Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I am looking for a hardware, which must run about 256 computationally intensive real-time concurrent tasks in 24 hour mode (one multi-threaded C application). Each task takes about 40-50 MFLOPs, so all tasks require about 10 GFLOPs. CPU-RAM speed is insignificant. All tasks must be managed by a Linux Kernel (32 bit, with SMP).

I am looking for a one-mainboard solution with one multi-core CPU (if such CPU exist). If such CPU doesn't exist, then I need one mulit-socket mainboard solution (with multiple CPUs).

Can you please recommend me any professional CPU/Mainboard solution which will satisfy such requirements? It is also very important that there are no issues with Linux Kernel (2.6.25). No virtualization, no needs in huge RAM or CPU cache. I also would prefer Intel architecture and well-proved stability. I still have doubts that it is feasible at all.

Thank you in advance.

UPDATE: I think I have found a right answer here and here.

share|improve this question
1  
A good question which could live equally well on SO, SU or SF. The best place for it is probably SuperUser, but the guys over at ServerFault.COM probably have the best expertise. –  Robert Harvey Dec 10 '09 at 17:48
    
Thank you, but SO/SU/SF guys still read/answer very seldom if at all. –  psihodelia Dec 10 '09 at 17:51
1  
You want 10GFLOPS but "CPU-RAM speed is insignificant" ???? From and to where do the 40-80GB/s of floating point numbers go then? –  Joe Koberg Dec 10 '09 at 17:52
    
My impression is that with 256 contexts, shared address spaces don't work out so well. Have you considered multi-process rather than multi-thread? –  asveikau Dec 10 '09 at 17:53
1  
@MarkR: yes, it is requirement. I don't need to address huge RAM because processing algorithms operate on I/O –  psihodelia Dec 11 '09 at 9:54
show 3 more comments

7 Answers

up vote 3 down vote accepted

UltraSPARC T2 has 8 cores with 8 threads each. Integrated high-bandwidth memory and IO. The T5140 carries two of them for 128 hardware threads.

The theoretical max raw performance of the 8 floating point units is 11 Giga flops per second (GFlops/s). A huge advantage over other implementations however is that 64 threads can share the units and thus we can achieve an extremely high percentage of theoretical peak. Our experiments have achieved nearly 90% of the 11 Gflop/s. - (http://blogs.oracle.com/deniss/entry/floating_point_performance_on_the)

share|improve this answer
    
Thank you. This is already interesting because they have info on GFLOPs! But I fear, it is very hard to find where to buy. –  psihodelia Dec 10 '09 at 18:06
1  
"T5140" in the first paragraph above links to Sun's product page. $23k. –  Joe Koberg Dec 10 '09 at 18:29
1  
1  
actually there is no GFlops/s, there is GFLOPS = floating point operations per second divided by 10^9 –  psihodelia Dec 11 '09 at 10:04
add comment
  1. Rent some Amazon EC2 nodes.

  2. Updated: How about PS3's then? The NASA uses them for their simulation engines.

  3. Maybe use CPU+GPU's in commercial servers?

  4. Build it around FPGAs: nowadays, some variants include processors that can run Linux.

share|improve this answer
    
impossible. this is very specific real-time solution –  psihodelia Dec 10 '09 at 17:45
    
i would use FPGA solution, but it requires longer time/money to develope specific cores than I can afford –  psihodelia Dec 10 '09 at 17:53
add comment

Even though you've given us the specs you think you need, we might be able to help you out better if you tell us what the application is intended to accomplish, and how it was implemented.

There may be a better way to split the work up or deal with it rather than your current solution.

share|improve this answer
    
It is for signal processing needs. This application deals with convolution in time domain and different digital filters. –  psihodelia Dec 10 '09 at 18:02
    
Then you are much better considering a DSP based architecture, where you should be able to reduce the number or speed of CPUs because they have built-in instructions that handle these computations much more quickly and efficiently than general purpose processors. There are a number of processors that have a general purpose CPU (such as ARM) combined with a DSP for the heavy duty processing. You may find that you need very few DSPs to meet your computational model. –  Adam Davis Dec 10 '09 at 19:40
add comment

Not Intel architecture but these run linux and have 64 cores on a single die.

TILEPro64

share|improve this answer
    
Can these do Floating Point? I see no mention of it. –  jsbueno Dec 10 '09 at 18:08
    
@jsbueno - good point - I'm not sure. –  Aaron Dec 10 '09 at 20:34
    
there is no info on FLOPS, MIPS -> so it is not serious to buy smth. if you cannot estimate its performance –  psihodelia Dec 11 '09 at 9:59
add comment

Get a bunch of four- or eight-core machines and split the processing across the machines using some sort of grid or clustering software. Maybe have a look at Beowulf.

As you mentioned, 10GFlops isn't exactly to be sneezed at so in a single machine, it'll be expensive. There's also the problem what you do when the machine breaks, you're unlikely to have a second machine of similar spec available. If you build a cluster using commodity hardware, you're a little more resilient and it's easier to find replacement machines.

share|improve this answer
    
I am not sure that it is feasible to achieve 10GFLOPs. Do you have some particular models in mind? –  psihodelia Dec 10 '09 at 17:49
    
No particular models, but if you're building a grid already you can add more computers if you don't get the necessary floating point throughput. One of the reasons why I'd be tempted to stay away from a single machine to achieve that sort of performance is that if it goes pop, you're not in a position to quickly replace it with a similar spec machine. If you're using a compute grid or cluster, you'll end up with dimished throughput but you'll still be able to process data. –  Timo Geusch Dec 10 '09 at 18:26
    
@Time: almost any real-time solution to operate on I/O cannot be run on any network device because of network delays (millisecs range!) –  psihodelia Dec 11 '09 at 10:01
add comment

MFLOPS and GFLOPS are very poor indicators of how well a program can run on any given CPU. These days, cache footprint is much more important; perhaps branch prediction accuracy as well.

There's almost no way to gauge performance of a given application on different architectures without actually giving it a spin. And even then, you may not get a good idea if you were unlucky enough to unknowingly build with compiler options that ruined your cache footprint, or used a bad threading library, or any of a hundred other things.

share|improve this answer
add comment

I see you'd prefer intel, but if you need one chip, I will again suggest the cell processor - its theoretical peak performance is arount 25GFlops - kernel 2.6.25 had support for it already.

You could try a pre-slim playstation 3 for experimenting with (that would cost you little) or get yourself a server-based solution at around US$8K - you will have to re-write and fine tune your threads to take advabtage of the SPU co-processors there, but you could achieve your computational needs without breaking a sweat with a single CELL (1 PPC core + 8 SPU's)

NB.: with a playstation 3, you'd have only 6 available co-processors - but you don't seen to be on a budget with this project - So you could at least try IBM's cell developer kit, which offers an emulator, to see if you can code your solution to run on it.

Thre are commercially available CELL products, both as stand-alone servers in blade form factory, and PCI Express add-on boards for PC workstations from Mercury Computer Systems: http://www.mc.com/microsites/cell/products.aspx?id=6986

Mercury does not list any prices on the site, but the pricing seens to be around the previoulsy mentioned U$8000.00 for these PCI Express cards.

A playstation 3 videogame can be purchased for about U$300.00 - and would allow you to prototype your application, and check if it is up to the needed performance. (I myself got one and have Fedora 9 running on it, although I did that as a hobbyst and have not, so far, used it for any calculations - I had also put together a Playstation-3 12 machinne cluster for Molecular simulations at the local University. The application they run did not take advantage of the multimedia SPU's, while I was in touch with then. But even so, clocked at 3.5GHz they performed better than standard ,s imlarly priced, PC's, even considering PS3's are priced 5x higher around here)

share|improve this answer
    
but where can I buy this processor, proper mainboard, etc. ? I need many of them in perspective. –  psihodelia Dec 11 '09 at 9:57
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.