89

The statement

printf("%f\n",0.0f);

prints 0.

However, the statement

printf("%f\n",0);

prints random values.

I realize I'm exhibiting some kind of undefined behaviour, but I can't figure out why specifically.

A floating point value in which all the bits are 0 is still a valid float with value of 0.
float and int are the same size on my machine (if that is even relevant).

Why does using an integer literal instead of a floating point literal in printf cause this behavior?

P.S. the same behaviour can be seen if I use

int i = 0;
printf("%f\n", i);
25
  • 38
    printf is expecting a double, and you're giving it an int. float and int may be the same size on your machine, but 0.0f is actually converted to a double when pushed into a variadic argument list (and printf expects that). In short, you're not fulfilling your end of the bargain with printf based on the specifiers your using and the arguments you're providing.
    – WhozCraig
    Jul 26, 2016 at 18:24
  • 22
    Varargs-functions don't automatically convert function arguments to the type of the corresponding parameter, because they can't. The necessary information is not available to the compiler, unlike non-varargs functions with a prototype.
    – EOF
    Jul 26, 2016 at 18:25
  • 3
    Oooh... "variadics." I just learned a new word ... Jul 26, 2016 at 18:29
  • 2
    Possible duplicate: Can printf result in undefined behavior? Jul 26, 2016 at 18:46
  • 3
    The next thing to try is to pass a (uint64_t)0 instead of 0 and see whether you still get random behavior (assuming double and uint64_t have the same size and alignment). Chances are the output will still be random on some platforms (e.g. x86_64) due to different types being passed in different registers.
    – Ian Abbott
    Jul 26, 2016 at 20:27

10 Answers 10

122

The "%f" format requires an argument of type double. You're giving it an argument of type int. That's why the behavior is undefined.

The standard does not guarantee that all-bits-zero is a valid representation of 0.0 (though it often is), or of any double value, or that int and double are the same size (remember it's double, not float), or, even if they are the same size, that they're passed as arguments to a variadic function in the same way.

It might happen to "work" on your system. That's the worst possible symptom of undefined behavior, because it makes it difficult to diagnose the error.

N1570 7.21.6.1 paragraph 9:

... If any argument is not the correct type for the corresponding conversion specification, the behavior is undefined.

Arguments of type float are promoted to double, which is why printf("%f\n",0.0f) works. Arguments of integer types narrower than int are promoted to int or to unsigned int. These promotion rules (specified by N1570 6.5.2.2 paragraph 6) do not help in the case of printf("%f\n", 0).

Note that if you pass a constant 0 to a non-variadic function that expects a double argument, the behavior is well defined, assuming the function's prototype is visible. For example, sqrt(0) (after #include <math.h>) implicitly converts the argument 0 from int to double -- because the compiler can see from the declaration of sqrt that it expects a double argument. It has no such information for printf. Variadic functions like printf are special, and require more care in writing calls to them.

14
  • 13
    A couple of excellent core points here. First, that it's double not float so the OP's width assumption may not (probably doesn't) hold. Second, the assumption that integer zero and floating-point zero have the same bit pattern also does not hold. Good work Jul 26, 2016 at 18:34
  • 2
    @LucasTrzesniewski: Ok, but I don't see how my answer begs the question. I did state that float is promoted to double without explaining why, but that wasn't the main point. Jul 26, 2016 at 20:11
  • 2
    @robertbristow-johnson: Compilers don't need to have special hooks for printf, though gcc, for example, does have some so it can diagnose errors (if the format string is a literal). The compiler can see the declaration of printf from <stdio.h>, which tells it that the first parameter is a const char* and the rest are indicated by , .... No, %f is for double (and float is promoted to double), and %lf is for long double. The C standard says nothing about a stack. It specifies the behavior of printf only when it's called correctly. Jul 26, 2016 at 23:53
  • 2
    @robertbristow-johnson: In the olden daze, "lint" often performed some of the extra checking that gcc now performs. A float passed to printf is promoted to double; there's nothing magical about that, it's just a language rule for calling variadic functions. printf itself knows via the format string what the caller claimed to pass to it; if that claim is incorrect, the behavior is undefined. Jul 27, 2016 at 1:07
  • 2
    Small correction: the l length modifier "has no effect on a following a, A, e, E, f, F, g, or G conversion specifier", the length modifier for a long double conversion is L. (@robertbristow-johnson might also be interested) Jul 27, 2016 at 19:29
60

First off, as touched on in several other answers but not, to my mind, spelled out clearly enough: It does work to provide an integer in most contexts where a library function takes a double or float argument. The compiler will automatically insert a conversion. For instance, sqrt(0) is well-defined and will behave exactly as sqrt((double)0), and the same is true for any other integer-type expression used there.

printf is different. It's different because it takes a variable number of arguments. Its function prototype is

extern int printf(const char *fmt, ...);

Therefore, when you write

printf(message, 0);

the compiler does not have any information about what type printf expects that second argument to be. It has only the type of the argument expression, which is int, to go by. Therefore, unlike most library functions, it is on you, the programmer, to make sure the argument list matches the expectations of the format string.

(Modern compilers can look into a format string and tell you that you've got a type mismatch, but they're not going to start inserting conversions to accomplish what you meant, because better your code should break now, when you'll notice, than years later when rebuilt with a less helpful compiler.)

Now, the other half of the question was: Given that (int)0 and (float)0.0 are, on most modern systems, both represented as 32 bits all of which are zero, why doesn't it work anyway, by accident? The C standard just says "this isn't required to work, you're on your own", but let me spell out the two most common reasons why it wouldn't work; that will probably help you understand why it's not required.

First, for historical reasons, when you pass a float through a variable argument list it gets promoted to double, which, on most modern systems, is 64 bits wide. So printf("%f", 0) passes only 32 zero bits to a callee expecting 64 of them.

The second, equally significant reason is that floating-point function arguments may be passed in a different place than integer arguments. For instance, most CPUs have separate register files for integers and floating-point values, so it might be a rule that arguments 0 through 4 go in registers r0 through r4 if they are integers, but f0 through f4 if they are floating-point. So printf("%f", 0) looks in register f1 for that zero, but it's not there at all.

7
  • 1
    Are there any architectures that use registers for variadic functions, even among those that use them for normal functions? I thought that was the reason that variadic functions are required to be properly declared even though other functions [except those with float/short/char arguments] can be declared with ().
    – Random832
    Jul 26, 2016 at 19:20
  • 3
    @Random832 Nowadays, the only difference between a variadic and a normal function's calling convention is that there may be some extra data supplied to a variadic, such as a count of the true number of arguments supplied. Otherwise everything goes in exactly the same place it would for a normal function. See for instance section 3.2 of x86-64.org/documentation/abi.pdf , where the only special treatment for variadics is a hint passed in AL. (Yes, this means the implementation of va_arg is much more complicated than it used to be.)
    – zwol
    Jul 26, 2016 at 19:29
  • @Random832: I always thought the reason was that on some architectures functions with a known number and type of arguments could be implemented more efficiently, by using special instructions.
    – celtschk
    Jul 27, 2016 at 7:36
  • @celtschk You might be thinking of the "register windows" on SPARC and IA64, which were supposed to accelerate the common case of function calls with a small number of arguments (alas, in practice, they do just the opposite). They don't require the compiler to treat variadic function calls specially, because the number of arguments at any one call site is always a compile-time constant, regardless of whether the callee is variadic.
    – zwol
    Jul 27, 2016 at 14:20
  • @zwol: No, I was thinking of the ret n instruction of the 8086, where n was a hard-coded integer, which therefore was not applicable for variadic functions. However I don't know if any C compiler actually took advantage of it (non-C compilers certainly did).
    – celtschk
    Jul 27, 2016 at 15:16
13

Ordinarily when you call a function that expects a double, but you provide an int, the compiler will automatically convert to a double for you. That doesn't happen with printf, because the types of the arguments aren't specified in the function prototype - the compiler doesn't know that a conversion should be applied.

2
  • 4
    Also, printf() in particular is designed so that its arguments could be of any type. You must know which type is expected by each element in the format-string, and you must provide it correctly. Jul 26, 2016 at 18:31
  • @MikeRobinson: Well, any primitive C type. Which is a very, very small subset of all possible types.
    – MSalters
    Jul 27, 2016 at 7:47
13

Why does using an integer literal instead of a float literal cause this behavior?

Because printf() doesn't have typed parameters besides the const char* formatstring as the 1st one. It uses a c-style ellipsis (...) for all the rest.

It's just decides how to interpret the values passed there according to the formatting types given in the format string.

You would have the same kind of undefined behavior as when trying

 int i = 0;
 const double* pf = (const double*)(&i);
 printf("%f\n",*pf); // dereferencing the pointer is UB
5
  • 3
    Some particular implementations of printf might work that way (except that the items passed are values, not addresses). The C standard doesn't specify how printf and other variadic functions work, it just specifies their behavior. In particular, there is no mention of stack frames. Jul 26, 2016 at 18:30
  • A small quibble: printf does have one typed parameter, the format string, which is of type const char*. BTW, the question is tagged both C and C++, and C is really more relevant; I probably wouldn't have used reinterpret_cast as an example. Jul 26, 2016 at 18:43
  • Just an interesting observation: Same undefined behaviour, and most likely due to identical mechanism, but with a small difference in detail: Passing an int as in the question, the UB happens within printf when trying to interprete the int as double - in your example, it happens already outside when dereferencing pf...
    – Aconcagua
    Jul 26, 2016 at 18:54
  • @Aconcagua Added clarification. Jul 26, 2016 at 18:58
  • This code sample is UB for strict aliasing violation, an entirely different problem to what the question is asking about. For example you completely ignore the possibility that floats are passed in different registers to integers.
    – M.M
    Feb 21, 2018 at 3:44
12

Using a mis-matched printf() specifier "%f"and type (int) 0 leads to undefined behavior.

If a conversion specification is invalid, the behavior is undefined. C11dr §7.21.6.1 9

Candidate causes of UB.

  1. It is UB per spec and the compile is ornery - 'nuf said.

  2. double and int are of different sizes.

  3. double and int may pass their values using different stacks (general vs. FPU stack.)

  4. A double 0.0 might not be defined by an all zero bit pattern. (rare)

10

This is one of those great opportunities to learn from your compiler warnings.

$ gcc -Wall -Wextra -pedantic fnord.c 
fnord.c: In function ‘main’:
fnord.c:8:2: warning: format ‘%f’ expects argument of type ‘double’, but argument 2 has type ‘int’ [-Wformat=]
  printf("%f\n",0);
  ^

or

$ clang -Weverything -pedantic fnord.c 
fnord.c:8:16: warning: format specifies type 'double' but the argument has type 'int' [-Wformat]
        printf("%f\n",0);
                ~~    ^
                %d
1 warning generated.

So, printf is producing undefined behavior because you are passing it an incompatible type of argument.

9

I'm not sure what's confusing.

Your format string expects a double; you provide instead an int.

Whether the two types have the same bit width is utterly irrelevant, except that it may help you avoid getting hard memory violation exceptions from broken code like this.

20
  • 3
    @Voo: That format string modifier is unfortunately named, but I still don't see why you'd think that an int would be acceptable here. Jul 26, 2016 at 18:27
  • 1
    @Voo: "(which would also qualify as a valid float pattern)" Why would an int qualify as a valid float pattern? Two's complement and various floating-point encodings have almost nothing in common. Jul 26, 2016 at 18:32
  • 2
    It's confusing because, for most library functions, providing the integer literal 0 to an argument typed double will do the Right Thing. It is not obvious to a beginner that the compiler doesn't do that same conversion for printf argument slots addressed by %[efg].
    – zwol
    Jul 26, 2016 at 18:34
  • 1
    @Voo: If you're interested in how horribly wrong this can go, consider that on x86-64 SysV ABI, floating-point arguments are passed in a different register-set than integer arguments.
    – EOF
    Jul 26, 2016 at 18:43
  • 1
    @LightnessRacesinOrbit I think it's always appropriate to discuss why something is UB, which usually involves talking about what implementation latitude is allowed and what actually happens in common cases.
    – zwol
    Jul 26, 2016 at 18:57
4

"%f\n" guarantees predictable result only when the second printf() parameter has type of double. Next, an extra arguments of variadic functions are subject of default argument promotion. Integer arguments fall under integer promotion, which never results in floating-point typed values. And float parameters are promoted to double.

To top it off: standard allows the second argument to be or float or double and nothing else.

4

Why it is formally UB has now been discussed in several answers.

The reason why you get specifically this behaviour is platform-dependent, but probably is the following:

  • printf expects its arguments according to standard vararg propagation. That means a float will be a double and anything smaller than an int will be an int.
  • You are passing an int where the function expects a double. Your int is probably 32 bit, your double 64 bit. That means that the four stack bytes starting at the place where the argument is supposed to sit are 0, but the following four bytes have arbitrary content. That's what is used for constructing the value which is displayed.
0

The main cause of this "undetermined value" issue stands in the cast of the pointer at the int value passed to the printf variable parameters section to a pointer at double types that va_arg macro carries out.

This causes a referencing to a memory area that was not completely initialized with value passed as parameter to the printf, because double size memory buffer area is greater than int size.

Therefore, when this pointer is dereferenced, it is returned an undetermined value, or better a "value" that contains in part the value passed as parameter to printf, and for the remaining part could came from another stack buffer area or even a code area (raising a memory fault exception), a real buffer overflow.


It can consider these specific portions of semplificated code implementations of "printf" and "va_arg"...

printf

va_list arg;
....
case('%f')
      va_arg ( arg, double ); //va_arg is a macro, and so you can pass it the "type" that will be used for casting the int pointer argument of printf..
.... 


the real implementation in vprintf (considering gnu impl.) of double value parameters code case management is:

if (__ldbl_is_dbl)
{
   args_value[cnt].pa_double = va_arg (ap_save, double);
   ...
}



va_arg

char *p = (double *) &arg + sizeof arg;  //printf parameters area pointer

double i2 = *((double *)p); //casting to double because va_arg(arg, double)
   p += sizeof (double);



references

  1. gnu project glibc implementation of "printf"(vprintf))
  2. example of semplification code of printf
  3. example of semplification code of va_arg

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