The Intel Optane SSD 900P 280GB Review
by Billy Tallis on October 27, 2017 9:30 AM ESTConclusion
The Intel Optane SSD 900P is an amazing piece of technology, but one whose benefits are difficult to fully enjoy. Its 3D XPoint memory enables it to break almost all the performance records, but some where difference to Optane SSD performance is too small to justify paying more than twice the price per GB. However, there are some scenarios where the Optane SSD absolutely blows away the competition and justifies its premium.
The low queue depth random read performance of the Optane SSD is several times faster than any flash-based SSD has attained. Mixed workloads that include a substantial component of random read operations also perform quite well, and throwing some write operations into a stream of reads barely impacts the read performance.
The Optane SSD 900P has enough space to be used as general-purpose storage, and larger capacity models can be introduced as necessary. There's no need to tangle with Intel's caching software and its associated platform lock-in as with the Optane Memory modules.
The biggest problem the Optane SSD 900P faces today is that few desktop users have workloads that stress the storage system enough for the Optane SSD to shine. Mechanical hard drives have not disappeared from use as primary storage, and most software for desktop and workstation use is still designed with their performance limitations in mind. If budget SSDs had relegated hard drives to backup and archival use years ago, then the software landscape would probably be more ready to take advantage of the speed offered by the Optane SSD 900P. Instead, the Optane SSD as a consumer/prosumer product only makes sense in a few niches. Most users- even those with relatively intense storage performance needs - will be better served by high quality flash SSDs like the Samsung 960 PRO.
The price of the Intel Optane SSD 900P is accessible enough that many enthusiasts will pay the premium to have the bragging rights of the fastest SSD money can buy. Workstation users who have massive datasets that don't fit in RAM will jump at the chance to buy a faster scratch drive. And if that isn't enough to clear the shelves, then enterprise customers who need high performance but don't need the extreme write endurance of the Intel Optane SSD DC P4800X can get the 900P with its solid 10 DWPD endurance rating for a third the price per GB. The Optane SSD 900P isn't for everybody, but it will nonetheless be a successful product, and Intel won't have any trouble selling them.
The long-term prospects for Intel's Optane SSDs look pretty good, too. The pricing doesn't leave Samsung a lot of room to introduce a Z-NAND based consumer SSD. No other alternative nonvolatile memory technology is close to being ready to challenge 3D XPoint. Intel could improve the sequential transfer speeds, but they're good enough for now. They'll need to deliver a big jump in performance when they adopt PCIe Gen 4, but that shouldn't be a challenge: increasing the controller's channel count from 7 to the 12 channels used by their current NAND flash controller or the 18 used by their first NVMe controller will bring plenty of extra throughput. The only question will then be over the power consumption. The latency is already close to being as low as possible over a PCIe link, and NVDIMMs with 3D XPoint won't be making Optane SSDs obsolete in the consumer market anytime soon.
In many ways, the performance profile of the Optane SSD is far simpler than that of NAND flash based SSDs. The Optane SSD 900P performs just as well when it is full as when it is almost empty. It performs quite consistently over time, with far fewer high-latency outliers thanks to the lack of garbage collection stalls. Unlike with flash-based SSDs, it is not necessary to buy the largest model to get the highest possible performance; the 280GB model we tested should be very similar to the 480GB model (which we're waiting for review). It doesn't matter whether TRIM commands are used, and it's never necessary to perform a secure erase operation to restore degraded performance.
Intel has almost taken all the fun out of testing a SSD.
Facebook
Twitter
RSS
205 Comments
View All Comments
Kevin G - Monday, October 30, 2017 - link
The software side does lag behind hardware by a substantial amount of time. However, the ground work is already being done. The first initial wave of support will be mundane as a 'RAM disk' but with firmware/hypervisor/OS support so that only Optane DIMMs are utilized for this functionality. Software overhead would still exist for the file system but legacy support would be maintained. I think patches already exist for this level of functionality in Linux, though I'm unsure if they're been rolled into the mainstream kernel.Kevin G - Monday, October 30, 2017 - link
Intel still has this potential on their road maps for 2018 with the Cascade Lake Xeons. Supporting Optane as memory requires some changes in the memory controllers and Intel is only targeting their Xeon lineup with such support. This was initially to arrive with Sky Lake-EP but was cut at the last minute due to apparently some bugs found in testing. This is what there are a few Sky Lake-EP motherboards out there with an extra memory slot that can't be used: it was only for the unreleased Optane DIMMs.The other thing is that Optane DIMMs were NEVER hyped to be faster than commodity DRAM. Intel never set that expectation and from all accounts, Optane is genuinely slower. However, byte addressability is there as is a strong increase in endurance for it to function in such a role, if slower. Any sort of performance gains will stems form various ideas that you mention, like the removal of a traditional storage stack etc.
The other side of storage is capacity which Intel has really yet to demonstrate. Their talk of Optane DIMMs were to hit 1 TB per DIMM eventually but the sizes here point toward capacities in DIMM format roughly the same as traditional DIMMs (128 GB right now in servers with 256 GB on the horizon). I know of a few big data guys that dream of a system that could easily support 96 TB (1 TB DIMM per slot, 12 DIMM slots per socket, 8 sockets total) that would permit their entire cluster to be run on a single node and in-memory. At this point having the Optane DIMMs being slower than DRAM wouldn't matter as it would eliminate traditional bulk storage and networking overhead which are slower still. The potential is huge at the highend if Intel can get the technology out in the right form factor and at the capacities they need.
Only reason Intel is launching like this now is that they need to get the technology out there and ramp up production. If it weren't for the Sky Lake bug, they would have launched the DIMM format by now.
4shrovetide - Sunday, October 29, 2017 - link
If someone picks up one of these and doesn't play games or just doesn't want the Star Citizen code, would you mind sending it to me? 4shrovetide@gmail.com Thank you in advance to anyone who helps out!AnnonymousCoward - Sunday, October 29, 2017 - link
What a copycat name, 900P! Like 950 Pro.Kevin G - Sunday, October 29, 2017 - link
I'm disappointed over all.The latency advantage is genuinely there as is random performance (which latency is factor in itself) but sequential performance falls short of the hype. What is disappointing as well is that only the 280 GB drive is going to be offered in U.2 format and capacities top out at 480 GB even of the add-in card model. The real ugly factor is power consumption which to Intel's credit wasn't hyping up prior to launch is high relative to other SSD solutions.
The biggest promise of 3D Xpoint/Optane is in DIMM form factor with byte addressability. Intel delayed that last minute with Sky Lake-EP and told people to expect that with Cannon Lake-EP. It looks like Cannon Lake-EP is being delayed due 10 nm issues into 2019 so we're getting a 2018 refresh of Sky Lake-EP called Cascade Lake with the missing Optane DIMM support back-in. The hype of Optane was that while radically slower than DRAM, you do get nonvolatile support and a massive capacity increase, everything else being equal. The performance equation does change as operating system and applications are adapted to an all in-memory centric view (i.e. the concept of long term disk storage is removed, everything is seen as 'in-memory'). It isn't that Optane magically becomes faster but simply that a chunk of software necessary to work in today's view of fast volatile memory and slow persistent memory is no longer needed. It is simply an opportunity to gain in algorithmic efficiency by not having a traditional storage stack. This effect can be seen again if Optane DIMM sizes are well beyond that of DDR4 DIMMs and used in conjunction with large socket (think 8 or more) that could replace some clustered workloads and removing the networking stack from the performance equation.
The really big disappointment is this launch doesn't point toward living up to the remaining hype at all. The lack luster capacity today certainly implies that the DIMM sizes necessary to threaten DRAM may not happen. 128 GB registered ECC DDR4 LR-DIMMs are out there today and 256 GB models are on the horizon. From the looks of it, Optane could make the 256 GB capacities in DIMM form and certainly come in cheaper but that wouldn't be as large of a game changer. Sure, the software changes for a pure in-memory system could still happen but it wouldn't enable any new workload that couldn't be done via current software and memory capacities. Tried and proven will win out even if it is more expensive because it is known quantity that works.
"Bullwinkle J Moose" - Monday, October 30, 2017 - link
Any thoughts on Advanced Persistent Threats that will be lingering around when 3D Xpoint/Optane is in DIMM form factor ?Seems no-one has yet been willing to address the issue
I would never consider persistent memory for just that reason alone
And, swapping boot drives or restoring backups won't help it seems
Any comments on the issue?
Kevin G - Monday, October 30, 2017 - link
While a threat may persist in non-volatile memory, it still needs to be executed which is invoked from the host system. Cleansing an Optane DIMM maybe as simple as putting it into a system that is programmed to immediate wipe said Optane DIMM. There will always need to be a means to do some initial configuration/initialization which would be embedded at the firmwire level. In other words, the DIMMs don't have to be running an OS for them to be securely erased.Similarly, moving a DIMM from one system to another system is also possible, though the default should actually be to do nothing by default. As weird as it is, there exists the possibility of moving a running application from system to system by this method. This goes to your point about security. Thus the default for any system capable of hot swap or detecting a newly installed DIMM after power cycle, should not actually access the contents of that DIMM until given instructions to access it.
"Bullwinkle J Moose" - Monday, October 30, 2017 - link
But wiping the DIMM defeats its very purpose for existing..............PERSISTENCE!Kaspersky found out how bad malware can be when it only runs in system memory and never touches a disk, networking the infected systems added persistence to the threat
If you need to wipe the DIMM or disconnect from any networked machines, you eliminate any tiny perceived benefit this technology "could" give you over the tech we already have
I say "Tiny" benefit only as it relates to the "massive" threat it can create from being persistent
regis440 - Monday, October 30, 2017 - link
Faster then SDRAM PC133. Sign of the time :)jrs77 - Monday, October 30, 2017 - link
General purpose storage starts at a very minimum of 1TB these days. 2TB would be more appropiate with the ever growing filesizes of high resolution video and image-files.480GB is filled up with a handfull of game-installations allready these days. So these SSDs are only usable as OS/software disks and for that the price is way too high.
Call me again when SSD-prices drop to ~ $100 / TB. Then we're talking usability as general storage drives.