The hidden question is: where do you put the mutex protecting your class?
As a summary, let's say you want to read the content of an object which is protected by a mutex.
The "read" method should be semantically "const" because it does not change the object itself. But to read the value, you need to lock a mutex, extract the value, and then unlock the mutex, meaning the mutex itself must be modified, meaning the mutex itself can't be "const".
If the mutex is external
Then everything's ok. The object can be "const", and the mutex don't need to be:
Mutex mutex ;
int foo(const Object & object)
{
Lock<Mutex> lock(mutex) ;
return object.read() ;
}
IMHO, this is a bad solution, because anyone could reuse the mutex to protect something else. Including you. In fact, you will betray yourself because, if your code is complex enough, you'll just be confused about what this or that mutex is exactly protecting.
I know: I was victim of that problem.
If the mutex is internal
For encapsulation purposes, you should put the mutex as near as possible from the object it's protecting.
Usually, you'll write a class with a mutex inside. But sooner or later, you'll need to protect some complex STL structure, or whatever thing written by another without mutex inside (which is a good thing).
A good way to do this is to derive the original object with an inheriting template adding the mutex feature:
template <typename T>
class Mutexed : public T
{
public :
Mutexed() : T() {}
// etc.
void lock() { this->m_mutex.lock() ; }
void unlock() { this->m_mutex.unlock() ; } ;
private :
Mutex m_mutex ;
}
This way, you can write:
int foo(const Mutexed<Object> & object)
{
Lock<Mutexed<Object> > lock(object) ;
return object.read() ;
}
The problem is that it won't work because object is const, and the lock object is calling the non-const lock and unlock methods.
The Dilemma
If you believe const is limited to bitwise const objects, then you're screwed, and must go back to the "external mutex solution".
The solution is to admit const is more a semantic qualifier (as is volatile when used as a method qualifier of classes). You are hiding the fact the class is not fully const but still make sure provide an implementation that keeps the promise that the meaningful parts of the class won't be changed when calling a const method.
You must then declare your mutex mutable, and the lock/unlock methods const:
template <typename T>
class Mutexed : public T
{
public :
Mutexed() : T() {}
// etc.
void lock() const { this->m_mutex.lock() ; }
void unlock() const { this->m_mutex.unlock() ; } ;
private :
mutable Mutex m_mutex ;
}
The internal mutex solution is a good one IMHO: Having to objects declared one near the other in one hand, and having them both aggregated in a wrapper in the other hand, is the same thing in the end.
But the aggregation has the following pros:
- It's more natural (you lock the object before accessing it)
- One object, one mutex. As the code style forces you to follow this pattern, it decreases deadlock risks because one mutex will protect one object only (and not multiple objects you won't really remember), and one object will be protected by one mutex only (and not by multiple mutex that needs to be locked in the right order)
- The mutexed class above can be used for any class
So, keep your mutex as near as possible to the mutexed object (e.g. using the Mutexed construct above), and go for the mutable qualifier for the mutex.
Edit 2013-01-04
Apparently, Herb Sutter have the same viewpoint: His presentation about the "new" meanings of const and mutable in C++11 is very enlightening:
http://herbsutter.com/2013/01/01/video-you-dont-know-const-and-mutable/
