Intel Launches Xeon E5 V3 Series Server CPUs With Up To 18 Cores 105
MojoKid writes Intel took the wraps off its Xeon E5 v3 server line-up today and the chip, based on Intel's Haswell-EP architecture, is looking impressive. Intel's previous generation Xeon E5 V2 chips, which were based on Ivy Bridge, topped out at 12 cores per socket. The new Xeon E5 v3 processors, in contrast, are going to push as high as 18 cores per socket — a 50% improvement. The TDP range is pushing slightly outwards in both directions; the E5 V2 family ranged from 50W to 150W, whereas the E5 V3 family will span 55W — 160W in a single workstation configuration. The core technologies Intel is introducing to the E5 V3 family pull from the Haswell architecture, including increased cache bandwidth, improved overall IPC, and new features like AVX2, which offers a theoretical near-doubling of floating point performance over the original AVX instructions. Full support for DDR4 DRAM memory is now included as well.
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Meh. Oracle just announced a 32-core Sparc proc, with variable thread count (1-8 per core, depending on load need - if it needs better single thread performance is shuts off the other threads). AMD's move next.
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And then, Atmel. Anyone up for a quad-core ATtiny85?
Re: Oooh Shiny (Score:1)
Re: Oooh Shiny (Score:2)
You lost me at Oracle.
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No idea yet. I'd expect AMD still rules on performance per $, and am interested in seeing the performance per watt and performance per core metrics. Interested in seeing how it lines up against POWER 8 and Intel's new Xeon (I personally wish AMD could compete in performance per watt against Intel. I'll keep wishing).
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Will it actually play the cha-ching sound when the extra features self-enable?
Why not 16? (Score:2)
I would have thought a 16 core config would be an efficient number.
Re:Why not 16? (Score:5, Funny)
You’re on 16, all the way up, all the way up...Where can you go from there? Nowhere. What we do, is if we need that extra push over the cliff...Eighteen. Two more cores."
DiBergi: "Why don’t you just make 16 faster and make 16 be the top number, and make each core faster?"
Nigel (after taking a moment to let this sink in): "These ones go to 18 cores."
Re:F**k Everything! We're Doing Nineteen Cores! (Score:1)
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At first it was a 32-cores CPU but they had to scale it down because of budget cuts.
alternate reply: they calculated the number of cores on an old Pentium.
It's how many they could pack in (Score:2)
The way they design their CPUs it is easy to have pretty much any number that is divisible by 2. It isn't a big deal to have something that is any particular amount more or less. So then it comes down to power, thermal, and die size limits.
Apparently 18 cores is what they cap out at, this time around. I'm sure you'll be able to get 16 core, and less, chips, that is just the most they could stuff in there before exceeding whatever design limitations they'd set.
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You may have noticed these are server chips. Intel is now doing the equivalent of ECC with its CPUs - every 9th core is a parity core. There are effectively only 16 cores.
compiling (Score:1)
As a programmer I so want one of these.
$ make -j 18 # FTW!
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Well, if you write a single non-recursive Makefile like you're supposed to[1], then GNU Make might be able to build thousands of targets in parallel, in which case it'd quickly grind to a halt under I/O pressure.
An easy rule of thumb for parallel jobs with mixed workloads is N+1, whether it's Make or something else entirely, where N is the number of CPUs.
[1] Usually that means using the include directive to build up a single dependency graph, which in turn means defining your recipes using absolute paths. F
Re: compiling (Score:2)
Earth (Score:2)
You know what would be awesome? A 42-cores CPU. To keep your cup of tea really, really hot.
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That would be almost, but not quite, entirely unlike a retro-gen GPU.
And highly improbable.
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You know what would be awesome? A 42-cores CPU. To keep your cup of tea really, really hot.
Unfortunately cores this large, powerful and complex all stand excellent chances of spontaneously self-triggering SMEF (Spontaneous Massive Existence Failure).
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Unfortunately cores this large, powerful and complex all stand excellent chances of spontaneously self-triggering SMEF (Spontaneous Massive Existence Failure).
That acronym is a fine example of Onomatopoeia. [wikipedia.org]
But is that really true? GPUs have far more than 42 cores, and they don't SMEF very often, do they?
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Ah. But that's where you're overthinking it.
How may multi-core GPUs have EXACTLY 42 (Forty Two) cores?
=)
=D
The plot thickens!
... not only earth ... (Score:1)
"The answer to the ultimate question of life, the universe and everything is 42"
--- The Hitchhiker's Guide to the Galaxy
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http://x2.fjcdn.com/thumbnails... [fjcdn.com]
Leave your nerd card at the door (Score:2)
If you don't know about 42, you don't belong here.
What happened to the core-wars? (Score:2)
As a hobbyist 3D modeller, the more cores the merrier (and more memory + cache of course). But I'm kind of disappointed about where we're headed. Announcements of new processor with an astonishing amount of cores appear all the time, but they never appear in the actual stores, are they too expensive or something?
I remember
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i think you can get up to 8 cores in a standard desktop.
These are server cpus. You can put a server cpu in a desktop pc, but these xeon cpus can be found in single, dual or quad variants. The price for one of these 18 core cpus? I figure it should be around 2800$. The motherboards for these will be around 500$. It's not something you'll normally see on someone's desk.
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i think you can get up to 8 cores in a standard desktop. These are server cpus. You can put a server cpu in a desktop pc, but these xeon cpus can be found in single, dual or quad variants. The price for one of these 18 core cpus? I figure it should be around 2800$. The motherboards for these will be around 500$. It's not something you'll normally see on someone's desk.
You know, kids buy 500-1000$ graphics cards, just for gaming. So to me, this isn't that far fetched. But of course you're right if we're talking about the Hendersons (Regular office Joe and Jenny Surf)...it would make NO sense for them to purchase an Alienware monster or similar.
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Yeah but these server chips aren't for gaming. Typically to put in that many cores and keep that amount of TDP, you're going to make sacrifices. Specifically in top speed. You may have 18 cores, but they're definitely not running at 4ghz like the i7-4790K. Try more like 2.7ghz. For gaming, single threaded performance is still king.
Also for gaming, it's fairly rare today to be cpu locked (cpu being the bottleneck) and instead being the graphics card, memory bus, etc.
These cpus are first and foremost use
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Exactly. These are for VMware farms.
Instead of 50 VM per core, now you can fit 75 VMs per core.
Which your QA's will stretch to the max anyway, so this is at least saving you money by not having to buy 50% more physical servers.
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Re: What happened to the core-wars? (Score:2)
I suppose Cisco will release a quad socket, 6TB RAM blade soon. I hope they'll loan me one to try. I was able to run entire companies with VDI on 3 60-core blade with V2, a little slowly, but effectively. 3 72-core V3 blades should be better.
The real problem comes tha
Re:What happened to the core-wars? (Score:4, Insightful)
Most people don't even make use of 4 cores on their desktop, so it doesn't make sense for them to push 16-core consumer chips. If you want to do server-like highly-parallel tasks, maybe you should buy a server CPU.
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that went to mobile where the fandroids cream their shorts over any mention of cores and megahertz
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It's a server chip. You'll need a server motherboard, but you can certainly buy one and use it for your computing needs.
Re:What happened to the core-wars? (Score:5, Informative)
I've been stuck with my 4 core cpu for the last 6-7 years now and the only thing that has improved my rendering is the NVIDIA GPUs
6-7 years ago, that's like a Q6600 or so? Have you actually looked at benchmarks like Q6600 vs 4790K [anandtech.com] because current top of the line quad-cores are 3-4 times faster than that.
I remember 8-16 cores being announced YEARS ago, but they never ever appeared in regular desktop computers
No, because of a couple things:
1) Single-threaded performance is still huge and often the bottleneck in interactive work - big multithreaded jobs just decide how long a coffee break you get.
2) Lots of cores means big die means big costs and poor yields meaning they aren't really interested in selling it at consumer prices.
3) Companies would no doubt try to use these as cheap servers or whatever and they don't want enterprise users buying anything but Xeon.
4) You can now get i7-5960x in an "enthusiast" system with 8 cores at least, though it'll cost you $1000. Or you can buy AMDs marketing and get an "8-core" FX processor...
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And how much more does it cost you in power to run that AMD? Plus add on cost for a more powerful PSU.
so (Score:2)
These shiny new processor having working TSX instruction sets? The ones that are supposed to help with virtualization?
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Isn't a TSX an American branded Japanese Honda Accord?
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Isn't a TSX an American branded Japanese Honda Accord?
Not anymore, it was axed, along with the TL, and they were both "combined" to make the TLX.
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we have accords here
the acuras are overpriced honda's for dummies who want "luxury"
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I know you do, but American Accords are not the same as Japanese Accords.
Re: TSX (Score:3)
> These shiny new processor having working TSX instruction sets? The ones that are supposed to help with virtualization?
TSX is not for virtualization, but for transactional synchronization [wikipedia.org], it provides efficient transaction locking for multi-threaded applications. Not necessarily virtualization, although it can benefit from efficient locking as well
No, as far as I know, these have TSX disabled [intel.com], or will be with a microcode update, as TSX isn't expected to be fixed until 2015 in Broadwell or Haswell-EX Xeons (not Haswell-EP which these are).
at least they have 4 and 8 core models as well (Score:5, Insightful)
SQL server went to per core pricing a few years back and are looking at around 8 cores per server now when we buy new hardware. more cores won't do much for us except send more money to microsoft
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And I am pretty sure that in a db environment, 2 sockets with 6 cores each will handily outperform a single socket with 12 cores...
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Postgres is calling you ... 0xG joooiiiinnn ussss ...
(in some sort of ghostly voice I guess)
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How precious, you think MS SQL Server is a "real SQL server".
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I do have an arm chair. That must be the reason no one is using MS SQL for anything serious at Google, Apple, Facebook, Yahoo, Netflix, Fitbit, Twitter, etc. Too many arm chairs here in the Valley.
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And when the developers of the software (that the LOB wants) says "we only support db 'x'"...
We're not big enough to "force" the developers to port their applications, just for us.
We're not rich enough to develop all of our own apps.
So, like many (most) IT organizations, you have to ignore the idealists and Utopian views, and just serve the business.
Comments like "real SQL server" are unconstru
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the single 12 core socket will have more on board cache and should outperform 2 sockets. plus the timing issues of running data between 2 physical CPU's
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I'm wondering how long before everyone demands that licensed software only make use of the hardware it's licensed for, which may only be part of the resources available to the server as a whole. For example, a 2-core license for SQL Server could run just fine on a 12-core server, but would only use 2 cores at a time. Make that happen, Microsoft, then we'll take your stupid per-core licensing seriously.
On a related side note, today I was greeted back to work on a Monday morning by a BizTalk re-licensing issu
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Of course, tossing in virtualization in the mix is fun as well. For example, if I'm sitting on two boxes with 36 cores, and run a relatively small Oracle instance for VMWare vCenter with one vCPU in fault-tolerant mode, I'm on the hook for 72 cores for the Oracle license. With the cost being around $60,000 per core for the enterprise tier, this can add up. Add to this something like vMotion HA where the license has to include every machine that -could- run the DB, and it can get painful even in the enter
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sounds like if i bent over my ass wouldn't be big enough for oracle
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Sybase is exactly the same. You can license it for development by the number of users, or production by the number of cores.
It can get so expensive due to the licensing model they use, that buying a POWER or SPARC machine actually saves money compared to putting it in a VM environment, just because of whatever the DB -can- touch for CPU cores has to be licensed.
I'm not sure about MS SQL server, but from what I read, it is pretty similar.
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I'm a fan of the way Oracle is doing the licensing on the Oracle DB Appliance - the box comes with lots of cores, but you license them on demand.
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that would actually be nice since the higher core CPU's have more cache which has been shown to increase performance for decades now. i'll take a top end CPU and disable cores any day over buying a lower end CPU just to save on licensing
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Oracle and Sybase as well have this type of licensing, unless something has changed.
IBM addressed this with POWER7 and newer in a fairly innovative way. They have an option called TurboCore mode which turns off half the cores. The ones still running can use the disabled core's caches, and because of the space available for heat dissipation, clock speed could be bumped up. The result was half the cores, but almost the same performance due to the faster clock and cache available.
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Intel has it too - it's called "TurboBoost". Basically if the CPU is not under thermal restraint, and the other co
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Until Microsoft moves to IBM style licensing where you pay for the cores on the hardware, regardless of what you are assigning to the virtual machine.
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It's unpossible! You math fail!
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And the winner will still be... (Score:1)
the architecture that can achieve the fastest speed on complex relational joins.
You remember normalized tables and joins of course because they aren't going away since they are the only program constructs that are remotely built on the solid foundation of real math set theory
AND they aren't even Turing machines!!! LOL.
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Partitioning a table over multiple drives has allowed RDMS's to utilize multiple processors for a single join ever since Teradata pioneered the hardware for this 30 years ago. The sky is the limit.
YAY! Lots of cores (Score:2)
This is really great for doing cpu intensive jobs but what seems to never get any love is moving massive amounts of data around. We need to put as much effort into buss bandwidth as we are with cpu's.
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Per Anandtech, the 2.3GHz 18-core model has an AVX base frequency of 1.9GHz. That's the only hard number I've come across. It seems to simply act as a warning that, under heavy usage of AVX, the chip may clock down below the advertised base frequency. It could still run higher, of course, if only a few cores are being used.
That's what i'm talking bout (Score:2)
Is there any reason for enthusiasts to choose the Core i7 over this?