This document, also linked in this answer, should clarify the point more in dept. An interesting excerpt (with bold text added by me) could be the following:
In user space, the ioctl system call has the following prototype:
int ioctl(int fd, unsigned long cmd, ...);
The prototype stands out in the list of Unix system calls because of the dots, which usually mark the function as having a variable number of arguments. In a real system, however, a system call can't actually have a variable number of arguments. System calls must have a well-defined prototype, because user programs can access them only through hardware "gates." Therefore, the dots in the prototype represent not a variable number of arguments but a single optional argument, traditionally identified as
char *argp. The dots are simply there to prevent type checking during compilation. The actual nature of the third argument depends on the specific control command being issued (the second argument). Some commands take no arguments, some take an integer value, and some take a pointer to other data. Using a pointer is the way to pass arbitrary data to the ioctl call; the device is then able to exchange any amount of data with user space.
The unstructured nature of the ioctl call has caused it to fall out of favor among kernel developers. Each ioctl command is, essentially, a separate, usually undocumented system call, and there is no way to audit these calls in any sort of comprehensive manner. It is also difficult to make the unstructured ioctl arguments work identically on all systems; for example, consider 64-bit systems with a user-space process running in 32-bit mode. As a result, there is strong pressure to implement miscellaneous control operations by just about any other means. Possible alternatives include embedding commands into the data stream (we will discuss this approach later in this chapter) or using virtual filesystems, either sysfs or driver-specific filesystems. (We will look at sysfs in Chapter 14.) However, the fact remains that ioctl is often the easiest and most straightforward choice for true device operations.
This means there is no any way to understand how to interpret an ioctl argument as an external observer, without an insightful knowledge of a device driver conventions/internals. An ioctl argument is untyped from userspace perspective, and somehow loosely typed in kernel space, since it's dealt with as an
unsigned long just to reserve space for it. It's a 'pure' number or any sequence of bits that fits into an
unsigned long integer space, could be used as a (very short) string, a (small) char array, a (small) struct - but being careful of endianness and architecture-specific sizes - could represent an opcode for a device's onboard chip, or even be dealt with as a float by type puning!
Also, this means it's very easy to mess things up, by passing inconsistent data to the driver (not just wrong data, but wrong data of the wrong type!), eventually causing undefined behaviour of the device, or corruption of userspace memory (e.g. by passing a pointer to a struct of the wrong size in a read ioctl).
A few more lines:
cmd argument is passed from the user unchanged, and the optional
arg argument is passed in the form of an
unsigned long, regardless of whether it was given by the user as an integer or a pointer. If the invoking program doesn't pass a third argument, the
arg value received by the driver operation is undefined. Because type checking is disabled on the extra argument, the compiler can't warn you if an invalid argument is passed to ioctl, and any associated bug would be difficult to spot.
Anyway, if you wanted to try a 'blind' audit of a device driver ioctl calls, without looking into header and source files, one could try and deal with arg as a pointer first, with copy_from_user(), on failure chances are that's an immediate value (or an error occurred), then one could try to log its value to give it a look and try to interprete it (but why reversing an ioctl instead of studying driver code?); on success, whitout knowledge, different sizes of memory could be read and logged for a decoding attempt (again, pointlessly as far as sources are available, as they should).
An operation of more interest is surely decoding an ioctl code (cmd), since it can point to the right direction to find the driver(s) its numeric value is tied to - there should be only one, if the convention for ioctl definition is applied, anyway different drivers are allowed to use the same magic character, thus a regular expression to grep all kernel source files for a
#define containing a 'r' or 'D' or the like could pick out a number of files to inspect for ioctl definitions, than matching against the function number should sort out a few or all wrong ones, and looking for correct argument size would complete the search.