On the subject of bullshit questions, anybody know what the latest max size for 3D CUDA/OGL textures would be? I think 4096^3, but I don't have a card to check.
I'm not sure that your interpretation of implementation defined is right in this particular case. The fixed width integer (signed) types, from <cstdint> are "signed integer type with width of exactly 8, 16, 32 and 64 bits respectively with no padding bits and using 2's complement for negative values (provided only if the implementation directly supports the type) ". To my understanding, if they are supported, the cast is well defined. — Bob__17 mins ago
@Mgetz Hm, I thought it's pretty straightforward. Are you saying that some internal implementation detail data of a container will not be allocated via the supplied allocator? Or is the problem something else?
@Mgetz I wouldn't say it's "not designed" for it. They design to get as high as they possibly can. Then they bin appropriately.
It's just that for my particular 7940X, there's 2 or 3 cores that are "so good" that the vcore table entry is set too low.
Those cores are capable of hitting 5 GHz at the right voltage. But they can't do 4.0 GHz light-AVX at the default vcore + 0.030v. All the other cores can because their vcore table entries are set much higher.
In case I lost you there, "good" cores don't need as much voltage to be stable. So they tend to get undervolted and have lower vcore table entries.
But in the case of overclocking, this undervolting overcompensates - thus making the "good" cores less stable than the bad ones.
And I can't override it without a motherboard that supports per-core voltage.
By comparison, my 7900X doesn't have this problem. All but one of the cores can actually do 4.5 GHz heavy-AVX512.
And the one that can't is actually the "best" core and has the lowest vcore table entry. (i.e. the same problem, but to a lesser degree)
@Mysticial no you didn't the quality of the transistors in those cores probably have fewer flaws. IIRC they actually run the calc in parallel because they know some paths are dead in silicon
@Mgetz: quite literally, I'd like to know how much memory a certain std::map takes up. Let's say neither key no values have internal dynamic memory of their own.
@Mysticial That's a little bit of an overstatement. If they were really pushing for the highest possible clock speed, they'd still be using a Prescott-like 30+ stage pipeline. In practice, that gives high clock speed, but uses a lot more power for only minimal gains in execution speed (or possibly even a loss of execution speed, depending on how effective branch prediction is for the code being executed).
a.) because some people don't like how CMake works b.) the project already has a Makefile that was tested and works c.) they may not like CMake, but maybe they're using yet another build engine that's not CMake nor Make
@Mikhail It has to be my judgement that decides whether it is unnecessary or not. My track record is 21 years without this kind of disrespectful behaviour.
@milleniumbug a) Why wouldn't they like it? it is IMO very clear/user-friendly unlike those cryptic Makefiles. But CMake's documentation is indeed not the best out there. b) ok, historical reasons c) anything better than CMake?
Oh, and note that CMake and Make aren't really competing in the same territory. CMake is more of an attempt at making better Autotools, and the only tool I know that competes with Make at its niche is Ninja.
@milleniumbug I agree. But the point is, we live in a day and age where if you'd start a project now, I don't see any technically sound reason why one would write a Makefile instead of a clear CMakeLists.txt file knowing it can generate the ugly Makefiles
