The reason you would use the
volatile keyword on AVR variables is to, as you said, avoid the compiler optimizing access to the variable. The question now is, how does this happen though?
A variable has two places it can reside. Either in the general purpose register file or in some location in RAM. Consider the case where the variable resides in RAM. To access the latest value of the variable, the compiler loads the variable from RAM, using some form of the
ld instruction, say
lds r16, 0x000f. In this case, the variable was stored in RAM location
0x000f and the program made a copy of this variable in
r16. Now, here is where things get interesting if interrupts are enabled. Say that after loading the variable, the following occurs
inc r16, then an interrupt triggers and its corresponding ISR is run. Within the ISR, the variable is also used. There is a problem, however. The variable exists in two different versions, one in RAM and one in
r16. Ideally, the compiler should use the version in
r16, but this one is not guaranteed to exist, so it loads it from RAM instead, and now, the code does not operate as needed. Enter then the
volatile keyword. The variable is still stored in RAM, however, the compiler must ensure that the variable is updated in RAM before anything else happens, thus the following assembly may be generated:
lds r16, 0x000f
sts 0x000f, r16
First, interrupts are disabled. Then, the the variable is loaded into r16. The variable is increased, interrupts are enabled and then the variable is stored. It may appear confusing for the global interrupt flag to be enabled before the variable is stored back in RAM, but from the instruction set manual:
The instruction following SEI will be executed before any pending interrupts.
This means that the
sts instruction will be executed before any interrupts trigger again, and that the interrupts are disabled for the minimum amount of time possible.
Consider now the case where the variable is bound to a register. Any operations done on the variable are done directly on the register. These operations, unlike operations done to a variable in RAM, can be considered atomic, as there is no read -> modify -> write cycle to speak of. If an interrupt triggers after the variable is updated, it will get the new value of the variable, since it will read the variable from the register it was bound to.
Also, since the variable is bound to a register, any test instructions will utilize the register itself and will not be optimized away on the grounds the compiler may have a "hunch" it is a static value, given that registers by their very nature are volatile.
Now, from experience, when using interrupts in AVR, I have sometimes noticed that the global volatile variables never hit RAM. The compiler kept them on the registers all the time, bypassing the read -> modify -> write cycle alltogether. This was due, however, to compiler optimizations, and it should not be relied on. Different compilers are free to generate different assembly for the same piece of code. You can generate a disassembly of your final file or any particular object files using the