Shared libraries in C++ are quite difficult because the standard says nothing about them. This means that every platform has a different way of doing them. If we restrict ourselves to Windows and some *nix variant (anything ELF), the differences are subtle. The first difference is Shared Object Visibility. It is highly recommended that you read that article so you get a good overview of what visibility attributes are and what they do for you, which will help save you from linker errors.
Anyway, you'll end up with something that looks like this (for compiling with many systems):
# define DLL_EXPORT __declspec(dllexport)
# define DLL_IMPORT __declspec(dllimport)
# define DLL_EXPORT __attribute__((visibility("default")))
# define DLL_IMPORT
# if __GNUC__ > 4
# define DLL_LOCAL __attribute__((visibility("hidden")))
# define DLL_LOCAL
# error("Don't know how to export shared object libraries")
Next, you'll want to make some shared header (
standard.h?) and put a nice little
#ifdef thing in it:
# define MY_LIBRARY_PUBLIC DLL_EXPORT
# define MY_LIBRARY_PUBLIC DLL_IMPORT
This lets you mark classes, functions and whatever like this:
class MY_LIBRARY_PUBLIC MyClass
MY_LIBRARY_PUBLIC int32_t MyFunction();
This will tell the build system where to look for the functions when it calls them.
Now: To the actual point!
If you're sharing constants across libraries, then you actually should not care if they are duplicated, since your constants should be small and duplication allows for much optimization (which is good). However, since you appear to be working with non-constants, the situation is a little different. There are a billion patterns to make a cross-library singleton in C++, but I naturally like my way the best.
In some header file, let's assume you want to share an integer, so you would do have in
// include the standard header, which has the MY_LIBRARY_PUBLIC definition
// Notice that it is a reference
MY_LIBRARY_PUBLIC int& GetSingleInt();
Then, in the
myfuncts.cpp file, you would have:
// keep the actual value as static to this function
static int s_value(0);
// but return a reference so that everybody can use it
Dealing with templates
C++ has super-powerful templates, which is great. However, pushing templates across libraries can be really painful. When a compiler sees a template, it is the message to "fill in whatever you want to make this work," which is perfectly fine if you only have one final target. However, it can become an issue when you're working with mutliple dynamic shared objects, since they could theoretically all be compiled with different versions of different compilers, all of which think that their different template fill-in-the-blanks methods is correct (and who are we to argue -- it's not defined in the standard). This means that templates can be a huge pain, but you do have some options.
Don't allow different compilers.
Pick one compiler (per operating system) and stick to it. Only support that compiler and require that all libraries be compiled with that same compiler. This is actually a really neat solution (that totally works).
Don't use templates in exported functions/classes
Only use template functions and classes when you're working internally. This does save a lot of hassle, but overall is quite restrictive. Personally, I like using templates.
Force exporting of templates and hope for the best
This works surprisingly well (especially when paired with not allowing different compilers).
Add this to
#define MY_LIBRARY_EXTERN extern
And in some consuming class definition (before you declare the class itself):
// force exporting of templates
MY_LIBRARY_EXTERN template class MY_LIBRARY_PUBLIC std::allocator<int>;
MY_LIBRARY_EXTERN template class MY_LIBRARY_PUBLIC std::vector<int, std::allocator<int> >;
class MY_LIBRARY_PUBLIC MyObject
This is almost completely perfect...the compiler won't yell at you and life will be good, unless your compiler starts changing the way it fills in templates and you recompile one of the libraries and not the other (and even then, it might still work...sometimes).
Keep in mind that if you're using things like partial template specialization (or type traits or any of the more advanced template metaprogramming stuff), all the producer and all its consumers are seeing the same template specializations. As in, if you have a specialized implementation of
ints or whatever, if the producer sees the one for
int but the consumer does not, the consumer will happily create the wrong type of
vector<T>, which will cause all sorts of really screwed up bugs. So be very careful.