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I'm writing a C++ app.

I have a class variable that more than one thread is writing to.

In C++, anything that can be modified without the compiler "realizing" that it's being changed needs to be marked volatile right? So if my code is multi threaded, and one thread may write to a var while another reads from it, do I need to mark the var volaltile?

[I don't have a race condition since I'm relying on writes to ints being atomic]


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What makes you think that writes are going to be atomic? – bmargulies Feb 26 '10 at 12:08
I'm no expert on multithreading, but I would always implement locking around any shared resource... – Martin Milan Feb 26 '10 at 12:12
I have done this sort of thing on an embedded PowerPC single-core processor and it works reliably. Better not do any read-modify-write (such as ++sharedInt) if it's possible that two threads have write access. (Actually, if two threads may write, it's probably only useful if you limit when they can write. E.g., thread A is allowed to change sharedInt from 0 to 1 while thread B is allowed to change it from 1 to 0.) – Dan Feb 27 '10 at 18:08

C++ hasn't yet any provision for multithreading. In practice, volatile doesn't do what you mean (it has been designed for memory adressed hardware and while the two issues are similar they are different enough that volatile doesn't do the right thing -- note that volatile has been used in other language for usages in mt contexts).

So if you want to write an object in one thread and read it in another, you'll have to use synchronization features your implementation needs when it needs them. For the one I know of, volatile play no role in that.

FYI, the next standard will take MT into account, and volatile will play no role in that. So that won't change. You'll just have standard defined conditions in which synchronization is needed and standard defined way of achieving them.

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"In practice, volatile doesn't do what you mean". What?? Volatile is designed to prevent compiler optimizations on a variable. It's highly, highly, highly recommended for multithreaded programming. Don't attempt multithreaded programming without volatile. Your program may work fine for years and suddenly crash out of nowhere. – annoying_squid Jan 28 at 14:48
@annoying_squid, see stackoverflow.com/a/2485177/136208. Starting from C++ 11, std::atomic<> is probably the way to get what you though volatile would provide. – AProgrammer Jan 28 at 14:55

Yes, volatile is the absolute minimum you'll need. It ensures that the code generator won't generate code that stores the variable in a register and always performs reads and writes from/to memory. Most code generators can provide atomicity guarantees on variables that have the same size as the native CPU word, they'll ensure the memory address is aligned so that the variable cannot straddle a cache-line boundary.

That is however not a very strong contract on modern multi-core CPUs. Volatile does not promise that another thread that runs on another core can see updates to the variable. That requires a memory barrier, usually an instruction that flushes the CPU cache. If you don't provide a barrier, the thread will in effect keep running until such a flush occurs naturally. That will eventually happen, the thread scheduler is bound to provide one. That can take milliseconds.

Once you've taken care of details like this, you'll eventually have re-invented a condition variable (aka event) that isn't likely to be any faster than the one provided by a threading library. Or as well tested. Don't invent your own, threading is hard enough to get right, you don't need the FUD of not being sure that the very basic primitives are solid.

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Volatile isn't the absolute minimum. It's well below the minimum. The minimum would also have to prevent read/write reordering around the shared variable. – jalf Feb 26 '10 at 15:55
@jalf - how many graduations below "absolute minimum" do you care to consider? – Hans Passant Feb 26 '10 at 17:19
Just one: "below it" ;) – jalf Feb 26 '10 at 18:35

volatile instruct the compiler not to optimize upon "intuition" of a variable value or usage since it could be optimize "from the outside".

volatile won't provide any synchronization however and your assumption of writes to int being atomic are all but realistic!

I'd guess we'd need to see some usage to know if volatile is needed in your case (or check the behavior of your program) or more importantly if you see some sort of synchronization.

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That's NOT true, when you are building HPC application/algorithms you are usually quite aware of the architecture you are going to work with. And thus you are not going to add a useless lock, if you don't need it. – Ben Feb 26 '10 at 12:18
Well hum, my point of view at least. – Ben Feb 26 '10 at 12:27
I always thought that write an int was an atomic op (at least on x86 CPU). Do you have some good documentations about atomic ops ? – Nicolas Guillaume Feb 26 '10 at 13:23
@Ben: In HPC apps, you know the architecture, but you don't know what optimizations the compiler will perform. And if one of the things you know about the architecture is "it uses out-of-order execution", which is usually the case, then a synchronization mechanism is absolutely critical... Which it usually also is even without OOO execution, because of compiler optimizations. – jalf Feb 26 '10 at 15:57
Ok, I was just saying assuming that writing an integer is an atomic operation is a common assumption. – Ben Feb 26 '10 at 16:38

I think that volatile only really applies to reading, especially reading memory-mapped I/O registers.

It can be used to tell the compiler to not assume that once it has read from a memory location that the value won't change:

while (*p)
  // ...

In the above code, if *p is not written to within the loop, the compiler might decide to move the read outside the loop, more like this:

while (cached_p)
  // ...

If p is a pointer to a memory-mapped I/O port, you would want the first version where the port is checked before the loop is entered every time.

If p is a pointer to memory in a multi-threaded app, you're still not guaranteed that writes are atomic.

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It's not only about reading: "for (i = 0; i < 10; ++i) { j = i; } can be replaced with j = 10; when j is not volatile. – stefaanv Feb 26 '10 at 14:09

Without locking you may still get 'impossible' re-orderings done by the compiler or processor. And there's no guarantee that writes to ints are atomic.

It would be better to use proper locking.

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Volatile will solve your problem, ie. it will guarantee consistency among all the caches of the system. However it will be inefficiency since it will update the variable in memory for each R or W access. You might concider using a memory barrier, only whenever it is needed, instead. If you are working with or gcc/icc have look on sync built-ins : http://gcc.gnu.org/onlinedocs/gcc-4.1.2/gcc/Atomic-Builtins.html

EDIT (mostly about pm100 comment): I understand that my beliefs are not a reference so I found something to quote :)

The volatile keyword was devised to prevent compiler optimizations that might render code incorrect in the presence of certain asynchronous events. For example, if you declare a primitive variable as volatile, the compiler is not permitted to cache it in a register

From Dr Dobb's

More interesting :

Volatile fields are linearizable. Reading a volatile field is like acquiring a lock; the working memory is invalidated and the volatile field's current value is reread from memory. Writing a volatile field is like releasing a lock : the volatile field is immediately written back to memory. (this is all about consistency, not about atomicity)

from The Art of multiprocessor programming, Maurice Herlihy & Nir Shavit

Lock contains memory synchronization code, if you don't lock, you must do something and using volatile keyword is probably the simplest thing you can do (even if it was designed for external devices with memory binded to the address space, it's not the point here)

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Why is this response downvoted? – anon Feb 26 '10 at 17:45
because its wrong. volatile has nothing to do with memory caches. – pm100 Mar 20 '10 at 1:37
@pm100, It was not designed for this I agree, but it has to do with caches, see my edit please. – Ben Mar 20 '10 at 10:32
your linked article is from 2001. We've since learned our lesson. Please see drdobbs.com/high-performance-computing/212701484 for a modern view of volatile. – deft_code Mar 20 '10 at 19:50
caching in a register is not the same as 'the caches of a system' - ie the problem of cache coherence for multi proc systems. THe reason I jumped on this is because it is radically wrong as the various articles have pointed out. I used to believe that c++ volatile helped here, but it does not; I am trying to pass on my lessons – pm100 Mar 22 '10 at 16:48

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