SKUs and Pricing

Before we start with the benchmarks, we first want to see what you get for your money. Let's compare the AMD chips with Intel's offerings. To reduce the clutter, we did not list all of the SKUs but have tried to include useful points of comparison.

AMD vs. Intel 2-socket SKU Comparison
Xeon
E5
Cores/
Threads
TDP Clock Speed
(GHz)
Price Opteron Modules/
Integer
cores
TDP Clock Speed
(GHz)
Price
High Performance High Performance
2697v2 12/24 130W 2.7-3.5 $2614          
2695v2 12/24 115W 2.4-3.2 $2336          
2687Wv2 8/16 150W 3.4-4.0 $2108          
2680v2 10/20 115W 2.8-3.6 $1723          
2680(*) 8/16 130W 2.7-3.5 $1723          
2660v2 10/20 115W 2.2-3.0 $1389 6386SE 8/16 140W 2.8-3.5 $1392
Midrange Midrange
2650v2 8/16 95W 2.6-3.4 $1166 6380 8/16 115W 2.5-3.4 $1088
2640v2 8/16 95W 2.0-2.5 $885          
          6376 8/16 115W 2.3-3.2 $703
Budget Budget
2630v2 6/12 80W 2.6-3.1 $612 6348 6/12 115W 2.8-3.4 $575
2620v2 6/12 80W 2.1-2.6 $406 6234 6/12 115W 2.4-3.0 $415
Power Optimized Power Optimized
2650Lv2 10/20 70W 1.7-2.1 $1219          
2630Lv2 6/12 70W 2.4-2.8 $612 6366HE 8/16 85W 1.8-3.1 $575

(*) Sandy Bridge based Xeon, for reference purposes

The lack of competition at the high-end cannot be more obvious. AMD simply does not have anything competitive at the moment in that part of the market. However, Intel and the OEMs still have to convince the data center people to keep the upgrade cycles relatively short. If you look at the the E5 2680 v2, you get two extra cores, a 100MHz clock speed bump and a lower TDP compared to the predecessor E5 2680. Intel charges more for the best Xeons, but you do get more for your money.

The most expensive Xeon (at 130W TDP) is a lot more expensive, but that is no surprise given the fact that it it is an expensive chip to make with such a massive die (12 cores, 30MB L3, two separate memory controllers).

Every Opteron has been relegated to the lower-end and midrange segments, and it is not looking good. We know that the AMD Opteron needs more threads or clock speed to keep up with the previous Xeon E5 performance wise. The midrange and budget AMD Opterons no longer have that advantage, and they need more power too. A price cut looks to be necessary, although an Opteron server is typically less expensive than a similar Xeon system.

Improvements, Continued Benchmarking Configuration
Comments Locked

70 Comments

View All Comments

  • Kevin G - Tuesday, September 17, 2013 - link

    Odd that Intel went the 3 die route with Ivy Bridge-EP. It was no surprise that the lowend would be a variant of the 6 core Ivy Bridge-E found in the Core i7-4900 series. Apple leaked that the line up would scale to 12 cores. The surprise is a native 10 core part and the differences between it and the 12 core design.

    Judging from the diagrams, Intel altered its internal ring bus for connecting cores. One ring goes orbits around all three columns of cores while another connects two columns. Thus the cores in the middle column have better latency for coherency as they have fewer stops on the ring bus to reach any core. The outer columns should have similar latency than the native 10 core chip for coherency: fewer cores to stop but longer traces on the die between columns.

    Not disclosed is how the 12 core chip divides cache. Previously each core would have a 2.5 MB of L3 cache that was more local than the rest of the L3 cache. The middle column may have access to L3 cache on both sides.

    The usage of dual memory controllers on the 12 core die is interesting. I wonder what measurable differences it produces. I'd fathom tests with a mix of reads/writes (ie databases) would show the greatest benefit as a concurrent read and write may occur. In a single socket configuration, enabling NUMA may produce a benefit. (Actually, how many single socket 2011 boards have this option?)
  • madmilk - Tuesday, September 17, 2013 - link

    It looks like each ring is connected to two columns. One ring goes around all three, but does not connect to the center column.
  • JlHADJOE - Tuesday, September 17, 2013 - link

    I'm guessing the 12-core might see action in the 8P segment, which is well overdue for an update.
  • psyq321 - Tuesday, September 17, 2013 - link

    There will be 15-core E7 8xxx v2 CPUs based on the same IvyTown architecture.

    As Intel is not showing the die-shot of a 12 core Ivy EP, I wonder if the 15-core EX and 12-core EP are using the same 3x5 die.
  • Kevin G - Tuesday, September 17, 2013 - link

    The memory controller interfaces are different between the Ivy Bridge-EP and Ivy Bridge-EX. The EP uses DDR3 in all of its forms (vanilla, ECC, buffered ECC, LR ECC) where as the EX version is going to use a serial interface similar in concept to FB-DIMMs. There will be two types of memory buffers for the EX line, one for DDR3 and later another that will use DDR4 memory. No changes need to be made to the new EX socket to support both types of memory.
  • Brutalizer - Tuesday, September 17, 2013 - link

    I would have expected this newest Intel 12-core cpu to perform better. For instance, in Java SPECjbb2013 benchmarks, it gets 35,500 and 4,500. However, the Oracle SPARC T5 gets 75.700 and 23.300 which totally demolishes the x86 cpu. Have not the x86 cpus improved that much in comparison to SPARC? The x86 still lags behind?
    https://blogs.oracle.com/BestPerf/entry/20130326_s...
  • JohanAnandtech - Tuesday, September 17, 2013 - link

    Be careful when you compare inflated, for marketing purposes results with independent "limited optimization" results ;-)
  • Phil_Oracle - Friday, February 21, 2014 - link

    What do you mean by inflated for marketing purposes? SPECjbb2013 is clearly a real world, recent benchmark that’s full audited by all vendors on the SPEC committee. If you make such claims, surely you have some evidence?
  • extide - Tuesday, September 17, 2013 - link

    Dont forget those T5's run at TDP's in the 200-300W range... If you clocked up one of these babies to those power levels I am sure it would be >= to the T5.
  • Kevin G - Tuesday, September 17, 2013 - link

    TDP's are indeed higher on the SPARC side but not as radically as you indicate. Generally they do not consume more than 200W. (Unfortunately Oracle doesn't give a flat power consumption figure for just the CPU, this is just an estimate based upon their total system power calculator. For reference, the POWER7 is 200W and the POWER7+ is 180W.)

Log in

Don't have an account? Sign up now