JavaScript is required to for searching.
Skip Navigation Links
Exit Print View
Multithreaded Programming Guide     Oracle Solaris 11.1 Information Library
search filter icon
search icon

Document Information


1.  Covering Multithreading Basics

2.  Basic Threads Programming

3.  Thread Attributes

4.  Programming with Synchronization Objects

5.  Programming With the Oracle Solaris Software

6.  Programming With Oracle Solaris Threads

7.  Safe and Unsafe Interfaces

8.  Compiling and Debugging

9.  Programming Guidelines

Rethinking Global Variables

Providing for Static Local Variables

Synchronizing Threads

Single-Threaded Strategy

Reentrant Function

Code Locking

Data Locking

Invariants and Locks

Avoiding Deadlock

Deadlocks Related to Scheduling

Locking Guidelines

Finding Deadlocks

Some Basic Guidelines for Threaded Code

Creating and Using Threads

Working With Multiprocessors

Underlying Architecture

Shared-Memory Multiprocessors

Peterson's Algorithm

Parallelizing a Loop on a Shared-Memory Parallel Computer

Examples of Threads Programs

Further Reading

A.  Extended Example: A Thread Pool Implementation


Avoiding Deadlock

Deadlock is a permanent blocking of a set of threads that are competing for a set of resources. Just because some thread can make progress does not mean that a deadlock has not occurred somewhere else.

The most common error that causes deadlock is self deadlock or recursive deadlock. In a self deadlock or recursive deadlock, a thread tries to acquire a lock already held by the thread. Recursive deadlock is very easy to program by mistake.

For example, assume that a code monitor has every module function grab the mutex lock for the duration of the call. Then, any call between the functions within the module protected by the mutex lock immediately deadlocks. If a function calls code outside the module that circuitously calls back into any method protected by the same mutex lock, the function deadlocks too.

The solution for this kind of deadlock is to avoid calling functions outside the module that might depend on this module through some path. In particular, avoid calling functions that call back into the module without reestablishing invariants and do not drop all module locks before making the call. Of course, after the call completes and the locks are reacquired, the state must be verified to be sure the intended operation is still valid.

An example of another kind of deadlock is when two threads, thread 1 and thread 2, acquire a mutex lock, A and B, respectively. Suppose that thread 1 tries to acquire mutex lock B and thread 2 tries to acquire mutex lock A. Thread 1 cannot proceed while blocked waiting for mutex lock B. Thread 2 cannot proceed while blocked waiting for mutex lock A. Nothing can change. So, this condition is a permanent blocking of the threads, and a deadlock.

This kind of deadlock is avoided by establishing an order in which locks are acquired, a lock hierarchy. When all threads always acquire locks in the specified order, this deadlock is avoided.

Adherence to a strict order of lock acquisition is not always optimal. For instance, thread 2 has many assumptions about the state of the module while holding mutex lock B. Giving up mutex lock B to acquire mutex lock A and then reacquiring mutex lock B in that order causes the thread to discard its assumptions. The state of the module must be reevaluated.

The blocking synchronization primitives usually have variants that attempt to get a lock and fail if the variants cannot get the lock. An example is pthread_mutex_trylock() . This behavior of primitive variants allows threads to violate the lock hierarchy when no contention occurs. When contention occurs, the held locks must usually be discarded and the locks reacquired in order.

Deadlocks Related to Scheduling

Because the order in which locks are acquired is not guaranteed, a problem can occur where a particular thread never acquires a lock.

This problem usually happens when the thread holding the lock releases the lock, lets a small amount of time pass, and then reacquires the lock. Because the lock was released, the appearance is that the other thread should acquire the lock. But, nothing blocks the thread holding the lock. Consequently, that thread continues to run from the time the thread releases the lock until the time the lock is reacquired. Thus, no other thread is run.

You can usually solve this type of problem by calling sched_yield()(3C) just before the call to reacquire the lock. The sched_yield() function allows other threads to run and to acquire the lock.

Because the time-slice requirements of applications are so variable, the system does not impose any requirements. Use calls to sched_yield() to make threads share time as you require.

Locking Guidelines

Follow these simple guidelines for locking.

Finding Deadlocks

The Oracle Solaris Studio Thread Analyzer is a tool that you can use to find deadlocks in your program. The Thread Analyzer can detect potential deadlocks as well as actual deadlocks. A potential deadlock does not necessarily occur in a given run, but can occur in any execution of the program depending on the scheduling of threads and the timing of lock requests by the threads. An actual deadlock is one that occurs during the execution of a program, causing the threads involved to hang, but may or may not cause the whole process to hang.

See the Oracle Solaris Studio 12.3: Thread Analyzer User’s Guide for more information.