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Database Upgrade

10-30-10 by . 23 comments

As part of our datacenter migration, the database server received a substantial upgrade:

48 GB
2 Xeon X5470 CPUs
8 total cores @ 3.33 Ghz
64 GB
2 Xeon X5680 CPUs
12 total cores @ 3.33 GHz

However, a few things didn’t go quite to plan in the migration. Much to our chagrin, the database server ended up being barely faster — and maybe even a bit slower than our old database! This was deeply troubling.

The new Nehalem CPUs (what you may know as Core i7) are sort of meh on the desktop, but they are monsters on the server. It’s not unusual to see 200% performance increases going from Core 2 class server CPUs, like the ones we have in Oregeon, to these newer Core i7 class server CPUs. Just ask AnandTech’s Johan De Gelas:

The Nehalem architecture only caused a small ripple in the desktop world, mostly due to high pricing and performance that only shines in high-end applications. However, it has created a giant tsunami in the server world. The Xeon 5570 doubles the performance of its predecessor in applications that matter to more than 80% of the server market. Pulling this off without any process technology or clock speed advantage, without any significant increase in power consumption, is nothing but a historic achievement for the ambitious and talented team of Ronak Singhal.

So … yeah. We should be seeing performance improvements, and big ones, not the break-even parity (at best!) we were actually seeing.

We began looking into it and troubleshooting. That’s why there was some downtime around 5 pm Pacific the last few days. We were messing around with our primary and backup database servers in NYC. Here’s what we tried:

  1. We thought maybe the combination of SQL Server 2008 R2 and Intel’s next-gen HyperThreading were not mixing well. We’re still not sure, but we opted to be on the safe side and disable HyperThreading for now; 12 real, physical cores seems like plenty for our workload without adding fake logical CPUs to the mix.
  2. We realized we had mixed up CPUs a bit and we didn’t have the correct CPU in the server. Close, but not quite right. This was easy enough to fix with a CPU swap, but it alone was not enough to explain the performance issues.
  3. After trying a few other minor things, and with a nudge from Brent “database ninja” Ozar we narrowed it down to the clock speed of the CPUs themselves. Despite having set high performance mode in Windows Server 2008 R2’s power management control panel, the CPUs weren’t clocking up at all under load — we were seeing about half the clock speed under load we should have.

Kyle asked why our CPUs weren’t clocking up on Server Fault. In the process of asking the question and researching it ourselves, we discovered the answer. These Dell servers were inexplicably shipped with BIOS settings that …

  • did not allow the host operating system to control the CPU power settings
  • did not set the machine to high performance mode
  • did not scale CPU speed under load properly

… kind of the worst of all worlds. But Kyle quickly flipped a few BIOS settings so that the machine was set to “hyperspeed mode”, and performance suddenly got a lot better. How much better?

My benchmarks, let me show you them! This is an average of 10 SQL query runs on a copy of the Stack Overflow database, under no (or very little) real world load.

  OR DB2
2.5 Ghz
3.33 GHz
3.33 Ghz
gnarly query for Sportsmanship badge 3177 ms 2919 ms 1285 ms
simple full text query 555 ms 423 ms 335 ms

Notice that database performance scales nearly linearly with CPU speed. This has always been the case in our benchmarking, but our dataset fits in memory. I don’t think that’s unusual these days. Building a 64 GB server like this one is not terribly expensive any more — and solid state drives are bridging the gap between disk and memory performance at 256 GB and beyond. Anyway, the received wisdom that “database servers need fast disks above all else” is kind of a lie in my experience. Paying extortionate rates for a crazy fast I/O subsystem is a waste; instead, spend that money on really fast CPUs and as much memory as you can afford.

Most of all, there’s the crushing 2x Nehalem Xeon performance increase we would expect to see! It’s “only” 25% faster on full text operations, but we’ll take that too!

So, our apologies for the downtime. We tried to share everything we learned in the process here and on Server Fault so the community can benefit. We hope this upgrade brings a faster and more responsive set of Stack Exchange sites to you!

(and if you’d like oodles more datacenter details, do check out the Server Fault blog.)

Filed under server


Alnitak Oct 30 2010

I wonder just how many other Dell servers are out there running undetected at low speed… Very poor show from them.

knweiss Oct 30 2010

Jeff, I think you’ve mixed up the CPU names. Your new database CPUs are Westmeres (Xeon 56xx) not Nehalems (Xeon 55xx). Nehalems are quad-cores just as your old Harpertowns (Xeon 54xx).

… erm.. but the reason for a lots of memory is so that you never have to hit IO, because the database puts as much as you need into ram as possible. It’s doing tons of caching.

Mircea Chirea Oct 30 2010

You should leave HyperThreading enabled. All Windows operating systems since XP are aware of it and will spread threads evenly on all cores before starting to make use of HyperThreading (running a second thread / core).

This provides 50%-75% more processing power with no significant disadvantages (since there’s no risk of the OS loading a core with two threads while others sit idle).

Aarobot Oct 30 2010

Congratulations Jeff! That’s an awesome improvement.

Just for the record, good luck fitting your entire data set in memory when your data set is in the terabytes, and most of it gets used every day. User scaling and data scaling are two very different animals!

@knweiss or, tl;dr: Westmere IS Nehalem, but smaller, and with a possibility of having more cores.

Now that you have your clock speed issue fixed, time to really give it the spurs and turn hyperthreading back on!

Right and upfront. Thank you very much for sharing. There is nothing better than learning with actual “big-site-problems” to sketch up an upgrading plan that covers some of these little-to-unknown oddities.

Thank you!

@HardwareGuy and Mircea – the problem with hyperthreading on database servers is that SQL Server is memory-intensive. When you enable hyperthreading, you’re effectively slicing the CPU L3 cache in half – twice as many threads are now competing for the same L3 cache space. This isn’t an issue for processor-intensive apps that aren’t as reliant on data, but it’s a huge issue for SQL Server.

@Aarobot – I’d argue that if you’re trying to scale a database to the terabytes on a single box and all of it is used every day, you’re doing it wrong. You need to scale out.

Richb Oct 30 2010

Stack exchange would appear to be read mostly. You still need the io performance if you are write mostly or more evenly read/write.

Surprised you don’t cache your data in a better data structure in the app tier if it all fits in ram and is predominantly read only.

Can anyone speak to why the #$%@! Dell would ship servers in anything _but_ \hyperspeed mode?\ Why does that mode even exist? Who wouldn’t want to go \hyperspeed?\

It reminds me of the old \turbo\ button on PC cases, except those had a reason to exist at one point (something to do with games on slow early gen PC microprocessors).

Quentin Oct 30 2010

It’s good for big site issues to be publicly detailed. Experiences like this are valuable to us all to see. And entertaining! Congrats on the new metal.

@Ryan – i’m guessing Dell want to get into the profitable enterprise consulting market, where you pay an HP/IBM specialist to tune your system.

With IBM you end up paying an IBM consultant to tell you what IBM hardware you need to buy in the first place

@Mircea Chirea
You sure with those percentage?

I have no experience building high end database boxes but my impression is that RAM speed (freq/latency/channels) may have a greater performance impact than CPU speed. Aren’t the indexes so large that you spend all your accessing RAM?

Stephen Oct 31 2010

Hyperthreading isn’t going to give you anywhere near that performance improvement..

I’d expect 5% or so.

JasonMichael Oct 31 2010

Maybe you should get rid of MicroSoft SQL and servers… Couldn’t a Linux solution get more more for the amount of money you’ve spent? Oh, never mind, then you’d have to get rid of all your code… .NET based eh?

Maybe Mono’s the answer, and moving things to another platform. Otherwise, you might need need a couple MicroSoft server farms (I know, they don’t still call them that… there’s some other fancy name…. ) to get the improvements you want.

With @Richb on this one.

Aaron Oct 31 2010

What were the bios settings you changed ?

helvick Nov 3 2010

The RAM config that you give for your new servers is a bit odd for Westmere\Nehalem Servers if performance is your main objective. It might be fine but you don’t provide enough detail to be certain and I’ve seen many examples where a RAM size like this indicates that not enough attention has been paid to ensuring the memory config is optimal.

To ensure maximum main memory bandwidth and lowest latency on Xeon 55xx\56xx platforms you should be populating the DIMMs so that all 6 channels (three per CPU, assuming a dual cpu server) have the same number (and capacity) of DIMMs present. You can’t have everything completely balanced with a 64GB config. At worst you have 8x8GB DIMMs populating only 4 channels; possibly you have 2 channels with 2 8GB DIMMs per channel and 4 with 1x8GB each which might not be so bad; and there are other 8GB\4GB combinations none of which are ideal.

Dell’s standard options for the R610\710 servers list a 64GB config with 8x8GB DIMMs that is set to “Advanced ECC mode” by default – that sacrifices bandwidth (one channel goes completely unused) for increased error correcting capability. That’s a good option to have but it may not be what you want. It should be possible to have 64GB running at 1333Mhz on the X5680 – if the DIMMs are not quad ranked, and you have them populated with 2 DIMMs in channel 1 and 1 DIMM each in the other 4. However you still end up with an unbalanced setup – you have two controllers managing 50% of your main memory and 4 managing the remaining 50% which isn’t ideal.

If high bandwidth and low latency (rather than absolute capacity, or fault tolerance) are your priorities there are a couple of rules you should follow.

Avoid using 16GB DIMMs for now because you can’t get 1333Mhz modules in that capacity (as far as I’m aware),

Use no more than 2 DIMMs in each channel because if you have 3 DIMMs in any channel then all channels will run at 800Mhz. The Westmere (Xeon X5600) handle this better than the original Nehalems (Xeon X5500) which was limited to 1 DIMM per channel at most for DDR1333.

You have to use RDIMMs not UDIMMS (almost certainly not an issue for you given the capacity you have).

Avoid quad-ranked DIMMS – at best you will be able to run at 1066Mhz if you use QR DIMMs.

If you get it right you will have 6 channels each managing the same proportion of your total memory with all DIMMs running at 1333Mhz.

This Dell document goes into much more detail – It is slightly out of date in that it refers to the Xeon 5500 rather than the newer Xeon 5600 series but the only significant difference is that the 5600’s that you have can now run DIMMs at 1333Mhz even if there are 2 DIMMs per channel.

Mircea Chirea Nov 11 2010

@Iyan @Stephen
Yes I am sure with those. Unless you do the same thing on the threads running on the same core, which won’t run as fast as it could, but if one thread does integer math and another float, then yes.

5% for running a thread nearly in parallel is a massively pessimistic improvement.

@Brent Ozar
In that case you should set SQL server to use only X threads, where X is your number of cores. That way the OS and whatever else is running can run in parallel without the OS switching between them. Hopefully SQL Server has such a setting.

I think the R710 only has 4 DIMM slots / CPU, that means three DIMMs, one per channel, and another odd DIMM. Using memory in that DIMM will cut your bandwith to single-channel, unless Dell’s BIOS sucks and it falls back to dual-channel or single-channel if that slot is populated.