Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

I am currently building a Kernel module and I want to face SMP issues in a quite-optimal way.

Currently, I have a set of objects and each one is bound to a particular CPU. The following code illustrates this :

struct my_object {
    int a_field;
};

struct my_object cpu_object[NR_CPUS];
/*
 * cpu_object[i] is "bound" to CPU number "i" !
 */

A simple call to smp_processor_id() will then give me the processor on which the current code is running. So if I have a function foo that does some work using the CPU-bound objects described above, it might look like :

void foo()
{
    int cpu = smp_processor_id();
    do_some_work_with(cpu_object[cpu]);
}

The question is : How to guarantee that

  1. There is no CPU switch between cpu assignment and do_some_work_with ?
  2. do_some_work_with() will only run on cpu ?

At the time, the solution I think about is :

  1. Disable preemption using a spinlock
  2. Get the CPU with smp_processor_id
  3. Set the processor affinity of the current task to make it stick with the current CPU
  4. Enable preemption again, releasing the lock
  5. Do the work do_some_work_with()
  6. Reset the affinity to its previous state

To me it is quite barbarian and I was wondering if there was smarter and lighter way to do it.

Thanks in advance.


EDIT : As stated in the comments, I edit to explain why I feel I need such features. I have to perform on-the-fly encryption on a filesystem level.
To do so, I will use the Kernel built-in cryptographic support (struct crypto_tfm and friends). Here is the original issue...

On multi-core machines, it is possible to perform multiple R/W operations at the same time. The common fs layer does it and does it well. But, here I come and mess things up :

  • A struct crypto_tfm-like object is in charge for the ciphering operation
  • A same transform object cannot be used at the same time since some parameters would be altered (private key and initialization vector) and screw all the process
  • A naive solution as described below is completely out of the question due to the complex cipher allocation system built in crypto.
    1. Allocate the crypto_tfm transformation
    2. Perform the ciphering operation
    3. Free the transformation object
  • A classic scheme where only one transform is available prevents multiple concurrent R/W operations since one task would have to wait for another to release the lock held to protect the transform object.

For these reasons, I need to deal with multiple transformation objects. I must find an efficient scheme that allows concurrent R/W. I feel my "Y" here is "the solution that is simple, neat ... and wrong". Any suggestion would be much appreciated.

Note : If I use a solution like the one I gave in the original question, I would limit it to very short sections to avoid heavy impact on CPU load balancing.

share|improve this question
2  
Why do you see a need to exercise this level of control? Does your module have problems if you don't? –  John Zwinck Feb 13 '13 at 13:33
3  
I feel quite strongly that your overall approach is wrong. Forcing the kernel to run a kernel thread on a particular CPU is definitely something not right. I do believe the method you describe would work, but it seems very wrong. –  Mats Petersson Feb 13 '13 at 13:34
    
@MatsPetersson I have the same feeling ... But I cannot figure out how to guarantee smooth SMP within the tasks I need to run. I could edit to explain you the context that lead me consider this kind of horrible things –  Rerito Feb 13 '13 at 13:42
3  
It may help - as I feel this is a typical XY question - you thin the right solution is to do Y to solve X, so you ask how to do Y. –  Mats Petersson Feb 13 '13 at 13:45
    
@MatsPetersson I edited, you should have the "X" now –  Rerito Feb 13 '13 at 14:05

1 Answer 1

up vote 2 down vote accepted

So, based on your edited question, I have to say that I think your solution is wrong.

The right thing to do is to have a "per operation" crypto_tfm, that follows that operation across CPU's. Using the "current CPU" is not the right thing here. [What happens if the this is running on a system with hot-swappable CPUs, and someone disconnects the CPU your task is running on - and never puts one back in it's place?]

If it's costly to allocate a crypto_tfm per operation, then you have to find some way to avoid allocating/freeing the objects - have a pool of them and assign an available to the current operation, and when the operation is complete, put it back into the available list again.

share|improve this answer
    
What are the available policies when there is no object ready to use, apart from the two obvious ones (allocate a new object or simply wait for an existing one to become available) ? From what I read so far, a CPU cannot be hot-unplugged if a task cannot be moved to another one –  Rerito Feb 13 '13 at 14:25
    
Those are the only two I can think of. Well, with a third "hybrid" one, I suppose, based on if (num_allocated_crypt_tfm < max_allocated_crypt_tfm) allocate_new_crypt_tfm(); else wait_for_available_crypt_tfm(); - that way, you can keep a limit on how many crypt_tfm there are, but at the same time not have to allocate a lot of them to start with. –  Mats Petersson Feb 13 '13 at 14:28

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.