Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

The common solution to preventing deadlock in code is to make sure the sequence of locking occur in a common manner regardless of which thread is accessing the resources.

For example given threads T1 and T2, where T1 accesses resource A and then B and T2 accesses resource B and then A. Locking the resources in the order they are needed causes a dead-lock. The simple solution is to lock A and then lock B, regardless of the order specific thread will use the resources.

Problematic situation:

Thread1                         Thread2
-------                         -------
Lock Resource A                 Lock Resource B
 Do Resource A thing...          Do Resource B thing...
Lock Resource B                 Lock Resource A
 Do Resource B thing...          Do Resource A thing...

Possible Solution:

Thread1                         Thread2
-------                         -------
Lock Resource A                 Lock Resource A
Lock Resource B                 Lock Resource B
 Do Resource A thing...          Do Resource B thing...
 Do Resource B thing...          Do Resource A thing...

My question is what other techniques, patterns or common practices are used in coding to guarantee dead lock prevention?

share|improve this question
    
Removed C++ tag, as the question is language agnostic. –  Raedwald May 18 '11 at 12:13

5 Answers 5

up vote 25 down vote accepted

The technique you describe isn't just common: it's the one technique that has been proven to work all the time. There are a few other rules you should follow when coding threaded code in C++, though, among which the most important may be:

  • don't hold a lock when calling a virtual function: even if at the time you're writing your code you know which function will be called and what it will do, code evolves, and virtual functions are there to be overridden, so ultimately, you won't know what it does and whether it will take any other locks, meaning you will lose your guaranteed order of locking
  • watch out for race conditions: in C++, nothing will tell you when a given piece of data is shared between threads and you don't use some kind of synchronization on it. One example of this was posted in the C++ Lounge on SO chat a few days ago, by Luc, as an example of this (code at the end of this post): just trying to synchronize on something else that happens to be in the neighborhood doesn't mean your code is correctly synchronized.
  • try to hide asynchronous behavior: you're usually better hiding your concurrency in your software's architecture, such that most calling code won't care whether there's a thread there or not. It makes the architecture easier to work with - especially for some-one who isn't used to concurrency.

I could go on for a while, but in my experience, the easiest way to work with threads is using patterns that are well-known to everyone who might work with the code, such as the producer/consumer pattern: it's easy to explain and you only need one tool (a queue) to allow your threads to communicate with each other. After all, the only reason for two threads to be synchronized with each other, is to allow them to communicate.

More general advice:

  • Don't try your hand at lock-free programming until you've had experience with concurrent programming using locks - it's an easy way to blow your foot off, or run into very strange bugs.
  • Reduce the number of shared variables and the number of times those variables are accessed to a bare minimum.
  • Don't count on two events always occurring in the same order, even if you can't see any way of them reversing order.
  • More generally: don't count on timing - don't think a given task should always take a given amount of time.

The following code will fail:

#include <thread>
#include <cassert>
#include <chrono>
#include <iostream>

void
nothing_could_possibly_go_wrong()
{
    int flag = 0;

    std::condition_variable cond;
    std::mutex mutex;
    int done = 0;
    typedef std::unique_lock<std::mutex> lock;

    auto const f = [&]
    {
        if(flag == 0) ++flag;
        lock l(mutex);
        ++done;
        cond.notify_one();
    };
    std::thread threads[2] = {
        std::thread(f),
        std::thread(f)
    };
    threads[0].join();
    threads[1].join();

    lock l(mutex);
    cond.wait(l, [done] { return done == 2; });

    // surely this can't fail!
    assert( flag == 1 );
}

int
main()
{
    for(;;) nothing_could_possibly_go_wrong();
}
share|improve this answer
    
"you won't know what it does and whether it will take any other locks" unless the specification of the base-class function is that the method never acquires a lock. –  Raedwald May 18 '11 at 14:31
    
@Raedwald that specification would have to be enforced somehow... –  rlc May 18 '11 at 14:47
    
"that specification would have to be enforced somehow": one might same the same claim about any aspect of the specification. In practice hardly any are enforced. Some are checked by review, most are checked by testing. –  Raedwald May 18 '11 at 15:47
    
@Raedwald What I meant to say is that you can't always rely on the specification of a base-class function to reflect the reality of what the function does (and.or other versions of the function do). most are checked by testing is correct, and regrettably, that means most problems aren't picked up in time to prevent damage. That doesn't mean the base class function shouldn't be clearly specified - it just means that such specifications, in practice, cannot necessarily be relied upon. –  rlc May 18 '11 at 16:57

Consistent ordering of locking is pretty much the first and last word when it comes to deadlock avoidance.

There are related techniques, such as lockless programming (where no thread ever waits on a lock, and thus there is no possibility of a cycle), but that's really just a special case of the "avoid inconsistent locking order" rule -- i.e. they avoid inconsistent locking by avoiding all locking. Unfortunately, lockless programming has its own issues, so it's not a panacea either.

If you want to broaden the scope a bit, there are methods for detecting deadlocks when they do occur (if for some reason you can't design your program to avoid them), and ways for breaking deadlocks when they do occur (e.g. by always locking with a timeout, or by forcing one of the deadlocked threads to have their Lock() command fail, or even just by killing one of the deadlocked threads); but I think they are all pretty inferior to simply making sure deadlocks cannot happen in the first place.

(btw if you want an automated way to check whether your program has potential deadlocks in it, check out valgrind's helgrind tool. It will monitor your code's locking patterns and notify you of any inconsistencies -- very useful)

share|improve this answer
1  
Lock-free programming isn't a technique to avoid inconsistent locking: it's a field of research aimed at creating truly scalable concurrent algorithms. The only issue with lock-free programming is that it is hard, so it's not something to recommend to some-one who doesn't have much experience with concurrent programming.. –  rlc May 16 '11 at 3:00
2  
@rlc and @Jeremy: And "lock-free" programming isn't even really lock free. It's just using locking implemented in the hardware, in the cache coherency protocols and the inter-processor communication. Without some kind of lock the much loved compare-exchange instructions couldn't possibly work. –  Zan Lynx May 16 '11 at 3:56
    
@rlc fair enough -- but I didn't claim otherwise, I only said it was a related technique. @Zan it's lock-free in the sense that a thread is guaranteed not to block indefinitely, and thus there is no chance of a deadlock occurring. –  Jeremy Friesner May 16 '11 at 5:21
    
@ZanLynx true: processors will synchronize with each other and, in the x86 architecture, the LOCK pin is asserted, both of which come at significant cost. The locks themselves are implemented using the same hardware-level synchronization mechanisms, though, and on the software level, while there are synchronization points, there are no locks in the sense that at least one thread will always make forward progress. Wikipedia has a nice definition here –  rlc May 16 '11 at 13:19

Another technique is transactional programming. This though is not very common as it usually involves specialized hardware (most of it currently only in research institutions).

Each resource keeps track of modifications from different threads. The first thread to commit changes to all resources (it is using) wins all other thread (using those resources) get rolled back to try again with the resources in the new committed state.

A simplistic starting point for reading on the subject is transactional memory.

share|improve this answer

While not an alternative to the known-sequence solution you mention, Andrei Alexandrescu wrote about some techniques for compile time checks that acquisition of locks is done through the intended mechanisms. See http://www.informit.com/articles/article.aspx?p=25298

share|improve this answer
2  
nice article, thanks :) –  Matthieu M. May 16 '11 at 6:39

You are asking about the design level, but I'll add some lower level, programming practices.

  • Classify each function (method) as blocking, non-blocking or having unknown blocking behaviour.
  • A blocking function is a function that acquires a lock, or calls a slow system call (which in practice means it does I/O), or calls a blocking function.
  • Whether a function is guaranteed to be non-blocking is part of the specificatino of that function, just like its preconditions and its degree of exception safety. It must therefore be documented as such. In Java I use an annotation; in C++ documented using Doxygen I'd use a forumalic phrase in the header commentary for the function.
  • Consider calling a function that is not specified to be non-blocking while holding a lock to be prima facie dangerous.
  • Refactor such prima facie dangerous code to eliminate the danger or to concentrate the danger into a small section of code (perhaps within its own function).
  • For the remaining prima facie dangerous code, provide an informal proof that the code is not actually dangerous in the commentary of the code.
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.