@Xaade: Generating the types occurs before generating ast/asm

but first, you would have to find out for which U this was used

then, if you had a std::vector<T>, where T has a base but the conversion to U is never used, the compiler never inherits and you don't pay any cost

For all U which are a base of T? Wouldn't that imply multi-inheritance?

not really

because interface<U> is a different type for every U

Oh... all Uwhich are a base of T, you really mean.... for all T: public U pairs

although I guess you do run into problems if you have complex inheritance hierarchies

you would have to respect virtual inheritance

well

because when you're finished doing

template<typename T> class vector ... { ... }; you don't have the full type

it only instantiates the inheritance for each U for which that instantiation is actually requested

after all, if you have a type T which has an inheritance hierarchy, you may not need this feature just because T has inheritance

I got that... it creates new types for each "type" used by creating a variable of said template giving it a type.

@DeadMG, See aldor.org for a quite different approach on typing.

Kinda like a macro doesn't actually mean anything unless you use it, and it creates the code from what you give the macro.

I'm not really sure what you are trying to do. Thinking about potential extension of C++ or something less constrained?

something less constrained

AH I got it

@Xaade: Not really

because macros don't change other macros

you can't have a macro that means X, unless I used macro Y down there, in which case it means Z

Looking at Aldor and Haskell is probably then a must if you want to know what has been done.

(and there are surely things I don't know which would be interesting)

You're trying to avoid building multiple classes with inheritance structures because then you incur the loss for each inheritance. So instead you have a template derive from another template giving each a base class.... which means the inheritance isn't compiled until you actually use a class of that type.

There is also the whole Aspect programming set of things which could be related.

Why not instead give a template two "classes", then use inheritance by delegation.

@Xaade: What do you mean?

Well, you'd have to make the members public in the "base" class, then have the template cross the methods from one class to call the base class..... by delegation.

show me some code

even crappy pseudocode

Go interfaces and the old G++ signature extension could also be of value to you. (Instead of trying to have declared subtyping relationship, use an infered one -- very similar to the way C++ handle template argument validity and what the concept proposals where out to do, execepted as a dynamic behaviour)

Let me lookup template real quick, been a while since I made one.

@AProgrammer: I'm doing both

or rather, ahem, considering both

technically, I'm not actually doing anything

right now, in C++, you can implement using proxy objects, for compile-time polymorphism

but it's hard to define how you could implement at run-time polymorphism

std::vector<std::vector<Object>* const> objects;
// Insert a pointer to a std::vector<Derived> and a std::vector<Derived1>?

ahem

damn, I always put that const in the wrong place

@DeadMG, look out for type erasure, that may help you.

Well, for right now the only way I could see my idea working is if you used methods that described whether the derived class handled the method call or not.

oh I know I can use type erasure

the problem is how to know which vector<T> needs it and to erase what types

hell, this is a type erasure system

Ok, I got it.

that occurs at run-time

this is a static system

what occurs at runtime?

function pointers and blablabla

my concept is, the whole thing is determined at compile-time about what runtime polymorphism is involved

Well, it would eliminate the cost of inheritance. I'm sorry, I thought that's what you wanted.

no, no

the point is how to determine when to invoke inheritance

as in, the inheritance cost should not be paid for any type where the feature is not used

but regular inheritance is a perfectly valid cost and indeed the correct implementation method, if you can determine that it's necessary

You mean that you want the compiler to determine whether TYPE A needs to inherit from TYPE B?

yep

and a whole lot more too, but we'll stick to this specific example

The only way I can think of that working is by using macros.... but then that's horrible to check compiling.

well

I had considered that it would be implemented by, like, implementing a new language

but that's far beyond the scope of what I can do in my spare time :P

Like, CREATENEWDERIVED (DerivedClass, BaseClass)

you still can't do that

I did that kind of thing for implementing interface implementing....

because once DerivedClass is defined, you can't make it inherit from BaseClass later

yeah you can.... you make the definition of Derived class be the macro itself.... Like I said, horrible to compile but at least you can change it on the fly.

sure

MFC type checking does this kinda.

but if I define DerivedClass in the macro, how am I going to use it before the macro is invoked?

How do you use a type created by a template before the line of code that instantiates the object?

you can't

So, what's the difference.

at least, not in C++

the difference is that I want to support that

You want to use an object before it's instantiated?

no, I want to instantiate it, then modify it's type later

How could the compiler ever know what methods to call, much less what methods are implemented..... forgiving linking the thing worrying about undefined externals?

Oh ok....

multiple pass compilation

hmm....

Well let's see...

pass 1: oh look, std::vector<T> was converted to std::const_vector_interface<U>& here, let's make it inherit

As long as the types share member DATA.... it should be fine.

Hell, you can do this in regular C++ by casting to another class altogether bypassing type checking, and any methods you call will work, as long as the data structure is the same.

You just can't expect the compiler to do any type checking for you anymore.

which is completely unacceptable

the objective of the exercise is to drastically increase the power available to the compiler, not decrease it

That would be another problem you'd run into.... how would type checking work, since you can change it's type at any given time.... the compiler can't know when you'll call what method.... so it can't know the object's type for sure at any given point.

the compiler does a pass and finds all the type modifiers and runs them before checking whether or not the method calls are valid

Like a recursion algorithm that may change an object's type before returning or not.... how would the compiler know what type the object is.

all the type modification takes place at compile-time, not run-time

I really don't think you can do this safely, even in a new language.

I understand that....

Ok.... here try this.

uh

because you tried to convert at run-time?

...

How would you convert at compile time?

the compiler does the first pass, and then if the system time (at compiletime...? your example, not mine) is 0 modulo 2, then it replaces the Car type with the Plane type

I mean, that's not really something that I had in mind

each type dictates how it can or cannot be modified

and methods cannot be removed, only added

So the only conditionals that could surround your "converts" must be those that can be determined at compile time?

yes

typically, a conversion would occur per template instantiation

And the class converted to must implement all methods and data that the first class had.

you can't convert types, I never said that you can convert them

they are template-based additions

class Vector {
    template<typename T> std::vector<T> vec;
};
int main() {
    Vector somevec;
    somevec.vec<float>.push_back(1.0f);
    somevec.vec<int>.push_back(1);
}

Well, why didn't you say that before.....

argh, I hate pseudocoding in this chat, the markdown problems suck

I did

Sorry, didn't understand you

or rather, I never demonstrated any ability other than inheriting from additional bases

and certainly not total replacement

That seems eerily similar to Visual Basic's variant types

never used

it is what you want to be whenever you want it to be that.... except instead of implementing EVERYTHING like variant does.... you'd want the compiler to implement only what you ask it to.

it was my understanding that the VARIANT types were run-time polymorphic

yeah

Ok, the way a variant works. It implements ALL possible types

Then whatever you put into it, it "makes" it that type as long as it stores that value.

like boost::any

This works by basically implementing a flag in the Variant that stores its type.

SOOOOOO......

What you could do, is make it somehow like a variant, except as you "change its type" the compiler would add that type to its list.... or as you said earlier, reimplement as the new type as long as that type encompassing the previous type.

Anything I can think of so far..... results in run-time checking.

yeah

the thing is that right now, you can't reflect upon your own program

like

you can't do, for every std::vector<int>, add 1 to this counter

unless you happen to own std::vector<int>

So, a multipass compile would check your "magic template" and compile it as the most encompassing type that it found your code using.

no, not really

the modification is not defined as how encompassing it is or something like that

it's defined in the modified class

How's its defined doesn't matter

template<typename T> class vector : public template<typename U> interface<U> {}

The point is that the compiler would compile it as the type that encompassed everything you used it for...

I think we have a different definition of encompassing

but I think the answer is yes

It would compile it as the type that contained everything needed to execute the code the variable used.

if that type is legal

like, in my example with the member vector, not all types can be passed to a vector

In that code above, T would have to implement everything U had in it's interface.

no

vector<T> would implement everything interface<U> had to offer, for all uses of it's inheritance of U

Darn... I am interested in the discussion, but I don't have time to even read/understand what has been said today!

@DavidRodríguezdribeas I know the pain...

BTW, if the potential base object does not have data (nor virtual methods), there is no cost associated to always inheriting from it. Now the question is whether the whole thing that I have not read can be implemented without dynamic polymorphism

you really need to read the whole thing

omg, how much conversation do you want! That just keeps on going :P

@thecoshman Sounds like something you would say to your girlfriend...

@FredO: lols

@DeadMG Are you "Mark" on Channel9? I recognized your puppy :)

lol

why yes

and my puppy goes there?

wow, it does

I like doing that with the star.....

mwa ha ha ha hah

@DeadMG Are you sure????

@Xaade: Am I sure about what?

Look at the starred column

hahahahhahah

I'm going to lose star privileges

lol

you are

Yeah.... I blanketed the thing.... but it's crackin me up

In the odd chance that one of you knows:

lol facebook.com/…

@sbi: I guess it's not inconsiderable possibility, but actually finding such is another matter?

@sbi: I wouldn't really know

how much disruption are you gonna cause the wife & kids?

@FredOverflow wait... do you know me in real life or something?

@DeadMG I wasn't being serious. (@Tony could explain the concept of exaggeration to you. :) ) I'm not going to do that to my kids unless the alternative is worse.

@sbi: lols

man

I wish I could do concurrency at university

:)

been assigned more PROLOG coursework and it makes me cry inside

hehe

not funny :(

I'm proud to say I never got the hang of prolog :p

made my brain feel upside down

PROLOG sucks

it's unintelligible

it's an interesting language. It's just not something I want to write code in :p

I prefer to think as

the fundamental concept might be interesting or useful or something

but PROLOG is such a shitty execution that I'll leave well enough alone

:)

Yeah, I can't say I miss it either

@DeadMG Didn't we have this discussion just the other day? You're not going to repeat all your "arguments" and expect us to reply, are you?

I wasn't there!

so I'm allowed to reply

@sbi: That was two months ago, and you completely misunderstood the arguments that I did make, and jalf wasn't here :P

@DeadMG Can't have been more than 10 days, and I wish I wasn't there.

@sbi: It was most definitely more than 10 days

it's been more than 10 days since I went home and visited my parents, and it was long before that

oo, a new and exciting argument

I haven't been cursed with having to write PROLOG since my last assignment, which was a couple of months ago

so it's unlikely that I brought it up since

was it before I got sick? surely, cause that was exam time and I had bigger things to worry about

@DeadMG Then maybe it was another language? Or was it another user? :) It surely feels like last week.

lol

@sbi: Oh, there could have been some other discussion about it last week, I wouldn't really know

and last week/the week before, it was PHP

interesting question, do I hate PHP or PROLOG more

I'd go with PHP

because PROLOG is at least an interesting concept

there is that

but then PHP could be so much more with the addition of some static types

and a redefined library to be object-orientated

yes, it could be a different kind of mess

lol

@DeadMG so what you're saying is, if PHP wasn't PHP, it wouldn't be so bad?

heh

there is that

it's true that PROLOG at least theoretically has a component which is new and different or something

see, I don't understand dynamic typing

like

just, who thought of it and decided it would be a good idea? why is it so popular?

@DeadMG I remember the PHP discussion. That wasn't unreasonable critic.

Dynamic typing is simple and easy and convenient, and you don't have to listen to a whiny compiler ;)

you'd think that programmers would know better

not at all

also most people who favor dynamic typing do so because they don't realize that proper statically typed languages allow type inference

even if they didn't

they compare it against Java where you spend all your time writing types

List<int> list = new List<int>()

or C or depending on circumstances, C++

I'd still rather spend all my time writing types

because ultimately, type mismatch detected by compiler prevents bugs

Why? You're telling the compiler something it already knows better than you

bugs that are gonna take me ten times as much time to fix at run-time

I want the compiler to tell me the types

@jalf: Compared to dynamic typing

not compared to my personal miracles of auto, decltype :P

I think the counter-argument is that because the language is so lenient, it's very easy to write lots of unit tests to compensate

only if the unit tests work

can be a pain to do that in C++, because if you set a foot wrong, one of your tests won't compile, and then none of them can be run

in python, you just write your tests, and if one of them has a problem, you'll find out when you run them, and it won't affect all the other tests

but then you don't have to spend six hours debugging why the test won't work at run-time

don't have any experience with Python

and whilst it seems a silly language to me, I've never used it and thus will not criticise it

I don't think people usually spend 6 hours debugging tests in python ;)

that's kind of the point

unlike prolog or php

anyway, it seems to work in practice. People using those languages are productive

miracle how that happens

you know

dynamic typing worked OK in Lua

which kind of voids any argument about how it only leads to more time wasted

productive != more productive than a statically typed language

well, most people seem to be more productive in (good) dynamically typed languages than in the clumsy old C-related statically typed ones

hmmm

I'm much more than competent in C++; learning and then using Python for some tasks increased my overall productivity

I'll admit, C++ has plenty of it's own pitfalls

But like I said, I don't think that's because dynamic typing is inherently better. Just because C-derived languages are terrible examples of static typing

not necessarily

I think that C-derived languages just have a whole host of problems of being C-derived

especially C++

but most people have never encountered a good example of a statically typed language, and so they assume that only dynamically typed languages can take away the pain of having to specify types all over the place

then Java and C#, they have plenty of problems originating from the dynamic/JIT orgasm

Java and C# aren't dynamically typed

I know

and I consider both to be C-derived as well

I meant, how they're built, as languages

like, everything off the heap, etc

because they're managed

they suffer from the same problems as C and C++ in that respect. Stupid syntax that requires the user to babysit the compiler

ah

that's a different discussion though

indeed it is

imo, it's not about stupid syntax per se

Anyway, I think I'm going to have to leave you before I pass out! 'night folks!

more like, the compiler technology isn't advancing as fast as what we can do with it

night

@DeadMG are you ranting again? I checked in earlier and you where on one :P

It is stupid syntax. Compilers have been good enough to infer types for 15 years

it's just never been applied to the C family of languages because they suck syntax-wise

other statically typed languages solved the problem ages ago

@jalf: Bjarne said auto in 1983, but didn't because of compatibility with C

I would join in this, but I only really understand what statically and dynamically typed mean. And whilst I have used languages from both type, I can't rally say I noticed any preference. Dynamic is nice in that you don't need to worry about types, but their is the odd time it can trip you up. Static is nice because it means you are forced to think a bit more about what you are doing. As far as performance is concerned, I have no idea.

@thecoshman No, just a general observation.

"You" as in "one", not you specifically.

from a TDD point of view, at the very least, static typing is redundant busywork

I don't follow TDD exclusively, but it is valuable; and it's all too easy to focus on fixing compiler problems so that you either ignore or don't have time to explore other issues

@FredOverflow figured that would be what you meant. she does rant on about her sowing and knitting stuff. The strange thing is, I get hooked up on the 'knitting physics'

to the point I learnt to knit so I could understand it better :P

@jalf Neither can you use int as a type argument in Java, nor can you instantiate interfaces ;)

@FredOverflow Its much better, you don't need to provide the type at all! List l = new ArrayList();

I just watched Herb Sutter's Lambdas talk he gave at PDC last year

I finally have an understanding on how to use Lambda's in C++. woot woot

:)

Have you used functors much? binders?