ZFS - Building, Testing, and Benchmarking
by Matt Breitbach on October 5, 2010 4:33 PM EST- Posted in
- IT Computing
- Linux
- NAS
- Nexenta
- ZFS
SuperMicro SC846E1-R900B
Our search for our ZFS SAN build starts with the Chassis. We looked at several systems from Supermicro, Norco, and Habey. Those systems can be found here :
SuperMicro : SuperMicro SC846E1-R900B
Norco : NORCO RPC-4020
Norco : NORCO RPC-4220
Habey : Habey ESC-4201C
The Norco and Habey systems were all relatively inexpensive, but none came with power supplies, nor did they support daisy chaining to additional enclosures without using any additional SAS HBA cards. You also needed to use multiple connections to the backplane to access all of the drive bays.
The SuperMicro system was by far the most expensive of the lot, but it came with redundant hot-swap power supplies, the ability to daisy chain to additional enclosures, 4 extra hot-swap drive bays, and the connection to the backplane was a single
The SuperMicro backplane also gives us the ability without any additional controllers to daisy chain to additional external chassis using the built in expander. This simplifies expansion significantly, allowing us to simply add a cable to the back of the chassis for additional enclosure expansion without having to add an extra HBA.
Given the cost to benefits analysis, we decided to go with the SuperMicro chassis. While it was $800 more than other systems, having a single connector to the backplane allowed us to save money on the SAS HBA card (more on this later). To support all of the other systems, you either needed to have a 24 port RAID card or a SAS controller card that supported 5
We also found that the power supplies we would want for this build would have significantly increased the cost. By having the redundant hot-swap power supplies included in the chassis, we saved additional costs. The only power supply that we found that would come close to fulfilling our needs for the Norco and Habey units was an Athena Power Hot Swap Redundant power supply that was $370 Athena Power Supply. Factoring that in to our purchasing decisions makes the SuperMicro chassis a no-brainer.
We moved the SuperMicro chassis into one of the racks in the datacenter for testing as testing it in the office was akin to sitting next to a jet waiting for takeoff. After a few days of it sitting in the office we were all threatening OSHA complaints due to the noise! It is not well suited for home or office use unless you can isolate it.
Rear of the SuperMicro chassis. You can also see three network cables running to the system. The one on the left is the connection to the IPMI management interface for remote management. The two on the right are the gigabit ports. Those ports can be used for internal
Removing the Power supply is as simple as pulling the plug, flipping a lever, and pulling out the PSU. The system stays online as long as one power supply is in the chassis and active.
This is the Power Distribution Backplane. This allows both PSU’s to be active and hot swapable. If this should ever go out, it is field replaceable, but the system does have to go offline.
A final thought on the Chassis selection – SuperMicro also offers chassis with 1200W power supplies. We considered this, but when we looked at the decisions that we were making on hard drive selections, we decided 900W would be plenty. Since we are selecting a hybrid storage solution using 7200
Another consideration would be if you decided to create a highly available system. If that is your goal you would want to use the E2 version of the chassis that we selected, as it supports dual SAS controllers. Since we are using SATA drives and SATA drives only support a single controller we decided to go with the single controller backplane.
Additional Photos :
This is the interior of the chassis, looking from the back of the chassis to the front of the chassis. We had already installed the SuperMicro X8ST3-F Motherboard, Intel Xeon E5504 Processor, Intel Heatsink, Intel X25-V SSD drives (for the mirrored boot volume), and cabling when this photo was taken.
This is the interior of the chassis, showing the memory, air shroud, and internal disk drives. The disks are currently mounted so that the data and power connectors are on the bottom.
Another photo of the interior of the chassis looking at the hard drives. 2.5″ hard drives make this installation simple. Some of our initial testing with 3.5″ hard drives left us a little more cramped for space.
The hot swap drive caddies are somewhat light-weight, but that is likely due to the high density of the drive system. Once you mount a hard drive in them though they are sufficiently rigid for any needs. Do not plan on dropping one on the floor though and having it save your drive. You can also see how simple it is to change out an SSD. We used the IcyDock’s for our SSD location because they are tool-less. If an SSD were to go bad, we simply pull the drive out, flip the lid open quick, and drop in a new drive. The whole process would take 30 seconds, which is very handy if the need ever arises.
The hot-swap fans are another nice feature. The fan on the right is partially removed, showing how simple it is to remove and install fans. Being able to simply slide the chassis out, open the cover, and drop in new fans without powering the system down is a must-have feature for a storage system such as this. We will be using this in a production environment where taking a system offline just to change a fan is not acceptable.
The front panel is not complicated, but it does provide us with what we need. Power on/off, reset, and indicator lights for Power, Hard Drive Activity, LAN1 and LAN2, Overheat, and Power fail (for failed Power Supply).
Motherboard Selection – SuperMicro X8ST3-F
Motherboard Top Photo
We are planning on deploying this server with OpenSolaris. As such we had to be very careful about our component selection. OpenSolaris does not support every piece of hardware sitting on your shelf. We had several servers that we tested with that would not boot into OpenSolaris at all. Granted, some of these were older systems with somewhat odd configurations. In any event, component selection needed to be made very carefully to make sure that OpenSolaris would install and work properly.
In the spirit of staying with one vendor, we decided to start looking with SuperMicro. Having one point of contact for all of the major components in a system sounded like a great idea.
Our requirements started with requiring that it support the Intel Xeon Nehalem architecture. The Intel Xeon architecture is very efficient and boasts great performance even at modest speeds. We did not anticipate unusually high loads with this system though, as we will not be doing any type of RAID that would require parity. Our RAID volumes will be mirrored VDEV’s (RAID10). As we did not anticipate large amounts of CPU time, we decided that the system should be single processor based.
Single CPU Socket for LGA 1366 Processor
Next on the list is RAM sizing. Taking in to consideration the functionality of the ARC cache in ZFS we wanted our system board to support a reasonable amount of RAM. The single processor systems that we looked at all support a minimum of 24GB of RAM. This is far ahead of most entry level RAID subsystems, most of which ship with 512MB-2GB of RAM (our 16 drive Promise RAID boxes have 512MB, upgradeable to a maximum of 2GB).
6 RAM slots supporting a max of 24GB of DDR3 RAM.
For expansion we required a minimum of 2 PCI-E x8 slots for Infiniband support and for additional SAS HBA cards should we need to expand to more disk drives than the system board supports. We found a lot of system boards that had one slot, or had a few slots, but none that had just the right number while supporting all of our other features, then we came across the X8ST3-F. The X8ST3-F has 3 X8 PCI-E slots (one is a physical X16 slot), 1 X4 PCI-E slot (in a physical X8 slot) and 2 32bit PCI slots. We believe that this should more than adequately handle anything that we need to put into this system.
PCI Express and PCI slots for Expansion
We also need Dual Gigabit Ethernet. This allows us to maintain one connection to the outside world, plus one connection into our current iSCSI infrastructure. We have a significant iSCSI setup deployed and we will need to migrate that data from the old iSCSI
Lastly, we required remote KVM capabilities, which is one of the most important factors in our system. Supermicro provides excellent remote KVM capabilities via their IPMI interface. We are able to monitor system temps, power cycle the system, re-direct CD/
Our search (and phone calls to SuperMicro) lead us to the SuperMicro X8ST3-F. It supported all of our requirements, plus it had an integrated SAS controller. The integrated SAS controller was is an
Jumper to switch from RAID to I/T mode and 8 SAS ports.
After speaking with SuperMicro, and searching different forums, we found that several people had successfully used the X8ST3-F with OpenSolaris. With that out of the way we ordered the Motherboard.
Processor Selection – Intel Xeon 5504
With the motherboard selection made, we could now decide what processor we wanted to put in this system. We initially looked at the Xeon 5520 series processors, as that is what we use in our BladeCenter blades. The 5520 is a great processor for our Virtualization environment due to the extra cache and hyperthreading, allowing it to work on 8 threads at once. Since our initial design plans dictated that we would be using Mirrored Striped VDEV’s with no parity, we decided that we would not need that much processing power. In keeping with that idea, we selected a Xeon 5504. This is a 2.0ghz processor with 4 cores. Our thoughts are that it should be able to easily handle the load that will be presented to it. If it does not, the system can be upgraded to a Xeon E5520 or even a W5580 processor, with a 3.2ghz operating speed if the system warrants it. Testing will be done to make sure that the system can handle the IO load that we will need to handle.
Cooling Selection – Intel BXSTS100A Active Heatsink with fan
We selected an Intel stock heatsink for this build. It has a TDP of 80Watts, which is exactly what our processor is rated at.
Memory Selection – Kingston Value Ram 1333mhz ECC Unbuffered DDR3
We decided to initially populate the ZFS server with 12GB of
To get the affordable part of the storage under hand, we had to investigate all of our options when it came to hard drives and available SATA technology. We finally settled on a combination of Western Digital RE3 1TB drives, Intel X25-M G2 SSD’s, Intel X25-E SSD’s, and Intel X25-V SSD’s.
The whole point of our storage build was to give us a reasonably large amount of storage that still performed well. For the bulk of our storage we planned on using enterprise grade SATA
To accelerate the performance of our ZFS system, we employed the L2ARC caching feature of ZFS. The L2ARC stores recently accessed data, and allows it to be read from a faster medium than traditional rotating
To accelerate write performance we selected 32GB Intel X25-E drives. These will be the ZIL (log) drives for the ZFS system. Since ZFS is a copy-on-write file system, every transaction is tracked in a log. By moving the log to SSD storage, you can greatly improve write performance on a ZFS system. Since this log is accessed on every write operation, we wanted to use an SSD drive that had a significantly longer life span. The Intel X25-E drives are an SLC style flash drive, which means they can be written to many more times than an MLC drive and not fail. Since most of the operations on our system are write operations, we had to have something that had a lot of longevity. We also decided to mirror the drives, so that if one of them failed, the log did not revert to a hard-drive based log system which would severely impact performance. Intel quotes these drives as 3300 IOPS write and 35,000 IOPS read. You may notice that this is lower than the X25-M G2 drives. We are so concerned about the longevity of the drives that we decided a tradeoff on IOPS was worth the additional longevity.
For our boot drives, we selected 40GB Intel X-25V SSD drives. We could have went with traditional rotating media for the boot drives, but with the cost of these drives going down every day we decided to splurge and use SSD’s for the boot volume. We don’t need the ultimate performance that is available with the higher end SSD’s for the boot volume, but we still realize that having your boot volumes on SSD’s will help reduce boot times in case of a reboot and they have the added bonus of being a low power draw device.
Important things to remember!
While building up our ZFS SAN server, we encountered a few issues in not having the correct parts on hand. Once we identified these parts, we ordered them as needed. The following is a breakdown of what not to forget.
Heatsink Retention bracket
We got all of our parts in, and we couldn’t even turn the system on. We neglected to take in to account that the heatsink that we ordered gets screwed down. The bracket needed for this is not included with the heatsink, the processor, the motherboard, or the case. It was a special order item from SuperMicro that we had to source before we could even turn the system on.
The Supermicro part number for the heatsink retention bracket is BKT-0023L – a Google search will lead you to a bunch of places that sell it.
SuperMicro Heatsink Retention Bracket
Reverse Breakout Cable
The motherboard that we chose actually has a built in
Reverse Breakout Cable – Discreet Connections.
Reverse Breakout Cable – SFF8087 End
Fixed
Dual 2.5″ HDD Tray part number – MCP-220-84603-0N
Single 3.5″ HDD Tray part number – MCP-220-84601-0N
LA or RA power and data cables – We also neglected to notice that when using the 3.5″ HDD trays that there isn’t really any room for cable clearance. Depending on how you mount your 3.5″ HDD’s, you will need Left Angle or Right Angle power and data connections. If you mount the power and data connectors at the top of the case, you’ll need Left Angle cabling. If you can mount the drives so the power and data are at the bottom of the case, you could use Right Angle cabling.
Left Angle Connectors
Left Angle Connectors connected to a HDD
Power extension cables – We did not run in to this, but we were advised by SuperMicro that it’s something they see often. Someone will build a system that requires 2x 8 pin power connectors, and the secondary 8 pin connector is too short. If you decide to build this project up using a board that requires dual 8 pin power connectors, be sure to order an extension cable, or you may be out of luck.
Fan power splitter – When we ordered our motherboard, we didn’t even think twice about the number of fan headers on the board. We’ve actually got more than enough on the board, but the location of those gave us another item to add to our list. The rear fans in the case do not have leads long enough to reach multiple fan headers. On the system board that we selected there was only one fan header near the dual fans at the rear of the chassis. We ordered up a 3 pin fan power splitter, and it works great.
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MGSsancho - Tuesday, October 5, 2010 - link
I haven't tried this myself yet but how about using 8kb blocks and using jumbo frames on your network? possibly lower through padding to fill the 9mb packet in exchange for lower latency? I have no idea as this is just a theory. dudes in the #opensolaris irc chan have always recommended 128K or 64K depending on the data.solori - Wednesday, October 20, 2010 - link
One easy way to check this would be to export the pool from OpenSolaris and directly import it to NexentaStor and re-test. I think you'll find that the differences - as your benchmarks describe - are more linked to write caching at the disk level than partition alignment.NexentaStor is focused on data integrity, and tunes for that very conservatively. Since SATA disks are used in your system, NexentaStor will typically disable disk write cache (write hit) and OpenSolaris may typically disable device cache flush operations (write benefit). These two feature differences can provide the benchmark differences you're seeing.
Also, some "workstation" tuning includes the disabling of ZIL (performance benefit). This is possible - but not recommended - in NexentaStor but has the side effect of risking application data integrity. Disabling the ZIL (in the absence of SLOG) will result in synchronous writes being committed only with transaction group commits - similar performance to having a very fast SLOG (lots of ARC space helpful too).
fmatthew5876 - Tuesday, October 5, 2010 - link
I'd be very interested to see how FreeBSD ZFS benchmark results would compare to Nexenta and Open Solaris.mbreitba - Tuesday, October 5, 2010 - link
We have benchmarked FreeNAS's implimentation of ZFS on the same hardware, and the performance was abysmal. We've considered looking into the latest releases of FreeBSD but have not completed any of that testing yet.jms703 - Tuesday, October 5, 2010 - link
Have you benchmarked FreeBSD 8.1? There were a huge number of performance fixes in 8.1.Also, when was this article written? OpenSolaris was killed by Sun on August 13th, 2010.
mbreitba - Tuesday, October 5, 2010 - link
There was a lot of work on this article just prior to the official announcement. The development of the Illumos foundation and subsequent OpenIndiana has been so rapidly paced that we wanted to get this article out the door before diving in to OpenIndiana and any other OpenSolaris derivatives. We will probably add more content talking about the demise of OpenSolaris and the Open Source alternatives that have started popping up at a later date.MGSsancho - Tuesday, October 5, 2010 - link
Not to mention that projects like illumos are currently not recommended for production, Currently only meant as a base for other distros (OpenIndiana.) Then there is Solaris 11 due soon. I'll try out the express version when its released.cdillon - Tuesday, October 5, 2010 - link
FreeNAS 0.7.x is still using FreeBSD 7.x, and the ZFS code is a bit dated. FreeBSD 8.x has newer ZFS code (v15). Hopefully very soon FreeBSD 9.x will have the latest ZFS code (v24).piroroadkill - Tuesday, October 5, 2010 - link
This is relevant to my interests, and I've been toying with the idea of setting up a ZFS based server for a while.It's nice to see the features it can use when you have the hardware for it.
cgaspar - Tuesday, October 5, 2010 - link
You say that all writes go to a log in ZFS. That's just not true. Only synchronous writes below a certain size go into the log (either built into the pool, or a dedicated log device). All writes are held in memory in a transaction group, and that transaction group is written to the main pool at least every 10 seconds by default (in OpenSolaris - it used to be 30 seconds, and still is in Solaris 10 U9). That's tunable, and commits will happen more frequently if required, based on available ARC and data churn rate. Note that _all_ writes go into the transaction group - the log is only ever used if the box crashes after a synchronous write and before the txg commits.Now for the caution - you have chosen SSDs for your SLOG that don't have a backup power source for their on board caches. If you suffer power loss, you may lose data. Several SLC SSDs have recently been released that have a supercapacitor or other power source sufficient to write cache data to flash on power loss, but the current Intel like up doesn't have it. I believe the next generation Intel SSDs will.