One thing that the API needs to do is to pass back and forth handles
Ok so far
(e.g. a structure containing a reference or pointer)
Why? A "handle" is just a way to identify an object. Doesn't necessarily mean it has to hold the reference or pointer.
One is the smart pointer paradigm, for example boost::shared_ptr or std::shared_ptr, which make sure the object is only destroyed when there are no more references to it.
might work fine here if you want to use it for your memory deallocation mechanism.
simply destroy the object within the library,
This can exist with smart pointers, its not one or the other.
have any subsequent function calls which pass a handle to that object as an input simply return an error code.
sure sounds good.
If your library is responsible for allocating memory, then it should be responsible for deallocating memory.
I would return simple integer "handles" from the library _GetNewObject() method.
Your library needs a map of handles to internal objects. No one outside the library should see the objects from the C interface.
All the library methods should take a handle as their first parameter.
For the multi-threaded stuff, do two threads need to access the same object? If so, you'll need to put in some sort of locking that occurs when a C API function is entered, and released before it leaves. You will have to make a decision if you want the code outside the library to know about this locking (you probably don't), a C function that calls the library function will probably just want to get the return value and not worry about the lock/unlock.
So your library needs:
- an interface to allocate and deallocate objects, viewed as handles by the outside
- an interface to do stuff given the handles.
EDIT: MORE INFO
Within the library I would use a Factory pattern to create new objects. The Factory should hand out a shared_ptr after the object allocation. This way everything else in the library just uses shared_ptr, and the cleanup will be fairly automatic (i.e. the factory doesn't have to store a list of what is created to remember to clean up, and no one has to call delete explicitly). Store the shared_ptr in the map with the handle. You'll probably need some sort of static counter along with a GetNextHandle() function to get the next available handle and to deal with wrap around (depending on how many objects are created and destroyed within the lifetime of the running program).
Next, put your shared pointer into a Proxy. The proxy should be very lightweight and you can have many Proxy objects per actual object. Each proxy will hold a private shared_ptr and whatever thread / mutex object you choose to use (you haven't given any information about this, so its hard to be any more specific). When a Proxy is created, it should acquire the mutex, and release on destruction (i.e. RAII for releasing the lock).
You haven't included any information on how to determine if you want to create a new object or find an existing object, and how two different threads would "find" the same object. However, lets assume that you have a GetObject() with enough parameters to uniquely identify each object and return the handle from the map, if the objects exists.
In this case, each of your visible extern C library functions would accept an object handle and:
Create a new Proxy for the given handle. In the Proxy constructor, the Proxy would look in the map to find the handle, if it doesn't exist, ask the Factory to create one (or return an error, your choice here). The Proxy would then acquire the lock. Your function would then get the pointer from the Proxy and use it. When the function exits, the Proxy goes out of scope, releases the lock, and decrements the reference counter.
If two functions are running in different threads, as long as a Proxy exists in one of the functions, the object will still exist. The other function could ask the library to delete the object which would remove the reference from the map. Once all the other functions with active Proxy objects finish, the final shared_ptr will go out of scope and the object will be deleted.
You can do most of this generically with templates, or write concrete classes.
EDIT: MORE INFO
The Proxy will be a small class. It will have a shared_ptr, and have a lock. You would instantiate a Proxy within the scope of the extern C function called by the client (note, this is actually a C++ function with all the benefits such as being able to use C++ classes). The proxy is small and should go on the stack (do not new and delete this, more trouble than its worth, just make a scoped variable and let C++ do the work for you). The proxy would use the RAII pattern to get a copy of the shared_ptr (which would increment the reference count of the shared_ptr) and acquire the lock at construction. When the Proxy goes out of scope, the shared_ptr it has is destroyed thus decrementing the reference count. The Proxy destructor should release the lock. BTW, you may want to think about blocking and how you want your thread mutexes to work. I don't know enough about your specific mutex implementation to suggest anything yet.
The map will contain the "master" shared_ptr that all others are copied from. However, this is flexible and decoupled because once a Proxy gets a shared_ptr from the map, it doesn't have to worry about "giving it back". The shared_ptr in the map can be removed (i.e. the object no longer "exists" to the Factory), but there can still be Proxy classes that have a shared_ptr, so the actual object will still exist as long as something is using it.