@Mysticial I always try to wait a few days before accepting, just to give people time to answer, and then I tend to forget all about it until much later ;)
Updated to sync with the OP's edit
By tinkering with the code, I've managed to see how GCC optimizes the first case.
Before we can understand why they are so different, first we must understand how GCC optimizes fast_trunc_one().
Believe it or not, fast_trunc_one() is being optimized to this:
...
If it gets accepted before the month ends, it'll make it onto the StackMonthly.
It might make it. 33 votes on the question might not be enough.
That has pretty much the same use than saying "I expect to work with a keyboard"
Perhaps they should ask "Do you expect to use a hammer?" (potential answers: (a) all the time (b) only when I see a nail (c) when I'm out of time (d) never)
@SteakOverflow Someone's brain might unvoluntarily have made a subconscious association of 'PHP' with 'developer'. You know how the brain works... There was no rational link of course
Mmh I'm computing the needed padding if pointer p is not aligned for value alignment. alignment - begin % alignment (where begin is the value of p) works but needlessly add alignment bytes if p is already aligned. What's the sane way to express what I want? (alignment - begin % alignment) % alignment doesn't seem like the best.
Ok, I just think it is not correct to compare them. I am a C++ developer now and I've been in PHP as well for years. I can assure it doesn't suck if THE DEVELOPER doesn't suck.
@ScottW I've used VB6 extensively. It's a rotten tool, but so were most competing tools. Just happy to be using better tools now, but I'm still quite convinced I used to build software about as well in VB6 as many would have using Java C#
It was the other way around, when you wanted to use ?: in streaming you have to enclose it in parens like cout << (foo? bar : baz), else you get (cout << foo)? bar : baz
@RMartinhoFernandes Assignment, comma and throw :)
in my code, I have to fit objects into a stack-like buffer, and I found it was easier to fill it "backwards", starting from the highest address. Then if end is the address of the last object allocated (or one past the end of the buffer if it's empty), then I could find a well-aligned address for a new object just with (end - obj_size) & ~(align-1). Basically just zeroing out the lower bits
ah, if you just need to allocate objects of the same type, just make sure the starting address of the buffer is well aligned. Then you just have to increment by sizeof(T) for each object
@LucDanton [ Note: every over-aligned type is or contains a class type to which extended alignment applies (possibly through a non-static data member). — end note ]
@jalf The weirdness of rebind regarding allocators makes sure that the arena has to deal with any type (although requests can come with multiple items, hence the 'n items of type T' above). In practice though only one type will be used, and the weirdness makes sense when taking into account e.g. std::list which won't allocate T's` outright.
@RMartinhoFernandes While I'm not surprised that the resulting array is also over-aligned the question if whether the alignment is still that of the element type. But nevermind those types.
@LucDanton yeah, but if your allocator is only actually going to be used in the simpler case, you don't have to worry about an optimal implementation of other cases. Other types could just be delegated to malloc or something, even
@LucDanton I mean that your allocator only really has to fit objects into your arena/pool if the type is some fixed predetermined value: the one that you intend to put into the pool. Yes, the allocator can be rebound for other types, and then it can just fall back to allocating with malloc or something
as long as you can ensure a single alignment for all objects in an arena, you save all the alignment headaches, speeding up your code (and simplifying it quite a bit too)
(On the other hand with this design it's inconvenient for the user to find the exact memory that he or she needs for N items if using something else than e.g. std::vector.)
If you share an arena with several containers, yes. And no, because deallocate is dumb (and allocate doesn't do bookkeeping). But that's not the preferred use case.
Preferred use case is arena a; std::vector<T, arena_allocator<T>> v(a); /* use v */
So in practice only one type will ever be active in an arena but allocator requirements being what they are well there I am.
Why not? The code has to keep track of the objects, and it doesn't know if they're all the same type/size/alignment or not, even though they typically are
But suppose you know you need to hold N (known at compile-time) elements, but you can't have all of them when constructing the container, and it's not default constructible.
@LucDanton also, I disagree. "borrow" seems to imply that the allocator can just decide to take back the memory at any time. That wouldn't make a valid vector
@Xeo Indeed. Also, no need to assume the type of vector. As long as the result of *(It()) is 'compatible' enough with the implementation of that function
@LucDanton why not? The problem with alloca is that its lifetime is determined when you call alloca. It appends to the current stack frame, and so, when you leave that stack frame, the memory is reclaimed. And so, if you swap that memory into a vector with a longer lifetime, that vector will, when you leave the current stack frame, have its internal array deleted
@jalf The lifetime (if we can call it that) of the memory an std::vector deals with is not tied to the vector itself. I think you'll agree that creating an object of type std::vector<T> doesn't create the free store, and that the free store still exists after such object has expired.
The std::vector does inform the allocator that it's done with it, yes.
@RMartinhoFernandes but is that legal to do? Doesn't vector guarantee that its memory will stay valid throughout its lifetime? Can you write a local allocator (whether with alloca or any other mechanism) which actually follows the standard?
@LucDanton and I'd argue that an implementation in which the free store suddenly vanished during a vector's lifetime would render the vector implementation noncompliant ;)
@LucDanton that's what I'm questioning. Does it follow the standard, when a consequence of it is that the vector might suddenly find its internal array deleted?
@LucDanton so you can write a valid and well-defined iterator which creates a valid and well-defined vector, on which perfectly valid and well-defined operations will lead to undefined behavior?
@IntermediateHacker (Re: Zurker) "A social network with owners, not users" - blargh that is upside down. Should be "with users, not owners" to be any kind of interesting in my book.
@IntermediateHacker (Re: Zurker) Also, already it is secretive from the start. So, who's controlling this beta they speak of? Presumably, those users that can't get in? You know, those users who supposedly are owners? Some users owners are more owners than others.
@RMartinhoFernandes well, no. Normally you get UB when you do something undefined. If I use the vector in the ways that the standard guarantees should work, then I'm pretty sure I shouldn't get any UB
The free store is guaranteed to outlive the vector, so it doesn't matter that the vectors have different lifetimes, because in both cases, their allocator ensures their memory will be available long enough
@thecoshman "However, with the 3.4 release of GCC, the #pragma once handling code was fixed to behave correctly with symbolic and hard links. The feature was "un-deprecated" and the warning removed."
Hey, wasn't the reputation count supposed to never drift again since a few months ago?
> I was able to bowl in the arena with a debug cart ball and aardvark pins, with various cascades and skidding. Nothing against aardvarks -- the alphabet just works against them for once.
Dammit Toady, stop playing games and give us the damn minecart update!
Updated to sync with the OP's edit
By tinkering with the code, I've managed to see how GCC optimizes the first case.
Before we can understand why they are so different, first we must understand how GCC optimizes fast_trunc_one().
Believe it or not, fast_trunc_one() is being optimized to this:
...
