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I've used mmap() with fopen("/dev/mem") to create a mapping to a block of physical memory shared between two processor cores in an ARM system. When the processor running Linux writes the memory, there can be a lag of over one second before the other non-Linux processor sees the written data. The long delay disappears if the Linux process makes this system call just after writing to memory:

system("sync; echo 3 > /proc/sys/vm/drop_caches" );

I've tried to duplicate that logic directly in code, but the long delay persists:

int fd;
char* data = "3";
sync();
fd = open("/proc/sys/vm/drop_caches", O_WRONLY);
write(fd, data, sizeof(char));
close(fd);

Why does the sync() call differ in behavior from the sync system command? Does the sync command effect virtual memory flushes that the sync() call does not?

I know the manual says that the sync program does nothing but exercise the sync(2) system call, but does the fact that I call sync() from userspace affect its behavior? It acts as though a call to sync from userspace merely schedules the sync rather than blocking until its completion.

  • 1
    This feels like a long shot, but your echo writes 2 bytes (3 and \n) to drop_caches, while your other code only writes the 3. Could that be the difference? – Wumpus Q. Wumbley Dec 26 '13 at 16:35
  • @WumpusQ.Wumbley sizeof(char) == 1 – wildplasser Dec 26 '13 at 17:46
  • I tried both methods, with an without the trailing newline, but there was no difference. The system echo command as coded in my example does output the (implied) newline. – edj Dec 26 '13 at 17:54
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You forgot the newline.

echo 3 outputs "3\n".

Additionally, you are taking an exceptionally circuitous route to implementing shared memory, and imposing massive costs on the rest of the operating system in doing so.

Every time you call sync-the-command or sync-the-system-call, you cause the OS to flush every filesystem on the entire computer; worse, you're telling the OS to forget every filesystem buffer it has, forcing the OS to re-read everything from disk. It's atrocious to performance to the entire operating system in just about every way you can think of.

There is a much, much easier way.

Use shm_open() to create a named shared memory region. Use mmap to access it. Use memory barriers or shared/named mutexes on just that chunk of memory to ensure that you can read and write it consistently and safely.

In terms of complexity, your current approach is probably 1,000,000 times more costly than normal shared memory.

  • I have a separate question pending that addresses specifically how to flush memory mapped with mmap. See this link. The current question is more about trying to understand why two supposedly identical sync approaches behave differently. – edj Dec 26 '13 at 18:16
  • The shm_open suggestion doesn't seem like a solution that would work in this case because second processor isn't running Linux. Am I wrong on that? – edj Dec 26 '13 at 18:20
  • Say what? You have two processors that can access the same memory, but are running two different operating systems? What kind of system architecture do you have? Are you talking about a subprocessor like a DSP or something? – antiduh Dec 26 '13 at 18:22
  • This is an Asymmetric Multiprocessing System (AMP). One processor is running Linux for UI and general application development. The other processor is running real-time algorithms as part of a data acquisition system supporting an FPGA. The entire system (two ARM cores, shared memory controller, and an FPGA) are in a Xilinx Zynq chip. – edj Dec 26 '13 at 18:59
  • Ah. That sort of information would've been very helpful upfront :). All this talk of "shared memory" is barking up the wrong tree. You just want to cause the linux processor to write to some phsyical address and make sure that the processor completes that write. That doesn't need to involve sync or dropping VM buffers etc. – antiduh Dec 26 '13 at 19:14
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Neither drop_caches nor sync are appropriate here, as both of them deal with file system caches - which aren't actually what you are running into here. The fact that sync appears to solve it is probably coincidental. (It is probably incidentally flushing the data cache when the sync tool is launched.)

Your application is most likely running into cache synchronization issues across the two processor cores on your system. Try using the cacheflush() system call to solve this:

#include <unistd.h>
#include <asm/unistd.h>
...
syscall(__ARM_NR_cacheflush, mapping_ptr, mapping_ptr + mapping_length, 0);

Note that you will probably need to flush the cache in both processes to see the correct results.

Flushing changes to mapped memory is often necessary for other mapped devices, but I think it may not be needed in this case. Trying an msync() as well couldn't hurt, though:

msync(mapping_ptr, mapping_length, MS_SYNC); // on process writing to memory
msync(mapping_ptr, mapping_length, MS_INVALIDATE); // on process reading from memory

Finally, make sure you are mapping this memory with the MAP_SHARED flag.

  • According to the manual, the cacheflush system call is available only on MIPS-based systems. I have an ARM system, without asm/cachectl.h source file, so that code snippet doesn't compile. I also tried msync(), fsync(), and fdatasync(), but none of those affected the latency. For the record, I do use MAP_SHARED on the memory mapping. I also tried adding O_DIRECT to the associated open call, but my kernel throws an invalid parameter error on that flag. – edj Dec 26 '13 at 17:50
  • The manual page is a bit misleading - cacheflush() exists on ARM as well, but has a different argument list, and isn't currently wrapped by libc. I've updated the sample code. – duskwuff Dec 26 '13 at 19:42
  • For what it's worth, it may also work to mark that hardware memory range as uncacheable. This will take a lot more magic than I'm familiar with, though. – duskwuff Dec 26 '13 at 19:44

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