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I'm aware of the fact that the containers from standard library are not thread-safe. By that I used to think that a container, say of type std::list, cannot be accessed by more than one thread concurrently (some of which may modify the container). But now it seems that there is more to it than meets the eye; something more subtle, something not so obvious, well at least to me.

For example, consider this function which accepts the first argument by value:

void log(std::string msg, severity s, /*...*/) 
{
   return; //no code!
}

Is this thread-safe?

At first, it seems that it is thread-safe, as the function body accesses no shared modifiable resources, hence thread-safe. On second thought, it comes to me that when invoking such a function, an object of type std::string will be created, which is the first argument, and I think that construction of this object isn't thread-safe, as it internally uses std::allocator, which I believe isn't thread-safe. Hence invoking such a function isn't thread-safe either. But if it is correct, then what about this:

void f()
{
   std::string msg = "message"; //is it thread-safe? it doesn't seem so!
}

Am I going right? Can we use std::string (or any container which uses std::allocator internally) in multi-threaded program?

I'm specifically talking about containers as local variables, as opposed to shared objects.

I searched google and found many similar doubts, with no concrete answer. I face similar problem as his:

Please consider C++03 and C++11, both.

share|improve this question
    
Nawaz - do you know what implementation of C++ they are talking about here: sgi.com/tech/stl/Allocators.html It states that the default allocator is threadsafe. – Sid Mar 1 '12 at 19:15
    
@Sid: That is not standard library; they support lots of things which stdlib doesn't. – Nawaz Mar 1 '12 at 19:25
    
Okay, sorry about the distraction. – Sid Mar 1 '12 at 19:26
up vote 6 down vote accepted

In C++11, std::allocator is thread safe. From its definition:

20.6.9.1/6: Remark: the storage is obtained by calling ::operator new(std::size_t)

and from the definition of ::operator new:

18.6.1.4: The library versions of operator new and operator delete, user replacement versions of global operator new and operator delete, and the C standard library functions calloc, malloc, realloc, and free shall not introduce data races (1.10) as a result of concurrent calls from different threads.

C++03 had no concept of threads, so any thread safety was implementation-specific; you'd have to refer to your implementation's documentation to see what guarantees it offered, if any. Since you're using Microsoft's implementation, this page says that it is safe to write to multiple container objects of the same class from many threads, which implies that std::allocator is thread-safe.

share|improve this answer
    
It is C++11. What about C++03? C++03 had no concept of multithreading. – Nawaz Mar 1 '12 at 18:44
    
Well, I searched C++03, and it seems C++03's allocator is not thread-safe. – Nawaz Mar 1 '12 at 18:49
    
@Nawaz: Indeed, C++03 says nothing about thread safety, so you'll have to refer to your compiler/library documentation. – Mike Seymour Mar 1 '12 at 19:03
    
I'm using MSVC 2010, and I've to look into it. – Nawaz Mar 1 '12 at 19:05
    
@Nawaz, others have noted that C++03 didn't address threads in any way. It's up to individual implementations to provide thread safety. You can't generalize. – Mark Ransom Mar 1 '12 at 19:08

In C++11 this would be addressed for the default allocator in:

20.6.9.1 allocator members [allocator.members]

Except for the destructor, member functions of the default allocator shall not introduce data races (1.10) as a result of concurrent calls to those member functions from different threads. Calls to these functions that allocate or deallocate a particular unit of storage shall occur in a single total order, and each such deallocation call shall happen before the next allocation (if any) in this order.

Any user-provided allocator would have to hold to the same constraints if it were going to be used across different threads.

Of course, for earlier versions of the standard, nothing is said about this since they didn't talk about multithreading. If an implementation were to support multithreading (as many or most do), it would be responsible for taking care of those issues. Similar to the way implementations provide a thread-safe malloc() (and other library functions) for C and C++ even though the standards prior to very recently said nothing about that.

share|improve this answer

As you may have already figured, there is not going to be an easy yes or no answer. However, I think this may help:

http://www.cs.huji.ac.il/~etsman/Docs/gcc-3.4-base/libstdc++/html/faq/index.html#5_6

I quote verbatim:

5.6 Is libstdc++-v3 thread-safe?

libstdc++-v3 strives to be thread-safe when all of the following conditions are met:

The system's libc is itself thread-safe, gcc -v reports a thread model other than 'single', [pre-3.3 only] a non-generic implementation of atomicity.h exists for the architecture in question.

share|improve this answer
    
This is about a particular implementation of the lib in a very old compiler...1 – David Rodríguez - dribeas Mar 1 '12 at 19:03
    
@DavidRodríguez-dribeas I think most answers we will find to this question will be dependent on what C++ compiler/version as well as what malloc implementation is being used. – Sid Mar 1 '12 at 19:10

When an std::string is copied during call to log, the allocator may be thread-safe (mandatory in C++11), but the copy itself isn't. So if there is another thread mutating the source string while copy is taking place, this is not thread safe.

You may end-up with half the string as it was before mutation and another half after, or may even end-up accessing deallocated memory if the mutating thread reallocated (e.g. by appending new characters) or deleted the string, while the copy was still taking place.


OTOH, the...

std::string msg = "message";

...is thread safe provided your allocator is thread safe.

share|improve this answer
    
"So if there is another thread mutating the source string while copy is taking place, this is not thread safe.". That is a different issue. I'm no talking about that, as in this case the problem lies in the reading the shared object, while I talk about local objects. – Nawaz Mar 1 '12 at 19:55
1  
@Nawaz Then the entire issue boils-down to the thread safety of your allocator, because this is the only thing that is shared between threads. – Branko Dimitrijevic Mar 1 '12 at 20:00

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