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I tracked down an extremely nasty bug hiding behind this little gem. I am aware that per the C++ spec, signed overflows are undefined behavior, but only when the overflow occurs when the value is extended to bit-width sizeof(int). As I understand it, incrementing a char shouldn't ever be undefined behavior as long as sizeof(char) < sizeof(int). But that doesn't explain how c is getting an impossible value. As an 8-bit integer, how can c hold values greater than its bit-width?

Code

// Compiled with gcc-4.7.2
#include <cstdio>
#include <stdint.h>
#include <climits>

int main()
{
   int8_t c = 0;
   printf("SCHAR_MIN: %i\n", SCHAR_MIN);
   printf("SCHAR_MAX: %i\n", SCHAR_MAX);

   for (int32_t i = 0; i <= 300; i++)
      printf("c: %i\n", c--);

   printf("c: %i\n", c);

   return 0;
}

Output

SCHAR_MIN: -128
SCHAR_MAX: 127
c: 0
c: -1
c: -2
c: -3
...
c: -127
c: -128  // <= The next value should still be an 8-bit value.
c: -129  // <= What? That's more than 8 bits!
c: -130  // <= Uh...
c: -131
...
c: -297
c: -298  // <= Getting ridiculous now.
c: -299
c: -300
c: -45   // <= ..........

Check it out on ideone.

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60  
"I am aware that per the C++ spec, signed overflows are undefined." -- Right. To be precise, not just the value is undefined, the behaviour is. Appearing to get physically impossible results is a valid consequence. –  hvd Apr 20 '13 at 22:06
    
@hvd I'm sure someone has an explanation for how common C++ implementations cause this behavior. Perhaps it has to do with alignment or how printf() does conversion? –  roliu Apr 20 '13 at 22:11
    
Others have addressed the main issue. My comment is more general and relates to diagnostic approaches. I believe part of why you found this such a puzzle is the unerlying belief it was ijpossible. Obviously, it is not impossible, so accept that and look again –  Tim X Apr 23 '13 at 23:27
    
@TimX - I observed the behavior and obviously drew the conclusion it was not impossible in that sense. My use of the word referred to an 8-bit integer holding a 9-bit value, which is an impossibility by definition. The fact that this happened suggests that it is not being treated as an 8-bit value. As others have addressed, this is due to a compiler bug. The only seeming impossibility here is a 9-bit value in an 8-bit space, and this apparent impossibility is explained by the space actually being "larger" than reported. –  Unsigned Apr 24 '13 at 2:33
    
I have just tested it on my mechine, and the result is just what it should be. c: -120 c: -121 c: -122 c: -123 c: -124 c: -125 c: -126 c: -127 c: -128 c: 127 c: 126 c: 125 c: 124 c: 123 c: 122 c: 121 c: 120 c: 119 c: 118 c: 117 And my environment is: Ubuntu-12.10 gcc-4.7.2 –  VELVETDETH May 2 '13 at 7:24

9 Answers 9

up vote 110 down vote accepted
+100

This is a compiler bug.

Although getting impossible results for undefined behaviour is a valid consequence, there is actually no undefined behaviour in your code. What's happening is that the compiler thinks the behaviour is undefined, and optimises accordingly.

If c is defined as int8_t, and int8_t promotes to int, then c-- is supposed to perform the subtraction c - 1 in int arithmetic and convert the result back to int8_t. The subtraction in int does not overflow, and converting out-of-range integral values to another integral type is valid. If the destination type is signed, the result is implementation-defined, but it must be a valid value for the destination type. (And if the destination type is unsigned, the result is well-defined, but that does not apply here.)

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I wouldn't describe it as a "bug". Since signed overflow causes undefined behaviour, the compiler is perfectly entitled to assume it won't happen, and optimise the loop to keep intermediate values of c in a wider type. Presumably, that's what's happening here. –  Mike Seymour Apr 20 '13 at 23:56
4  
@MikeSeymour: The only overflow here is on the (implicit) conversion. Overflow on signed conversion does not have undefined behavior; it merely yields an implementation-defined result (or raises an implementation-defined signal, but that doesn't seem to be happening here). The difference in definedness between arithmetic operations and conversions is odd, but that's the way the language standard defines it. –  Keith Thompson Apr 21 '13 at 0:55
2  
@KeithThompson That's something that differs between C and C++: C allows for an implementation-defined signal, C++ does not. C++ just says "If the destination type is signed, the value is unchanged if it can be represented in the destination type (and bit-field width); otherwise, the value is implementation-defined." –  hvd Apr 21 '13 at 7:07
    
As it happens, I can't reproduce the odd behaviour on g++ 4.8.0. –  Daniel Landau Apr 24 '13 at 1:24
1  
@DanielLandau See comment 38 in that bug: "Fixed for 4.8.0." :) –  hvd Apr 24 '13 at 8:02

I guess that the underlying hardware is still using a 32-bit register to hold that int8_t. Since the specification does not impose a behaviour for overflow, the implementation does not check for overflow and allows larger values to be stored as well.


If you mark the local variable as volatile you are forcing to use memory for it and consequently obtain the expected values within the range.

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1  
Oh wow. I forgot that the compiled assembly will store local variables in registers if it can. This seems like the most likely answer along with printf not caring about the sizeof the format values. –  roliu Apr 20 '13 at 22:16
3  
@roliu Run g++ -O2 -S code.cpp , and you'll see the assembly. Moreover, printf() is a variable argument function, so arguments whose rank are less than an int will be promoted to an int. –  nos Apr 20 '13 at 22:19
    
@nos I would like to. I haven't been able to install a UEFI boot loader (rEFInd in particular) to get archlinux running on my machine, so I haven't actually coded with GNU tools in a long time. I'll get to it... eventually. For now it's just C# in VS and trying to remember C/learn some C++ :) –  roliu Apr 20 '13 at 22:22
    
@rollu Run it in a virtual machine, e.g VirtualBox –  nos Apr 20 '13 at 22:23
    
@nos Don't want to derail topic, but yeah, I could. I could also just install linux with a BIOS bootloader. I'm just stubborn and if I can't get it working with a UEFI bootloader then I probably won't get it working at all :P. –  roliu Apr 20 '13 at 22:28

I can't fit this in a comment, so I'm posting it as an answer.

For some very odd reason, the -- operator happens to be the culprit.

I tested the code posted on Ideone and replaced c-- with c = c - 1 and the values remained within the range [-128 ... 127]:

c: -123
c: -124
c: -125
c: -126
c: -127
c: -128 // about to overflow
c: 127  // woop
c: 126
c: 125
c: 124
c: 123
c: 122

Freaky ey? I don't know much about what the compiler does to expressions like i++ or i--. It's likely promoting the return value to an int and passing it. That's the only logical conclusion I can come up with because you ARE in fact getting values that cannot fit into 8-bits.

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4  
Because of the integral promotions, c = c - 1 means c = (int8_t) ((int)c - 1. Converting an out-of-range int to int8_t has defined behaviour but an implementation-defined result. Actually, isn't c-- is supposed to perform those same conversions too? –  hvd Apr 20 '13 at 22:18

A compiler can have bugs which are other than nonconformances to the standard, because there are other requirements. A compiler should be compatible with other versions of itself. It may also be expected to be compatible in some ways with other compilers, and also to conform to some beliefs about behavior that are held by the majority of its user base.

In this case, it appears to be a conformance bug. The expression c-- should manipulate c in a way similar to c = c - 1. Here, the value of c on the right is promoted to type int, and then the subtraction takes place. Since c is in the range of int8_t, this subtraction will not overflow, but it may produce a value which is out of the range of int8_t. When this value is assigned, a conversion takes place back to the type int8_t so the result fits back into c. In the out-of-range case, the conversion has an implementation-defined value. But a value out of the range of int8_t is not a valid implementation-defined value. An implementation cannot "define" that an 8 bit type suddenly holds 9 or more bits. For the value to be implementation-defined means that something in the range of int8_t is produced, and the program continues. The C standard thereby allows for behaviors such as saturation arithmetic (common on DSP's) or wrap-around (mainstream architectures).

The compiler is using a wider underlying machine type when manipulating values of small integer types like int8_t or char. When arithmetic is performed, results which are out of range of the small integer type can be captured reliably in this wider type. To preserve the externally visible behavior that the variable is an 8 bit type, the wider result has to be truncated into the 8 bit range. Explicit code is required to do that since the machine storage locations (registers) are wider than 8 bits and happy with the larger values. Here, the compiler neglected to normalize the value and simply passed it to printf as is. The conversion specifier %i in printf has no idea that the argument originally came from int8_t calculations; it is just working with an int argument.

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This is a lucid explanation. –  David Healy Apr 24 '13 at 1:10
    
The compiler produces good code with the optimizer turned off. Therefore, explanations using "rules" and "definitions" aren't applicable. It's a bug in the optimizer. –  user2513931 Jun 25 '13 at 18:51

I think this is doing by optimization of the code:

for (int32_t i = 0; i <= 300; i++)
      printf("c: %i\n", c--);

The compilator use the int32_t i variable both for i and c. Turn off optimization or make direct cast printf("c: %i\n", (int8_t)c--);

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That doesn't work. It produces the same errors. –  user2513931 Jun 25 '13 at 18:49
    
Then turn off optimization. or do something like this: (int8_t)(c & 0x0000ffff)-- –  Vsevolod Jun 25 '13 at 19:32

Use %hhd instead of %i! Should solve your problem.

What you see there is the result of compiler optimizations combined with you telling printf to print a 32bit number and then pushing a (supposedly 8bit) number onto the stack, which is really pointer sized, because this is how the push opcode in x86 works.

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I'm able to reproduce the original behavior on my system using g++ -O3. Changing %i to %hhd doesn't change anything. –  Keith Thompson Jun 17 '13 at 22:22

I think it happened because your loop will go until the int i will become 300 and c become -300. And the last value is because

printf("c: %i\n", c);
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'c' is an 8 bit value, therefore it's impossible for it to ever hold a number as large as -300. –  user2513931 Jun 24 '13 at 19:13

The assembler code reveals the problem:

:loop
mov esi, ebx
xor eax, eax
mov edi, OFFSET FLAT:.LC2   ;"c: %i\n"
sub ebx, 1
call    printf
cmp ebx, -301
jne loop

mov esi, -45
mov edi, OFFSET FLAT:.LC2   ;"c: %i\n"
xor eax, eax
call    printf

EBX should be anded with FF post decrement, or only BL should be used with the remainder of EBX clear. Curious that it uses sub instead of dec. The -45 is flat-out mysterious. It's the bitwise inversion of 300 & 255 = 44. -45 = ~44. There's a connection somewhere.

It goes through a lot more work using c = c - 1:

mov eax, ebx
mov edi, OFFSET FLAT:.LC2   ;"c: %i\n"
add ebx, 1
not eax
movsx   ebp, al                 ;uses only the lower 8 bits
xor eax, eax
mov esi, ebp

It then uses only the low portion of RAX, so it's restricted to -128 thru 127. Compiler options "-g -O2".

With no optimization, it produces correct code:

movzx   eax, BYTE PTR [rbp-1]
sub eax, 1
mov BYTE PTR [rbp-1], al
movsx   edx, BYTE PTR [rbp-1]
mov eax, OFFSET FLAT:.LC2   ;"c: %i\n"
mov esi, edx

So it's a bug in the optimizer.

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c is itself defined as int8_t, but when operating ++ or -- over int8_t it is implicitly converted first to int and the result of operation instead the internal value of c is printed with printf which happens to be int.

See the actual value of c after entire loop, especially after last decrement

-301 + 256 = -45 (since it revolved entire 8 bit range once)

its the correct value which resembles the behaviour -128 + 1 = 127

c starts to use int size memory but printed as int8_t when printed as itself using only 8 bits. Utilizes all 32 bits when used as int

[Compiler Bug]

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