I am doing experiments with IPC, especially with Mutex, Semaphore and Spin Lock. What I learnt is Mutex is used for Asynchronous Locking (with sleeping (as per theories I read on NET)) Mechanism, Semaphore are Synchronous Locking (with Signaling and Sleeping) Mechanism, and Spin Locks are Synchronous but Non-sleeping Mechanism.

Can anyone help me to clarify these stuff deeply? And another doubt is about Mutex, when I wrote program with thread & mutex, while one thread is running another thread is not in Sleep state but it continuously tries to acquire the Lock. So Mutex is sleeping or Non-sleeping???


3 Answers 3


First, remember the goal of these 'synchronizing objects' :

These objects were designed to provide an efficient and coherent use of 'shared data' between more than 1 thread among 1 process or from different processes.

These objects can be 'acquired' or 'released'.

That is it!!! End of story!!!

Now, if it helps to you, let me put my grain of sand:

1) Critical Section= User object used for allowing the execution of just one active thread from many others within one process. The other non selected threads (@ acquiring this object) are put to sleep.

[No interprocess capability, very primitive object].

2) Mutex Semaphore (aka Mutex)= Kernel object used for allowing the execution of just one active thread from many others, within one process or among different processes. The other non selected threads (@ acquiring this object) are put to sleep. This object supports thread ownership, thread termination notification, recursion (multiple 'acquire' calls from same thread) and 'priority inversion avoidance'.

[Interprocess capability, very safe to use, a kind of 'high level' synchronization object].

3) Counting Semaphore (aka Semaphore)= Kernel object used for allowing the execution of a group of active threads from many others, within one process or among different processes. The other non selected threads (@ acquiring this object) are put to sleep.

[Interprocess capability however not very safe to use because it lacks following 'mutex' attributes: thread termination notification, recursion?, 'priority inversion avoidance'?, etc].

4) And now, talking about 'spinlocks', first some definitions:

Critical Region= A region of memory shared by 2 or more processes.

Lock= A variable whose value allows or denies the entrance to a 'critical region'. (It could be implemented as a simple 'boolean flag').

Busy waiting= Continuosly testing of a variable until some value appears.


Spin-lock (aka Spinlock)= A lock which uses busy waiting. (The acquiring of the lock is made by xchg or similar atomic operations).

[No thread sleeping, mostly used at kernel level only. Ineffcient for User level code].

As a last comment, I am not sure but I can bet you some big bucks that the above first 3 synchronizing objects (#1, #2 and #3) make use of this simple beast (#4) as part of their implementation.

Have a good day!.


-Real-Time Concepts for Embedded Systems by Qing Li with Caroline Yao (CMP Books).

-Modern Operating Systems (3rd) by Andrew Tanenbaum (Pearson Education International).

-Programming Applications for Microsoft Windows (4th) by Jeffrey Richter (Microsoft Programming Series).

  • Re "Critical section .. the other threads are put to sleep." - only true for very primitive implementation of a critical section, where interrupts are disabled upon entry of that section. See Wikipedia - Critical section for discussion of that implementation, as well as the alternative of using a semaphore for more efficient implementation, of what is still referred to as a "critical section" of code. Commented Feb 2, 2017 at 5:00
  • 2
    ... later definitions here are even more misleading when they say "other threads are put to sleep". That implies to me that other threads can't run at all, which completely misses the point of these mechanisms. Specifically, any thread that needs to use the shared resource (protected by one of these mechanisms) must indeed be blocked (put to sleep), but threads that are not using the shared resource, are not put to sleep. Commented Feb 2, 2017 at 5:04
  • ... the distinction between mutex and semaphore is ..weak.. [don't know if that is a problem with the references, or with the re-statement in this answer]. For a clearer distinction, see barrgroup.com/Embedded-Systems/How-To/RTOS-Mutex-Semaphore The key sentence "The correct use of a semaphore is for signaling from one task to another. A mutex is meant to be taken and released, always in that order, by each task that uses the shared resource it protects. By contrast, tasks that use semaphores either signal or wait—not both. " Commented Feb 2, 2017 at 5:09
  • @ToolmakerSteve, the distinction between a mutex and semaphore is weak? Really?. Please, I beg you to read one of the book from the references. The Li & Yao book is superb to get your ideas clear.
    – fante
    Commented Feb 6, 2017 at 12:56
  • @ToolmakerSteve, however I should say (as you refer in your comments) that these objects are used to provide 'signaling' between threads too. Let me think about it and I will add that feature to my answer.
    – fante
    Commented Feb 6, 2017 at 13:12

Here is a great explanation of the difference between semaphores and mutexes:


The short answer has to do with ownership at least with binary semaphores but I suggest you read the entire article.


Mutex is the locking mechanism while the semaphore is the wait and signal mechanism. Both have different applications.

There is a very good explanation given by the IISC professor.

Link for video

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