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I'm running a Linux 3.2 kernel with the following ioctl prototype:

long ioctl(struct file *f, unsigned int cmd, unsigned long arg);

I noticed that arg is always unsigned long regardless of the actual data type passed to ioctl from the respective userspace function. Examples for ioctl typically show the following implementation (source):

typedef struct
    int status, dignity, ego;
} query_arg_t;

#define QUERY_GET_VARIABLES _IOR('q', 1, query_arg_t *)

static long my_ioctl(struct file *f, unsigned int cmd, unsigned long arg)
        query_arg_t q;

        switch (cmd)
                case QUERY_GET_VARIABLES:
                        q.status = status;
                        q.dignity = dignity;
                        q.ego = ego;
                        if (copy_to_user((query_arg_t *)arg, &q, sizeof(query_arg_t)))
                                return -EACCES;
                        return -EINVAL;

    return 0;

Notice that a query_arg_t * type is expected, so a cast is applied: (query_arg_t *)arg

Doesn't this break the strict aliasing rule though, since arg is of type unsigned long while the cast is query_arg_t *?

share|improve this question
It does, but it works and that's enough :P – user529758 Apr 16 '13 at 19:23
I wonder if it doesn't though, since it's not the address which is cast, but the integer value itself. For example, would this break the strict alias rule: (query_arg_t *)(42)? – Vilhelm Gray Apr 16 '13 at 19:27
Oh, so that's it... no, it won't. I was confused by the title. What you are talking about is then not type punning (IIRC that would be *(query_arg_t *)&some_unsigned_long_long). – user529758 Apr 16 '13 at 19:29
Oops, I suppose I should change the title to say "casting" rather than "type punning". – Vilhelm Gray Apr 16 '13 at 19:31
@WhozCraig That assumption is guaranteed valid by the ABI for this operating system. (The code shown is part of an operating system kernel. Kernel code often leans really hard on the rules, and in particular, relies on behavior that is formally undefined in the C standard but is well-defined taking into account all relevant standards, such as the ABI and the documented behavior of the system bus.) – zwol Apr 16 '13 at 19:56
up vote 3 down vote accepted

Pointers are integral types. It's entirely fine to store a pointer in any integral type that is large enough to contain it. For example, the following is perfectly valid C:

double f()
    double a = 10.5;

    uintptr_t p = (uintptr_t)(&a);

    double * q = (double *)p;

    return *q;

By contrast, the following is a clear aliasing violation:

short buf[100] = {};

double x = *(double*)(buf + 13);

The point is that it doesn't matter how you store your pointer values. What matters is that you must only treat those pointers as pointers to an object that are actually pointers to an object of the correct type.

In the first example, p does really store the pointer to a double, although it is not itself a double *. In the second example, buf + 13 is simply not a pointer to a double, so dereferencing it as such is type punning, and an aliasing violation.

(Pointers and casts are one of the reasons that C is not a safe language: The correctness of an operation can depend on the value of a variable, rather than just its type.)

share|improve this answer
Your second example is not an aliasing violation, because of the "or a character type" exception to the aliasing rules. It might be UB because the pointer is misaligned for double, though. May I suggest uint64_t l = 99; double x = *(double *)&l; instead? – zwol Apr 16 '13 at 20:52
@Zack: I think it's the other way round: interpreting any object pointer as a char pointer is not an aliasing violation. (But I've changed the type.) – Kerrek SB Apr 16 '13 at 20:53
The way it's written, it doesn't sound like it, but the aliasing rules are intended to be symmetric. The committee specifically didn't want to disallow the idiom of overlaying a structure on a char buffer. – zwol Apr 16 '13 at 20:54
short x = (double*)(buf + 13); are you really assigning a double * to a short? I think there is a typo here. – ouah Apr 16 '13 at 21:01
@ouah: Oh, sorry, I was missing the dereferencing, and my previous "correction" just made it worse. Thanks! – Kerrek SB Apr 16 '13 at 21:04

This does not break the aliasing rules.

Object arg is accessed only here in the my_ioctl function:

(query_arg_t *)arg

And the object is accessed only through its type unsigned long. The cast only converts the value of the object from an unsigned long value to a query_arg_t * value.

share|improve this answer
However, if the implementation first modifies arg (say arg += 1) for whatever reason before casting its value, wouldn't that give the compiler the opportunity to reorganize instructions, resulting in the casting coming before the modification? – Vilhelm Gray Apr 16 '13 at 19:50
No. Let's say you have arg += 1 before. The implementation knows it has to perform this statement before reading arg in your copy_to_user function call. What you have is a simple evaluation of an unsigned long object followed by a cast operation; this has nothing to do with aliasing rules. – ouah Apr 16 '13 at 20:00
If you cast a pointer value to uintptr_t, do arithmetic on the value, cast it back to the pointer type, and then dereference it, the behavior is implementation-defined (not undefined). § "An integer may be converted to any pointer type. Except as previously specified, the result is implementation-defined, might not be correctly aligned, might not point to an entity of the referenced type, and might be a trap representation." The "might be" clauses license an implementation to define at least some such modified pointers as triggering UB at runtime if dereferenced. – zwol Apr 16 '13 at 20:02
... however, because this is implementation-defined behavior, it is not compile-time undefined behavior, i.e. the compiler is not allowed to optimize on the assumption that you have not done this. – zwol Apr 16 '13 at 20:03
uintptr_t is a typedef for some unspecified integer type with the property that a valid pointer can be cast to it, and back, without loss of information. typedef names are just labels; the property of interconvertibility with pointers belongs to the underlying integer type. And header files are not magic; they just contain more code. Therefore, as long as whoever wrote linux/types.h did not make a mistake, its uintptr_t is just as good as the one from stdint.h. And so is unsigned long, if you are on an ABI that says that that's the underlying type of uintptr_t. – zwol Apr 16 '13 at 20:50

Keep in mind that while these are aliases, they exist in entirely different execution contexts - the user space and the kernel. The strict aliasing rule is meant to prevent issues that can arise when the compiler deals with possible aliases in a unit of code. This never happens for user space and kernel space code. They are separate units of code, that never mix together in ways that can cause issues related to what the strict aliasing rule is meant to address.

share|improve this answer

unsigned long (or some other integer type which is cast-compatible with unsigned long) is the underlying type of uintptr_t in all Linux ABIs.

$ grep -rw uintptr_t /usr/include/stdint.h
typedef unsigned long int uintptr_t;

C99 says that any pointer type can be cast to uintptr_t (or its underlying type) and back to the original pointer type without loss of information or violation of the strict-aliasing rules. So as long as the user space code that called ioctl(fd, QUERY_GET_ARGS, ptr) passed a query_arg_t * as the ptr argument, the program-as-a-whole is conformant.

Note also that the ioctl prototype you show is the in-kernel, driver-side interface. In user space, the prototype is

extern int ioctl(int fd, unsigned long int request, void *arg);

which makes it more apparent that the third argument is some concrete but unspecified pointer type, and that caller and (ultimate) callee had better agree on the actual type of the pointer. (That being the normal use pattern for void * in C.)

(Further note for pedants: the actual user space prototype is

extern int ioctl(int fd, unsigned long int request, ...);

This is a compatibility kludge for programs that pass numeric constants as the third argument without a cast. You may be beginning to understand why ioctl is not considered a well-designed API anymore.)

share|improve this answer
I don't think uintptr_t is guaranteed to have an underlying type of unsigned long though. – Vilhelm Gray Apr 16 '13 at 19:46
@VilhelmGray TO my knowledge it isn't, but I'm not that well versed on that part of the spec, only that the optional type uintptr_t, if provided, is sufficient to hold true to the back-and-forth cast. Considering uintptr_t is not required to be provided by a standard-compliant implementation (C99 §, ymmv. – WhozCraig Apr 16 '13 at 19:49
@VilhelmGray The C standard does not guarantee that, but all Linux ABIs define uintptr_t either as unsigned long or as an unsigned integer type that is the same width and precision as unsigned long (e.g. when unsigned int and unsigned long are the same width, uintptr_t might be unsigned int). Since this question is about the guts of ioctl on Linux, that's something that can be relied upon. – zwol Apr 16 '13 at 19:49
@Zack When you mention that the underlying type of uintptr_t can be used just as uintptr_t, do you mean this is implicitly true (rather than explicitly stated in the C99 spec) because uintptr_t is a typedef variable so this implies the underlying type must have the same property? – Vilhelm Gray Apr 16 '13 at 21:25
It is explicitly stated in C99 that: if the typedef uintptr_t is provided by the implementation, then its underlying type has the property of being interconvertible with pointers without loss of information. The exact wording is "[uintptr_t, if present, is a typedef for] an unsigned integer type with the property that any valid pointer to void can be converted to this type, then converted back ...". The property belongs to the unsigned integer type, not the typedef name for it. – zwol Apr 16 '13 at 21:43

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