Isn't this pretty much the same thing as making C a template <typename Foo>?

Yes, but you can't choose a specialization at runtime unless you do it manually...you can only choose a specific template at compile-time, meaning you can't wrap compile-time polymorphism with run-time polymorphism without doing the type checks yourself manually, which is error prone and fragile. This method is basically having the compiler do it for you, based on runtime information.

Well the right foo has to be chosen manually anyway, so I don't really see the difference. Well, one can now put multiple Cs with different foos in one container - but this will probably never happen since C has virtual functions itself and one probably wants container<unique_ptr<SomeInterface>>.

What do you mean "foo has to be chosen manually"? It's done at runtime, and you don't need an exhaustive type tree to do it...you just specialize for the types you know.

Yes, exactly, you call through SomeInterface, and you dynamically get the right C_FooX, but you then statically call the right FooX. Or you statically call C and it dynamically gets you the right FooX. Two virtual calls instead of one, and you can do this to however arbitrary nesting level as long as the type information is in the current TU, and it's resilient against additional types being added in other TUs (so you don't need whole program analysis).

(The big problem is that, unlike templates, you don't know which of these specializations you actually need until runtime, so if you do it blindly you'll duplicate huge amounts of code...so you need heuristics or programmer hints)

This ideone.com/71VWTG should produce perfect instructions. There's only one virtual call if we know the type. I don't really see the problem. :)

but you instantiated a template over foo! that's the whole point...what if foo was passed to you from elsewhere? Also, the call foo_->foo(); will not be reliably statically dispatched...it might here, with flow analysis, since everything is in one TU, but you can create a unique_ptr<Foo> that holds a subtype of Foo. Just because it's a unique_ptr<Foo> doesn't provide any guarantee that it's non-polymorphic because there's no syntax in C++ for specifying a non-polymorphic pointer to a polymorphic type.

It is not only statically dispatched, the function disappears completely (gets inlined), because we already know the exact type. If we do not know the type I just pass an unique_ptr<foo_base>, as demonstrated. Edit: Note that the type of the template parameter does not have to be polymorphic! It can be anything you want!

That relies on flow analysis that might not be reliable. What if you were passed a unique_ptr<Foo> from another TU? There's no way to know it actually holds a Foo rather than a subtype of Foo. And the point is, in the unique_ptr<foo_base> case there will be two virtual calls instead one one.

Look, I program with templates all the time :) I'm not saying they don't work when you have compile time type information. In fact, they work so well, I think the compiler should generate pseudo-templates them automatically so they can be used when you don't have compile-time type information. That's the whole point.

Yes, of course, because the unique_ptr<foo_base> class demonstrates the unknown case. And it is definitely reliable that the other call gets inlined because it is not virtual. That's the whole point.

Hi :)

Sorry, I saw what you did so I was wrong on the flow analysis part...

But you still need to instantiate the template explicitly

You can't use this is you were passed an arbitrary foo from some other TU

The point is, you compile this TU with knowledge of Foo's subtypes, so when a foo comes a long that has the right type, you switch to the right C automatically.

Well I can still use it, it's just going to be 2 virtual calls then - but that's also the case for the compiler optimization

Well, this is how a compiler could optimize it

By dynamically doing something like what you did

That's what I'm asking...is that legal? :)

I don't see what you're not understanding

It's actually better, because the call can get completely inlined even if one does more than forward the call. Also, it doesn't introduce object-creation overhead. ;)

I really don't know what you mean. I'm not arguing that templates don't work better...obviously if you have compile-time info you can do more than if you only have run-time info.

That's not the point.

The point is, you can't take an arbitrary foo that you have no idea of its concrete type (it might even be one you don't know about at compile-time) and get an appropriate "templated" type for it.

Well.. it kinda is, if you don't have any compile-time info the optimization gets impossible as well.

That's the point, isn't it? Knowing some of the types and optimizing with that knowledge

The set of cases where you have the type information available is larger than the set of cases where you have the exactly runtime information for specific variables.

You can know that types FooA, FooB, and FooC exist at runtime

and have no idea whether a particular foo given to you from another TU is one of them

in that case, you can't use a template unless you check the typeid manually and do it yourself

(so you have to add more cases every time a new type is added)

Anyway, just because you can do it with templates in some situations doesn't mean you should be forced to, either

The point is, the compiler could theoretically figure this out and do it for you

I don't think any do and I'm curious if it's legal

Does that make sense?

It probably is legal, as soon as there's a virtual somewhere the standard pretty much stop guaranteeing anything about the memory layout etc.

Sorry I mean "You can know that types FooA, FooB, and FooC exist at compile-time"

Yeah, that's all I'm asking :)

I think so too

But who knows?

The trick is, you can eliminate 10 levels of indirection this way just as easily as 1

The problem is you end up creating lots of specializations that may or may not be used and checking for them at runtime

So I can see why nobody does it (if indeed nobody does)

Well it has some drawbacks. First of all the creation overhead can get really big (really, typeid stuff is 10x more expensive than virtual calls as you probably know), so, that's a thing. And then: Who does really use extensive virtual calls if he wants performance? So, it's a quite complicated optimization that probably isn't going to help too much people.

*many

My english is horrible so late at night^^

You can make typeid faster

It doesn't have to do the entire typeid thing, that's just the only way to express it

Anyway, it might not help that much, because everyone does templates anyway for this

But how do you expose a templated type outside C++?

That's a problem

You don't, yeah^^

Exactly, no one outside of the C++ compiler knows anything about the templates

You have to make some manual interface between dynamic and static dispatch

This does it for you automatically

So it has non-zero usefullness

I'm not saying it's that great, it's just an idea and was worth about 1/3 of a thesis

(I went through a lot more cases than this, but this is the general idea)

It could definitely speed up some programs, but the problem is it does the speedup in places where speed doesn't seem to matter anyway^^

Yeah, premature optimization and all

Totally understand, that's why I didn't bother adding this to gcc or clang myself or something like that

I just implemented it in my own dopey compiler

Because if speed matters in that place one probably has to change the design anyway^^

Well, but you can imagine some other language (maybe not C++) that isn't very hard to learn but the same technique is used automatically

so people get most of the benefits of templates

without actually having to understand compile-time vs run-time polymorphism

say, Java

(since it doesn't have true generics right now)

If C++ wouldn't have a completely messed-up build system template-like optimizations would probably a lot more common^^ Just hoping for C++17

I think lots of people have a hard time understanding how compile-time polymorphism and run-time polymorphism are basically orthogonal to each other (Java doesn't help, because it implements generics with run-time polymorphism)

So this would be a useful technique in making things easier for those people

Obviously, I use templates whenever I can

But it's a pain when you have this huge templated hierachy and people keep messing it up because they don't understand compile-time polymorphism

Should get better with concepts

This way, you just have one type of polymorphism and you have the compile do its best to make some parts compile-time and some parts run-time

Sure

I mean, I worked with some really smart quants in finance that can do very complicated numerical algorithms but can't figure out why they can't make a pointer that can point to any instantiation of a templated type

Well it's not really a compile-time optimization. With concepts one could actually do the thing I did more or less automatically. Just take a object from concept HasFoo (or something like that) - here foo() can be virtual or non-virtual -> bam^^

Yeah, but your hierachy has to be designed around compile-time polymorphism

I always do that, but many people don't

So the idea is, you have this run-time hierachy, but you basically creating all the corresponding templates for it, and you expose it to the outside world through constructors

Not quite, not quite. If we have modules at the same time, it becomes irrelevant what is in which TU. This way, one can just always take concepts without hurting compile-time and having everything exposed in header files (like it is now with templates). And now the "user" can decide what to use. :)

and those constructor calls basically choose the right "template" at runtime, and everything is statically bound after that

so you have one "lookup the right specialization" step at the constructor and you stop paying for virtual dispatch after that

well, right, if you're pure c++ and everyone understands templates then you're fine

but you don't always have that luxury

you might need to expose a dynamically bound interface to someone else

right now, you're basically screwed if all you have is compile-time polymorphism under the hood

(possibly you can do so macro magic to fix that ::shrug::)

but that's macros, templates, and virtual functions

three types of polymorphism to mix together to make it all seamless

Doesn't work for other languages as well the macro thing^^ Maybe for C

i mean macros at the entry points

so you macro some conversion between runtime types and compile-time types

at the functions you're exposing externally

i can't think of a better way than that

because no matter what you have to find some what of hiding instantiatation of compile-time types behind some runtime checking

this is basically doing it for you automatically

Oh well, that'd be a pain, I don't even think it's possible.^^ But my point being: If one has to interface with another language one better do it in few, very heavy calls because that shit is going to be quite heavy anyway. So I don't care too much about optimizing that stuff

maybe, someone else might though

it's not necessary that it's one heavy call either

make_me_this_crazy_factory(arg0, arg1, arg2, arg3, arg4)

and everything else is "virtual calls" after that

on the factory or objects created by the factory

make_me_this_crazy_factory can create a factory object exactly specialized for the exact data in every single argument

(in theory)

so after that, you pay only one level on indirection cost per call, no matter how deep it goes into your compile-time hierachy

and this might be something in-process, not some out-of-process CORBA or COM thing

so it might be much much much faster

But in that case the language that creates the hierarchy has to make the optimization, not the one calling make_me_this_crazy_factory

well, you're the one doing the factory and you're doing it in C++

with this optimization

and the caller of make_me_this_crazy_factory doesn't know anything about compile-time types

it might be python or something like that

-> If it is done in C++ I can use templates for everything but the last type :p

So in the end, maybe you should ask Java to do this kind of optimization for C++? :D

yeah, but how are you going to implement that last type? :D

that's the kicker

actually, it might not be that hard

but who knows

depends on the hierachy and the entry point signatures

well, Java will never handle compile-time polymorphism because the JVM can't handle it, and it would have to be able to parse C++ to access your templates anyway

since they basically don't exist after compile-time

But Java could do your "virtual fold" thing at runtime ;)

well, that's asking a lot

especially since there's no stable ABI

how the hell is Java going to figure out your template hierachy from your mangled exported symbols??

:D

And Java doesn't even have templates as alternative, so it might even make stuff a lot faster - I mean, virtual calls are much more common there anyway

oh sorry

I think I know what you mean

I don't know if any JVMs do class specialization at runtime

I mean, if anyone could (and probably should) erase virtual calls at runtime it's Java

there was a research paper that someone wrote doing this (that I found independently of my work)

but i don't know if it's implemented anywhere

i think they just do the thing where they check at the call site

with a call guard

on the actual call, kind of like branch prediction

but nothing where you make a whole new vtable

pharm.ece.wisc.edu/papers/cgo4.pdf

there you go (i never published my thesis, myself...just an undergrad)

anyway, I hear you--definitely Java should do this and it would be much easier there to guarantee that it works without breaking things

(some asshole could always muck around with vptrs manually in C++)

If you do, do it for Java, these guys are much more appreciative about stuff like that, C++ programmers are just weirdos that want to do everything at runtime with their precious templates^^

at compile-time you mean

ah yea

It's late <.<

yeah, but then I'd have to learn Java :D

and who wants to do that?

Oh, learning Java was the first thing I had to do at my university. Before that my opinion of Java was pretty neutral, didn't have big interest since it didn't solve any problems I had it C++.

Now, since I know Java, I absolutely hate it. It's such a horrible language. xD

yeah, fake generics

that's terrible

this could probably be done in C# too, but it would be less novel

It feels like someone designed it with 6th graders in mind as a pure teaching language. And then people started actually using it and they hacked all the "advanced" features into the language. ^^

since they've got real generics at the CLR level too

well, anyway, I still put the question up

I mean, I'm really not a fanboy of any language. I actually think C++ is completely broken without concepts and modules. (Because Templates are just horrible without these features.) But Java has a special hate-place in my heart.

hopefully someone can answer it

i suspect it's all kosher

i can't think of as reason it wouldn't be

well, you can use C#

that's not that bad

The problem with the question is that it's pretty much not answerable as long as you haven't memorized half of the standard.^^

and in C# you can even have a generic where the recursion depth is dynamic based on runtime info

since generics are JIT-compiled as they're expanded

that's kind of neat

in C++, your recursion has to terminate at compile-time

I actually think that's a good thing^^

i'm positive some crazy meta-programmer has taken advantage of that to do something :D

haha, ok

well, it's just something you can do

obviously it's more performant the C++ way, no JIT to run at runtime

I'm not even too worried about performance here. I just think recursion can generate unexpected results, so I'd rather use it carefully

well, you can probably implement your entire logic using runtime generic instantiation in C#

pretty sure it's Turing-complete

you can only do that in C++ if all your inputs are constexprs

Hehe, Generic-Meta-Programming :p

anyway...yeah, maybe I'll do this in Java

i wonder if it's done

I'm guessing not

Hopefully the implementation language is C++, at least

(HotSpot is, I think)

Well, I really have to go to bed. good night :)

ok, thanks for chatting