First of all, "volatile" tries to reduce visibility problems that might occur across different threads (think of the local variables/copies of the shared variables in each thread scope). However, the level of parallelisation is more and easier to visualise when you have multiple CPU cores (caches, registers). IMO, that's why it makes more sense in multi-core architectures. Nevertheless, that visibility issue may even arise when you have a single-core, multiple threads and two of them happens to read the same variable value one after another before the other updates it. In either case, volatile's gonna work the same way regardless of having a single or multi core architecture.
The key is understanding your volatile variables on the CPU cache or registers will be written back to main memory with an IMMEDIATE write policy, so any subsequent reads of the same variable reads the latest updated value.
Volatile only increases the chance of having synched threads - but it's not guaranteed. If you've multiple threads updating the shared data volatile might not be enough alone. There're other features that you can take advantage of with the volatile concept. Please take a look here.
volatile
is important to consider in both cases.volatile
is more likely to break on SMP machines but there’s no point in speculating about the likeliness of breaking when writing software. And you are right, reordering and deferred read/writes are relevant on single-CPU/Core systems as well.