988

Is there any difference between a binary semaphore and mutex or are they essentially the same?

10
  • 18
    They're semantically the same, but in practice you will notice weird differences (especially on Windows). Oct 9, 2009 at 5:30
  • 10
    @Michael Foukarakis: What are the weird differences?
    – Philipp
    Jul 11, 2010 at 13:56
  • 5
    I suppose weird wasn't the correct expression. A mutex also supports ownership and sometimes reentry. This is the case in Windows. In addition, semaphores in Windows are implemented on top of Event objects, however, I'm unsure of the practical implications of this. Jul 11, 2010 at 15:13
  • 4
    @philipxy Nicely hid 'rn' in place of 'm'.
    – Mooncrater
    Oct 20, 2018 at 11:09
  • 4
    @Mooncrater Wow. Good eye. I expect its due to OCR. (Yes, it is.)
    – philipxy
    Oct 20, 2018 at 17:05

37 Answers 37

816

They are NOT the same thing. They are used for different purposes!
While both types of semaphores have a full/empty state and use the same API, their usage is very different.

Mutual Exclusion Semaphores
Mutual Exclusion semaphores are used to protect shared resources (data structure, file, etc..).

A Mutex semaphore is "owned" by the task that takes it. If Task B attempts to semGive a mutex currently held by Task A, Task B's call will return an error and fail.

Mutexes always use the following sequence:

  - SemTake
  - Critical Section
  - SemGive

Here is a simple example:

  Thread A                     Thread B
   Take Mutex
     access data
     ...                        Take Mutex  <== Will block
     ...
   Give Mutex                     access data  <== Unblocks
                                  ...
                                Give Mutex

Binary Semaphore
Binary Semaphore address a totally different question:

  • Task B is pended waiting for something to happen (a sensor being tripped for example).
  • Sensor Trips and an Interrupt Service Routine runs. It needs to notify a task of the trip.
  • Task B should run and take appropriate actions for the sensor trip. Then go back to waiting.

   Task A                      Task B
   ...                         Take BinSemaphore   <== wait for something
   Do Something Noteworthy
   Give BinSemaphore           do something    <== unblocks

Note that with a binary semaphore, it is OK for B to take the semaphore and A to give it.
Again, a binary semaphore is NOT protecting a resource from access. The act of Giving and Taking a semaphore are fundamentally decoupled.
It typically makes little sense for the same task to call both give and take on the same binary semaphore.

15
  • 14
    Isn't a mutex better than a binary semaphore then? Since it doesn't make sense if someone releases a lock which he doesn't actually hold.
    – Pacerier
    Dec 8, 2011 at 16:31
  • 171
    They have different purposes. Mutex is for exclusive access to a resource. A Binary semaphore should be used for Synchronization (i.e. "Hey Someone! This occurred!"). The Binary "giver" simply notifies whoever the "taker" that what they were waiting for happened.
    – Benoit
    Dec 9, 2011 at 17:16
  • 6
    @Pacerier You are confusing the purpose. A mutex is intended protect a critical region. You are correct it doesn't make sense to use a Binary Semaphore. I'll update the answer to explain the purpose of each.
    – Benoit
    Jan 7, 2012 at 17:48
  • 5
    @Benoit So Can we say that Mutex are Used for atomicity and Binary Semaphore for Ordering perspective since Task B will be waiting for Task A to signal the release of lock inherently making sure of ordering of operations on a data strurcture?
    – abhi
    Feb 23, 2014 at 9:16
  • 5
    The little book of semaphores is a valuable read about these issues.
    – G. Bach
    Jul 17, 2017 at 15:10
541
  • A mutex can be released only by the thread that had acquired it.
  • A binary semaphore can be signaled by any thread (or process).

so semaphores are more suitable for some synchronization problems like producer-consumer.

On Windows, binary semaphores are more like event objects than mutexes.

5
  • 41
    Mutex can be released only by thread that had acquired it -- I just tried with a simple pthread_mutex based program, a thread can unlock mutex locked in main thread
    – daisy
    Jul 28, 2012 at 3:55
  • 22
    @warl0ck As per the man page of pthread_mutex_lock linux.die.net/man/3/pthread_mutex_lock : "If the mutex type is PTHREAD_MUTEX_ERRORCHECK, then error checking shall be provided....If a thread attempts to unlock a mutex that it has not locked or a mutex which is unlocked, an error shall be returned."
    – amit kumar
    Jan 11, 2013 at 10:20
  • 56
    @warl0ck Please see stackoverflow.com/a/5492499/385064 'Pthreads has 3 different kinds of mutexes: Fast mutex, recursive mutex, and error checking mutex. You used a fast mutex which, for performance reasons, will not check for this error. If you use the error checking mutex on Linux you will find you get the results you expect.' Nov 27, 2013 at 6:37
  • 3
    In our code we have used mutex also for synchronization purposes.The Thread which locks the mutex again tried to lock the mutex.Then it goes to blocked state.What we have seen is that we are able to unlock this from another thread .Thus achieving synchronization between the two.We are using posix standard only .So the major difference sited between mutex and binary semaphore seems vague.
    – achoora
    Feb 18, 2016 at 8:37
  • 1
    @achoora I agree that it is wrong to specialize semaphore for synchronization. Actually all the mutex,binary-semaphore,barrier,pipelines are different patterns for synchronization. In design perspective, mutex are more like state-pattern where the algorithm that is selected by the state can change the state. The binary-semaphore are more like strategy pattern where the external algorithm can change the state and eventually the algorithm/strategy selected to run.
    – KRoy
    May 17, 2016 at 18:39
493

The Toilet example is an enjoyable analogy:

Mutex:

Is a key to a toilet. One person can have the key - occupy the toilet - at the time. When finished, the person gives (frees) the key to the next person in the queue.

Officially: "Mutexes are typically used to serialise access to a section of re-entrant code that cannot be executed concurrently by more than one thread. A mutex object only allows one thread into a controlled section, forcing other threads which attempt to gain access to that section to wait until the first thread has exited from that section." Ref: Symbian Developer Library

(A mutex is really a semaphore with value 1.)

Semaphore:

Is the number of free identical toilet keys. Example, say we have four toilets with identical locks and keys. The semaphore count - the count of keys - is set to 4 at beginning (all four toilets are free), then the count value is decremented as people are coming in. If all toilets are full, ie. there are no free keys left, the semaphore count is 0. Now, when eq. one person leaves the toilet, semaphore is increased to 1 (one free key), and given to the next person in the queue.

Officially: "A semaphore restricts the number of simultaneous users of a shared resource up to a maximum number. Threads can request access to the resource (decrementing the semaphore), and can signal that they have finished using the resource (incrementing the semaphore)." Ref: Symbian Developer Library

11
  • 288
    ... but this is regarding mutex vs counting semaphore. The question was asked about binary. Nov 10, 2009 at 7:47
  • 32
    While what is said by david is correct, but it is NOT the answer to the question asked. Mladen Jankovic answer is the answer to the question asked, where point is made to differentiate "binary-semaphore" vs "mutex". Aug 21, 2011 at 15:45
  • 24
    Unfortunately, this incorrect answer has more votes than the best answer by @Benoit
    – NeonGlow
    Apr 29, 2013 at 9:18
  • 10
    This answer is misleading.Should have compared only with Binary Semaphore.
    – Hemanth
    Mar 15, 2014 at 8:27
  • 5
    In other words: A binary semaphore is identical to a mutex. Downvoted for presenting the information of a one-liner in several paragraphs. And not even addressing the question being asked. Nov 15, 2017 at 23:19
178

Nice articles on the topic:

From part 2:

The mutex is similar to the principles of the binary semaphore with one significant difference: the principle of ownership. Ownership is the simple concept that when a task locks (acquires) a mutex only it can unlock (release) it. If a task tries to unlock a mutex it hasn’t locked (thus doesn’t own) then an error condition is encountered and, most importantly, the mutex is not unlocked. If the mutual exclusion object doesn't have ownership then, irrelevant of what it is called, it is not a mutex.

4
  • Thanks for the link, the explanations there are excellent. The link has changed: feabhas.com/blog/2009/09/… (Use < Prev and Next > to navigate to the other two articles.
    – Aaron H.
    May 13, 2010 at 23:03
  • Note - the lack of ownership also prevents the operating system from working around priority inversion. For this reason, I generally use condition variables as opposed to semaphores for producer/consumer architectures.
    – kgriffs
    Feb 4, 2011 at 19:49
  • 3
    +1 foe excellent article links. The best article explaining semaphore and mutex with "what-it-is" and "what-it-does" computing.llnl.gov/tutorials/pthreads I had used this article as my behind the scene reference, which technically does explain everything about mutex/conditionals and other constructs built on their top like semaphore/barrier/reader-writer, but nowhere explicit and concise about problems faced with constructs. In short it is reference. :) Aug 21, 2011 at 16:15
  • more easily understood than the other answers.
    – Kindred
    Dec 31, 2018 at 6:15
117

Since none of the above answer clears the confusion, here is one which cleared my confusion.

Strictly speaking, a mutex is a locking mechanism used to synchronize access to a resource. Only one task (can be a thread or process based on OS abstraction) can acquire the mutex. It means there will be ownership associated with mutex, and only the owner can release the lock (mutex).

Semaphore is signaling mechanism (“I am done, you can carry on” kind of signal). For example, if you are listening songs (assume it as one task) on your mobile and at the same time your friend called you, an interrupt will be triggered upon which an interrupt service routine (ISR) will signal the call processing task to wakeup.

Source: http://www.geeksforgeeks.org/mutex-vs-semaphore/

49

Their synchronization semantics are very different:

  • mutexes allow serialization of access to a given resource i.e. multiple threads wait for a lock, one at a time and as previously said, the thread owns the lock until it is done: only this particular thread can unlock it.
  • a binary semaphore is a counter with value 0 and 1: a task blocking on it until any task does a sem_post. The semaphore advertises that a resource is available, and it provides the mechanism to wait until it is signaled as being available.

As such one can see a mutex as a token passed from task to tasks and a semaphore as traffic red-light (it signals someone that it can proceed).

33

At a theoretical level, they are no different semantically. You can implement a mutex using semaphores or vice versa (see here for an example). In practice, the implementations are different and they offer slightly different services.

The practical difference (in terms of the system services surrounding them) is that the implementation of a mutex is aimed at being a more lightweight synchronisation mechanism. In oracle-speak, mutexes are known as latches and semaphores are known as waits.

At the lowest level, they use some sort of atomic test and set mechanism. This reads the current value of a memory location, computes some sort of conditional and writes out a value at that location in a single instruction that cannot be interrupted. This means that you can acquire a mutex and test to see if anyone else had it before you.

A typical mutex implementation has a process or thread executing the test-and-set instruction and evaluating whether anything else had set the mutex. A key point here is that there is no interaction with the scheduler, so we have no idea (and don't care) who has set the lock. Then we either give up our time slice and attempt it again when the task is re-scheduled or execute a spin-lock. A spin lock is an algorithm like:

Count down from 5000:
     i. Execute the test-and-set instruction
    ii. If the mutex is clear, we have acquired it in the previous instruction 
        so we can exit the loop
   iii. When we get to zero, give up our time slice.

When we have finished executing our protected code (known as a critical section) we just set the mutex value to zero or whatever means 'clear.' If multiple tasks are attempting to acquire the mutex then the next task that happens to be scheduled after the mutex is released will get access to the resource. Typically you would use mutexes to control a synchronised resource where exclusive access is only needed for very short periods of time, normally to make an update to a shared data structure.

A semaphore is a synchronised data structure (typically using a mutex) that has a count and some system call wrappers that interact with the scheduler in a bit more depth than the mutex libraries would. Semaphores are incremented and decremented and used to block tasks until something else is ready. See Producer/Consumer Problem for a simple example of this. Semaphores are initialised to some value - a binary semaphore is just a special case where the semaphore is initialised to 1. Posting to a semaphore has the effect of waking up a waiting process.

A basic semaphore algorithm looks like:

(somewhere in the program startup)
Initialise the semaphore to its start-up value.

Acquiring a semaphore
   i. (synchronised) Attempt to decrement the semaphore value
  ii. If the value would be less than zero, put the task on the tail of the list of tasks waiting on the semaphore and give up the time slice.

Posting a semaphore
   i. (synchronised) Increment the semaphore value
  ii. If the value is greater or equal to the amount requested in the post at the front of the queue, take that task off the queue and make it runnable.  
 iii. Repeat (ii) for all tasks until the posted value is exhausted or there are no more tasks waiting.

In the case of a binary semaphore the main practical difference between the two is the nature of the system services surrounding the actual data structure.

EDIT: As evan has rightly pointed out, spinlocks will slow down a single processor machine. You would only use a spinlock on a multi-processor box because on a single processor the process holding the mutex will never reset it while another task is running. Spinlocks are only useful on multi-processor architectures.

3
  • 2
    I don't think it is common practice for a mutex to be implemented with spinlocks. On a Uni-proc machine this would be absolutely terrible for performance.
    – Evan Teran
    Nov 22, 2008 at 20:11
  • Normally you would only use spinlocks on multi-processor systems. Nov 23, 2008 at 13:09
  • Even on SMP, after spinning a few times you fall-back to OS-assisted sleep/wake. (e.g. the Linux futex system call exists to assist low-latency userspace mutex / semaphore implementations. en.wikipedia.org/wiki/Futex) In the no-contention fast path, or if the resource becomes available soon, you never have the overhead of a system call. But you don't spend more than a few micro-seconds busy-waiting (spinning). Tuning the parameters of spin-loop backoff and wait is hardware and workload-dependent, of course, but the standard library usually has reasonable choices. Oct 26, 2019 at 4:01
21

Though mutex & semaphores are used as synchronization primitives ,there is a big difference between them. In the case of mutex, only the thread that locked or acquired the mutex can unlock it. In the case of a semaphore, a thread waiting on a semaphore can be signaled by a different thread. Some operating system supports using mutex & semaphores between process. Typically usage is creating in shared memory.

1
  • "can be signaled by a different thread" what is it mean give an example.
    – Myanju
    Aug 17, 2017 at 18:52
20

Mutex: Suppose we have critical section thread T1 wants to access it then it follows below steps. T1:

  1. Lock
  2. Use Critical Section
  3. Unlock

Binary semaphore: It works based on signaling wait and signal. wait(s) decrease "s" value by one usually "s" value is initialize with value "1", signal(s) increases "s" value by one. if "s" value is 1 means no one is using critical section, when value is 0 means critical section is in use. suppose thread T2 is using critical section then it follows below steps. T2 :

  1. wait(s)//initially s value is one after calling wait it's value decreased by one i.e 0
  2. Use critical section
  3. signal(s) // now s value is increased and it become 1

Main difference between Mutex and Binary semaphore is in Mutext if thread lock the critical section then it has to unlock critical section no other thread can unlock it, but in case of Binary semaphore if one thread locks critical section using wait(s) function then value of s become "0" and no one can access it until value of "s" become 1 but suppose some other thread calls signal(s) then value of "s" become 1 and it allows other function to use critical section. hence in Binary semaphore thread doesn't have ownership.

0
12

On Windows, there are two differences between mutexes and binary semaphores:

  1. A mutex can only be released by the thread which has ownership, i.e. the thread which previously called the Wait function, (or which took ownership when creating it). A semaphore can be released by any thread.

  2. A thread can call a wait function repeatedly on a mutex without blocking. However, if you call a wait function twice on a binary semaphore without releasing the semaphore in between, the thread will block.

1
12

Myth:

Couple of article says that "binary semaphore and mutex are same" or "Semaphore with value 1 is mutex" but the basic difference is Mutex can be released only by thread that had acquired it, while you can signal semaphore from any other thread

Key Points:

•A thread can acquire more than one lock (Mutex).

•A mutex can be locked more than once only if its a recursive mutex, here lock and unlock for mutex should be same

•If a thread which had already locked a mutex, tries to lock the mutex again, it will enter into the waiting list of that mutex, which results in deadlock.

•Binary semaphore and mutex are similar but not same.

•Mutex is costly operation due to protection protocols associated with it.

•Main aim of mutex is achieve atomic access or lock on resource

11

Mutex are used for " Locking Mechanisms ". one process at a time can use a shared resource

whereas

Semaphores are used for " Signaling Mechanisms " like "I am done , now can continue"

10

You obviously use mutex to lock a data in one thread getting accessed by another thread at the same time. Assume that you have just called lock() and in the process of accessing data. This means that you don’t expect any other thread (or another instance of the same thread-code) to access the same data locked by the same mutex. That is, if it is the same thread-code getting executed on a different thread instance, hits the lock, then the lock() should block the control flow there. This applies to a thread that uses a different thread-code, which is also accessing the same data and which is also locked by the same mutex. In this case, you are still in the process of accessing the data and you may take, say, another 15 secs to reach the mutex unlock (so that the other thread that is getting blocked in mutex lock would unblock and would allow the control to access the data). Do you at any cost allow yet another thread to just unlock the same mutex, and in turn, allow the thread that is already waiting (blocking) in the mutex lock to unblock and access the data? Hope you got what I am saying here? As per, agreed upon universal definition!,

  • with “mutex” this can’t happen. No other thread can unlock the lock in your thread
  • with “binary-semaphore” this can happen. Any other thread can unlock the lock in your thread

So, if you are very particular about using binary-semaphore instead of mutex, then you should be very careful in “scoping” the locks and unlocks. I mean that every control-flow that hits every lock should hit an unlock call, also there shouldn’t be any “first unlock”, rather it should be always “first lock”.

7

A Mutex controls access to a single shared resource. It provides operations to acquire() access to that resource and release() it when done.

A Semaphore controls access to a shared pool of resources. It provides operations to Wait() until one of the resources in the pool becomes available, and Signal() when it is given back to the pool.

When number of resources a Semaphore protects is greater than 1, it is called a Counting Semaphore. When it controls one resource, it is called a Boolean Semaphore. A boolean semaphore is equivalent to a mutex.

Thus a Semaphore is a higher level abstraction than Mutex. A Mutex can be implemented using a Semaphore but not the other way around.

6

Modified question is - What's the difference between A mutex and a "binary" semaphore in "Linux"?

Ans: Following are the differences – i) Scope – The scope of mutex is within a process address space which has created it and is used for synchronization of threads. Whereas semaphore can be used across process space and hence it can be used for interprocess synchronization.

ii) Mutex is lightweight and faster than semaphore. Futex is even faster.

iii) Mutex can be acquired by same thread successfully multiple times with condition that it should release it same number of times. Other thread trying to acquire will block. Whereas in case of semaphore if same process tries to acquire it again it blocks as it can be acquired only once.

1
  • 2
    i) Wrong. ii) Source? iii) It depends.
    – curiousguy
    Oct 24, 2011 at 7:39
6

Diff between Binary Semaphore and Mutex: OWNERSHIP: Semaphores can be signalled (posted) even from a non current owner. It means you can simply post from any other thread, though you are not the owner.

Semaphore is a public property in process, It can be simply posted by a non owner thread. Please Mark this difference in BOLD letters, it mean a lot.

5

Mutex work on blocking critical region, But Semaphore work on count.

5

http://www.geeksforgeeks.org/archives/9102 discusses in details.

Mutex is locking mechanism used to synchronize access to a resource. Semaphore is signaling mechanism.

Its up to to programmer if he/she wants to use binary semaphore in place of mutex.

4

Apart from the fact that mutexes have an owner, the two objects may be optimized for different usage. Mutexes are designed to be held only for a short time; violating this can cause poor performance and unfair scheduling. For example, a running thread may be permitted to acquire a mutex, even though another thread is already blocked on it. Semaphores may provide more fairness, or fairness can be forced using several condition variables.

2
  • In which specific cases is fairness guaranteed for semaphores but not for mutexes?
    – curiousguy
    Oct 24, 2011 at 7:34
  • 1
    POSIX has specific requirements which thread should be awakened by sem_post() for SCHED_FIFO and SCHED_RR (both of these are not default): the highest priority thread, and if there are multiple with the same priority, the thread that has been waiting the longest. OpenSolaris follows this FIFO rule to some degree even for normal scheduling. For glibc and FreeBSD, unlocking a simple mutex (i.e. not priority protect or priority inherit) and posting a semaphore are basically the same, marking the object as unlocked and then, if there may be waiting threads, calling the kernel to wake one.
    – jilles
    Oct 26, 2011 at 19:37
4

In windows the difference is as below. MUTEX: process which successfully executes wait has to execute a signal and vice versa. BINARY SEMAPHORES: Different processes can execute wait or signal operation on a semaphore.

4

While a binary semaphore may be used as a mutex, a mutex is a more specific use-case, in that only the process that locked the mutex is supposed to unlock it. This ownership constraint makes it possible to provide protection against:

  • Accidental release
  • Recursive Deadlock
  • Task Death Deadlock

These constraints are not always present because they degrade the speed. During the development of your code, you can enable these checks temporarily.

e.g. you can enable Error check attribute in your mutex. Error checking mutexes return EDEADLK if you try to lock the same one twice and EPERM if you unlock a mutex that isn't yours.

pthread_mutex_t mutex;
pthread_mutexattr_t attr;
pthread_mutexattr_init (&attr);
pthread_mutexattr_settype (&attr, PTHREAD_MUTEX_ERRORCHECK_NP);
pthread_mutex_init (&mutex, &attr);

Once initialised we can place these checks in our code like this:

if(pthread_mutex_unlock(&mutex)==EPERM)
 printf("Unlock failed:Mutex not owned by this thread\n");
4

The concept was clear to me after going over above posts. But there were some lingering questions. So, I wrote this small piece of code.

When we try to give a semaphore without taking it, it goes through. But, when you try to give a mutex without taking it, it fails. I tested this on a Windows platform. Enable USE_MUTEX to run the same code using a MUTEX.

#include <stdio.h>
#include <windows.h>
#define xUSE_MUTEX 1
#define MAX_SEM_COUNT 1

DWORD WINAPI Thread_no_1( LPVOID lpParam );
DWORD WINAPI Thread_no_2( LPVOID lpParam );

HANDLE Handle_Of_Thread_1 = 0;
HANDLE Handle_Of_Thread_2 = 0;
int Data_Of_Thread_1 = 1;
int Data_Of_Thread_2 = 2;
HANDLE ghMutex = NULL;
HANDLE ghSemaphore = NULL;


int main(void)
{

#ifdef USE_MUTEX
    ghMutex = CreateMutex( NULL, FALSE, NULL);
    if (ghMutex  == NULL) 
    {
        printf("CreateMutex error: %d\n", GetLastError());
        return 1;
    }
#else
    // Create a semaphore with initial and max counts of MAX_SEM_COUNT
    ghSemaphore = CreateSemaphore(NULL,MAX_SEM_COUNT,MAX_SEM_COUNT,NULL);
    if (ghSemaphore == NULL) 
    {
        printf("CreateSemaphore error: %d\n", GetLastError());
        return 1;
    }
#endif
    // Create thread 1.
    Handle_Of_Thread_1 = CreateThread( NULL, 0,Thread_no_1, &Data_Of_Thread_1, 0, NULL);  
    if ( Handle_Of_Thread_1 == NULL)
    {
        printf("Create first thread problem \n");
        return 1;
    }

    /* sleep for 5 seconds **/
    Sleep(5 * 1000);

    /*Create thread 2 */
    Handle_Of_Thread_2 = CreateThread( NULL, 0,Thread_no_2, &Data_Of_Thread_2, 0, NULL);  
    if ( Handle_Of_Thread_2 == NULL)
    {
        printf("Create second thread problem \n");
        return 1;
    }

    // Sleep for 20 seconds
    Sleep(20 * 1000);

    printf("Out of the program \n");
    return 0;
}


int my_critical_section_code(HANDLE thread_handle)
{

#ifdef USE_MUTEX
    if(thread_handle == Handle_Of_Thread_1)
    {
        /* get the lock */
        WaitForSingleObject(ghMutex, INFINITE);
        printf("Thread 1 holding the mutex \n");
    }
#else
    /* get the semaphore */
    if(thread_handle == Handle_Of_Thread_1)
    {
        WaitForSingleObject(ghSemaphore, INFINITE);
        printf("Thread 1 holding semaphore \n");
    }
#endif

    if(thread_handle == Handle_Of_Thread_1)
    {
        /* sleep for 10 seconds */
        Sleep(10 * 1000);
#ifdef USE_MUTEX
        printf("Thread 1 about to release mutex \n");
#else
        printf("Thread 1 about to release semaphore \n");
#endif
    }
    else
    {
        /* sleep for 3 secconds */
        Sleep(3 * 1000);
    }

#ifdef USE_MUTEX
    /* release the lock*/
    if(!ReleaseMutex(ghMutex))
    {
        printf("Release Mutex error in thread %d: error # %d\n", (thread_handle == Handle_Of_Thread_1 ? 1:2),GetLastError());
    }
#else
    if (!ReleaseSemaphore(ghSemaphore,1,NULL) )      
    {
        printf("ReleaseSemaphore error in thread %d: error # %d\n",(thread_handle == Handle_Of_Thread_1 ? 1:2), GetLastError());
    }
#endif

    return 0;
}

DWORD WINAPI Thread_no_1( LPVOID lpParam ) 
{ 
    my_critical_section_code(Handle_Of_Thread_1);
    return 0;
}


DWORD WINAPI Thread_no_2( LPVOID lpParam ) 
{
    my_critical_section_code(Handle_Of_Thread_2);
    return 0;
}

The very fact that semaphore lets you signal "it is done using a resource", even though it never owned the resource, makes me think there is a very loose coupling between owning and signaling in the case of semaphores.

1
  • If you read the other answers, it's clear that the concept of "ownership" only makes sense with mutexes, not semaphores. Semaphores could be used for things like a thread letting other threads know that processing of a chunk of data is done; results ready to be read. Oct 26, 2019 at 4:06
4

Best Solution

The only difference is

1.Mutex -> lock and unlock are under the ownership of a thread that locks the mutex.

2.Semaphore -> No ownership i.e; if one thread calls semwait(s) any other thread can call sempost(s) to remove the lock.

2

Mutex is used to protect the sensitive code and data, semaphore is used to synchronization.You also can have practical use with protect the sensitive code, but there might be a risk that release the protection by the other thread by operation V.So The main difference between bi-semaphore and mutex is the ownership.For instance by toilet , Mutex is like that one can enter the toilet and lock the door, no one else can enter until the man get out, bi-semaphore is like that one can enter the toilet and lock the door, but someone else could enter by asking the administrator to open the door, it's ridiculous.

2

I think most of the answers here were confusing especially those saying that mutex can be released only by the process that holds it but semaphore can be signaled by ay process. The above line is kind of vague in terms of semaphore. To understand we should know that there are two kinds of semaphore one is called counting semaphore and the other is called a binary semaphore. In counting semaphore handles access to n number of resources where n can be defined before the use. Each semaphore has a count variable, which keeps the count of the number of resources in use, initially, it is set to n. Each process that wishes to uses a resource performs a wait() operation on the semaphore (thereby decrementing the count). When a process releases a resource, it performs a release() operation (incrementing the count). When the count becomes 0, all the resources are being used. After that, the process waits until the count becomes more than 0. Now here is the catch only the process that holds the resource can increase the count no other process can increase the count only the processes holding a resource can increase the count and the process waiting for the semaphore again checks and when it sees the resource available it decreases the count again. So in terms of binary semaphore, only the process holding the semaphore can increase the count, and count remains zero until it stops using the semaphore and increases the count and other process gets the chance to access the semaphore.

The main difference between binary semaphore and mutex is that semaphore is a signaling mechanism and mutex is a locking mechanism, but binary semaphore seems to function like mutex that creates confusion, but both are different concepts suitable for a different kinds of work.

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  • This statement contrasts with the other answers: "So in terms of binary semaphore, only the process holding the semaphore can increase the count" - Semaphore, including binary semaphore, can be released by any other thread, not only the one who acquired the semaphore. That's all the other answers are saying. Mar 9, 2022 at 8:30
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The answer may depend on the target OS. For example, at least one RTOS implementation I'm familiar with will allow multiple sequential "get" operations against a single OS mutex, so long as they're all from within the same thread context. The multiple gets must be replaced by an equal number of puts before another thread will be allowed to get the mutex. This differs from binary semaphores, for which only a single get is allowed at a time, regardless of thread contexts.

The idea behind this type of mutex is that you protect an object by only allowing a single context to modify the data at a time. Even if the thread gets the mutex and then calls a function that further modifies the object (and gets/puts the protector mutex around its own operations), the operations should still be safe because they're all happening under a single thread.

{
    mutexGet();  // Other threads can no longer get the mutex.

    // Make changes to the protected object.
    // ...

    objectModify();  // Also gets/puts the mutex.  Only allowed from this thread context.

    // Make more changes to the protected object.
    // ...

    mutexPut();  // Finally allows other threads to get the mutex.
}

Of course, when using this feature, you must be certain that all accesses within a single thread really are safe!

I'm not sure how common this approach is, or whether it applies outside of the systems with which I'm familiar. For an example of this kind of mutex, see the ThreadX RTOS.

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  • 2
    The kind of mutex you are talking about are called "recursive mutex" and should be avoided since they are slow and tend to promote bad design: (see David Butenhof: zaval.org/resources/library/butenhof1.html) Jan 21, 2010 at 9:20
  • Agreed. On this particular OS, I use the mutex service where I want to make it clear that the code is for "mutual exclusion" and not reference counting, but I don't use the recursive feature for fear of ugly unwinding. Still, in the context of the question, this is an important difference between a "mutex" and "binary semaphore." Jan 21, 2010 at 13:53
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Mutexes have ownership, unlike semaphores. Although any thread, within the scope of a mutex, can get an unlocked mutex and lock access to the same critical section of code,only the thread that locked a mutex should unlock it.

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  • what is ownership?You mean the context which acquires mutex can only un-aquire it.??
    – Raulp
    May 30, 2012 at 15:15
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As many folks here have mentioned, a mutex is used to protect a critical piece of code (AKA critical section.) You will acquire the mutex (lock), enter critical section, and release mutex (unlock) all in the same thread.

While using a semaphore, you can make a thread wait on a semaphore (say thread A), until another thread (say thread B)completes whatever task, and then sets the Semaphore for thread A to stop the wait, and continue its task.

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MUTEX

Until recently, the only sleeping lock in the kernel was the semaphore. Most users of semaphores instantiated a semaphore with a count of one and treated them as a mutual exclusion lock—a sleeping version of the spin-lock. Unfortunately, semaphores are rather generic and do not impose any usage constraints. This makes them useful for managing exclusive access in obscure situations, such as complicated dances between the kernel and userspace. But it also means that simpler locking is harder to do, and the lack of enforced rules makes any sort of automated debugging or constraint enforcement impossible. Seeking a simpler sleeping lock, the kernel developers introduced the mutex.Yes, as you are now accustomed to, that is a confusing name. Let’s clarify.The term “mutex” is a generic name to refer to any sleeping lock that enforces mutual exclusion, such as a semaphore with a usage count of one. In recent Linux kernels, the proper noun “mutex” is now also a specific type of sleeping lock that implements mutual exclusion.That is, a mutex is a mutex.

The simplicity and efficiency of the mutex come from the additional constraints it imposes on its users over and above what the semaphore requires. Unlike a semaphore, which implements the most basic of behaviour in accordance with Dijkstra’s original design, the mutex has a stricter, narrower use case: n Only one task can hold the mutex at a time. That is, the usage count on a mutex is always one.

  1. Whoever locked a mutex must unlock it. That is, you cannot lock a mutex in one context and then unlock it in another. This means that the mutex isn’t suitable for more complicated synchronizations between kernel and user-space. Most use cases, however, cleanly lock and unlock from the same context.
  2. Recursive locks and unlocks are not allowed. That is, you cannot recursively acquire the same mutex, and you cannot unlock an unlocked mutex.
  3. A process cannot exit while holding a mutex.
  4. A mutex cannot be acquired by an interrupt handler or bottom half, even with mutex_trylock().
  5. A mutex can be managed only via the official API: It must be initialized via the methods described in this section and cannot be copied, hand initialized, or reinitialized.

[1] Linux Kernel Development, Third Edition Robert Love

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Mutex and binary semaphore are both of the same usage, but in reality, they are different.

In case of mutex, only the thread which have locked it can unlock it. If any other thread comes to lock it, it will wait.

In case of semaphone, that's not the case. Semaphore is not tied up with a particular thread ID.

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