My question is related to exporting a C++ class with STL inside. For example:

class __declspec(dllexport) Hello
    std::string   name;

    std::string&  getName();
    void          setName(const std::string& name);

Various articles seems to indicate that this is very bad, which is quite understandable. Everything must be compiled with the same compiler settings and CRT version. Otherwise everything will crash and burn.


What I don't understand is why only data members seem to have an issue. With the below code, I get: "C4251: needs to have dll-interface to be used by clients of class"; which is apparently fixed by exporting the instantiated std::string:

struct __declspec(dllexport) SomeClass
    // Removes the warning?
    // http://www.unknownroad.com/rtfm/VisualStudio/warningC4251.html
    //   template class __declspec(dllexport) std::string;

    std::string name;  // Compiler balks at this

And the fixed version is:

// Export the instantiations of allocator and basic_string
template class __declspec(dllexport) std::allocator<char>;
template class __declspec(dllexport) std::basic_string<char, std::char_traits<char>, std::allocator<char> >;

struct __declspec(dllexport) SomeClass
    std::string name;  // No more balking!

(This will give LNK2005 "basic_string already defined" when you try to use the DLL, meaning you have to not link in the CRT on the client - so it ends up using the instantiation in the DLL).

Return types and arguments seem to have no problem with the STL, and do not receive the same treatment data members get from the compiler.

// No exporting required?
struct __declspec(dllexport) SomeOtherClass
    std::string  doSomething1();                       // No problemo
    void         doSomething2(const std::string& s);   // No problemo

Additional Info (Question is above)

In both:

class A {
    std::string foo() { return std::string(); }
    // std::string& foo(); gives the same result!
    // std::string* foo(); also gives the same result!

class B {
    std::string a;

Neither seem to export std::basic_string or std::allocator. Rather, they only export the members/functions of the class.

However the fixed version mentioned in the question exports both basic_string and allocator.

  • I'm assuming you meant to type std::string and not stl::string in class Hello. Change the getName() member function to return the string by value and you'll probably get the same warning. Also, it's not just the same CRT version you have to maintain, but if you're passing types that manage memory (such as string) across a DLL boundary, then you need to have both the DLL and the client dynamically link to the CRT; static linking will not work.
    – Praetorian
    Dec 13, 2012 at 16:51
  • Ah yes, bad typo. I did try getting the function to return by value and there doesn't seem to be any complaints from MSVC. I compared function vs variable in dependency walker, which I'll update my post with
    – yiyang-dev
    Dec 13, 2012 at 17:05
  • 1
    "very bad" is relative.. we do this the whole time, everywhere except where interfacing with 3rd party code, and never got problems. It's just a matter of having a clean build setup that automatically makes projects link to the correct platform/config/static/dynamic version of each lib.
    – stijn
    Dec 13, 2012 at 17:11

2 Answers 2


Various articles seems to indicate that this is very bad

Yes, it can be. And your project settings are going to get you into the kind of trouble they are warning about. Exposing C++ objects by value requires the client of your DLL to use the same CRT so that objects that are created in the DLL can be safely destroyed by the client app. And the other way around. Which requires that these modules use the same heap.

And your project settings prevent that from being possible, the gist of the compiler warning. You must specify the shared version of the CRT so that all modules load the one-and-only implementation of the CRT.

Fix that with Project + Properties, C/C++, Code Generation, Runtime library setting. You have it now at /MT, it must be /MD. Change this for all modules and all configurations.

  • Op understands this perfectly.
    – Basilevs
    Dec 14, 2012 at 7:14
  • 3
    @Bas - What he didn't understand is that he used the wrong compile option. Use the right one and everything comes together without any hacks. That was not stated in the question, he didn't realize it mattered. Original insight, not worth a downvote. Dec 14, 2012 at 8:18

This boils down to how certain things get built.

When the compiler sees

__declspec(dllimport)    std::string f();
// ...

  std::string tmp = f();

It must figure out what to call, and where to get it from. So in this case :

std::string tmp; => sizeof( std::string ), new (__stack_addr) std::string;
tmp = f();       => call f(), operator=( std::string )

But because it sees the complete implementation of std::string it can just use a new instance of the the according template. So it can just instantiate the template functions of std::string and call it a day, and leave the function coalescing to the linker stage, where the linker tries to figure out which functions it can fold into just one. The only unknown function is f() which the compiler must import from the dll itself. (It's marked external for him).

Members are a bigger problem for the compiler. It has to know the according functions to export (constructor,copy-constructor,assignment-operator,destructor call) and when you mark a class as 'dllexport', it must export/import every single one of them. You can export explicitly only certain parts of your class, by declaring only the necessary functions as dllexport (ctor/dtor) and disallow e.g. copying. This way, you don't have to export everything.

One note about std::string is, that its size/contents changed between compiler versions, so that you never can safely copy a std::string between compiler versions. (E.g. in VC6 a string was 3 pointers large, currently it's 16 bytes + size + sizeof allocator, which I think got optimized away in VS2012). You never should use std::string objects in your interface. You may create a dll-exported string implementation that converts on the caller site into a std::string by using non-exported inline functions.

  • I'll try to expand this later (or tomorrow) Dec 13, 2012 at 18:21
  • Thanks for the reply. I'll admit I'm not too familiar with the steps in compilation. I'm a bit confused about how the second paragraph is related. I'm assuming what you're saying is - because the compiler also has to export the constructor for the class, it needs to instantiate std::string for the DLL in order to call the string constructor? EDIT: Nevermind, I seem to be understanding it wrong, since std::string foo() { return std::string(); } doesn't give an error :P
    – yiyang-dev
    Dec 13, 2012 at 18:44

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