A mutex, when properly implemented, can never be locked concurrently. For this, you need some atomic operations (operations that are guaranteed to be the only thing happening to an object at one moment) that have useful properties.
One such operation is
xchg (exchange) in the x86 architecture. For instance
xchg eax, [ebp] will read the value at the address
ebp, write the value in
eax to the address
ebp and then set
eax to the read value, while guaranteeing that these actions won't be interleaved with concurrent reads and writes to that address.
Now you can implement a mutex. To lock, load
eax with the value of the mutex and look at
eax. If it's
1, it was already locked, so you might want to sleep and try again later. If it's
0, you just locked the mutex. To unlock, simply write a value of
0 to the mutex.
Please note that I'm glossing over important details here. For instance, x86's
xchg is atomic enough for pre-emptive multitasking on a single processor. When you're sharing memory between multiple processors (e.g. in a multi-core system), it won't be enough unless you use the
lock prefix (e.g.
lock xchg eax, [ebp], rather than
xchg eax, [ebp]), which ensures that only one processor can access that memory while the instruction is executed.