Can someone help me out with example of a situation in which absence of mutexes "definetely" leads to incorrect result.

I need this so that I could test my mutex implementation.

-- Neeraj

  • Now that's a really well stated question. – sharptooth Jun 28 '10 at 9:35

Consider any correct code that uses mutexes for synchronization. By removing the locking, you will introduce new (possibly incorrect) behaviors (executions) to the program. However, the new code will still contain all of the old behaviors, therefore there will always be at least one execution that will yield a correct result. Hence, what you're asking for is impossible.

  • i think that only holds, if you don't stop a particular process to affect the order in which instruction are executed. – sud03r Jun 28 '10 at 10:20
  • wouldn't it be nice if such a test existed, which was guaranteed to uncover synchronization bugs. Unfortunately, as @avakar says, it's impossible. Removing synchronization only expands the range of possible behaviors. It doesn't prevent the correct behavior from occuring. – jalf Jun 28 '10 at 10:28
  • i agree to your views – sud03r Jun 28 '10 at 17:17

Make a program that has a fork() in it. Then, make both the child process and the parent process read a number from the same file, increment it and then write it back to the file. Do this 100 times in each process.

  • 2
    This will probably, but not definitely cause synchronization problems. – daramarak Jun 28 '10 at 9:54

You definitely need a mutex (or similar mechanism) when there is a need from mutual exclusion.


Are you just testing that it locks correctly? If so maybe something like this? Two threads

#Global Variables
int counter = 1
int factorial = 1

#Critical Section
Delay for some amount of time
factorial *= counter
#End Critical Section

If your Mutex works then the end result should be 6. Otherwise it will be 9. Edit or 3 I suppose as the *= is not atomic but not 6 anyway.

  • sounds correct to me, thanks! – sud03r Jun 28 '10 at 10:03

I think not, because the scheduler as implemented in current OSes is not deterministic from an application's point of view. However, if you start a lot of threads and test the code several times, the probability of a clash should be high enough.


The classic case is the ATM shared by husband and wife. One makes a deposit, the other a withdrawal in different threads. If the critical section isn't guarded appropriately by a mutex it's possible for each of them to see inconsistent results.

If a "definite situation" is required, have the husband make a deposit and then sleep for sufficient time so the wife can make a withdrawal. The husband's result will overwrite the wife's, and the the account balance isn't ACID anymore.

  • 1
    If you understand my question correctly, i dont need a "possiblity", i need a "definite situation" which is guarranted to produce wrong results. – sud03r Jun 28 '10 at 9:41

Here is the kind of test I used in my mutex implementation test suite:

// global:
enum { HUGE_VAL = 50000 }
Mutex mutex;
int variable;

// main thread
for(int i = 0; i < HUGE_VAL; ++i)
assert(variable == HUGE_VAL);
assert(variable == -HUGE_VAL);

// parallel thread
variable = -HUGE_VAL;

Of course, adapt HUGE_VAL as you feel it, because a mutex is used to protect from concurrent acces. Therefore, to test it, you need to create concurrency, and the faster the machine, the huger HUGE_VAL should be...


You can simulate the famous "bank transfer" scenario used to illustrate database transactions. We have accounts A and B and need to transfer 200 bucks from A to B.

C++ - like pseudocode (not tested)

 int accountA = 200;
 int accountB = 0;

 void transfer( int& from, int& to, int amount )
     //mutex acquisition should be here
     if( from < amount ) {
         printf( "error" );
         // mutex release should be here
     from -= amount;
     Sleep( 5000 ); //wait idle for 5 seconds
     to += amount;
     // mutex release should be here

 void display( const int& account1, const int& account2 )
     //mutex acquisition should be here
     Sleep( 3000 ); //wait 3 seconds
     printf( "%d", account1 );
     printf( %d", account2 );
     // mutex release should be here

now spawn two threads and execute transfer( accountA, accountB, 200 ); on one and display( accountA, accountB ); on another starting at the same moment of time.

On a system without load the program will show that money have disappeared "in the middle of transfer" - the accounts are read in the middle of "transaction" (the problem there's no transaction here), so there's no isolation. With mutexes you would see the final state - "after the transfer".

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