme, the specification says nothing about optimization of tail calls. Rather, it says that an implementation must support an unbounded number of active tail calls — a semantic property of the language runtime. They can be implemented as normal calls, but usually aren't.

Example, in C:

Take a C version of your example.

int example(int arg)
    if (arg == 0)
        return 0;
    if ((arg % 2) == 0)
        return example(arg - 1);
    return 3 + example(arg - 1);

Compile it using gcc's usual optimization settings (-O2) for i386:

    pushl   %ebp
    xorl    %eax, %eax
    movl    %esp, %ebp
    movl    8(%ebp), %edx
    testl   %edx, %edx
    jne L5
    jmp L15
    .align 4,0x90
    decl    %edx
    testl   %edx, %edx
    je  L7
    testb   $1, %dl
    je  L14
    decl    %edx
    addl    $3, %eax
    testl   %edx, %edx
    jne L5
    xorl    %eax, %eax

Note that there are no function calls in the assembly code. GCC has not only optimized your tail call into a jump, it optimized the non-tail call into a jump as well.

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As far as I understand it, a smart compiler could apply tail recursion to your first call by just jumping to the example entry point instead of setting up a new stack frame. A following return will unwind the stack to the original caller, effectively "ending" both calls in one step, even if it cannot do that for the other call.

And you could optimize your function by moving the adding of 3 inside the call:

def example(arg, add=0):
    arg += add
    return example(arg - 1, 3)  # tail now too

Another technique would be to create a second function and have both call each other.

I don't know if python or C++ compilers can handle that though, but you can check assembly output for C++. Strangely I think checking bytecode output for python may be harder.

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Yeah I know I can change it where it's unconditionally tail recursive but I wanted to give an example of what I was talking about. And yes, I'm pretty sure that C++ (at least MSVC++) can turn mutually recursive functions into tail-calls. – Seth Carnegie Aug 23 '11 at 1:28
The CPython implementation never optimizes tail calls, and Guido has put his foot down on the subject, calling it "unpythonic". See… – Dietrich Epp Aug 23 '11 at 1:30
@Dietrich yeah, I noticed this when I tried what should have been a tail-recursive factorial function :) too bad guido is so short sighted. – Seth Carnegie Aug 23 '11 at 4:03
@Seth: Please don't talk so rudely of language designers. Tail call optimization comes with trade-offs, it is not an obvious choice. – Dietrich Epp Aug 23 '11 at 6:12

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