But see my counter example. It's how I find this "intuitive".
But really, "going inside the type" requires the type to be complete. "getting the size of a type" - ditto and all variations where these are implied (declaring an array of the type, because that requires the size etc)
The type cannot be complete without instantiating. In fact, instantiation may lead to failure.
I've been "victim" of the "every header only means every template can be inlined" approach. It really doesn't scale.
It is still important to go through that "extremist" phase, perhaps, because it taught me that I need to make compromises and exactly where I want to make them so they are acceptable.
@sehe How does that apply exactly? Not sure I entirely understand that principle.
I mean, imagine, we have boost signals in a public header, because that's how signals work, kind of. Now after I've tested the "just PCH it" approach, I can see that certain instantiations "survive" clang's in-PCH instantiation phase, and now I even understand why.
I'd say it's usually possible/fine to hide the signals interface. E.g. making onSignal(boost::function<Signature>&&). This might smell like it would introduce multiple level of virtual dispatch (in the function<> type erasure) but (a) I'd check the profiler that that is significant (b) there is a non-zero chance that the internal representation uses boost::function so there is no additional overhead, instead the actual instance is forwarded
In short there's a 100% chance that the slot callbacks get type erased. So, there is zero reason to try to prevent that. Then the next goal becomes, finding the sweet spot, where you have the least library coupling and the most performance.
@sehe those signals in out project are in the orders of 10(10's) invocations/minute at worst, that is, rare enough not to care about performance (yet). Yet your point makes sense, thanks for the explanation!
Ah, right, I see now, you would try to forward the boost::function into the connect function.