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Yesterday, someone showed me this code:

#include <stdio.h>

int main(void)
{
    unsigned long foo = 506097522914230528;
    for (int i = 0; i < sizeof(unsigned long); ++i)
        printf("%u ", *(((unsigned char *) &foo) + i));
    putchar('\n');

    return 0;
}

That results in:

0 1 2 3 4 5 6 7

I am very confused, mainly with the line in the for loop. From what I can tell, it seems like &foo is being cast to an unsigned char * and then being added by i. I think *(((unsigned char *) &foo) + i) is a more verbose way of writing ((unsigned char *) &foo)[i], but this makes it seem like foo, an unsigned long is being indexed. If so, why? The rest of the loop seems typical to printing all elements of an array, so everything seems to point to this being true. The cast to unsigned char * is further confusing me. I tried searching about casting integer types to char * specifically on google, but my research got stuck after some unhelpful search results about casting int to char, itoa(), etc. 506097522914230528 specifically prints out 0 1 2 3 4 5 6 7, but other numbers appear to have their own unique 8 numbers shown in the output, and bigger numbers seem to fill in more zeroes.

24
  • 24
    Convert 506097522914230528 to hexadecimal, it will make more sense. – harold Feb 16 at 14:24
  • 8
    And think little endian. – Fred Larson Feb 16 at 14:25
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    @harold you're right, it is showing 706050403020100. Does that mean I'm treating this long like some sort of array by converting its address to a char * and dereferencing it? – mediocrevegetable1 Feb 16 at 14:27
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    @mediocrevegetable1 Bingo! – user4815162342 Feb 16 at 14:28
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    This question is being discussed on meta. – Sinatr Feb 17 at 11:17
38

As a preface, this program will not necessarily run exactly like how it does in the question as it exhibits implementation-defined behavior. In addition to this, tweaking the program slightly can cause undefined behavior as well. More information on this at the end.

The first line of the main function defines an unsigned long foo as 506097522914230528. This seems confusing at first, but in hexadecimal it looks like this: 0x0706050403020100.

This number consists of the following bytes: 0x07, 0x06, 0x05, 0x04, 0x03, 0x02, 0x01, 0x00. By now, you can probably see its relation to the output. If you're still confused about how this translates into the output, take a look at the for loop.

for (int i = 0; i < sizeof(unsigned long); ++i)
        printf("%u ", *(((unsigned char *) &foo) + i));

Assuming a long is 8 bytes long (otherwise this weird program would not even work), this loop runs eight times (remember, two hex digits are enough to display all possible values of a byte, and since there are 16 digits in the hex number, the result is 8, so the for loop runs eight times). Now the real confusing part is the second line. Think about it this way: as I previously mentioned, two hex digits can show all possible values of a byte, right? So then if we could isolate the last two digits of this number, we would get a byte value of seven! Now, assume the long is actually an array which looks like this:

{00, 01, 02, 03, 04, 05, 06, 07}

We get the address of foo with &foo, cast it to an unsigned char * to isolate two digits, then use pointer arithmetic to basically get foo[i] if foo is an array of eight bytes. As I mentioned in my question, this probably looks less confusing as ((unsigned char *) &foo)[i].


A bit of a warning: This program exhibits implementation-defined behavior. This means that this program will not necessarily work the same way/give the same output for all implementations of C. Not only is a long 32 bits in some implementations, but when we declare the unsigned long, the way/order in which it stores the bytes of 0x0706050403020100 (AKA endianness) is also implementation-defined. Credit to @philipxy for pointing out the implementation-defined behavior first. This type punning causes another issue which @Ruslan pointed out, which is that, if the long is casted to anything other than a char */unsigned char *, C's strict aliasing rule comes into play and you will get undefined behavior (Credit of the link goes to @Ruslan as well). More detail on these two points in the comment section. Ultimately though, there are a probably many more things wrong with this program; a long is not meant to be an array, and if you think it is, C will bombard you with undefined behavior to change your mind.

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    And for extra credit, try changing the number to 2314886970912564552, and the printf format to %c. Or maybe 7308324466019755382. – Steve Summit Feb 16 at 15:31
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    For this program to be meaningful (for example in the sense you describe) certain implementation-defined behaviour has to be defined by the implementation, but you don't discuss or identify it. – philipxy Feb 17 at 7:13
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    Again: The program only has meaning if certain "implementation defined behaviour" is defined in a certain way by the implementation. That's a C technical term, research it. It is relevant to your answer in that your answer claims without justification that the program does a certain thing & it would only be justified under certain implementation-defined circumstances. If you think the language is defined to act per your post, you are wrong. Of course the author of the code has such expectations & it affected their writing that code, whether that was appropriate for them to expect or not. – philipxy Feb 17 at 8:20
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    @AndrewHenle: Fortunately, _Alignof(char) is guaranteed to be 1, same as sizeof(char), so it's always safe to create and even deref an unsigned char* to an object. Also note that while ISO C doesn't define the behaviour of creating a misaligned pointer, some implementations do define it (e.g. because they'd have to go out of their way to break such code, and because it's required by some extensions, like for Intel's SIMD intrinsic). Of course deref of a misaligned int64_t is unsafe even on x86 because of UB. – Peter Cordes Feb 17 at 12:45
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    Not sure what all these comments about alignment and strict aliasing are for. Sure, those are issues with types other than unsigned char, but this example does use unsigned char, so it's fine in that respect. The example is indeed implementation-defined in that unsigned long might not be 64 bits wide, and might not be little-endian, so if you're going to criticize it, please do so on that basis. – Steve Summit Feb 17 at 15:53
11

There's already an answer explaining what the code does, but since this post for some reason is getting a lot of strange attention and getting repeatedly closed for the wrong reasons, here's some more insights on what the code does, what C guarantees and what it does not guarantee:


  • unsigned long foo = 506097522914230528;. This integer constant is 506 * 10^15 large. That one may or may not fit inside an unsigned long, depending on if long is 4 or 8 byte large on your system (implementation-defined).

    In case of 4 byte long, this will get truncated to 0x03020100 1).

    In case of 8 byte long, it can handle numbers up to 18.44 * 10^18 so the value will fit.

  • ((unsigned char *) &foo) is a valid pointer conversion and well-defined behavior. C17 6.3.2.3/7 makes this guarantee:

    A pointer to an object type may be converted to a pointer to a different object type. If the resulting pointer is not correctly aligned for the referenced type, the behavior is undefined. Otherwise, when converted back again, the result shall compare equal to the original pointer.

    The concern about alignment does not apply since we have a pointer to character.

    If we keep reading 6.3.2.3/7:

    When a pointer to an object is converted to a pointer to a character type, the result points to the lowest addressed byte of the object. Successive increments of the result, up to the size of the object, yield pointers to the remaining bytes of the object.

    This is a special rule allowing us to inspect any type in C through a character type. Whether the successive increments is done by a pointer++ or by pointer arithmetic pointer + i doesn't matter. As long as we keep pointing within the inspected object, which i < sizeof(unsigned long) ensures. This is well-defined behavior.

  • Another special rule "strict aliasing" that was mentioned contains a similar exception for characters. It is in sync with the 6.3.2.3/7 rule. Specifically, "strict aliasing" allows (C17 6.5/7):

    An object shall have its stored value accessed only by an lvalue expression that has one of the following types:
    ...

    • a character type.

    The "stored object" in this case is unsigned long and should normally only get accessed as such. However, when the unsigned char* is de-referenced with * we access it as a character type. This is allowed by the exception to the strict aliasing rule mentioned above.

    As a side note, the other way around, accessing an array of unsigned char arr[sizeof(long)] through an *(unsigned long*)arr lvalue access would have been a strict aliasing violation and undefined behavior. But this is not the case here.

  • Using %u to print a character is strictly speaking not correct since printf then expects an unsigned int. However, since printf is a variadic function, it comes with some oddball implicit promotion rules that makes this code well-defined. The unsigned char value will get promoted by the default argument promotions 2) to type int. printf then internally re-interprets this int as unsigned int. It can't be a negative value because we started from unsigned char. The conversion3) is well-defined and portable.

  • So we get the byte values one by one. The hex representation is 07 06 05 04 03 02 01 00 but how this is stored in an unsigned long is CPU specific/implemention-defined behavior. Which in turn is a very common FAQ, see What is CPU endianness? which contains a very similar example to this code.

    On little endian it will print 1 2..., on big endian it will print 7 6....


1) See the unsigned integer conversion rule C17 6.3.1.3/2.
2) C17 6.5.2.2/6.
3) C17 6.3.1.3/1 "When a value with integer type is converted to another integer type other than _Bool, if the value can be represented by the new type, it is unchanged."

2
  • Hello @Lundin, and thank you for providing an answer which addresses some of the comments with relevant sources. I hadn't realised that truncation occurs as opposed to overflow when you define a variable with a value too large. Thanks to the sizeof(unsigned long) in the for loop condition, that should mean that even on a system with a 32-bit long, this program should print 0 1 2 3 or 3 2 1 0 (depending on endianness, as you mentioned), right? – mediocrevegetable1 Feb 18 at 16:03
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    @mediocrevegetable1 Strictly speaking there's some mathematical modulus "Otherwise, if the new type is unsigned, the value is converted by repeatedly adding or subtracting one more than the maximum value that can be represented in the new type until the value is in the range of the new type." but in this case it is the same as truncating. Unsigned variables cannot overflow, only wrap-around. Had you used signed variables it would have been another story. – Lundin Feb 18 at 16:20

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