Think about this: we have the copy_to_user() helper routine; the first parameter is the destination to address, which should be a user space virtual address (a UVA), of course. Regular usage will comply with this and provide a legal and valid user space virtual address as the destination address, and all will be well.
But what if we don't? What if we pass another user space address, or, check this out – a kernel virtual address (a KVA) – in its place? The copy_to_user() code will now, running with kernel privileges, overwrite the destination with whatever data is in the source address (the second parameter) for the number of bytes in the third parameter! Indeed, hackers often attempt techniques such as this, to insert code posing as data into a user space buffer and execute it with kernel privilege, leading to a quite deadly privilege escalation (privesc) scenario.
To clearly demonstrate the adverse effects of not carefully designing and implementing a driver, we deliberately introduce errors (bugs, really!) into both the read and write methods of a 'bad' version of our previous driver (although here, we only consider the scenario with respect to the very common copy_[from|to]_user() routines and nothing else).
To get a more hands-on feel for this, we will write a "bad" version of our ch1/miscdrv_rdwr driver. We'll call it (ever so cleverly) ch1/bad_miscdrv. In this version, we deliberately have two buggy code paths built into it:
- One within the driver's read method
- The other, the more exciting one, as you shall soon see, within the write method.
Let's check both out. We'll begin with the buggy read.
