Threaded RT-application with memory locking and stack handling example

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How to deal with threads

While creating a new thread new memory will be allocated for a new stack and for the thread administration. These allocations will result in new page faults. Therefore all threads need to be created at startup time, before RT show time.
After a thread is created, all stack pages of that thread need to be forced to RAM to prevent page faults when it is accessed for the first time. The entire stack of every thread inside the application is forced to RAM when mlockall(MCL_CURRENT) is called. Threads started after a call to mlockall(MCL_CURRENT | MCL_FUTURE) will generate page faults immediately since the new stack is immediately forced to RAM (due to the MCL_FUTURE flag).
Threads are created with a default stack size of 8MB. Forcing 8MB to RAM per thread is overkill for most applications. If we leave the stack size default to 8MB, then we are probably out-of-memory in no-time. So, we need to figure out the maximum size of stack space used by a certain thread, and then create that thread with the amount of stack space it requires. You may add a little bit more, but surely nothing less.

Here is an example that shows how this can be done:

   // Compile with 'gcc thisfile.c -lpthread -lrt -Wall'
   #include <stdlib.h>
   #include <stdio.h>
   #include <sys/mman.h>	// Needed for mlockall()
   #include <unistd.h>		// needed for sysconf(int name);
   #include <malloc.h>
   #include <sys/time.h>	// needed for getrusage
   #include <sys/resource.h>	// needed for getrusage
   #include <pthread.h>
   #include <limits.h>
   
   #define PRE_ALLOCATION_SIZE (100*1024*1024) /* 100MB pagefault free buffer */
   #define MY_STACK_SIZE       (100*1024)      /* 100 kB is enough for now. */
   
   static void setprio(int prio, int sched)
   {
   	struct sched_param param;
   	// Set realtime priority for this thread
   	param.sched_priority = prio;
   	if (sched_setscheduler(0, sched, &param) < 0)
   		perror("sched_setscheduler");
   }
   
   void show_new_pagefault_count(const char* logtext, 
   			      const char* allowed_maj,
   			      const char* allowed_min)
   {
   	static int last_majflt = 0, last_minflt = 0;
   	struct rusage usage;
   
   	getrusage(RUSAGE_SELF, &usage);
   
   	printf("%-30.30s: Pagefaults, Major:%ld (Allowed %s), " \
   	       "Minor:%ld (Allowed %s)\n", logtext,
   	       usage.ru_majflt - last_majflt, allowed_maj,
   	       usage.ru_minflt - last_minflt, allowed_min);
   	
   	last_majflt = usage.ru_majflt; 
   	last_minflt = usage.ru_minflt;
   }
   
   static void prove_thread_stack_use_is_safe(int stacksize)
   {
   	volatile char buffer[stacksize];
   	int i;
   
   	/* Prove that this thread is behaving well */
   	for (i = 0; i < stacksize; i += sysconf(_SC_PAGESIZE)) {
   		/* Each write to this buffer shall NOT generate a 
   			pagefault. */
   		buffer[i] = i;
   	}
   
   	show_new_pagefault_count("Caused by using thread stack", "0", "0");
   }
   
   /*************************************************************/
   /* The thread to start */
   static void *my_rt_thread(void *args)
   {
   	struct timespec ts;
   	ts.tv_sec = 30;
   	ts.tv_nsec = 0;
   
   	setprio(sched_get_priority_max(SCHED_RR), SCHED_RR);
   
   	printf("I am an RT-thread with a stack that does not generate " \
   	       "page-faults during use, stacksize=%i\n", MY_STACK_SIZE);
   
   //<do your RT-thing here>
   
   	show_new_pagefault_count("Caused by creating thread", ">=0", ">=0");
   
   	prove_thread_stack_use_is_safe(MY_STACK_SIZE);
   
   	/* wait 30 seconds before thread terminates */
   	clock_nanosleep(CLOCK_REALTIME, 0, &ts, NULL);
   
   	return NULL;
   }
   
   /*************************************************************/
   
   static void error(int at)
   {
   	/* Just exit on error */
   	fprintf(stderr, "Some error occured at %d", at);
   	exit(1);
   }
   
   static void start_rt_thread(void)
   {
   	pthread_t thread;
   	pthread_attr_t attr;
   
   	/* init to default values */
   	if (pthread_attr_init(&attr))
   		error(1);
   	/* Set the requested stacksize for this thread */
   	if (pthread_attr_setstacksize(&attr, PTHREAD_STACK_MIN + MY_STACK_SIZE))
   		error(2);
   	/* And finally start the actual thread */
   	pthread_create(&thread, &attr, my_rt_thread, NULL);
   }
   
   static void configure_malloc_behavior(void)
   {
   	/* Now lock all current and future pages 
   	   from preventing of being paged */
   	if (mlockall(MCL_CURRENT | MCL_FUTURE))
   		perror("mlockall failed:");
   
   	/* Turn off malloc trimming.*/
   	mallopt(M_TRIM_THRESHOLD, -1);
   
   	/* Turn off mmap usage. */
   	mallopt(M_MMAP_MAX, 0);
   }
   
   static void reserve_process_memory(int size)
   {
   	int i;
   	char *buffer;
   
   	buffer = malloc(size);
   
   	/* Touch each page in this piece of memory to get it mapped into RAM */
   	for (i = 0; i < size; i += sysconf(_SC_PAGESIZE)) {
   		/* Each write to this buffer will generate a pagefault.
   		   Once the pagefault is handled a page will be locked in
   		   memory and never given back to the system. */
   		buffer[i] = 0;
   	}
   
   	/* buffer will now be released. As Glibc is configured such that it 
   	   never gives back memory to the kernel, the memory allocated above is
   	   locked for this process. All malloc() and new() calls come from
   	   the memory pool reserved and locked above. Issuing free() and
   	   delete() does NOT make this locking undone. So, with this locking
   	   mechanism we can build C++ applications that will never run into
   	   a major/minor pagefault, even with swapping enabled. */
   	free(buffer);
   }
   
   int main(int argc, char *argv[])
   {
   	show_new_pagefault_count("Initial count", ">=0", ">=0");
   
   	configure_malloc_behavior();
   
   	show_new_pagefault_count("mlockall() generated", ">=0", ">=0");
   
   	reserve_process_memory(PRE_ALLOCATION_SIZE);
   
   	show_new_pagefault_count("malloc() and touch generated", 
   				 ">=0", ">=0");
   
   	/* Now allocate the memory for the 2nd time and prove the number of
   	   pagefaults are zero */
   	reserve_process_memory(PRE_ALLOCATION_SIZE);
   	show_new_pagefault_count("2nd malloc() and use generated", 
   				 "0", "0");
   
   	printf("\n\nLook at the output of ps -leyf, and see that the " \
   	       "RSS is now about %d [MB]\n",
   	       PRE_ALLOCATION_SIZE / (1024 * 1024));
   
   	start_rt_thread();
   
   //<do your RT-thing>
   
   	printf("Press <ENTER> to exit\n");
   	getchar();
   
   	return 0;
   }
   


Author/Maintainer

Remy Bohmer

Revision

Revision History
Revision 2 2008-01-15
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