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I bumped into this strange macro code in /usr/include/linux/kernel.h:

/* Force a compilation error if condition is true, but also produce a
   result (of value 0 and type size_t), so the expression can be used
   e.g. in a structure initializer (or where-ever else comma expressions
   aren't permitted). */
#define BUILD_BUG_ON_ZERO(e) (sizeof(struct { int:-!!(e); }))
#define BUILD_BUG_ON_NULL(e) ((void *)sizeof(struct { int:-!!(e); }))

What does :-!! do?

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185  
@Lundin One thing you may be overlooking is that the kernel must compile on a wide variety of architectures. One cost of this is that you will inevitably see some apparent strangeness to handle this or that case. I think it's fair to extend Linus the benefit of the doubt here. After all, if you gaze into the abyss for too long, pretty soon the abyss gazes back at you. :) –  John Feminella Feb 10 '12 at 15:46
26  
@Lundin: git blame tells us that this particular form of static assertion was introduced by Jan Beulich in 8c87df4. Obviously he had good reasons to do it (see the commit message). –  Niklas B. Feb 10 '12 at 16:34
44  
@Lundin: If this is the reason to stay away from Linux machines, then please name just one modern operating system the source code of which looks better. –  Sven Marnach Feb 10 '12 at 17:32
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@Lundin: assert() does NOT cause a compile-time error. That's the whole point of the above construction. –  Chris K Feb 10 '12 at 21:19
8  
@foljs: there's no need to resort to personal attacks here. Everyone learns the difference between a build failure and an assert() at some point, and today is Lundin's day. Life goes on. –  sarnold Feb 11 '12 at 3:01

6 Answers 6

up vote 836 down vote accepted

This is, in effect, a way to check whether the expression e can be evaluated to be 0, and if not, to fail the build.

The macro is somewhat misnamed; it should be something more like BUILD_BUG_OR_ZERO, rather than ...ON_ZERO. (There have been occasional discussions about whether this is a confusing name.)

You should read the expression like this:

sizeof(struct { int: -!!(e); }))
  1. (e): Compute expression e.

  2. !!(e): Logically negate twice: 0 if e == 0; otherwise 1.

  3. -!!(e): Numerically negate: 0 if e == 0; otherwise -1.

  4. struct{int: -!!(0);} --> struct{int: 0;}: If it was zero, then we declare a struct with an anonymous integer bitfield that has width zero. Everything is fine and we proceed as normal.

  5. struct{int: -!!(1);} --> struct{int: -1;}: On the other hand, if it isn't zero, then it will be some negative number. Declaring any bitfield with negative width is a compilation error.

So we'll either wind up with a bitfield that has width 0 in a struct, which is fine, or a bitfield with negative width, which is a compilation error. Then we take sizeof that field, so we get a size_t with the appropriate width (which will be zero in the case where e is zero).


Some people have asked: Why not just use an assert?

keithmo's answer here has a good response:

These macros implement a compile-time test, while assert() is a run-time test.

Exactly right. You don't want to detect problems in your kernel at runtime that could have been caught earlier! It's a critical piece of the operating system. To whatever extent problems can be detected at compile time, so much the better.

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49  
recent variants of C++ or C standards have something like static_assert for related purposes. –  Basile Starynkevitch Feb 10 '12 at 17:00
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@Lundin - #error would require use of 3 lines of code #if/#error/#endif, and would only work for evaluations accessible to the pre-processor. This hack works for any evaluation accessible to the compiler. –  Ed Staub Feb 10 '12 at 17:50
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The Linux kernel does not use C++, at least not while Linus is still alive. –  Mark Ransom Feb 10 '12 at 17:52
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It is worth noting that !!e does not evaluate to zero "or a nonzero positive number", but rather to zero or one, specifically. Boolean expressions in C are defined to always evaluate to zero or one. –  Dolda2000 Feb 11 '12 at 8:48
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I'd wondered about that too, especially as I explicitly said 0 or 1 but I assumed you were writing like a pure mathematician and claiming just enough to prove the point, and no more than necessary. –  David Heffernan Feb 11 '12 at 14:08

The : is a bitfield. As for !!, that is logical double negation and so returns 0 for false or 1 for true. And the - is a minus sign, i.e. arithmetic negation.

It's all just a trick to get the compiler to barf on invalid inputs.

Consider BUILD_BUG_ON_ZERO. When -!!(e) evaluates to a negative value, that produces a compile error. Otherwise -!!(e) evaluates to 0, and a 0 width bitfield has size of 0. And hence the macro evaluates to a size_t with value 0.

The name is weak in my view because the build in fact fails when the input is not zero.

BUILD_BUG_ON_NULL is very similar, but yields a pointer rather than an int.

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5  
is sizeof(struct { int:0; }) strictly conforming? –  ouah Feb 10 '12 at 15:08
2  
Why would the result in general be 0? A struct with only an empty bitfield, true, but I don't think that struct with size 0 are allowed. E.g if you'd create an array of that type, the individual array elements still must have different addresses, no? –  Jens Gustedt Feb 10 '12 at 15:09
1  
they actually don't care as as they use GNU extensions, they disable strict aliasing rule and don't consider integer overflows as UB. But I was wondering if this is strictly conforming C. –  ouah Feb 10 '12 at 15:13
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@ouah regarding unnamed zero length bitfields, see here: stackoverflow.com/questions/4297095/… –  David Heffernan Feb 10 '12 at 15:14
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@ouah Pretty much identical text is present in the C standard also. –  David Heffernan Feb 10 '12 at 15:36

Some people seem to be confusing these macros with assert().

These macros implement a compile-time test, while assert() is a run-time test.

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3  
So what? How does it matter whether the Linux dev cries during compilation or cries during the first execution? As long as the production code does what it's supposed to do. –  Lundin Feb 10 '12 at 15:39
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@Lundin Are you joking? Clearly it is much better to have a compiler error in your kernel, than to leave it undiscovered until you launch a cruise missile whose guidance system initiates a kernel-panic. –  John Feminella Feb 10 '12 at 15:50
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@JohnFeminella: Yes I'm joking, who have ever heard of people that actually try to run the code they have written! Testing - hah! It compiles, ship it! –  Lundin Feb 10 '12 at 15:53
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@Lundin: It isn't irony and sarcasm if you still think that it doesn't matter. It does matter. It matters a lot, and a compilation error is miles ahead of a runtime one. And if you think all it takes to fix runtime errors is to run your code at least once... well see my comment above. –  gparent Feb 14 '12 at 19:24
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@Lundin: Actually I do understand all this, you just don't make it obvious that you do. And either way, it'd STILL be better at compile time than run time, making the whole argument irrelevant. –  gparent Feb 15 '12 at 21:17

It's creating a size 0 bitfield if the condition is false, but a size -1 (-!!1) bitfield if the condition is true/non-zero. In the former case, there is no error and the struct is initialized with an int member. In the latter case, there is a compile error (and no such thing as a size -1 bitfield is created, of course).

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3  
Actually it's returning a size_t with value 0 in case the condition is true. –  David Heffernan Feb 10 '12 at 14:58

Well, I am quite surprised that the alternatives to this syntax have not been mentioned. Another common (but older) mechanism is to call a function that isn't defined and rely on the optimizer to compile-out the function call if your assertion is correct.

#define MY_COMPILETIME_ASSERT(test)              \
    do {                                         \
        extern void you_did_something_bad(void); \
        if (!(test))                             \
            you_did_something_bad(void);         \
    } while (0)

While this mechanism works (as long as optimizations are enabled) it has the downside of not reporting an error until you link, at which time it fails to find the definition for the function you_did_something_bad(). That's why kernel developers starting using tricks like the negative sized bit-field widths and the negative-sized arrays (the later of which stopped breaking builds in GCC 4.4).

In sympathy for the need for compile-time assertions, GCC 4.3 introduced the the error function attribute that allows you to extend upon this older concept, but generate a compile-time error with a message of your choosing -- no more cryptic "negative sized array" error messages!

#define MAKE_SURE_THIS_IS_FIVE(number)                          \
    do {                                                        \
        extern void this_isnt_five(void) __attribute__((error(  \
                "I asked for five and you gave me " #number))); \
        if ((number) != 5)                                      \
            this_isnt_five();                                   \
    } while (0)

In fact, as of Linux 3.9, we now have a macro called compiletime_assert which uses this feature and most of the macros in bug.h have been updated accordingly. Still, this macro can't be used as an initializer. However, using by statement expressions (another GCC C-extension), you can!

#define ANY_NUMBER_BUT_FIVE(number)                           \
    ({                                                        \
        typeof(number) n = (number);                          \
        extern void this_number_is_five(void) __attribute__(( \
                error("I told you not to give me a five!"))); \
        if (n == 5)                                           \
            this_number_is_five();                            \
        n;                                                    \
    })

This macro will evaluate its parameter exactly once (in case it has side-effects) and create a compile-time error that says "I told you not to give me a five!" if the expression evaluates to five or is not a compile-time constant.

So why aren't we using this instead of negative-sized bit-fields? Alas, there are currently many restrictions of the use of statement expressions, including their use as constant initializers (for enum constants, bit-field width, etc.) even if the statement expression is completely constant its self (i.e., can be fully evaluated at compile-time and otherwise passes the __builtin_constant_p() test). Further, they cannot be used outside of a function body.

Hopefully, GCC will amend these shortcomings soon and allow constant statement expressions to be used as constant initializers. The challenge here is the language specification defining what is a legal constant expression. C++11 added the constexpr keyword for just this type or thing, but no counterpart exists in C11. While C11 did get static assertions, which will solve part of this problem, it wont solve all of these shortcomings. So I hope that gcc can make a constexpr functionality available as an extension via -std=gnuc99 & -std=gnuc11 or some such and allow its use on statement expressions et. al.

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1  
All of your solutions are NOT alternatives. The comment above the macro is pretty clear "so the expression can be used e.g. in a structure initializer (or where-ever else comma expressions aren't permitted)." The macro returns an expression of type size_t –  Wiz Jul 22 '13 at 18:09
    
@Wiz Yes, I am aware of this. Perhaps this was a bit verbose and maybe I need to re-visit my wording, but my point was to explore the various mechanisms for static assertions and show why we're still using negative sized bitfields. In short, if we get a mechanism for constant statement expression, we will have other options open. –  Daniel Santos Jul 23 '13 at 20:52

Well, I don't see why the beautiful division by zero haven't been used for this, as in:

#define BUILD_BUG_ON_ZERO(e) (0 / !e)

Which would evaluate into a zero, as long as e is zero, and would raise a compile-time error warning that you have divided by zero. Alternatively modulo by zero would also do the same:

#define BUILD_BUG_ON_ZERO(e) (0 % !e)

The macro-in-question does what all the others have explained (one year ago); and if I am not mistaken, it does the same of what these two macros do. Maybe just the tiny difference that mine produces an int result, instead of an unsigned int = size_t, which can be covered by typecasting if you really want to have an unsigned int.

One upside; you'd probably have understood what's going on at the first sight, if this was the macro being used.

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1  
This will still build the program since it is a warning which would probably just get lost in the build output noise –  FDinoff Feb 22 at 17:28

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