The key in lock-free programming is to use hardware-intrinsic atomic operations.
As a matter of fact, even locks themselves must use those atomic operations!
But the difference between locked and lock-free programming is that a lock-free program can never be stalled entirely by any single thread. By contrast, if in a locking program one thread acquires a lock and then gets suspended indefinitely, the entire program is blocked and cannot make progress. By contrast, a lock-free program can make progress even if individual threads are suspended indefinitely.
Here's a simple example: A concurrent counter increment. We present two versions which are both "thread-safe", i.e. which can be called multiple times concurrently. First the locked version:
int counter = 0;
Now the lock-free version:
Now imagine hundreds of thread all call the
increment_* function concurrently. In the locked version, no thread can make progress until the lock-holding thread unlocks the mutex. By contrast, in the lock-free version, all threads can make progress. If a thread is held up, it just won't do its share of the work, but everyone else gets to get on with their work.
It is worth noting that in general lock-free programming trades throughput and mean latency throughput for predictable latency. That is, a lock-free program will usually get less done than a corresponding locking program if there is not too much contention (since atomic operations are slow and affect a lot of the rest of the system), but it guarantees to never produce unpredictably large latencies.