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From what I know, the compiler never optimizes a variable that is declared as volatile. However, I have an array declared like this.

volatile long array[8];

And different threads read and write to it. An element of the array is only modified by one of the threads and read by any other thread. However, in certain situations I've noticed that even if I modify an element from a thread, the thread reading it does not notice the change. It keeps on reading the same old value, as if compiler has cached it somewhere. But compiler in principal should not cache a volatile variable, right? So how come this is happening.

NOTE: I am not using volatile for thread synchronization, so please stop giving me answers such as use a lock or an atomic variable. I know the difference between volatile, atomic variables and mutexes. Also note that the architecture is x86 which has proactive cache coherence. Also I read the variable for long enough after it is supposedly modified by the other thread. Even after a long time, the reading thread can't see the modified value.

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volatile is not for threads. You need to use a mutex. – Vaughn Cato Oct 3 '12 at 14:16
AFAIK in C++ volatile only affects the compiler optimizations, not the possible CPU reorders that can still happen. – Tudor Oct 3 '12 at 14:22
Your note doesn't affect my answer, btw, and probably not other people's answers. You might not think you're using volatile for thread synchronization, but if you expect it to introduce a relationship between a read and a write in different threads, then in point of fact you are, because by definition that's what thread synchronization is. – Steve Jessop Oct 3 '12 at 14:40
@Eric: it explicitly states an expectation about when the readers will see updates: "I read the variable for long enough after is is supposedly modified by the other thread". Assuming the test code is doing what it's intended to, this is an argument between user1018562 and his implementation, over how long is "long enough". He says there's a limit, the implementation apparently says there isn't. The standard will not intervene in that argument, it has nothing to say about whether the compiler "in principal should not cache a volatile variable", because the code has a data race. – Steve Jessop Oct 3 '12 at 14:59
I would try a mutex. If that fixes it, then you can expect it is a cache issue. If that doesn't fix it, then you can look for the problem elsewhere. – Vaughn Cato Oct 3 '12 at 15:11
up vote 5 down vote accepted

But compiler in principal should not cache a volatile variable, right?

No, the compiler in principle must read/write the address of the variable each time you read/write the variable.

[Edit: At least, it must do so up to the point at which the the implementation believes that the value at that address is "observable". As Dietmar points out in his answer, an implementation might declare that normal memory "cannot be observed". This would come as a surprise to people using debuggers, mprotect, or other stuff outside the scope of the standard, but it could conform in principle.]

In C++03, which does not consider threads at all, it is up to the implementation to define what "accessing the address" means when running in a thread. Details like this are called the "memory model". Pthreads, for example, allows per-thread caching of the whole of memory, including volatile variables. IIRC, MSVC provides a guarantee that volatile variables of suitable size are atomic, and it will avoid caching (rather, it will flush as far as a single coherent cache for all cores). The reason it provides that guarantee is because it's reasonably cheap to do so on Intel -- Windows only really cares about Intel-based architectures, whereas Posix concerns itself with more exotic stuff.

C++11 defines a memory model for threading, and it says that this is a data race (i.e. that volatile does not ensure that a read in one thread is sequenced relative to a write in another thread). Two accesses can be sequenced in a particular order, sequenced in unspecified order (the standard might say "indeterminate order", I can't remember), or not sequenced at all. Not sequenced at all is bad -- if either of two unsequenced accesses is a write then behavior is undefined.

The key here is the implied "and then" in "I modify an element from a thread AND THEN the thread reading it does not notice the change". You're assuming that the operations are sequenced, but they're not. As far as the reading thread is concerned, unless you use some kind of synchronization the write in the other thread hasn't necessarily happened yet. And actually it's worse than that -- you might think from what I just wrote that it's only the order of operations that is unspecified, but actually the behavior of a program with a data race is undefined.

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I know what you are saying, but I run the program for enough time to notice that the thread keeps on reading the same value, even long after it has been changed by another thread. The cache coherence might take some time, but it can be not more than few microseconds I guess, actually much lesser than that I think. – pythonic Oct 3 '12 at 14:25
@user1018562: the point is that the data race is undefined behavior. One motivation for it being UB is to do with non-coherent caches, but the behavior once it happens might be anything, because the optimizer might have relied on there being no data races when it transformed your code. The purpose of requiring your code to have no data races, is to allow the compiler to perform transformations that are incorrect for code that has them. – Steve Jessop Oct 3 '12 at 14:26
@SteveJessop: People place too much emphasis on “undefined behavior”. Behavior is never specified to be undefined. It is not simply not defined. The difference is that the C standard might not define behavior, but it does not prevent another specification from defining it. You cannot conclude from the fact that C does not define behavior that we cannot expect particular hardware to behave in certain ways. If the hardware does propagate changes after a small time, and a change occurs, and the change is not observed after the time has passed, then there is a bug. – Eric Postpischil Oct 3 '12 at 16:10
@Eric: mostly true, but since the questioner doesn't say what compiler or code we're talking about then it's a massive guess to say what the results should be, regardless of the hardware. It's no use having hardware that propagates changes if you don't write code (or use a compiler) that actually makes a change. If the questioner had asked a different question then I might have given a different answer with less emphasis on standards and more on the behavior of a particular compiler. You're right, there probably is a bug, almost certainly in the questioner's code. – Steve Jessop Oct 4 '12 at 9:55
And you're right to suggest looking at the assembly too, but the point of this answer is that even if the questioner discovers that the compiler has omitted the read or write or memory barrier that he expects, he doesn't get to call it a non-conforming compiler. He asked about "in principle", not about "in my compiler". – Steve Jessop Oct 4 '12 at 10:00


What volatile does:

  • Guarantees an up-to-date value in the variable, if the variable is modified from an external source (a hardware register, an interrupt, a different thread, a callback function etc).
  • Blocks all optimizations of read/write access to the variable.
  • Prevent dangerous optimization bugs that can happen to variables shared between several threads/interrupts/callback functions, when the compiler does not realize that the thread/interrupt/callback is called by the program. (This is particularly common among various questionable embedded system compilers, and when you get this bug it is very hard to track down.)

What volatile does not:

  • It does not guarantee atomic access or any form of thread-safety.
  • It cannot be used instead of a mutex/semaphore/guard/critical section. It cannot be used for thread synchronization.

What volatile may or may not do:

  • It may or may not be implemented by the compiler to provide a memory barrier, to protect against instruction cache/instruction pipe/instruction re-ordering issues in a multi-core environment. You should never assume that volatile does this for you, unless the compiler documentation explicitly states that it does.
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I am not using volatile variables as atomic variables, for memory barrier, or for thread synchronization. – pythonic Oct 3 '12 at 17:18

With volatile you can only impose that a variable is re-read whenever you use its value. It doesn't guarantee that the different values/representations that are present on different levels of your architecture are consistent.

To have such gurantees you'd need the new utilities from C11 and C++1 concerning atomic access and memory barriers. Many compilers implement these already in terms of extension. E.g the gcc family (clang, icc, etc) have builtins starting with prefix __sync to implement these.

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I think with __sync you ensure atomic operations but you won't prevent race condition. – Genís Oct 3 '12 at 14:20
sure that atomics avoid race conditions, that is exactly their definition. But they also guarantee coherence of data. – Jens Gustedt Oct 3 '12 at 14:21
Sorry, I should have said atomics doesn't ensure correct synchronization among threads. – Genís Oct 3 '12 at 14:26

The volatile keyword has nothing to do with concurrency in C++ at all! It is used to have the compiler prevented from making use of the previous value, i.e., the compiler will generate code accessing a volatile value every time is accessed in the code. The main purpose are things like memory mapped I/O. However, use of volatile has no affect on what the CPU does when reading normal memory: If the CPU has no reason to believe that the value changed in memory, e.g., because there is no synchronization directive, it can just use the value from its cache. To communicate between threads you need some synchronization, e.g., an std::atomic<T>, lock a std::mutex, etc.

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It can also prevent the compiler from optimizing away a variable that you "aren't using". – Derek Oct 3 '12 at 14:27

Volatile Keyword only guarantees that the compiler will not use register for this variable. Thus every access to this variable will go and read the memory location. Now, I assume that you have cache coherence among the multiple processors in your architecture. So if one processor writes and other reads it, then it should be visible under normal conditions. However, you should consider the corner cases. Suppose the variable is in the pipeline of one processor core and other processor is trying to read it assuming that has been written, then there is a problem. So essentially, the shared variables should be either guarded by locks or should be protected by using barrier mechanism correctly.

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But eventually it should be seen, right. – pythonic Oct 3 '12 at 17:18
yes, you are right. it should be seen sometime. – knowledge_seeker Oct 4 '12 at 10:47
Also, I am wondering with some optimization levels enabled while compiling, if the compiler by any chance removed this statement? This is just a thought. One of the methods to see what is going on, is by dumping the assembly code using some utility. – knowledge_seeker Oct 4 '12 at 10:52

For C++:

From what I know, the compiler never optimizes a variable that is declared as volatile.

Your premise is wrong. volatile is a hint to the compiler and doesn't actually guarantee anything. Compilers can choose to prevent some optimizations on volatile variables, but that's it.

volatile isn't a lock, don't try to use it as such.

7) [ Note: volatile is a hint to the implementation to avoid aggressive optimization involving the object because the value of the object might be changed by means undetectable by an implementation. See 1.9 for detailed semantics. In general, the semantics of volatile are intended to be the same in C++ as they are in C. —end note]

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Actually, the requirements on volatile are fairly strong from a compiler point-of-view. It's not like register or inline, which compilers are free to ignore. Precise access to volatile objects is one of the minimal requirements of a conforming implementation: if the compiler treats it as merely a hint, the implementation is nonconforming. (See of the C standard, I believe it's similar for C++.) Your conclusion is correct, but not for the reason you give. – hvd Oct 3 '12 at 14:16
@hvd looking for a quote right now, but I believe you're wrong. – Luchian Grigore Oct 3 '12 at 14:17
@hvd see edit.. – Luchian Grigore Oct 3 '12 at 14:18
I don't know about C++, but in C the compiler is not allowed to optimize volatile. C11 "Accessing a volatile object, ... are all side effects". "An actual implementation need not evaluate part of an expression if it can deduce that its value is not used and that no needed side effects are produced (including any caused by calling a function or accessing a volatile object)." "The least requirements on a conforming implementation are: — Accesses to volatile objects are evaluated strictly according to the rules of the abstract machine." – Lundin Oct 3 '12 at 14:27
This answer is basically correct, volatile doesn't mean "don't optimize". In fact, I don't think "don't optimize this variable" even has a well-defined meaning. But the semantics of volatile aren't solely a hint to avoid optimization, so volatile doesn't guarantee nothing. Access to volatile objects are observable behavior. Since hvd mentioned it to compare, C++ compilers aren't free to ignore inline or register either: both have defined meanings in addition to their secondary roles as optimization hints. C compilers can ignore register, and also restrict. – Steve Jessop Oct 3 '12 at 14:31

Volatile only affects the variable it is in front of. Here in your example, a pointer. Your code: volatile long array[8], the pointer to the first element of the array is volatile, not it's content. (same for objects of any kind)

you could adapt it like in How do I declare an array created using malloc to be volatile in c++

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However, in certain situations I've noticed that even if I modify an element from a thread, the thread reading it does not notice the change. It keeps on reading the same old value, as if compiler has cached it somewhere.

This is not because the compiler cached it somewhere, but because the reading thread reads from its CPU core's cache, which might be different from the writing thread's one. To ensure value change propagation across CPU cores, you need to use proper memory fences, and you neither can nor need to use volatile for that in C++.

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But in a processor with proactive cache coherence like x86, the cache of a core should be updated in this case, that is, whenever a core A writes to memory X, if core B tries to read from X, its cache corresponding to X will be updated. – pythonic Oct 3 '12 at 17:16

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