I was under the impression that flock(2) is thread safe, I recently, ran across the case in the code, where multiple threads are able to get a lock on the same file which are all synchronized with the use of obtaining exclusive lock using the c api flock. The process 25554 is multi-threaded app which has 20 threads, the number of threads having lock to the same file varies when the deadlock happens. The multi threaded app testEvent is writer to the file, where was the push is the reader from the file. Unfortunately the lsof
does not print the LWP value so I cannot find which are the threads that are holding the lock. When the below mentioned condition happens both the process and threads are stuck on the flock call as displayed by the pstack
or strace
call on the pid 25569 and 25554. Any suggestions on how to overcome this in RHEL 4.x.
One thing I wanted to update is flock does not misbehave all the time, when the tx rate of the messages is more than 2 mbps only then I get into this deadlock issue with flock, below that tx rate everything is file. I have kept the num_threads
= 20, size_of_msg
= 1000bytes constant and just varied the number of messages tx per second start from 10 messages to 100 messages which is 20*1000*100 = 2 mbps, when I increase the number of messages to 150 then flock issue happens.
I just wanted to ask what is your opinion about flockfile c api.
sudo lsof filename.txt
COMMAND PID USER FD TYPE DEVICE SIZE NODE NAME
push 25569 root 11u REG 253.4 1079 49266853 filename.txt
testEvent 25554 root 27uW REG 253.4 1079 49266853 filename.txt
testEvent 25554 root 28uW REG 253.4 1079 49266853 filename.txt
testEvent 25554 root 29uW REG 253.4 1079 49266853 filename.txt
testEvent 25554 root 30uW REG 253.4 1079 49266853 filename.txt
The multithreaded test program that will call the write_data_lib_func
lib function.
void* sendMessage(void *arg) {
int* numOfMessagesPerSecond = (int*) arg;
std::cout <<" Executing p thread id " << pthread_self() << std::endl;
while(!terminateTest) {
Record *er1 = Record::create();
er1.setDate("some data");
for(int i = 0 ; i <=*numOfMessagesPerSecond ; i++){
ec = _write_data_lib_func(*er1);
if( ec != SUCCESS) {
std::cout << "write was not successful" << std::endl;
}
}
delete er1;
sleep(1);
}
return NULL;
The above method will be called in the pthreads in the main function of the test.
for (i=0; i<_numThreads ; ++i) {
rc = pthread_create(&threads[i], NULL, sendMessage, (void *)&_num_msgs);
assert(0 == rc);
}
Here is the writer/reader source, due to proprietary reasons I did not want to just cut and paste, the writer source will accessed multiple threads in a process
int write_data_lib_func(Record * rec) {
if(fd == -1 ) {
fd = open(fn,O_RDWR| O_CREAT | O_APPEND, 0666);
}
if ( fd >= 0 ) {
/* some code */
if( flock(fd, LOCK_EX) < 0 ) {
print "some error message";
}
else {
if( maxfilesize) {
off_t len = lseek ( fd,0,SEEK_END);
...
...
ftruncate( fd,0);
...
lseek(fd,0,SEEK_SET);
} /* end of max spool size */
if( writev(fd,rec) < 0 ) {
print "some error message" ;
}
if(flock(fd,LOCK_UN) < 0 ) {
print some error message;
}
In the reader side of things is a daemon process with no threads.
int readData() {
while(true) {
if( fd == -1 ) {
fd= open (filename,O_RDWR);
}
if( flock (fd, LOCK_EX) < 0 ) {
print "some error message";
break;
}
if( n = read(fd,readBuf,readBufSize)) < 0 ) {
print "some error message" ;
break;
}
if( off < n ) {
if ( off <= 0 && n > 0 ) {
corrupt_file = true;
}
if ( lseek(fd, off-n, SEEK_CUR) < 0 ) {
print "some error message";
}
if( corrupt_spool ) {
if (ftruncate(fd,0) < 0 ) {
print "some error message";
break;
}
}
}
if( flock(fd, LOCK_UN) < 0 )
print some error message ;
}
}
}
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