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I'm told that Clojure has lockless concurrency and that this is Important.

I've used a number of languages but didn't realize they were performing locks behind the scenes.

Why is this an advantage in Clojure (or in any language that has this feature)?

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up vote 8 down vote accepted

I can't speak about Clojure specifically, but ... it means you don't need to wait for someone to be done with something before you can get to work. Which is great.

Typically it's achieved with immutable types. If nothing can be modified, you don't really need to wait till someone else is done with it before you can access it.

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Who is 'someone'? Could you give an example? I don't think there are any 'someone's sharing my objects with me. Maybe I should check under the bed. – i_like_monkeys Sep 1 '09 at 6:08
someone is just another piece of code, in another thread, accessing that object. – Noon Silk Sep 1 '09 at 6:37
It's sometimes faster sometimes slower - like most optimizations that are done without measuring. So sometimes it's a good thing, and sometimes those locks would have been better. This is why we're called software engineers. – Eloff May 31 '10 at 6:29
note that Clojure achieves lockless concurrency with a combination of immutable data structures and mutable "managed references". See: infoq.com/presentations/Value-Identity-State-Rich-Hickey – mikera May 12 '12 at 4:48

Lockless concurrency also provides the nice advantage that readers never have to wait for other readers. This is especially useful when many threads will be reading data from a single source. You still need to define the data dependencies in your program and explicitly define the parts of a transaction that can be commuted safely.
STM saves you from deadlocks and almost all occurrences of livelock though it does not save you from concurrency failures you can still create cases where a transaction will fail because it lacks the resources to maintain its history but the important part is that concurrency failures will be explicit and you can recover from them

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Yep! STM = Software Transactional Memory. That's a good work to look up if you want to know more about how this works. – Anders Rune Jensen Oct 1 '09 at 10:19
in Clojure STM, readers don't even have to wait for other writers (unless they want to do a transactional read to get a consistent snapshot across multiple references) – mikera Jan 8 '11 at 13:47
readers never have to wait for other readers In the imperative world, read-write locks provide this functionality :) – vemv Jan 13 '13 at 18:46

Deadlocks. Or to be more correct the lack of them.

One of the biggest problems in most languages is that you end up with deadlocks that are:

  1. Hell on earth to debug.
  2. Difficult to be sure you have gotten rid.

Now with no locks, obviously you won't run into deadlocks.

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I've never encountered a deadlock that I was aware of. Is it happening more frequently than I realize perhaps? I guess I'm just not familiar with this issue even though I've programmed a lot. The only locking issues I've been aware of were in the database. – i_like_monkeys Sep 1 '09 at 6:13
@i_like_monkeys If you are writing a webfrontend in C# then most of the locking issues are going to be in the lower layers (the webserver and the database), but if you are going to develop programs that is definitely an issue. – tomjen Sep 2 '09 at 16:30
If you have a deadlock, the symptom will usually be that your program freezes up (0% CPU usage, none of its tasks get done, ever again, until you manually kill it with Task Manager or etc). Deadlocks can occur if your threads are holding more than one lock at a time, and different threads are acquiring the locks in a different order. – Jeremy Friesner Oct 14 '09 at 4:48

The biggest deal is that locks don't compose.

While it's trivial to write code with a simple locking strategy (e.g. put it in a synchronized Java class.....), it gets exponentially more complicated as you start to lock multiple objects, and start to create complex transactions that combine different locked operations. Deadlocks can occur, performance suffers, locking logic starts to make the code extremely convoluted and at some point the code starts to become unmaintainable.

These problems will become apparent to anyone who has to build a large, complex concurrent system (and solving them was a major motivation for Rich Hickey in creating Clojure).

The second issue is performance.

Both locking and STM clearly impose overhead. But in some important cases the STM overhead can be much lower.

In particular, lockless concurrency (as with Clojure STM) usually implies that readers are not impaired by any other threads (including writers!) if they access data outside a transaction. This can be a huge win in the fairly common case that reads don't need to be transactional and dramatically outnumber writes (think most web applications.....). Non-transactional reads of an STM reference in Clojure are essentially overhead free.

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Non-transactional reads of an STM reference in Clojure are essentially overhead free. In principle so should transactional reads? Doc says "Readers and commuters will never block writers, commuters, or other readers." – vemv Jan 13 '13 at 19:00

As long as you write strictly sequential programs (do A, then B, then C; finished!) you don't have concurrency problems, and a language's concurrency mechanisms remain irrelevant.

When you graduate from "programming exercise" programs to real world stuff, pretty soon you encounter problems whose solution is multi-threading (or whatever flavor of concurrency you have available).

Case: Programs with a GUI. Say you're writing an editor with spell checking. You want the spell checker to be quietly doing its thing in the background, yet you want the GUI to smoothly accept user input. So you run those two activities as separate threads.

Case: I recently wrote a program (for work) that gathers statistics from two log files and writes them to a database. Each file takes about 3 minutes to process. I moved those processes into two threads that run side by side, cutting total processing time from 6 minutes to a little over 3.

Case: Scientific/engineering simulation software. There are lots and lots of problems that are solved by calculating some effect (heat flow, say) at every point in a 3 dimensional grid representing your test subject (star nucleus, nuclear explosion, geographic dispersion of an insect population...). Basically the same computation is done at every point, and at lots of points, so it makes sense to have them done in parallel.

In all those cases and many more, whenever two computing processes access the same memory (= variables, if you like) at roughly the same time there is potential for them interfering with each other and messing up each others' work. The huge branch of Computer Science that deals with "concurrent programming" deals with ideas on how to solve this kind of problem.

A reasonably useful starting discussion of this topic can be found in Wikipedia.

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The benefit of lockless concurrency is the lack of complexity in the program. In imperative languages, concurrent programming relies on locks, and once the program gets even moderately complex, difficult-to-fix deadlock bugs creep in.

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Has this ever happened to you? – i_like_monkeys Sep 1 '09 at 6:14

Such "lockless concurrency" isn't really a feature of a language; rather, it's a feature of a platform or runtime environment, and woe be the language that won't get out of the way to give you access to these facilities.

Thinking about the trades between lock-based and lock-free concurrency is analogous to the metacircular evaluator problem: one can implement locks in terms of atomic operations (e.g. compare-and-swap, or CAS), and one can implement atomic operations in terms of locks. Which should be at the bottom?

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