Sign up ×
Stack Overflow is a community of 4.7 million programmers, just like you, helping each other. Join them; it only takes a minute:

On a SMP machine we must use spin_lock_irqsave and not spin_lock_irq from interrupt context.

Why would we want to save the flags (which contains the IF)?

Is there another interrupt routine that could interrupt us?

share|improve this question

4 Answers 4

up vote 12 down vote accepted

I am new in the kernel but from what I gather from Robert Love book "Linux Kernel Development", it says that if the interrupts are already disabled on the processor before your code starts locking, when you call spin_unlock_irq you will release the lock in an erroneous manner. If you save the flags and release it with the flags, the function spin_lock_irqsave will just return the interrupt to its previous state.

Example with spin_lock_irqsave

spinlock_t mLock = SPIN_LOCK_UNLOCK;
unsigned long flags;

spin_lock_irqsave(&mLock, flags); // save the state, if locked already it is saved in flags
// Critical section
spin_unlock_irqrestore(&mLock, flags); // return to the formally state specified in flags

Example with spin_lock_irq( without irqsave ):

spinlock_t mLock = SPIN_LOCK_UNLOCK;
unsigned long flags;

spin_lock_irq(&mLock); // Does not know if already locked
// Critical section
spin_unlock_irq(&mLock); // Could result in an error unlock...
share|improve this answer
I don't believe spin_unlock_irqsave exists, probably should be spin_unlock_irqrestore: Linux Device Drivers – mikhail Feb 9 '13 at 0:12
This answer is incorrect. spin_lock_irq will uncondtinoally disable interrupts, while the irqsave variants will save the interrupt state in cases that you cannot know what state you are currently in. – Noah Watkins May 10 '13 at 21:18
@NoahWatkins That is the point of the last portion. It say Could result in an error unlock in a comment. The spin_lock_irq is to show that the IRQ is enabled when it should not be. The answer is not incorrect; just not very clear. – artless noise Apr 25 '14 at 20:16

spin_lock_irqsave is basically used to save the interrupt state before taking the spin lock, this is because spin lock disables the interrupt, when the lock is taken in interrupt context, and re-enables it when while unlocking. The interrupt state is saved so that it should reinstate the interrupts again.


  1. Lets say interrupt x was disabled before spin lock was acquired
  2. spin_lock_irq will disable the interrupt x and take the the lock
  3. spin_unlock_irq will enable the interrupt x.

So in the 3rd step above after releasing the lock we will have interrupt x enabled which was earlier disabled before the lock was acquired.

So only when you are sure that interrupts are not disabled only then you should spin_lock_irq otherwise you should always use spin_lock_irqsave.

share|improve this answer

Reading Why kernel code/thread executing in interrupt context cannot sleep? which links to Robert Loves article, I read this :

some interrupt handlers (known in Linux as fast interrupt handlers) run with all interrupts on the local processor disabled. This is done to ensure that the interrupt handler runs without interruption, as quickly as possible. More so, all interrupt handlers run with their current interrupt line disabled on all processors. This ensures that two interrupt handlers for the same interrupt line do not run concurrently. It also prevents device driver writers from having to handle recursive interrupts, which complicate programming.

share|improve this answer

The need for spin_lock_irqsave besides spin_lock_irq is quite similar to the reason local_irq_save(flags) is needed besides local_irq_disable. Here is a good explanation of this requirement taken from Linux Kernel Development Second Edition by Robert Love.

The local_irq_disable() routine is dangerous if interrupts were already disabled prior to its invocation. The corresponding call to local_irq_enable() unconditionally enables interrupts, despite the fact that they were off to begin with. Instead, a mechanism is needed to restore interrupts to a previous state. This is a common concern because a given code path in the kernel can be reached both with and without interrupts enabled, depending on the call chain. For example, imagine the previous code snippet is part of a larger function. Imagine that this function is called by two other functions, one which disables interrupts and one which does not. Because it is becoming harder as the kernel grows in size and complexity to know all the code paths leading up to a function, it is much safer to save the state of the interrupt system before disabling it. Then, when you are ready to reenable interrupts, you simply restore them to their original state:

unsigned long flags;

local_irq_save(flags);    /* interrupts are now disabled */ /* ... */
local_irq_restore(flags); /* interrupts are restored to their previous
state */

Note that these methods are implemented at least in part as macros, so the flags parameter (which must be defined as an unsigned long) is seemingly passed by value. This parameter contains architecture-specific data containing the state of the interrupt systems. Because at least one supported architecture incorporates stack information into the value (ahem, SPARC), flags cannot be passed to another function (specifically, it must remain on the same stack frame). For this reason, the call to save and the call to restore interrupts must occur in the same function.

All the previous functions can be called from both interrupt and process context.

share|improve this answer

Your Answer


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.