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106 lines
5.8 KiB
Plaintext
106 lines
5.8 KiB
Plaintext
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# @(#)README 10.1 (Sleepycat) 4/12/97
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Resource locking routines: lock based on a db_mutex_t. All this gunk
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(including trying to make assembly code portable), is necessary because
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System V semaphores require system calls for uncontested locks and we
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don't want to make two system calls per resource lock.
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First, this is how it works. The db_mutex_t structure contains a resource
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test-and-set lock (tsl), a file offset, a pid for debugging and statistics
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information.
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If HAVE_SPINLOCKS is defined (i.e. we know how to do test-and-sets for
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this compiler/architecture combination), we try and lock the resource tsl
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TSL_DEFAULT_SPINS times. If we can't acquire the lock that way, we use
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a system call to sleep for 10ms, 20ms, 40ms, etc. (The time is bounded
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at 1 second, just in case.) Using the timer backoff means that there are
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two assumptions: that locks are held for brief periods (never over system
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calls or I/O) and that locks are not hotly contested.
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If HAVE_SPINLOCKS is not defined, i.e. we can't do test-and-sets, we use
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a file descriptor to do byte locking on a file at a specified offset. In
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this case, ALL of the locking is done in the kernel. Because file
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descriptors are allocated per process, we have to provide the file
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descriptor as part of the lock/unlock call. We still have to do timer
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backoff because we need to be able to block ourselves, i.e. the lock
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manager causes processes to wait by having the process acquire a mutex
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and then attempting to re-acquire the mutex. There's no way to use kernel
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locking to block yourself, i.e. if you hold a lock and attempt to
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re-acquire it, the attempt will succeed.
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Next, let's talk about why it doesn't work the way a reasonable person
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would think it should work.
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Ideally, we'd have the ability to try to lock the resource tsl, and if
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that fails, increment a counter of waiting processes, then block in the
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kernel until the tsl is released. The process holding the resource tsl
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would see the wait counter when it went to release the resource tsl, and
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would wake any waiting processes up after releasing the lock. This would
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actually require both another tsl (call it the mutex tsl) and
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synchronization between the call that blocks in the kernel and the actual
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resource tsl. The mutex tsl would be used to protect accesses to the
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db_mutex_t itself. Locking the mutex tsl would be done by a busy loop,
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which is safe because processes would never block holding that tsl (all
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they would do is try to obtain the resource tsl and set/check the wait
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count). The problem in this model is that the blocking call into the
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kernel requires a blocking semaphore, i.e. one whose normal state is
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locked.
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The only portable forms of locking under UNIX are fcntl(2) on a file
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descriptor/offset, and System V semaphores. Neither of these locking
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methods are sufficient to solve the problem.
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The problem with fcntl locking is that only the process that obtained the
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lock can release it. Remember, we want the normal state of the kernel
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semaphore to be locked. So, if the creator of the db_mutex_t were to
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initialize the lock to "locked", then a second process locks the resource
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tsl, and then a third process needs to block, waiting for the resource
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tsl, when the second process wants to wake up the third process, it can't
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because it's not the holder of the lock! For the second process to be
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the holder of the lock, we would have to make a system call per
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uncontested lock, which is what we were trying to get away from in the
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first place.
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There are some hybrid schemes, such as signaling the holder of the lock,
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or using a different blocking offset depending on which process is
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holding the lock, but it gets complicated fairly quickly. I'm open to
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suggestions, but I'm not holding my breath.
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Regardless, we use this form of locking when HAVE_SPINLOCKS is not
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defined, (i.e. we're locking in the kernel) because it doesn't have the
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limitations found in System V semaphores, and because the normal state of
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the kernel object in that case is unlocked, so the process releasing the
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lock is also the holder of the lock.
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The System V semaphore design has a number of other limitations that make
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it inappropriate for this task. Namely:
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First, the semaphore key name space is separate from the file system name
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space (although there exist methods for using file names to create
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semaphore keys). If we use a well-known key, there's no reason to believe
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that any particular key will not already be in use, either by another
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instance of the DB application or some other application, in which case
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the DB application will fail. If we create a key, then we have to use a
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file system name to rendezvous and pass around the key.
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Second, System V semaphores traditionally have compile-time, system-wide
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limits on the number of semaphore keys that you can have. Typically, that
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number is far too low for any practical purpose. Since the semaphores
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permit more than a single slot per semaphore key, we could try and get
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around that limit by using multiple slots, but that means that the file
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that we're using for rendezvous is going to have to contain slot
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information as well as semaphore key information, and we're going to be
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reading/writing it on every db_mutex_t init or destroy operation. Anyhow,
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similar compile-time, system-wide limits on the numbers of slots per
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semaphore key kick in, and you're right back where you started.
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My fantasy is that once POSIX.1 standard mutexes are in wide-spread use,
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we can switch to them. My guess is that it won't happen, because the
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POSIX semaphores are only required to work for threads within a process,
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and not independent processes.
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Note: there are races in the statistics code, but since it's just that,
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I didn't bother fixing them. (The fix requires a mutex tsl, so, when/if
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this code is fixed to do rational locking (see above), then change the
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statistics update code to acquire/release the mutex tsl.
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