Extending on a suggestion I mentioned in your earlier related question, I think the following (Linux-specific, definitely not portable) scheme should work quite reliably:
Set up a datagram socket pair using
socketpair(AF_UNIX, SOCK_DGRAM, 0, &sv),
and signal handler for
SIGSEGV. (You won't need to worry about
SIGBUS, even if other processes might truncate the data file.)
The signal handler uses
write() to write the
size_t addr = siginfo->si_addr; to its end of the socket. The signal handler then
read()s one byte from the socket it wrote into (blocking -- this is basically just a reliable
sleep() -- so remember to handle
EINTR), and returns.
Note that even if there are multiple threads faulting at or near the same time, there is no race condition. The signals just get reraised until the mappings are fixed.
If there is any kind of a problem with the socket communications, you can use
.sa_handler = SIG_DFL to restore the default
SIGSEGV signal handler, so that when the same signal is reraised the entire process dies as normal.
A separate thread reads the other end of the socket pair for addresses faulted with
SIGSEGV, does all the mapping and file I/O necessary, and finally writes a zero byte to the same end of the socket pair to let the real signal handler know the mapping should be fixed now.
This is basically the "real" signal handler, without the drawbacks of an actual signal handler. Remember, the same thread will keep reraising the same signal until the mapping is fixed, so any race conditions between the separate thread and
SIGSEGV signals are irrelevant.
MAP_PRIVATE | MAP_ANONYMOUS | MAP_NORESERVE mapping matching the size of the original data file.
To reduce the cost in actual RAM -- using
MAP_NORESERVE you use neither RAM nor SWAP for the mapping, but for gigabytes of data, the page table entries themselves require considerable RAM --, you could try using
MAP_HUGETLB too. It would use huge pages, and therefore significantly less entries, but I am unsure whether there are issues when normal page sized holes are eventually punched into the mappings; you'd probably have to use huge pages all the way.
This is the "full" mapping that your "userspace" will use to access the data.
PROT_READ | PROT_WRITE,
MAP_PRIVATE | MAP_ANONYMOUS mapping for pristine or dirty (respectively), converted data. If your "userspace" almost always modifies the data, you can always treat the converted data as "dirty", but otherwise you can avoid unnecessary writes of unmodified data by first mapping the converted data
PROT_READ only; if it faults,
PROT_READ | PROT_WRITE and mark it dirty (so needs to be converted and saved back to the file). I'll call these two stages "clean" and "dirty" mappings respectively.
When the dedicated thread punches a hole into a "full" mapping for a "clean" page(s), you first
mmap(NULL, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANONYMOUS, ...) a new memory area of suitable size,
read() the data from the desired data file into it, convert the data,
mprotect(..., PROT_READ) if you separate "clean" and "dirty" mappings, and finally
mremap(newly_mapped, size, size, MREMAP_MAYMOVE | MREMAP_FIXED, new_ptr) it over the section of the "full" mapping.
Note that to avoid any accidents, you should use a global
pthread_mutex_t, which is grabbed for the duration of these
mremap()s and any
mmap() calls elsewhere, to avoid having the kernel give the punched hole to the wrong thread by accident. The mutex will guard against any other thread getting in between. (Otherwise, the kernel might place a small map requested by another thread into the temporary hole.)
When discarding "clean" page(s), you call
mmap(NULL, length, PROT_NONE, MAP_PRIVATE | MAP_ANONYMOUS | MAP_NORESERVE, -1, 0) to get a new map of suitable length, then grab the global mutex mentioned above, and
mremap() that new map over the "clean" page(s); the kernel does an implicit
munmap(). Unlock the mutex.
When discarding "dirty" page(s), you call
mmap(NULL, length, PROT_NONE, MAP_PRIVATE | MAP_ANONYMOUS | MAP_NORESERVE, -1, 0) *twice to get two new maps of suitable length*. You then grab the global mutex mentioned above, and
mremap() the dirty data over the first of the new mappings. (Basically it was only used to find out a suitable address to move the dirty data into.) Then,
mremap() the second of the new mappings to where the dirty data used to reside in. Unlock the mutex.
Using a separate thread to handle the fault conditions avoids all async-signal-safe function problems.
sigaction() are all async-signal safe.
You only need one global
pthread_mutex_t to avoid the case where the kernel hands the recently-moved hole (
mremap()ped from memory area) to another thread; you can also use it to protect your internal data structure (pointer chain, if you support multiple concurrent file mappings).
There should be no race conditions (other than when other threads use
mremap(), which is handled by the mutex mentioned above). When a "dirty" page or page group is moved away, it becomes inaccessible to other threads, before it is converted and saved; even perfectly concurrent access by another thread should be handled perfectly: the page will simply be re-read from the file, and re-converted. (If that occurs often, you might wish to cache recently saved page groups.)
I do recommend using large page groups, say 2M or more, instead of single pages, to reduce the overhead. The optimal size depends on your applications access patterns, but the huge page size (if supported by your architecture) is a very good starting point.
If your data structures do not align to pages or page groups, you should cache the full converted first and last records (which are only partially within the page or page group). It usually makes the conversion back to storage format much easier.
If you know or can detect typical access patterns within the file, you probably should use
posix_fadvise() to tell the kernel;
POSIX_FADV_DONTNEED are most useful. It helps the kernel avoid keeping unnecessary pages of the actual data file in page cache.
Finally, you might consider adding a second special thread for converting and writing dirty records back to disk asynchronously. If you take care to make sure the two threads don't get confused when the first thread wants to re-read back a record still being written to disk by the second thread, there should be no other issues there either -- but asynchronous writing is likely to increase your throughput with most access patterns, unless you are I/O bound anyway, or really short on RAM (relatively speaking).
write() instead of another memory map? Because of the overhead in-kernel for the virtual memory structures needed.