In the following code, I memset() a stdbool.h bool variable to value 123. (Perhaps this is undefined behaviour?) Then I pass a pointer to this variable to a victim function, which tries to protect against unexpected values using a conditional operation. However, GCC for some reason seems to remove the conditional operation altogether.

#include <stdio.h>
#include <stdbool.h>
#include <string.h>

void victim(bool* foo)
    int bar = *foo ? 1 : 0;
    printf("%d\n", bar);

int main()
    bool x;
    bool *foo = &x;
    memset(foo, 123, sizeof(bool));
    return 0;
user@host:~$ gcc -Wall -O0 test.c
user@host:~$ ./a.out 

What makes this particularly annoying is that the victim() function is actually inside a library, and will crash if the value is more than 1.

Reproduced on GCC versions 4.8.2-19ubuntu1 and 4.7.2-5. Not reproduced on clang.

  • From C99 standard: 6.5.2 2 An object declared as type _Bool is large enough to store the values 0 and 1. Dec 26, 2014 at 20:49
  • 10
    By defining x as a bool, you've promised the compiler that you'll only store 0 or 1 in it. By storing 123 in x1, you've lied to the compiler. "If you lie to the compiler, it will get its revenge." -- Henry Spencer Dec 26, 2014 at 20:52
  • 3
    @SeverinPappadeux: Yes, but since any non-bitfield object must be at least CHAR_BIT bits (and CHAR_BIT >= 8), it's also large enough to hold the value 123. You're not prevented from storing 123 in a bool object because of its size, but it's undefined behavior. Dec 26, 2014 at 20:53
  • As you have <stdbool.h> header included you might consider using true and false value only (just like in Pascal with Boolean type). It'll make your code slightly more readable and keep you away from other values. Dec 26, 2014 at 22:33
  • 2
    @MSalters: Some bit patterns can be trap representations; accessing an object with such a representation (via an lvalue of the appropriate type) causes undefined behavior. The rules for _Bool conspire to make things confusing in ways that I'm too lazy to explore at the moment. Bottom line: Storing values other than 0 and 1 in a _Bool object is a thing to be avoided. Dec 27, 2014 at 2:02

3 Answers 3


When GCC compiles this program, the assembly language output includes the sequence

movzbl (%rax), %eax
movzbl %al, %eax
movl %eax, -4(%rbp)

which does the following:

  1. Copy 32 bits from *foo (denoted by (%rax) in assembly) to the register %eax and fill in the higher-order bits of %eax with zeros (not that there are any, because %eax is a 32-bit register).
  2. Copy the low-order 8 bits of %eax (denoted by %al) to %eax and fill in the higher-order bits of %eax with zeros. As a C programmer you would understand this as %eax &= 0xff.
  3. Copy the value of %eax to 4 bytes above %rbp, which is the location of bar on the stack.

So this code is an assembly-language translation of

int bar = *foo & 0xff;

Clearly GCC has optimized the line based on the fact that a bool should never hold any value other than 0 or 1.

If you change the relevant line in the C source to this

int bar = *((int*)foo) ? 1 : 0;

then the assembly changes to

movl (%rax), %eax
testl %eax, %eax
setne %al
movzbl %al, %eax
movl %eax, -4(%rbp)

which does the following:

  1. Copy 32 bits from *foo (denoted by (%rax) in assembly) to the register %eax.
  2. Test 32 bits of %eax against itself, which means ANDing it with itself and setting some flags in the processor based on the result. (The ANDing is unnecessary here, but there's no instruction to simply check a register and set flags.)
  3. Set the low-order 8 bits of %eax (denoted by %al) to 1 if the result of the ANDing was 0, or to 0 otherwise.
  4. Copy the low-order 8 bits of %eax (denoted by %al) to %eax and fill in the higher-order bits of %eax with zeros, as in the first snippet.
  5. Copy the value of %eax to 4 bytes above %rbp, which is the location of bar on the stack; also as in the first snippet.

This is actually a faithful translation of the C code. And indeed, if you add the cast to (int*) and compile and run the program, you'll see that it does output 1.

  • This is by far the best answer. I guess you've got fewer votes for being "late to the party".
    – Alex
    Dec 27, 2014 at 11:04
  • 3
    This tells "what does GCC actually do", which is a good complement to hvd's answer "why is GCC allowed to do this". I happened to be more interested in the latter, which is why I've accepted that one instead.
    – jpa
    Dec 27, 2014 at 15:25
  • @jpa yeah, I figured this would be a good complement to the other answer. Though I would note that your question doesn't actually ask anything (it just says "Look at this weird behavior"), which makes it kind of hard to tell which sort of answer you wanted.
    – David Z
    Dec 27, 2014 at 19:01

(Perhaps this is undefined behaviour?)

Not directly, but reading from the object afterwards is.

Quoting C99:

6.2.6 Representations of types General

5 Certain object representations need not represent a value of the object type. If the stored value of an object has such a representation and is read by an lvalue expression that does not have character type, the behavior is undefined. [...]

Basically, what this means is that if a particular implementation has decided that the only two valid bytes for a bool are 0 and 1, then you'd better make sure you don't use any trickery to attempt to set it to any other value.

  • The Gcc doc reads GCC supports only two's complement integer types, and all bit patterns are ordinary values. This means, _Bool also hasn't got trap representations. Not sure, if this is sloppiness in the documentation, or if there is something else in the standard allowing this optimization, though.
    – mafso
    Dec 27, 2014 at 6:50
  • @mafso I think that's sloppiness in the wording. Unsigned integer types (including _Bool) can never use two's complement, because they don't have any sign bit at all.
    – user743382
    Dec 27, 2014 at 10:50
  • Yes, the two's complement doesn't apply, but that doesn't change the "all bit patterns are ordinary values" and _Bool must have at least 8 bits. To put my question differently: Would it be, strictly speaking, necessary for Gcc to document _Bool as having CHAR_BIT - 1 padding bits to make the optimization in the question possible? I'm not sure if there is perhaps another part in the standard mandating this. [...]
    – mafso
    Dec 27, 2014 at 11:27
  • [...] That _Bool must be able to represent 0 and 1 doesn't automatically mean it's UB to store something different in it. That a char must be capable of holding every character of the basic execution character set doesn't mean you cannot store anything else in it (127 is perfectly legal, for example, no matter if this is in the basic execution character set).
    – mafso
    Dec 27, 2014 at 11:28
  • 1
    @mafso There is no requirement in the standard for an implementation to document whether any type has padding bits, except indirectly through comparisons of sizeof(T) * CHAR_BIT to the value of T_MAX as defined in <limits.h>. If a type has padding bits, there is no requirement in the standard for an implementation to document whether those padding bits are significant (whether wrong values of padding bits can produce trap representations).
    – user743382
    Dec 27, 2014 at 13:09

Storing a value different than 0 or 1 in a bool is undefined behavior in C.

So actually this:

int bar = *foo ? 1 : 0;

is optimized with something close to this:

int bar = *foo ? *foo : 0;
  • 8
    You might go one step further and say that since x ? x : 0 is an identity in this case, it further gets optimized to just x, whence the result. Dec 26, 2014 at 22:03

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