It seems to me that:
- wrapping fields representing a logical state into a single immutable consumable object
- updating the object's authoritative reference with a call to
- and handling update failures appropriately
provides a kind of concurrency that renders the "lock" construct not only unnecessary, but a truly misleading construct that dodges certain realities about concurrency and introduces a host of new problems as a result.
First, let's consider the main problems with using a lock:
- Locks cause a performance hit, and must be used in tandem for reading and writing.
- Locks block thread execution, hindering concurrency and risking deadlocks.
Consider the ridiculous behavior inspired by the "lock". When the need arises to update a logical set of resources concurrently, we "lock" the set of resources, and we do so via a loosely associated, but dedicated locking object, which otherwise serves no purpose (red flag #1).
We then use the "lock" pattern to mark-off a region of code where a logically consistent state change on a SET of data fields occurs, and yet we shoot ourselves in the foot by mixing the fields with unrelated fields in the same object, while leaving them all mutable and then forcing ourselves into a corner (red flag #2) where we have to also use locks when reading these various fields, so we don't catch them in an inconsistent state.
Clearly, there's a serious problem with that design. It's somewhat unstable, because it requires careful management of the lock objects (locking order, nested locks, coordination among threads, blocking/waiting on a resource in use by another thread that's waiting for you to do something, etc.), which depends on the context. We also hear people talk about how avoiding deadlock is "hard", when it's actually very straightforward: don't steal the shoes of a person you plan on asking to run a race for you!
Stop using "lock" altogether. Properly roll your fields into an incorruptible/immutable object representing a consistent state or schema. Perhaps it's simply a pair of dictionaries for converting to and from display-names and internal-identifiers, or maybe it's a head node of a queue containing a value and a link to the next object; whatever it is, wrap it into it's own object and seal it for consistency.
Recognize write or update failure as a possibility, detect it when it occurs, and make a contextually informed decision to retry immediately (or later) or do something else instead of blocking indefinitely.
While blocking seems like a simple way to queue a task that seems like it must be done, not all threads are so dedicated and self-serving that they can afford to do such a thing at the risk of compromising the entire system. Not only is it lazy to serialize things with a "lock", but as a side affect of trying to pretend a write shouldn't fail, you block/freeze your thread, so it sets there unresponsive and useless, forsaking all other responsibilities in its stubborn wait to accomplish what it set out to do some time earlier, ignorant of the fact that assisting others is sometimes necessary for fulfilling it's own responsibilities.
Race conditions are normal when independent, spontaneous actions are occurring simultaneously, but unlike uncontrolled Ethernet collisions, as programmers we have total control over our "system" (i.e. deterministic digital hardware) and its inputs (no matter how random, and how random can a zero or one really be?) and outputs, and the memory that stores our system's state, so livelock should be a non-issue; furthermore, we have atomic operations with memory barriers that resolve the fact that there may be many processors operating concurrently.
- Grab the current state object, consume its data, and construct a new state.
- Realize that other active threads will be doing the very same thing, and may beat you to it, but all observe an authoritative reference point representing the "current" state.
- Use Interlocked.CompareExchange to simultaneously see if the state object you based your work on is still the most current state, and replace it with your new one, otherwise fail (because another thread finished first) and take appropriate corrective action.
The most important part is how you handle the failure and get back on your horse. This is where we avoid livelocks, thinking too much and not doing enough or doing the right thing. I would say that locks create the illusion that you'll never fall off your horse, despite riding in a stampede, and while a thread daydreams in such a fantasy land, the rest of the system can fall apart and crash and burn.
So, is there something the "lock" construct can do that can't be achieved (better, in a less unstable fashion) with a lock-free implementation using CompareExchange and immutable logical state objects?
All of this is a realization I've come to on my own after dealing with locks intensely, but after some searching, in another thread Is lock free multithreaded programming making anything easier?, someone mentions that lock-free programming is going to be very important when we face highly parallel systems with hundreds of processors, were we cannot afford to use highly contended locks.