@crasic Not to mention that the cost of the CPU as a percentage of the rig is small when you're building a HPC box. Its actually smaller as a % then in a laptop. For example, a full loaded node might be $200k, only $40k is for the CPU.
@Mysticial Well AMDs new thing scales a lot better no? IIRC I read an article that more or less implies they can "lego block" shit together and make CPUs a lot faster and with smaller teams than they used to. (I'm simplifying ofc)
Seems like that could be something useful for Intel as well
@Mikhail Just a categorization by size and thereby root cause. Compare the impact of some local heterogeneity in the substrate (atomic scale) vs say mask misalignment that causes a larger defect.
Isn't mask alignment easily fixed? Aka, the moment you notice it, you fix it compared to contamination or whatever the tension method Intel is using instead of doping...
Problem is the direction of the ship isn't clear. If they sail in the wrong direction, and pursue an impossible process, they're fucked. Curiously, the people I know claim to not know whats going with the new shrink. So, the company is keeping whatever is going wrong under wraps.
This is bad for investors because you don't know if its just some contamination that can be fixed with assiduity or their process is unworkable.
Since council doesn't allow roosters to be kept on premise, I am going to swap the cockerel that has started crowing with 3 dozens free range eggs. The bird will be living on a farm with his new buddies instead.
The guy reports 11 - 14% speedup with the Skylake AVX512 binary over Broadwell AVX2 at the same frequency. But the speedup narrows once you factor in the AVX512 clockspeed throttle.
I mean, are those the max speeds for both chips? Or did he downclock the old one to make it have the same clock as the AVX512 when the FMA unit is engaged?
@Mikhail Without the 2nd FMA, I wouldn't expect any speedup at all - maybe even a regression due to the additional shuffling overhead. But maybe the reduced instruction count is helping out with the decoders.
Fucking shit took 25 min. and 105 GB to compile on my 14-core box.
Last time I checked it was only 80GB.
@Mikhail I'm gonna try something a little different. I usually don't release binaries until I get the hardware first. But this also means missing out on all the launch reviews.
Depending on how this Cannonlake binary turns out, I might just enable it for the next version - prior to me getting the hardware.
Cannonlake will probably be the last "new binary" for a while. There's nothing particularly useful in Ice Lake.
Bad concepts/comparisons, unclear structure of sententess, bad code examples, needless repeating explanations of C++ features that are useless for one who knows and give no clue for one don't.
And most of all I hate, that he refers to listing of codes that is far from where you're reading now.
@nwp You mean, Grimm's book? No, I have it, new edition was published this Tuesday, but didn't read it yet. Want to finish Wiliams's book first. I just was wondering if some have something to say about Grimm's book.
I have to make a substitution management system for my school in C++ using data file handling. And unfortunately I could't make it due to some emergencies. can anybody write the code for me ? I have to submit it by 16th June 2018
@ratchetfreak The "real" reason for the speedup is that back in 2016, I built a completely new algorithm from scratch around the new Cannonlake instruction sets. I just haven't said much about it since it was a 60k LOC gamble that I wasn't sure would actually pay off.
Around January of 2016, I realized that the Cannonlake instructions can be (ab)used in a very special way to construct the next "killer" algorithm for multiplying large numbers.
Even though Cannonlake was far from being released, I was "so sure" that the algorithm would hold up both mathematically and in performance that I went ahead and implemented it from February to May 2016 - fully optimized based on theoretical performance models I had constructed of Cannonlake's architecture.
Of course some of those models fell apart when Skylake X came out and I realized that the AVX512 implementation isn't as good as I had anticipated. But it wasn't enough to completely offset the (theoretical) speedup I had calculated prior to starting the algorithm.
The speedup on this Cannonlake laptop hovers around 25%. But this will drop off once the core-count goes up and the memory bandwidth problem comes back. Likewise, dual-FMAs will also reduce this gap. The old algorithm is FMA-heavy, the new one isn't - which is why it's crushing the old code on this single-FMA chip.