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An example of unspecified behavior in the C language the the order of evaluation of arguments to a function. It might be left to right or right to left, you just don't know. This would affect how foo(c++, c) or foo(++c, c) gets evaluated.

What other unspecified behavior is there that can surprise the unaware programmer?

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closed as too broad by templatetypedef, Pascal Cuoq, Steve Barnes, Brad Rem, torazaburo Aug 16 '13 at 11:56

There are either too many possible answers, or good answers would be too long for this format. Please add details to narrow the answer set or to isolate an issue that can be answered in a few paragraphs.If this question can be reworded to fit the rules in the help center, please edit the question.

foo(c++, c) and foo(++c, c) are both undefined behavior, which completely trumps unspecified. –  Pascal Cuoq Aug 15 '13 at 22:03
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13 Answers 13

up vote 36 down vote accepted

A language lawyer question. Hmkay.

My personal top3:

  1. violating the strict aliasing rule
  2. violating the strict aliasing rule
  3. violating the strict aliasing rule


Edit Here is a little example that does it wrong twice:

(assume 32 bit ints and little endian)

float funky_float_abs (float a)
  unsigned int temp = *(unsigned int *)&a;
  temp &= 0x7fffffff;
  return *(float *)&temp;

That code tries to get the absolute value of a float by bit-twiddling with the sign bit directly in the representation of a float.

However, the result of creating a pointer to an object by casting from one type to another is not valid C. The compiler may assume that pointers to different types don't point to the same chunk of memory. This is true for all kind of pointers except void* and char* (sign-ness does not matter).

In the case above I do that twice. Once to get an int-alias for the float a, and once to convert the value back to float.

There are three valid ways to do the same.

Use a char or void pointer during the cast. These always alias to anything, so they are safe.

float funky_float_abs (float a)
  float temp_float = a;
  // valid, because it's a char pointer. These are special.
  unsigned char * temp = (unsigned char *)&temp_float;
  temp[3] &= 0x7f;
  return temp_float;

Use memcopy. Memcpy takes void pointers, so it will force aliasing as well.

float funky_float_abs (float a)
  int i;
  float result;
  memcpy (&i, &a, sizeof (int));
  i &= 0x7fffffff;
  memcpy (&result, &i, sizeof (int));
  return result;

The third valid way: use unions. This is explicitly not undefined since C99:

float funky_float_abs (float a)
     unsigned int i;
     float f;
  } cast_helper;

  cast_helper.f = a;
  cast_helper.i &= 0x7fffffff;
  return cast_helper.f;
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This sounds interesting...can you expand? –  Benoit Sep 19 '08 at 0:39
aehm. I mentioned that I assume 32 bit ints and little endian. Btw - the union usage is still undefined behaviour not because of the IEEE bit representation but simply because you are (in theory) not allowed to write into field f and read from field i. –  Nils Pipenbrinck Sep 19 '08 at 14:34
onebyone, it's undefined behavior even if the implementation uses ieee. the point is it reads from a different member that was last written to. –  Johannes Schaub - litb Dec 21 '08 at 0:38
csci.csusb.edu/dick/c++std/cd2/basic.html#basic.lval bullet 15 seems to imply that type punning through a union is safe. The wording in the c standard is identical. –  Greg Rogers Dec 22 '08 at 15:20
the C99 standard allows type punning through unions; see footnote 82, which was added with TC3: "If the member used to access the contents of a union object is not the same as the member last used to store a value in the object, the appropriate part of the object representation of the value is reinterpreted as an object representation in the new type as described in 6.2.6 (a process sometimes called "type punning"). This might be a trap representation." –  Christoph Jan 28 '10 at 20:52
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My personal favourite undefined behaviour is that if a non-empty source file doesn't end in a newline, behaviour is undefined.

I suspect it's true though that no compiler I will ever see has treated a source file differently according to whether or not it is newline terminated, other than to emit a warning. So it's not really something that will surprise unaware programmers, other than that they might be surprised by the warning.

So for genuine portability issues (which mostly are implementation-dependent rather than unspecified or undefined, but I think that falls into the spirit of the question):

  • char is not necessarily (un)signed.
  • int can be any size from 16 bits.
  • floats are not necessarily IEEE-formatted or conformant.
  • integer types are not necessarily two's complement, and integer arithmetic overflow causes undefined behaviour (modern hardware won't crash, but some compiler optimizations will result in behavior different from wraparound even though that's what the hardware does. For example if (x+1 < x) may be optimized as always false when x has signed type: see -fstrict-overflow option in GCC).
  • "/", "." and ".." in a #include have no defined meaning and can be treated differently by different compilers (this does actually vary, and if it goes wrong it will ruin your day).

Really serious ones that can be surprising even on the platform you developed on, because behaviour is only partially undefined / unspecified:

  • POSIX threading and the ANSI memory model. Concurrent access to memory is not as well defined as novices think. volatile doesn't do what novices think. Order of memory accesses is not as well defined as novices think. Accesses can be moved across memory barriers in certain directions. Memory cache coherency is not required.

  • Profiling code is not as easy as you think. If your test loop has no effect, the compiler can remove part or all of it. inline has no defined effect.

And, as I think Nils mentioned in passing:

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Steve - I encountered exactly what you described (the ending newline problem) in the early 90s w/ the Microtec compiler for the 68K family. I thought the tool was buggy, but I just added the newline "to work around the stupid tool". Unlike my overconfident co-worker (see my other comment on this subject), I wasn't so cocksure that I'd write a defect report... good thing I didn't. –  Dan Jan 28 '11 at 3:24
Signed integer overflow being undefined isn't just pedantry; at least GCC applies optimizations on the assumption that it never happens, such as 'if (a + 1 > a)' always passing and never detecting wraparound. –  BCoates Nov 29 '11 at 23:29
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My favorite is this:

// what does this do?
x = x++;

To answer some comments, it is undefined behaviour according to the standard. Seeing this, the compiler is allowed to do anything up to and including format your hard drive. See for example this comment here. The point is not that you can see there is a possible reasonable expectation of some behaviour. Because of the C++ standard and the way the sequence points are defined, this line of code is actually undefined behaviour.

For example, if we had x = 1 before the line above, then what would the valid result be afterwards? Someone commented that it should be

x is incremented by 1

so we should see x == 2 afterwards. However this is not actually true, you will find some compilers that have x == 1 afterwards, or maybe even x == 3. You would have to look closely at the generated assembly to see why this might be, but the differences are due to the underlying problem. Essentially, I think this is because the compiler is allowed to evaluate the two assignments statements in any order it likes, so it could do the x++ first, or the x = first.

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Modifying a variable more than once between two sequence points is explicitly stated as undefined behaviour in both standard C and C++. –  KTC Sep 19 '08 at 4:42
I'm cracking up laughing right now at the thought of someone writing a C compiler that formats your hard drive upon seeing x = x++ because it's undefined in the standard :-) –  dancavallaro Dec 21 '08 at 1:31
+1, especially for the "formatting hard drive part". Actually, for people who code like this, formatting the hard drive might save future generations of maintenance programmers a lot of grief... –  sleske Dec 28 '09 at 0:59
2 things: 1) it's absolutely undefined behavior; about 15 years ago I debated with someone in my group who wrote a defect report to the compiler vendor (yikes!) when he wrote this exact code (except he used "i" instead of "x") and "i" was stuck at 1; and 2) I laughed when I read the part about formatting the hard drive, probably because that's the kind of thing I'd say too. –  Dan Jan 28 '11 at 3:20
I would say that x is incremented, then assigned with it's previous value, because x++ returns that and has precedence over assignment. But yeah it's undefined... As many things in the language (making a lot of headache...) –  Calmarius Dec 9 '11 at 8:49
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Dividing something by a pointer to something. Just won't compile for some reason... :-)

result = x/*y;
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result = x/(*y) should work. –  Charles Graham Sep 19 '08 at 0:54
Haha nice one, I am writing it down :-) –  Drealmer Sep 19 '08 at 7:50
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A compiler doesn't have to tell you that you're calling a function with the wrong number of parameters/wrong parameter types if the function prototype isn't available.

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Yes. Benevolent compilers however will usually help you with a warning... –  sleske Dec 28 '09 at 1:04
As of C99, calling a function with no visible declaration requires a diagnostic. That declaration doesn't have to be a prototype (i.e., a declaration that specifies the types of the parameters), but it always should be. (Variadic functions like printf can still be problematic.) –  Keith Thompson Aug 15 '13 at 20:08
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Another issue I encountered (which is defined, but definitely unexpected).

char is evil.

  • signed or unsigned depending on what the compiler feels
  • not mandated as 8 bits
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Well, it's not evil if you use it for what it is meant for, i.e. for characters... –  sleske Dec 28 '09 at 1:03
Actually, there are three different types of char: char, unsigned char and signed char. They are explicitly distinct types. –  Lstor Apr 11 '12 at 9:16
Sorry to be blunt, but that answer is stupid. You must use (pointers to or arrays of plain) char when dealing with strings. Many standard library functions (like all the str*() functions) take pointers to char and giving them anything else requires ugly casts. –  Jens Sep 5 '13 at 15:54
Who said anything about strings ? Embedded programmers sometimes play with variable size for efficiency. Assuming anything about char doesn't work cross-platform. Calling library functions aimed at strings, but defined when a string was simply a char* and Unicode had not been invented may be OK, but if I'm going to be blunt... not writing programs to at least support unicode characters is stupid –  itj Sep 9 '13 at 7:11
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The clang developers posted some great examples a while back, in a post every C programmer should read. Some interesting ones not mentioned before:

  • Signed integer overflow - no it's not ok to wrap a signed variable past its max.
  • Dereferencing a NULL Pointer - yes this is undefined, and might be ignored, see part 2 of the link.
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The EE's here just discovered that a>>-2 is a bit fraught.

I nodded and told them it was not natural.

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Be sure to always initialize your variables before you use them! When I had just started with C, that caused me a number of headaches.

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I can't count the number of times I've corrected printf format specifiers to match their argument. Any mismatch is undefined behavior.

  • No, you must not pass an int (or long) to %x - an unsigned int is required
  • No, you must not pass an unsigned int to %d - an int is required
  • No, you must not pass a size_t to %u or %d - use %zu
  • No, you must not print a pointer with %d or %x - use %p and cast to a void *
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The standard implies (in a non-normative footnote) that passing an int to %x, or an unsigned int to %d, is ok as long as the value is within the range of both types. Still, I prefer to avoid it. –  Keith Thompson Aug 15 '13 at 19:58
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I've seen a lot of relatively inexperienced programmers bitten by multi-character constants.



is a string literal (which is of type char[2] and decays to char* in most contexts).



is an ordinary character constant (which, for historical reasons, is of type int).



is also a perfectly legal character constant, but its value (which is still of type int) is implementation-defined. It's a nearly useless language feature that serves mostly to cause confusion.

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Using the macro versions of functions like "max" or "isupper". The macros evaluate their arguments twice, so you will get unexpected side effects when you call max(++i, j), or isupper(*p++)

The above is for standard C. In C++ these problems have largely disappeared. The max function is now a templated function.

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onebyone, whether it's UB or not depends on the implementation of those. if it's a > b ? a : b; then it's not. but if it happens to use a or b between two sequence points more than once, then it is UB (with a or b being ++i) –  Johannes Schaub - litb Dec 21 '08 at 0:33
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forgetting to add static float foo(); in the header file, only to get floating point exceptions being thrown when it would return 0.0f;

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