java.util.concurrent.locks.ReentrantLock, you can specify a fairness policy that's relevant here. Passing
true to the referenced constructor requests that the lock "play fair." What that means is a little vague in the documentation, but studying the documentation for the underlying
AbstractQueuedSynchronizer type and the implementation of
ReentrantLock$FairSync (in the Sun JDK) gives additional hints:
Namely, when one thread attempts to acquire the lock in fair mode, it will not "barge" ahead of other waiting threads; if any other threads are waiting for the lock, the newly arriving thread will "get it line."
Now, it's still possible—though highly unlikely—that this newly-queued thread will acquire the lock next when it's next released by its current holder, if it by then happens to wind up as first in line due to predecessors being interrupted, but observe that even though the logical model for a condition queue is a set of waiting threads, in the aforementioned implementation it is in fact a queue (a CLH Queue, described in its application to the Java library in the paper The java.util.concurrent Synchronizer Framework). In the fair mode, only the first item in the queue will acquire the lock.
Obviously, two threads can race when trying to acquire the lock "at the same time." With a fair lock, you can expect that if thread A arrives first and calls
Lock#lock(), and winds up having to wait because the lock is held by thread C, and later thread B arrives and calls
Lock#lock() while thread C still holds it, B will get in line behind the already-queued A, and once C releases the lock, A will get a chance before B to acquire it. See the implementation in
AbstractQueuedSynchronizer$unparkSuccessor() for the specific walk forward from the CLH queue's head toward its tail. A will be closer to the head than B.
The documentation for
ReentrantLock warns that even when operating in fair mode, it's possible that threads already waiting on the lock will lose out to the thread currently holding the lock releasing it and acquiring it again. I think—but am not sure—that this can occur when the current thread wins at getting in line ahead of other threads that have not yet landed in the queue. Also, note the warning concerning
ReentrantLock#tryLock(); unlike the timed
ReentrantLock#tryLock(long, TimeUnit), the former does not honor the fairness policy.
This survey makes some conclusions based on one implementation. In general, it's safer to take Mr. Barousse's view: the acquisition ordering is best thought of as being a random grab from a set of waiters. However, with a fairness policy studied in enough depth, you can see that there is some determinism to be had. It doesn't come for free, though; note the warnings about decreases in throughput when barging is prohibited.