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Ciliates contain two types of nuclei: a micronucleus and a macronucleus. The micronucleus serves as the germ line nucleus but does not express its genes.
I still don't know what CoC or the whole license thing is. I am just furious because losing $5000-$10000 these 2-3 months due to my own strategic misjudgement.
It's not a big problem, but it's a 5k -10k I would rather have.
Also this low pay contractor I hired is of inferior quality.
Constantly trying to cram 12 hours worth of work load into 24 hours this December while everyone else seems to going on holidays.
Good percentage of the work load is caused by my own strategic mistakes and low quality people which is also part of my strategic mistake - why don't I stay away from those low quality people!!
With that said, must say our current tenants and A.I. in Robotic group members are all upright, not low quality people. At least fire is not burning in those areas. <3 Those two areas are worth happiness.
@Mikhail There's "starting a company" and "moving out", so consider me doubly not interested x)
@Mikhail Yeah, I never really used meta-programming for work: just a bit but only when the other solutions are way too much of a PITA otherwise people just don't understand
Lemme blind your precious eyes with newbie listing of my 1st airbnb property. Let's see whether I can lure someone into booking this, it's listed pretty much at 50% price of other similar independent houses in this suburb. I have already indicated that I am nu with hosting so do expect some inferior services.
It's only available for the next 8 weeks. Still kind of prefer long term tenants.
basically in the distant future there would be two different ways to to write coroutines, but for coroutine consumers it wouldn't change anything from an API point of view
@Mgetz With 8 oxygen's bound to one carbon? If you could (somehow) manage to do that in the first place, getting half a dozen of those oxygen atoms to come unbound from the carbon would happen really easily. The real question would be what form it would take. Part of what makes ClF3 and FOOF so dangerous is that (at reasonably normal temperatures) they're both liquid, so they're extremely dense compared to a gas. I can't guess what form CO8 would have at room temp. if it existed.
Guys, I started to monitor a few of our servers at work, at first it felt like a good idea, now I'm wondering if I was better off being blind or to actually see how bad the server are running
@Mgetz Maybe. I believe I'm immortal. This seems to be correct so far.
@LoïcFaure-Lacroix Probably better to remain blind. Now you can think of the fact that your servers probably run better than most, and realize what a miracle it is that this chat (for only one example) actually works at all.
Supports AVX512 through Cannon Lake. I actually knew that since August of last year. (Their chip architects told me at HotChips.) But I couldn't say a thing about it.
The VIA chip architect said (in August 2018) they had it implemented. But they weren't sure if the implementation would match Intel's. So they kept the CPUID bits off. They were also taping out at around the same time.
@Mysticial Unfortunately, I don't have enough spare time to view and know all the NSFW content available. Now that I think of it, that's an interesting question: could anybody do so, or is more than 24 hours or porn filmed in an average day? My guess is the latter, so even if you did nothing else, you couldn't view porn as fast as it's made.
@Mgetz Simple rule of thumb: anytime anybody attributes much of anything to "RISC", chances are they're full of crap.
@Mysticial Seems to me like that's asking the wrong question. The meaningful question isn't whether they match Intel, but whether using it gives better performance than not using it.
@Mgetz I think it's usually because they were taught using books by Hennesy and Patterson, and have never given significant consideration to doing anything else.
@Mgetz I don't think most are zealots, exactly. I think for most of them, considering the possibility of CISC being superior would be a little like a 2 year-old American child considering that Mandarin might be a better language that English in some ways. To the extent they've learned anything about CISC at all, it's purely as a foil for arguments about how RISC is better (and more often than not, an example so extreme it's pretty much, if not actually, a true straw man).
"Imagine a processor in which every instruction was encoded uniquely. Now consider how much better it would be if we designed a simple, regular scheme for encoding instructions instead. That's RISC."
@JerryCoffin I find this hilarious because there was recently research showing that insofar as you do CISC well the pipelining benefits outweigh the complexity
is x86 a bit absurd... yes it is. But it shouldn't be held up as an architectural example of 'clean'
Imagine for a sec a 'clean' x86-64 implementation, no compatibility mode, no compat only instructions. In theory you could cut the binary implementation down quite a bit to something sane
of course we can't do that because of backwards compat
@Mgetz Of course, not. Even Intel wouldn't claim such a thing. x86 is the result of hacking on one backward compatible extension after another for 40 years or so. RISC designs haven't aged a whole lot better--just most of them haven't been around nearly as long.
@Mgetz The problem is that the big advantage of RISC is mostly the simple instruction encoding. The problem with that is that the simple encoding also means instruction streams are less dense--the same program is bigger (typically about twice as big). So, to get similar performance, you need twice as big of a cache. When instruction decoders were big and caches tiny, that made sense. Nowadays, instruction decoders are ~1% of a CPU, and cache around 80%, so RISC is optimizing the wrong thing.
@JerryCoffin also pipelining generally needs to be deeper and you better pray your branch predictor works or just give up and use prefetch instructions. Your IPC is hard to keep up because comparative to CISC you'd need to run at something like 7/7/7 instead of the 4/4/4 that intel does last I checked
@Mgetz This is another place RISC got things kind of wrong. They basically just rather blindly assumed that more registers was always better. Up to a point that was true--but once you get past that point, saving and restoring registers (for either interrupts or task switches) starts to add significant overhead. So Itanium (for an obvious example) does decently for pure computation, but sucks air as soon as you add interrupts and multitasking to the mix.
@JerryCoffin the wider your dispatch the more interrupts are going to suck to restart from unless you keep a separate register bank for kernel mode (I think x86 does this to an extent)
Sun's stack-oriented register use at least saved them a bit, but (also having 256 registers) they put a huge amount of work into keeping register save/restore from killing them (and still never entirely succeeded).
@Mgetz ...and ARM definitely does (or, at least some implementations do--but I think probably all of them do).
@Mgetz Oh yeah. Interestingly, years ago this went the opposite direction. Pentium IV's (Northwoods, and especially Prescotts) suffered from it horribly, so a 3 GHz P4 was around the same speed as a 1 GHz SPARC. But the tables have turned...
@JerryCoffin well the theory, and the sims, said that Netburst wasn't a problem because you'd just crank the clock speed. So they hard optimized on that both for marketing and allegedly performance reasons. The issue was that leakage current is a thing and is unavoidable... Prescott fixed some of the issues but Northwood was deliberately locked down to limit so it wouldn't catch fire
@Mgetz Prescott fixed a few issues, but added so many more that improvement was minimal at best. From what I recall of testing at the time, a 3.2 GHz Prescott was usually slower than a 2.8 GHz Northwood (and yes, burned a whole lot more power).
So the issue with having a ton of registers isn't the silicon, but rather the need save them on interrupts? IOW, asking to expose all the physical registers and eliminating renaming isn't actually feasible?
I have plenty of workloads that can utilize 100+ explicitly addressable registers.
@Mysticial depends on how it's implemented, that many registers creates other headaches for the ISA too. It's usually easier to use register renaming even if it's partially exposed.
Exposing all the physical registers and eliminating renaming has another problem. You can't add more registers in the future when the silicon becomes more capable.
@Mysticial I'm not sure it's the only issue, but it definitely is an issue, anyway. You could certainly have more explicitly addressable registers than x86 does though. Quite a few designs use 32 or 64 registers without a significant problem.
I guess my point is that in the vast majority of cases, most code doesn't need more than 15 locals based on what I've seen. Moreover quite a few registers get lopped off for ABI reasons
@Mgetz I haven't looked carefully (recently), but that wouldn't surprise me. When you get down to it, I think a lot of that is limits on how much a programmer can keep track of at once. Even using 15 probably involves merging what were written as multiple functions together more often than not.
@JerryCoffin Sorry, I didn't mean implementation. But rather the behavior of the instruction. As in VIA implemented it using only Intel's official documentation. They didn't have any Intel hardware to double-check. So any errors or ambiguities in the Intel documentation could've led to mismatches between Intel's instruction and VIA's instruction.
@Borgleader I think they're probably running into the same problems that have plagued VLIW for decades. It's (fairly) easy to design a CPU that can theoretically do a lot in parallel. Then you try to write a compiler that can actually take advantage of that. Then you spend as much as you can afford on compiler development. Then you declare bankruptcy. Don't get me wrong: every iteration of this cycle compilers get a little better, and we get a little closer to it actually working.
Eventually it probably will work--but I'm not sure Mill is going to be the the time it comes out ahead. Or breaks even, for that matter.
@JerryCoffin I snuck a peek at their forums, their mid tier processor is getting the same as their top tier right now in sims and they haven't even taped silicon
so they are working on fixing that before they ask for more money
@Mgetz From what I recall them saying a few years ago, they gave kind of a non-answer, saying they're interested in niches that aren't served well by the big vendors, so they were doing tooling that would let them plug in specs and quickly/cheaply get a design for a specific niche (and repeat as needed).
@JerryCoffin ok... but what segments are those? ARM has mobile covered, Intel and AMD desktop and datacenter. Embedded controllers are increasingly moving ARM because of the volume of chips on the market last I checked... so aside from mainframe which is dominated by Z and whatever fujitsu has... I must be missing something?
@Mgetz Like I said, it struck me as a non-answer. Maybe they have some specific targets in mind, and just don't want to tip their hand ahead of time. But (having been involved in some things before) it kind of strikes me as a quite possibly a solution in search of a problem.
@JerryCoffin yeah, the thing that strikes me is that the people that don't like ARM are going RISC V and there are already a ton of tools and tape outs for that
@Mgetz And not just tools. It's sufficiently conventional that porting something like Linux or BSD (or Windows, if it ever gets enough market share to justify doing so) to it will be fairly straightforward.
@Mgetz Ah. I hadn't kept track of things, but I probably should have expected it. If anything, that emphasizes the basic point I was trying to make though. It's an easy target, so making lots of conventional code run well on it is a simple re-compile.
@Mgetz Some have, others haven't. ASICs are (or should be) more efficient when they're designed, but GPUs have enough larger (and more dependable) market that they get updated even when Bitcoin prices are low.
@Mgetz Here's the secret: nearly everything that's true of crypto currency...is equally true of other currency. Crypto currency has value to exactly the degree that others trust it enough to give you something valuable in return for it. And the same is true with other currencies, up to an definitely including Euros and US dollars. The only fundamental difference is how many people put how much trust into one vs. the other.
@JerryCoffin The difference is who holds the majority of any currency. Right now for crypto it's almost always the people that came up with it. Bitcoin was invented to evade money laundering and sanctions
@Mgetz Which drastically (and quite rightly) improves the degree of trust you have in the currency. But it's still a matter of how much trust you put in it.
@Mgetz A little. Gold, platinum and silver all have intrinsic value to at least some degree. Gold is highly malleable and nearly immune to corrosion. Platinum is extremely useful as a catalyst. Silver has the lowest electrical resistance of any element. They all have commercial uses so even if they were as common as iron or aluminium or copper, they'd have at least a fair amount of value (as iron, aluminium and copper do). US dollars have no intrinsic value (and likewise Euros, etc.)
@JerryCoffin and yet if you rely on them you'll be forced into a boom bust cycle based on the inability of the economy to expand past the availability of the shiny rocks. Unless of course you lie and create promissory notes for shiny rocks
Don't get me wrong: the value of gold or platinum is based largely on its rarity, so you'd lose a lot of the value if they became drastically more common. But at least you wouldn't lose it all.
@Mgetz The boom/bust cycle wasn't based so much on relying on the shiny rocks themselves. It was much more a result of having a predetermined price ($100/troy ounce for a long time).
@Mgetz That meant (among other things) that when the economy grew, prices went up and you couldn't afford to mine it any more (until the bust happened, and you had lots of people willing work for lower wages).
