How do atomic operations work, under the hood?
Are atomic operations so-called "wait-free"?
I'm seeking for a description of the "least common divisor" of atomic operations. What do all atomic operations share?
Atomicity as a concept occurs in several places, I suspect you're thinking about atomic operations in code, but there are other meanings.
One fundamantal property of a Database transaction is Atomicity, see a description of ACID properties of transactions.
In this case you have lots of database cleverness, locks and so on, which almost certainly imply waiting when two threads of control (or two processes) want to get at the same data.
When you come to lines of code I guess you're thinking about a declaration (in some fictitious language)
global int x = 7;
in one thread
x = 25000; print x;
and in another
Can we say anything about what the second thread will print? We might accept either 7 or 25000, we'd be less happy to get a number that was the high order byte of 25,000 and a low order byte of 7 - which conceptually would be the result of non-atomic integer assignment.
Different programming languages are free to define whatever semantics they wish, it's conceivable that some would just accept whatever natural behaviours that the CPU they work on (say 32 bit int was atomic, 64 long was not) or they might do something much cleverer, and if the CPU itself doesn't provide atomic operations then I don't see much alternative to some kind of waiting if they want to fake atomicity - eg. Java synchronized keyword.
If we're talking about atomic operations that are used by synchronization mechanism (mutexes, semaphores etc) they have to be supported by the OS on single CPU machines and by the hardware on multi CPU.
On a single CPU machine an instruction sequence can be made "atomic" in the sense that it cannot be interrupted in the middle (for e.g. the timer interrupt which gives a switch to another thread) if interrupts are shut off. This means that synchronization primitives can be written quite simply once the CPU enters kernel mode and can access the interrupt control registers.
In a multi core machine it is more complex. Then the instructions have to be truly atomic, across all CPUs. This requires all CPUs, not only the one executing the atomic instructions, to flush relevant parts of their cache to RAM. This flushing is what makes synchronization so expensive on these architectures.
The instructions themselves take the form of "Bit test and set" in one operation. This is enough to implement a simple mutex. Even if two threads on different CPU/cores are executing the test and set operation on the same time on the same address, only one will get the result that the bit was unset and is now set. That thread is the one that owns the mutex.
Depends on the atomic operation you're talking about. If you're talking about ISA-level stuff, "test and set" instructions are included in some popular ISAs, I think.