The only portable way of using templates at the moment is to implement them in header files by using inline functions.
Why is this?
Because when instantiating a template, the compiler creates a new class with the given template argument. For example:
When reading this line, the compiler will create a new class (let's call it
Consequently, the compiler needs to have access to the implementation of the methods, to instantiate them with the template argument (in this case
A common solution to this is to write the template declaration in a header file, then implement the class in an implementation file (for example .tpp), and include this implementation file at the end of the header.
This way, implementation is still separated from declaration, but is accessible to the compiler.
Another solution is to keep the implementation separated, and explicitly instantiate all the template instances you'll need:
If my explanation isn't clear enough, you can have a look at the C++ FaqLite on this subject.
Plenty correct answers here, but I wanted to add this (for completeness):
If you, at the bottom of the implementation cpp file, do explicit instantiation of all the types the template will be used with, the linker will be able to find them as usual.
Edit: Adding example of explicit template instantiation. Used after the template has been defined, and all member functions has been defined.
This will instantiate (and thus make available to the linker) the class and all its member functions (only). Similar syntax works for template functions, so if you have non-member operator overloads you may need to do the same for those.
The above example is fairly useless since vector is fully defined in headers, except when a common include file (precompiled header?) uses
It's because of the requirement for separate compilation and because templates are instantiation-style polymorphism.
Lets get a little closer to concrete for an explanation. Say I've got the following files:
Separate compilation means I should be able to compile foo.cpp independently from bar.cpp. The compiler does all the hard work of analysis, optimization, and code generation on each compilation unit completely independently; we don't need to do whole-program analysis. It's only the linker that needs to handle the entire program at once, and the linker's job is substantially easier.
bar.cpp doesn't even need to exist when I compile foo.cpp, but I should still be able to link the foo.o I already had together with the bar.o I've only just produced, without needing to recompile foo.cpp. foo.cpp could even be compiled into a dynamic library, distributed somewhere else without foo.cpp, and linked with code they write years after I wrote foo.cpp.
"Instantiation-style polymorphism" means that the template
So when foo.cpp is compiled, the compiler can't see bar.cpp to know that
If foo.cpp itself uses
You might think that when compiling a template the compiler should "generate all versions", with the ones that are never used being filtered out during linking. Aside from the huge overhead and the extreme difficulties such an approach would face because "type modifier" features like pointers and arrays allow even just the built-in types to give rise to an infinite number of types, what happens when I now extend my program by adding:
There is no possible way that this could work unless we either
Nobody likes (1), because whole-program-analysis compilation systems take forever to compile , and because it makes it impossible to distribute compiled libraries without the source code. So we have (2) instead.
Templates need to be instantiated by the compiler before actually compiling them into object code. This instantiation can only be achieved if the template arguments are known. Now imagine a scenario where a tempate function is declared in
One can argue that compiers can be made smarter to "look ahead" for all uses of the template, but I'm sure that it wouldn't be difficult to create recursive or otherwise complicated scenarios. AFAIK, compliers don't do such look aheads. As Anton pointed out, some compilers support explicit export decarations of tempate instantiations, but not all compilers support it (yet?).
Actually, the C++ standard defines the 'export' keyword that would make it possible to simply declare templates in a header file and implement them elsewhere.
Unfortunately, none of the popular compilers implements this keyword. The only one I know about is the frontend written by the Edison Design Group, which is used by the Comeau C++ compiler. All others are stuck with having to write templates in header files, because the compiler needs the definition of the code for proper instantiation (as others pointed out already).
Although standard C++ has no such requirement, some compilers require that all function and class templates need to be made available in every translation unit they are used. In effect, for those compilers, the bodies of template functions must be made available in a header file. To repeat: that means those compilers won't allow them to be defined in non-header files such as .cpp files
There is an export keyword which is supposed to mitigate this problem, but it's nowhere close to being portable.
Templates must be used in headers because the compiler needs to instantiate different versions of the code, depending on the parameters given/deduced for template parameters. Remember that a template doesn't represent code directly, but a template for several versions of that code.
When you compile a non-template function in a
There was a feature with the
For separate compilation to be achieved, separate template body checking must be possible. It seems that a solution is possible with concepts. Take a look at this paper recently presented at the standards commitee meeting. I think this is not the only requirement, since you still need to instantiate code for the template code in user code.
The separate compilation problem for templates I guess it's also a problem that is arising with the migration to modules, which is currently being worked.
That is exactly correct because the compiler has to know what type it is for allocation. So template classes, functions, enums,etc.. must be implemented as well in the header file if it is to be made public or part of a library (static or dynamic) because header files are NOT compiled unlike the c/cpp files which are. If the compiler doesn't know the type is can't compile it. In .Net it can because all objects derive from the Object class. This is not .Net.
It means that the most portable way to define method implementations of template classes is to define them inside the template class definition.
I recently was refactoring some code and I ran into a special case of this situation: a method was taking a
In code this means:
can be replaced by
In both ways you can call the function like this:
note: example taken from cprogramming.com.
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