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I always wondered what they are: every time I hear about them, images of futuristic flywheel-like devices go dancing (rolling?) through my mind...

What are they?

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9 Answers 9

up vote 32 down vote accepted

When you use regular locks (mutexes, critical sections etc), operating system puts your thread in the WAIT state and preempts it by scheduling other threads on the same core. This has a performance penalty if the wait time is really short, because your thread now has to wait for a preemption to receive CPU time again.

Besides, kernel objects are not available in every state of the kernel, such as in an interrupt handler or when paging is not available etc.

Spinlocks don't cause preemption but wait in a loop ("spin") till the other core releases the lock. This prevents the thread from losing it's quantum and continue as soon as the lock gets released. The simple mechanism of spinlocks allow a kernel to utilize it in almost any state.

That's why on a single core machine a spinlock is simply a "disable interrupts" or "raise IRQL" which prevents thread scheduling completely.

Spinlocks ultimately allow kernels to avoid "Big Kernel Lock"s (a lock acquired when core enters kernel and released at the exit) and have granular locking over kernel primitives, causing better multi-processing on multi-core machines thus better performance.

EDIT: A question came up: "Does that mean I should use spinlocks wherever possible?" and I'll try to answer it:

As I mentioned Spinlocks are only useful in places where anticipated waiting time is shorter than a quantum (read: milliseconds) and preemption doesn't make much sense (e.g. kernel objects aren't available).

If waiting time is unknown, or if you're in user mode Spinlocks aren't efficient. You consume 100% CPU time on the waiting core while checking if a spinlock is available. You prevent other threads from running on that core till your quantum expires. This scenario is only feasible for short bursts at kernel level and unlikely an option for a user-mode application.

Here is a question at SO addressing that: Spinlocks, How Useful Are They?

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does it mean that I should spin-locks (instead of mutex, critical-section etc.) wherever possible? –  anon Dec 24 '09 at 12:21
    
Answered your question too. –  ssg Dec 24 '09 at 13:17
    
somebody please correct me if I am wrong, but a spinlock does not disable preemption (ie. re-scheduling). for the simple reason that, if the spinlock is waiting for a resource locked by another process, then that second process must be given a chance to run and to free the resource. or, running the second process requires preempting the first (spinning) process. –  axeoth Nov 20 '12 at 10:52
    
what spinlock does instead is that it does not change the process state from TASK_RUNNING into TASK_INTERRUPTIBLE (which is a sleeping state) and, thus, it does not save everything about that process (memory, cache and so on). instead, the spinning process is preempted, but it never quits the "immediately schedulable" processes: it is kept in memory and the other processes are regularily run until one of them frees the resource that the spinner is waiting for: at that time, the spinlock simply returns and the spinning process is able to continue. it waits in a always TASK_RUNNING state. –  axeoth Nov 20 '12 at 10:54
    
@axeoth: spinlock disables preemption only on single core machines INSTEAD OF waiting in a loop. disabling preemption guarantees lock acquisition and doesn't waste quanta in context switching or loops. –  ssg Nov 20 '12 at 11:26

It's a type of lock that does busy waiting

It's considered an anti-pattern, except for very low-level driver programming (where it can happen that calling a "proper" waiting function has more overhead than simply busy locking for a few cycles).

See for example Spinlocks in Linux kernel.

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Well, yes - the point of spin locks (vs a traditional critical sections, etc) is that they offer better performance under some circumstances (multicore systems..), because they don't immediately yield the rest of the thread's quantum.

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Good point, but that doesnt provide a general explanation. –  RCIX Dec 24 '09 at 9:44

In nutshell, spinlock employs atomic compare and swap (CAS) or test-and-set like instructions to implement lock free, wait free thread safe idiom. Such structures scale well in multi-core machines.

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SpinLocks are the ones in which thread waits till the lock is available. This will normally be used to avoid overhead of obtaining the kernel objects when there is a scope of acquiring the kernel object within some small time period.

Ex:

While(SpinCount-- && Kernel Object is not free)
{}

try acquiring Kernel object
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Say a resource is protected by a lock ,a thread that wants access to the resource needs to acquire the lock first. If the lock is not available, the thread might repeatedly check if the lock has been freed. During this time the thread busy waits, checking for the lock, using CPU, but not doing any useful work. Such a lock is termed as a spin lock.

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It is pertty much a loop that keeps going till a certain condition is met:

while(cantGoOn) {};
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 while(something != TRUE ){};
 // it happend
 move_on();
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It's a loop that spins around until a condition is met.

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