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I want to use the pimpl idiom to avoid having users of my library need our external dependencies (like boost, etc) however when my class is templated that seems to be impossible because the methods must be in the header. Is there something I can do instead?

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up vote 4 down vote accepted

If the class is templated, your users essentially need to compile it (and this is literally true in the most widely-used C++ implementations) and so they need your external dependencies.

The simplest solution is to put the bulk of your class's implementation in a non-template base class (or encapsulated member object of some class). Solve the module-hiding problem there.

And then write the template derived (or enclosing) class to add type safety to it.

For example, suppose you have a template that provides the amazing ability to allocate on first access (omitting the necessary copy constructor, assignment, destructor):

template <class T>
class MyContainer
    T *instance_;

    MyContainer() : instance_(0) {}

    T &access()
        if (instance_ == 0)
            instance_ = new T();

        return *instance_;

If you wanted the "logic" to be separated into a non-template base class, you'd have to parameterise the behaviour in the non-template way, which is to say, use virtual functions:

class MyBase
    void *instance_;

    virtual void *allocate() = 0;

    MyBase() : instance_(0) {}

    void *access()
        if (instance_ == 0)
            instance_ = allocate();

        return instance_;

Then you can add the type-awareness in the outer layer:

template <class T>
class MyContainer : MyBase
    virtual void *allocate()
        { return new T(); }

    T &access()
        { return *(reinterpret_cast<T *>(MyBase::access())); }

i.e. You use virtual functions to allow the template to "fill in" the type-dependent operations. Obviously this pattern would only really make sense if you have some business logic that is worth the effort of hiding.

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I think this approach could be also useful if you don't want your preprocessor definitions (#define), constants etc. to be visible. As a developer, I don't want to see implementation details of a class/library that I'm using, especially in auto-complete list. You may want to hide those even if your business logic is unworthy of hiding. – mostruash Apr 16 '14 at 12:43

There are two general solutions:

  • while the interface depends on some type T, it defers to a more weakly typed implementation (e.g. one using void* pointers directly or trough type erasure), or

  • you support only a specific and quite limited number of types.

The second solution is relevant for e.g. char/wchar_t-dependent stuff.

The first solution was quite common in the early days of C++ templates, because at that time compilers were not good at recognizing commonalities in the generated machine code, and would introduce so called “code bloat”. Today, much to the surprise of any novice who tries it out, a templated solution can often have smaller machine code footprint than a solution relying on runtime polymorphism. Of course, YMMV.

Cheers & hth.,

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Someone's attempted edit suggested removing the "directly or through type erasure" elaboration and the "specific and..." qualification. The elaboration is necessary for meaning, and the qualification is necessary for correctness. The current accepted-as-solution answer is an example of the "directly". There is as yet no example of "type erasure", and the only mention is in this answer; it would be a shame if someone succeeded in deleting that. – Cheers and hth. - Alf Apr 10 '14 at 19:12

You can explicitly instantiate templates in the source file, but that is possible only if you know what the template type is going to be. Otherwise, do not use pimpl idiom for templates.

Something like this :

header.hpp :

#ifndef HEADER_HPP
#define HEADER_HPP

template< typename T >
class A
  // constructor+methods + pimpl


source.cpp :

#include "header.hpp"

// implementation

// explicitly instantiate for types that will be used
template class A< int >;
template class A< float >;
// etc...
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-1 Don't use auto_ptr for PIMPL (it's undefined behavior to instantiate auto_ptr with an incomplete type). It does work if you define both constructor and destructor for the outer class. But in that case you don't need a smart pointer. – Cheers and hth. - Alf Oct 22 '11 at 8:29
Yes, both OK (although I'm not sure about the details of how to use unique_ptr in this case; I would just use shared_ptr and accept the overhead as the cost of not requiring people to read fine print in the standard). Cheers, – Cheers and hth. - Alf Oct 22 '11 at 8:33
unique_ptr also requires a user-defined destructor, just like auto_ptr did. I don't see this as an issue, honestly... it doesn't have to do anything, just not be compiler generated, and show up after Impl is completed. – Dennis Zickefoose Oct 22 '11 at 8:49
@DanielEarwicker in A's copy ctor member initialization list you would write pimpl(new *right.pimpl.get()). The usage you described isn't copying pimpl, it's sharing it. That is a very big difference and usually one that would be undesired and broken - however it could be a design choice to do it that way. And btw, to address your last line ego trip thing - don't do that unless you're RIGHT. – David Oct 22 '11 at 11:02
@DanielEarwicker Read #2. – David Dec 20 '11 at 4:17

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