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Why does M(0) and N(0) have different results?

#define CAT_I(a, b) a ## b
#define CAT(a, b) CAT_I(a, b)

#define M_0 CAT(x, y)
#define M_1 whatever_else
#define M(a) CAT(M_, a)
M(0);       //  expands to CAT(x, y)

#define N_0() CAT(x, y)
#define N_1() whatever_else
#define N(a) CAT(N_, a)()
N(0);       //  expands to xy
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Uhhh.... what is it you're exactly trying to achieve here... and for what purpose? –  t0mm13b Apr 12 '11 at 21:30
7  
I don't really want to achieve anything, just noticed this while working on something, and I'm curious about the reasons. It annoys me when I don't understand something :) . –  imre Apr 12 '11 at 21:41

3 Answers 3

up vote 13 down vote accepted

In fact, it depends on your interpretation of the language standard. For example, under mcpp, a preprocessor implementation that strictly conforms to the text of the language standard, the second yields CAT(x, y); as well [extra newlines have been removed from the result]:

C:\dev>mcpp -W0 stubby.cpp
#line 1 "C:/dev/stubby.cpp"
        CAT(x, y) ;
        CAT(x, y) ;
C:\dev>

There is a known inconsistency in the C++ language specification (the same inconsistency is present in the C specification, though I don't know where the defect list is for C). The specification states that the final CAT(x, y) should not be macro-replaced. The intent may have been that it should be macro-replaced.

To quote the linked defect report:

Back in the 1980's it was understood by several WG14 people that there were tiny differences between the "non-replacement" verbiage and the attempts to produce pseudo-code.

The committee's decision was that no realistic programs "in the wild" would venture into this area, and trying to reduce the uncertainties is not worth the risk of changing conformance status of implementations or programs.


So, why do we get different behavior for M(0) than for N(0) with most common preprocessor implementations? In the replacement of M, the second invocation of CAT consists entirely of tokens resulting from the first invocation of CAT:

M(0) 
CAT(M_, 0)
CAT_I(M_, 0)
M_0
CAT(x, y)

If M_0 was instead defined to be replaced by CAT(M, 0), replacement would recurse infinitely. The preprocessor specification explicitly prohibits this "strictly recursive" replacement by stopping macro replacement, so CAT(x, y) is not macro replaced.

However, in the replacement of N, the second invocation of CAT consists only partially of tokens resulting from the first invocation of CAT:

N(0)
CAT(N_, 0)       ()
CAT_I(N_, 0)     ()
N_0              ()
CAT(x, y)
CAT_I(x, y)
xy

Here the second invocation of CAT is formed partially from tokens resulting from the first invocation of CAT and partially from other tokens, namely the () from the replacement list of N. The replacement is not strictly recursive and thus when the second invocation of CAT is replaced, it cannot yield infinite recursion.

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Interesting... The preprocessors in VC++ and the online Comeau compiler both expand N(0) to "xy". –  imre Apr 12 '11 at 21:44
    
Also, is it somehow possible to work around this recursion limitation and make the last CAT evaluate? (Besides defining another alternative CAT?) –  imre Apr 12 '11 at 21:52
1  
I have a dim memory to the effect that because the () supplied to N_0 came from outside any macro expansion, that counts as a new macro expansion, so the "blue paint" comes off CAT() and it can be expanded once more. So this might be a bug in mcpp. FWIW gcc agrees with Comeau and VC++. –  Zack Apr 12 '11 at 21:54
1  
BTW, it's important to note that mcpp scores perfectly on the CPP validation suite ... written by the author of mcpp. So all that score shows is that mcpp does what its author thinks it should; it does not show that it is actually faithful to the C standard. –  Jim Balter Apr 12 '11 at 22:35
1  
@Jim: I would recommend reading the mcpp test suite documentation, which contains an eight page discussion on the subject and explains the contradictions in the specifications and the manner in which the specifications have changed. In C99 the behavior is explicitly unspecified. A conforming implementation may replace the second invocation of CAT or it may not. –  James McNellis Apr 13 '11 at 2:29

Just follow the sequence:

1.)

M(0); //  expands to CAT(x, y) TRUE 
CAT(M_, 0)
CAT_I(M_, 0)
M_0
CAT(x, y)

2.)

N(0); //  expands to xy TRUE
CAT(N_, 0)()
CAT_I(N_, 0)()
N_0()
CAT(x, y)
CAT_I(x, y)
xy

You only need to recursively replace the macros.

Notes on ## preprocessor operator: Two arguments can be 'glued' together using ## preprocessor operator; this allows two tokens to be concatenated in the preprocessed code.

Unlike standard macro expansion, traditional macro expansion has no provision to prevent recursion. If an object-like macro appears unquoted in its replacement text, it will be replaced again during the rescan pass, and so on ad infinitum. GCC detects when it is expanding recursive macros, emits an error message, and continues after the offending macro invocation. (gcc online doc)

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1  
Umm... I still don't get it. The two sequences both reach the same CAT(x, y) -- so why stop there in one case but not the other? –  imre Apr 12 '11 at 21:46
    
I think the recursion here it depends on the interpretation of the standard like James McNellis said. Nice question imre. –  cacho Apr 12 '11 at 22:08
1  
@imre: In the case of M(0), the second CAT(...) invocation results entirely from the first CAT(...) invocation, thus it is a strictly recursive call. In the case of N(0), the second CAT(...) invocation results only partially from the first CAT(...) invocation and partially from other tokens that appear after that (the () in the replacement list of N). Thus, it is not entirely recursive. –  James McNellis Apr 12 '11 at 22:09

There seems to be something that you might have failed to spot but your macro has N(a) CAT(N_,a)(), whereas M(a) is defined as CAT(M_, a) Notice the extra parameter brackets used....

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I know. And correspondingly, N_0 is defined as a function-style (0-argument) macro. And for some reason, that seems to make a difference in recursive evaluations, but I don't know exactly why; that's my question. –  imre Apr 12 '11 at 21:39

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