Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have a very latency sensitive routine that generates integers sequentially, but needs to store the last generated one to disk in case of a crash or re-start.

Currently I'm doing a seek to beginning of file then writing out the integer then flush each time a new int is generated. The flush is required so the write at least hits the battery-backed controller cache.

The seek is quite costly so I was thinking about just appending 4 bytes and if recovery is needed then to seek to the end and read the last 4 bytes. This previous statement obviously assumes that there isn't too much other disk activity happening, so the write head should ideally stay at end of the file.

The number won't typically go higher than 10,000,000 so 40MB isn't so bad.

Any advice as to how to achieve minimum latency without sacrificing integrity?

C or C++ on Linux 2.6+

share|improve this question
    
sounds like exactly what a database's transaction log does; you sure you are not trying to re-invent the wheel? –  Mitch Wheat Jan 26 '11 at 23:38
    
Unless you're running in an embedded system where you are very "close" to the disk hardware, you have no guarantees that the head will stay at any particular place on the disk. On linux you might achieve this by allocating an entire disk and writing to the raw device file. However, as @Mitch pointed out it sure sounds like you're reinventing an old wheel. –  Jim Garrison Jan 26 '11 at 23:43
2  
Note, a seek of 4 bytes will not hit the drive. It's more or less just a subtraction in the kernel. –  nos Jan 26 '11 at 23:43
    
@not But seek is a syscall and every syscall is quite expensive. –  Elalfer Jan 26 '11 at 23:47
2  
if you want to save a seek call, use pwrite –  nos Jan 26 '11 at 23:53

8 Answers 8

up vote 8 down vote accepted

I would think the fastest/easiest way to do this would be with mmap/msync -- mmap 1 page of the file into memory and store the value on that page. Any time the value changes, call msync(2) to force the page back to disk. This way you need only one system call per store

share|improve this answer
    
I like this idea a lot, I am pulling out my Richard Stevens book to learn more about the mmap facility. –  chriskirk Jan 27 '11 at 14:34

If I read correctly, how about using a memory mapped file? Just write your number to the assigned address and it appears in the file. This makes assumptions that the OS writing the cache to disk robustly when needed, but you might find it worth a try.

int len = sizeof(unsigned);
int fildes = open(...)
void* address = mmap(0, len, PROT_READ, MAP_PRIVATE, fildes, 0)
unsigned* mappedNumber = (unsigned*)(address);

*mappedNumber can now contain your integer.

share|improve this answer
1  
still need to call msync on the address each time the value changes, or it will only be changed in ram and if the power is cut the new value will be lost. –  Chris Dodd Jan 26 '11 at 23:53
    
No need to cast address in line 4. –  user562374 Jan 27 '11 at 0:20

Measure.

How much control do you have over the hardware? If anything less than full, you'll get no guarantees.

On Linux I'd probably try making a kernel driver that would do its writes with the highest priority, possibly even without using a file system.

But, theoretically... If it is enough for you to hit the controller cache, data will hit it every time you flush anything to disk. This means regardless of whether there will be physical seek inside the drive or not, the data will already be there. And because you'll never know what will other applications do, or how fast does the disk rotate, your seeks will be random even if you keep the logical file handle at the beginning or end of file.

And you can always ask your user to use a flash drive.

share|improve this answer
    
Even with flash drive, data will still be cached in ram for awhile. You need fsync/msync to flush it to the disk –  Chris Dodd Jan 26 '11 at 23:54
    
@Chris Dodd, sure, but fsync will force it to the drive, and flash drives have much much better seek time. –  liori Jan 26 '11 at 23:55
    
I can get pretty close to the hardware, however the machine(s) this particular app will run on aren't necessarily homogeneous. Some will have RAID controllers with tons of cache; some won't; some may someday have flash drives... –  chriskirk Jan 27 '11 at 14:37
    
@chriskirk: basically, if you have at least one IO operation, it stops to matter how many syscalls you'll have--IOs are almost always more expensive. A syscall can often not even leave processor cache, an IO operation has to leave it. And whether it is an mmap() or write(), both will be translated to seek+write in the hardware layer. But... you know your environment better, so measure it. –  liori Jan 27 '11 at 19:47
    
@chriskirk: Also note that even a USB pendrive will have quite good seek times. It doesn't have to be a SSD drive. –  liori Jan 27 '11 at 19:49

The fastest way to write a file is to map that file into memory and treat it as a char array.

You don't need to sync the file if you don't care about OS crashes (Linux never crashed on me in production). All your writes go to that file mapping bypassing the kernel, in other words, real zero-copy (you can't do that with sockets on the standard hardware yet). You may need to keep a header in that file that contains a number of records written in case your application crash during writing a record into the memory. I.e. write a record and only after that increment the record counter.

Resizing this file requires ftruncate()/remap() sequence which may take a bit too long, so you may want to minimize resizing by growing the file by a factor, like std::vector<> grows by 1.5 its size on push_back() when it overflows. Depending on your throughput and latency requirements certain optimization can be applied.

The kernel is going to write the file mapping to disk asynchronously (as if there were another thread in your application dedicated to writing to disk). There is a way to force the writes to disk if necessary by using msync(). This is only necessary, however, if you'd like to survive an OS crash. But surviving an OS crash requires sophisticated application design anyway, so in practice surviving the application crash is good enough.

share|improve this answer
    
Good general advice, but re "surviving the application crash is good enough" - that depends very much on the industry, system etc.. The question explicitly asks for more - not good to second guess that without asking related questions. And it's not just "OS versus app", there's hardware, environmental things (power supply, aircon, flooding, fire), and human error (unplugging the wrong cables, flicking the wrong switches). –  Tony D Jan 27 '11 at 3:10
    
Very good advice. The application in question needs to keep track of 2 sequence numbers - one can be approximate (can lose the last few updates) but the other one needs to be guaranteed except under kernel failure. I think you accommodated both contexts quite well. Thank you. –  chriskirk Jan 27 '11 at 14:48

Why does your application have to wait for the write complete at all?

Write your data asynchronously, or perhaps from another thread.

You don't really have much low-level control over the harddrive. As long as you write so little data at a time, you're going to incur a lot of expensive seeks. But since you're only using it as "checkpoints" to recover from in case of a crash, there seems to be no reason why the write couldn't occur asynchronously.

share|improve this answer
    
"another thread" falls apart as soon as the program crashes. "Another process" might work, but at that point you may well rely on the kernel to be that other process, since either mechanism involves a syscall. –  Tom Jan 27 '11 at 6:39
    
Why exactly? The absolutely worst that can happen is that you lose the latest checkpoint, and have to do a bit more work when the process restarts. So what? Write those checkpoints to disk more often then. In fact, if it's running in a separate thread, you could write them constantly, so it just doesn't matter if you lose the very last one because of a crash. –  jalf Jan 27 '11 at 10:50
    
My point is that you risk losing the latest checkpoint. The question specifies minimizing latency without sacrificing integrity. Deferring the I/O to another thread in the same process sacrifices integrity, because the process may die before the data has been handed off to the OS. The mmap approach allows the "other thread" to be the kernel (pdflush I think, but I could be wrong), which will not die when the process dies. –  Tom Jan 28 '11 at 3:18
    
@Tom: integrity is only sacrificed if we risk writing bad data. The exact age of the last checkpoint has nothing to do with integrity. And like I said, if you avoid blocking the main thread, then you can get away with storing these checkpoints that much more often, so the net result is going to be that regardless of when your process crashes, you have a newer checkpoint than you would if you'd written it from the main thread. Note that I'm not arguing against the memory mapping approach, just that given these requirements, I see no reason why this wouldn't also work. –  jalf Jan 28 '11 at 3:25

Storing an int only takes one block on disc, regardless of block size. So you have to sync one block to disc, and it takes as long as it takes, and there is nothing you can do to make it faster.

Whatever else you do, fdatasync() will be the killer, time-wise. It will sync one block into your (battery-backed RAID) controller.

Unless you have some kind of non-volatile ram, all (sensible) methods are going to be exactly equivalent because they all require one block to be sync'd.

Doing a seek system call is not going to make any difference, as that has no effect on hardware. In any case, you can avoid it by using pwrite().

share|improve this answer

Consider what "appending 4 bytes" means. Disks don't store files, or even bytes. They store clusters, and a fixed number of them. The notion of a file is created by the OS. It allocates some clusters to file system tables, to keep track of where a file is precisely located. Now, appending 4 bytes means at least writing the 4 bytes to a cluster. But that also means determining which cluster. What's the existing file size? Do we need a new cluster? If not, we need to read the last cluster, patch the 4 bytes in the correct position, and write back the cluster, then update the file size in the file system. If we do append a new cluster, we can write the 4 bytes followed by zeroes (don't need old value) but we need to do a whole lot of bookkeeping to add a cluster to a file.

So, the absolute fastest way cannot ever be to append 4 bytes. You must overwrite 4 existing bytes. Preferably in a sector that you already have in memory. Others have already pointed out that you can achieve this with mmap/msync.

Obviously, given current SSD and developer prices, and your 40 MB limit, you'll be using an SSD. It pays for itself if you save an hour. Therefore seek times are irrelevant; SSDs don't have physical heads.

share|improve this answer
    
With mmap/msync, if there is battery-backed cache on the controller card, isn't the physical medium more or less irrelevant? From my understanding, calling msync will hit the controller card which will basically return once committed to memory. As long as the memory stays non-volatile, the medium could even be a tape for all it cares. Thoughts? –  chriskirk Jan 27 '11 at 14:51
1  
@chriskirk: if the battery is big enough, a second level of stone tablets would be OK. Essentially you want one level of non-volatile solid-state storage. –  MSalters Jan 28 '11 at 10:54

There are a lot of people here talking about mmap() as if that will fix something, but your syscall overhead is basically zero compared to the disk write overhead. Remember that appending or writing to a file requires you to update the inode (mtime, filesize) anyway, so that means a disk seek.

I suggest you consider storing the integer somewhere other than a disk. For example:

  • write it to some nvram that you control (eg. on an embedded system). (If your RAID controller has nvram for writing, it might do this for you. But if you're asking this question, it probably doesn't.)

  • write it to free bytes in the system CMOS memory (eg. on PC hardware).

  • write it to another machine on the network (if it's a fast network) and get them to acknowledge.

  • redesign your application so you can get away with syncing after every n transactions, instead of after every transaction. That will be about n times faster than doing it every time.

  • redesign your application so that if the integer is lost, the changes from your most recent transaction are also lost. Then the fact that you've technically lost an integer update doesn't matter; when you reboot, it'll be as if you never incremented it, so you can just resume from there.

You didn't explain why you need this behaviour; to be honest, if your app needs this, it sounds like your application is probably not designed very well. For example, some people suggested using a database because they do this sort of thing all the time; true, but databases do it by being slow (ie. syncing the disk every time), unless you create a transaction first, in which case the disk only needs to get synced when you do 'commit transaction'. But if you absolutely must have a sync after every integer, you'd be constantly committing transactions, and a database couldn't save you from that; there's no magical way a database could guarantee not to lose data unless it does at least fdatasync().

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.