I have a custom class that uses boost mutexes and locks like this (only relevant parts):
template<class T> class FFTBuf
{
public:
FFTBuf();
[...]
void lock();
void unlock();
private:
T *_dst;
int _siglen;
int _processed_sums;
int _expected_sums;
int _assigned_sources;
bool _written;
boo开发者_开发技巧st::recursive_mutex _mut;
boost::unique_lock<boost::recursive_mutex> _lock;
};
template<class T> FFTBuf<T>::FFTBuf() : _dst(NULL), _siglen(0),
_expected_sums(1), _processed_sums(0), _assigned_sources(0),
_written(false), _lock(_mut, boost::defer_lock_t())
{
}
template<class T> void FFTBuf<T>::lock()
{
std::cerr << "Locking" << std::endl;
_lock.lock();
std::cerr << "Locked" << std::endl;
}
template<class T> void FFTBuf<T>::unlock()
{
std::cerr << "Unlocking" << std::endl;
_lock.unlock();
}
If I try to lock more than once the object from the same thread, I get an exception (lock_error):
#include "fft_buf.hpp"
int main( void ) {
FFTBuf<int> b( 256 );
b.lock();
b.lock();
b.unlock();
b.unlock();
return 0;
}
This is the output:
sb@dex $ ./src/test
Locking
Locked
Locking
terminate called after throwing an instance of 'boost::lock_error'
what(): boost::lock_error
zsh: abort ./src/test
Why is this happening? Am I understanding some concept incorrectly?
As the name implies, the Mutex is recursive
but the Lock is not.
That said, you have here a design problem. The locking operations would be better off not being accessible from the outside.
class SynchronizedInt
{
public:
explicit SynchronizedInt(int i = 0): mData(i) {}
int get() const
{
lock_type lock(mMutex);
toolbox::ignore_unused_variable_warning(lock);
return mData;
}
void set(int i)
{
lock_type lock(mMutex);
toolbox::ignore_unused_variable_warning(lock);
mData = i;
}
private:
typedef boost::recursive_mutex mutex_type;
typedef boost::unique_lock<mutex_type> lock_type;
int mData;
mutable mutex_type mMutex;
};
The main point of the recursive_mutex
is to allow chain locking in a given thread which may occur if you have complex operations that call each others in some case.
For example, let's add tweak get:
int SynchronizedInt::UnitializedValue = -1;
int SynchronizedInt::get() const
{
lock_type lock(mMutex);
if (mData == UnitializedValue) this->fetchFromCache();
return mData;
}
void SynchronizedInt::fetchFromCache()
{
this->set(this->fetchFromCacheImpl());
}
Where is the problem here ?
get
acquires the lock onmMutex
- it calls
fetchFromCache
which callsset
set
attempts to acquire the lock...
If we did not have a recursive_mutex
, this would fail.
The lock should not be part of the protected ressource but of the caller as you have one caller by thread. They must use different unique_lock.
The purpose of unique_lock is to lock and release the mutex with RAII, so you don't have to call unlock explicitly.
When the unique_lock is declared inside a method body, it will belong to the calling thread stack.
So a more correct use is :
#include <boost/thread/recursive_mutex.hpp>
#include <iostream>
template<class T>
class FFTBuf
{
public :
FFTBuf()
{
}
// this can be called by any thread
void exemple() const
{
boost::recursive_mutex::scoped_lock lock( mut );
std::cerr << "Locked" << std::endl;
// we are safe here
std::cout << "exemple" << std::endl ;
std::cerr << "Unlocking ( by RAII)" << std::endl;
}
// this is mutable to allow lock of const FFTBuf
mutable boost::recursive_mutex mut;
};
int main( void )
{
FFTBuf< int > b ;
{
boost::recursive_mutex::scoped_lock lock1( b.mut );
std::cerr << "Locking 1" << std::endl;
// here the mutex is locked 1 times
{
boost::recursive_mutex::scoped_lock lock2( b.mut );
std::cerr << "Locking 2" << std::endl;
// here the mutex is locked 2 times
std::cerr << "Auto UnLocking 2 ( by RAII) " << std::endl;
}
b.exemple();
// here the mutex is locked 1 times
std::cerr << "Auto UnLocking 1 ( by RAII) " << std::endl;
}
return 0;
}
Note the mutable on the mutex for const methods.
And the boost mutex types have a scoped_lock typedef which is the good unique_lock type.
Try this:
template<class T> void FFTBuf<T>::lock()
{
std::cerr << "Locking" << std::endl;
_mut.lock();
std::cerr << "Locked" << std::endl;
}
template<class T> void FFTBuf<T>::unlock()
{
std::cerr << "Unlocking" << std::endl;
_mut.unlock();
}
You use the same instance of unique_lock _lock
twice and this is a problem.
You either have to directly use methods lock () and unock() of the recursive mutex or use two different instances of unique_lock like foe example _lock
and _lock_2
;.
Update
I would like to add that your class has public methods lock()
and unlock()
and from my point of view in a real program it is a bad idea. Also having unique_lock as a member of class in a real program must be often a bad idea.
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