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After discovering the Boost preprocessor's capabilities I found myself wondering: Is the C99 preprocessor Turing complete?

If not, what does it lack to not qualify?

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The missing thing in CPP for turing completeness is essentially recursion, since it can't loop without it (and really has a fairly limited conditional since you can't conditionally expand portions of a macro) – Spudd86 Jun 29 '10 at 16:18
up vote 28 down vote accepted

Here is an example of abusing the preprocessor to implement a Turing machine. Note that an external build script is needed to feed the preprocessor's output back into its input, so the preprocessor in and of itself isn't Turing complete. Still, it's an interesting project.

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This answer is incorrect, as the 77 point answer below it shows extensively. Please unaccept it and accept the more useful answer, thank you. – nightpool Oct 12 '15 at 14:25

Well macros don't directly expand recursively, but there are ways we can work around this.

The easiest way of doing recursion in the preprocessor is to use a deferred expression. A deferred expression is an expression that requires more scans to fully expand:

#define EMPTY()
#define DEFER(id) id EMPTY()
#define OBSTRUCT(...) __VA_ARGS__ DEFER(EMPTY)()
#define EXPAND(...) __VA_ARGS__

#define A() 123
A() // Expands to 123
DEFER(A)() // Expands to A () because it requires one more scan to fully expand
EXPAND(DEFER(A)()) // Expands to 123, because the EXPAND macro forces another scan

Why is this important? Well when a macro is scanned and expanding, it creates a disabling context. This disabling context will cause a token, that refers to the currently expanding macro, to be painted blue. Thus, once its painted blue, the macro will no longer expand. This is why macros don't expand recursively. However, a disabling context only exists during one scan, so by deferring an expansion we can prevent our macros from becoming painted blue. We will just need to apply more scans to the expression. We can do that using this EVAL macro:

#define EVAL(...)  EVAL1(EVAL1(EVAL1(__VA_ARGS__)))
#define EVAL1(...) EVAL2(EVAL2(EVAL2(__VA_ARGS__)))
#define EVAL2(...) EVAL3(EVAL3(EVAL3(__VA_ARGS__)))
#define EVAL3(...) EVAL4(EVAL4(EVAL4(__VA_ARGS__)))
#define EVAL4(...) EVAL5(EVAL5(EVAL5(__VA_ARGS__)))
#define EVAL5(...) __VA_ARGS__

Now if we want to implement a REPEAT macro using recursion, first we need some increment and decrement operators to handle state:

#define CAT(a, ...) PRIMITIVE_CAT(a, __VA_ARGS__)
#define PRIMITIVE_CAT(a, ...) a ## __VA_ARGS__

#define INC(x) PRIMITIVE_CAT(INC_, x)
#define INC_0 1
#define INC_1 2
#define INC_2 3
#define INC_3 4
#define INC_4 5
#define INC_5 6
#define INC_6 7
#define INC_7 8
#define INC_8 9
#define INC_9 9

#define DEC(x) PRIMITIVE_CAT(DEC_, x)
#define DEC_0 0
#define DEC_1 0
#define DEC_2 1
#define DEC_3 2
#define DEC_4 3
#define DEC_5 4
#define DEC_6 5
#define DEC_7 6
#define DEC_8 7
#define DEC_9 8

Next we need a few more macros to do logic:

#define CHECK_N(x, n, ...) n
#define CHECK(...) CHECK_N(__VA_ARGS__, 0,)

#define NOT_0 ~, 1,

#define COMPL_0 1
#define COMPL_1 0

#define BOOL(x) COMPL(NOT(x))

#define IIF(c) PRIMITIVE_CAT(IIF_, c)
#define IIF_0(t, ...) __VA_ARGS__
#define IIF_1(t, ...) t

#define IF(c) IIF(BOOL(c))

#define EAT(...)
#define EXPAND(...) __VA_ARGS__
#define WHEN(c) IF(c)(EXPAND, EAT)

Now with all these macros we can write a recursive REPEAT macro. We use a REPEAT_INDIRECT macro to refer back to itself recursively. This prevents the macro from being painted blue, since it will expand on a different scan(and using a different disabling context). We use OBSTRUCT here, which will defer the expansion twice. This is necessary because the conditional WHEN applies one scan already.

#define REPEAT(count, macro, ...) \
    WHEN(count) \
    ( \
        ( \
            DEC(count), macro, __VA_ARGS__ \
        ) \
        OBSTRUCT(macro) \
        ( \
            DEC(count), __VA_ARGS__ \
        ) \

//An example of using this macro
#define M(i, _) i
EVAL(REPEAT(8, M, ~)) // 0 1 2 3 4 5 6 7

Now this example is limited to 10 repeats, because of limitations of the counter. Just like a repeat counter in a computer would be limited by the finite memory. Multiple repeat counters could be combined together to workaround this limitation, just like in a computer. Furthermore, we could define a FOREVER macro:

#define FOREVER() \
    ? \
// Outputs question marks forever

This will try to output ? forever, but will eventually stop because there are no more scans being applied. Now the question is, if we gave it an infinite number of scans would this algorithm complete? This is known as the halting problem, and Turing completeness is necessary to prove the undecidability of the halting problem. So as you can see, the preprocessor can act as a Turing complete language, but instead of being limited to the finite memory of a computer it is instead limited by the finite number of scans applied.

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...Wow. Very impressive! Here I thought that the C99 preprocessor was definetely not turing complete.. +1 for thinking out of the box – Earlz Aug 11 '12 at 2:36
+1 Quite a creative way to show that preprocessor can scan symbols on a tape ;-) (Thanks to the mod for accepting the flagging to remove the wiki!). – P.P. Feb 12 '14 at 21:55
I like how this uses O(log(N)) macros to recurse N times. This is better than Boost Preprocessor which uses O(N) macros. – qbt937 Jan 3 at 0:16
@qbt937 The EVAL macro applies over 250 scans to the algorithm even it is not needed. Whereas Boost.PP only uses the number of scans that is needed by the algorithm, so Boost.PP is much more efficient. – Paul Fultz II Jan 14 at 0:10
@Paul I guess that it is a sort of a macro source size vs speed trade off. This does make me wonder if there is a way to get both log(N) macro size and Boost.PP's reduced number of scans. Maybe it would be possible to quit at the first power of two number of scans after the algorithm finishes, so it would only have up to N extra scans. – qbt937 Jan 14 at 6:33

It's Turing complete within limits (as are all computers since they don't have infinite RAM). Check out the kinds of things you can do with Boost Preprocessor.

Edit in response to question edits:

The main limitation on Boost is the maximum macro expansion depth which is compiler-specific. Also, the macros that implement recursion (FOR..., ENUM..., etc.) aren't truly recursive, they just appear that way thanks to a bunch of near-identical macros. In the big picture, this limitation is no different than having a maximum stack size in an actually recursive language.

The only two things that are really necessary for limited Turing-completeness (Turing-compatibility?) are iteration/recursion (equivalent constructs) and conditional branching.

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hi. That was actually what prompted my question, I have been using preprocessor for a while. – Anycorn Jun 28 '10 at 22:54
Erp.. yeah, go me reading the question >< – Cogwheel Jun 28 '10 at 22:55
I believe that macros can't do recursion. Boost just seems to simulate them by having hardcoded macros named like macro0, macro1 .. macro255. I'm not sure whether that counts as "turing complete". The preprocessor has an explicit rule that forbids going from macro255 back to macro0 :( It seems like trying to build a verifyer for fully parenthesized expressions using a finite state automaton. It can work for a limited number of parentheses, but that's not a general verifyer anymore. I've no clue about boost.pp inner workings though, so i could likely be wrong on this. – Johannes Schaub - litb Jun 28 '10 at 23:23
@Johannes: The chaos preprocessor doesn't have any macros like that. Check it out here: sourceforge.net/projects/chaos-pp – Joe D Aug 24 '10 at 21:01
@0x69 m4 is arcane black magic – hirschhornsalz May 10 '12 at 13:49

To be Turing complete, one needs to define recursion that may never finish (one calls them mu-recursive operator -- https://en.wikipedia.org/wiki/%CE%9C-recursive_function).

To define such an operator one needs an infinite space of identifiers (in case that each identifier is evaluated a finite number of times), as one cannot know a priori an upper limit O(n) in which the result is found.

So this class of functions cannot be computed by the C preprocessor.

The C preprocessor can compute only sigma-recursive operators -- https://en.wikipedia.org/wiki/Primitive_recursive_function .

For details see the course of computation of Marvin L. Minsky (1967) -- Computation: Finite and Infinite Machines, Prentice-Hall, Inc. Englewood Cliffs, N.J. etc.

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