Whole-Drive Fill

This test starts with a freshly-erased drive and fills it with 128kB sequential writes at queue depth 32, recording the write speed for each 1GB segment. This test is not representative of any ordinary client/consumer usage pattern, but it does allow us to observe transitions in the drive's behavior as it fills up. This can allow us to estimate the size of any SLC write cache, and get a sense for how much performance remains on the rare occasions where real-world usage keeps writing data after filling the cache.

Both tested capacities of the 980 PRO perform more or less as advertised at the start of the test: 5GB/s writing to the SLC cache on the 1TB model and 2.6GB/s writing to the cache on the 250GB model - the 1 TB model only hits 3.3 GB/s when in PCIe 3.0 mode. Surprisingly, the apparent size of the SLC caches is larger than advertised, and larger when testing on PCIe 4 than on PCIe 3: the 1TB model's cache (rated for 114GB) lasts about 170GB @ Gen4 speeeds and about 128GB @ Gen3 speeds, and the 250GB model's cache (rated for 49GB) lasts for about 60GB on Gen4 and about 49GB on Gen3. If anything it seems that these SLC cache areas are quoted more for PCIe 3.0 than PCIe 4.0 - under PCIe 4.0 however, there might be a chance to free up some of the SLC as the drive writes to other SLC, hence the increase.

An extra twist for the 1TB model is that partway through the drive fill process, performance returns to SLC speeds and stays there just as long as it did initially: another 170GB written at 5GB/s (124GB written at 3.3GB/s on Gen3). Looking back at the 970 EVO Plus and 970 EVO we can see similar behavior, but it's impressive Samsung was able to continue this with the 980 PRO while providing much larger SLC caches—in total, over a third of the drive fill process ran at the 5GB/s SLC speed, and performance in the TLC writing phases was still good in spite of the background work to flush the SLC cache.

Sustained 128kB Sequential Write (Power Efficiency)
Average Throughput for last 16 GB Overall Average Throughput

On the Gen4 testbed, the overall average throughput of filling the 1TB 980 PRO is only slightly slower than filling the MLC-based 970 PRO, and far faster than the other 1TB TLC drives. Even when limited by PCIe Gen3, the 980 Pro's throughput remains in the lead. The smaller 250GB model doesn't make good use of PCIe Gen4 bandwidth during this sequential write test, but it is a clear improvement over the same capacity of the 970 EVO Plus.

Working Set Size

Most mainstream SSDs have enough DRAM to store the entire mapping table that translates logical block addresses into physical flash memory addresses. DRAMless drives only have small buffers to cache a portion of this mapping information. Some NVMe SSDs support the Host Memory Buffer feature and can borrow a piece of the host system's DRAM for this cache rather needing lots of on-controller memory.

When accessing a logical block whose mapping is not cached, the drive needs to read the mapping from the full table stored on the flash memory before it can read the user data stored at that logical block. This adds extra latency to read operations and in the worst case may double random read latency.

We can see the effects of the size of any mapping buffer by performing random reads from different sized portions of the drive. When performing random reads from a small slice of the drive, we expect the mappings to all fit in the cache, and when performing random reads from the entire drive, we expect mostly cache misses.

When performing this test on mainstream drives with a full-sized DRAM cache, we expect performance to be generally constant regardless of the working set size, or for performance to drop only slightly as the working set size increases.

Since these are all high-end drives, we don't see any of the read performance drop-off we expect from SSDs with limited or no DRAM buffers. The two drives using Silicon Motion controllers show a little bit of variation depending on the working set size, but ultimately are just as fast when performing random reads across the whole drive as they are reading from a narrow range. The read latency measured here for the 980 PRO is an improvement of about 15% over the 970 EVO Plus, but is not as fast as the MLC-based 970 PRO.

Testing PCIe 4.0 AnandTech Storage Bench
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  • Nyceis - Thursday, October 1, 2020 - link

    Wonder when the 2TB will be available.... Reply
  • Oxford Guy - Saturday, October 3, 2020 - link

    We hope you won’t notice it’s an EVO. Reply
  • jtester - Wednesday, October 14, 2020 - link

    I am no expert on comparing SSDs, but why are people saying the testing shows that the 970 pro is better to have than the 980 pro? MOST of the charts show the 980 pro well above the 970 pro and even the 970 evo and 970 evo plus above the 970 pro.

    So what am i missing? And although the 970 pro is MLC, a 2tb evo plus would have the same 1200 for writes/endurance, albeit due to twice the space (but the more space is also a plus).

    I actually have a 970 pro ordered because I got a deal where after discounts, even after tax, I am spending only $240. But I made the purchase just based on what people have said before about MLC and the evos needing an SLC cache, etc... But once I looked closer, I realized all of these specs where the evos (970 and 980) seem to be faster and the caches are big for most people.

    hopefully, someone can explain where I know whether to cancel the order and get another evo plus or 980 pro instead... I have asked all over the place online and nobody gives me straight answers.
    Reply
  • entrigant - Wednesday, November 11, 2020 - link

    So the new Pro is an EVO. Wonderful. This is most disappointing. :( Guess I should stock up on 970 Pro's while I still can. Reply
  • ph1nn - Friday, November 27, 2020 - link

    So basically the 980 Pro is a complete disaster considering the couple year old SX8200 Pro is beating it almost across the board and is half the price. Anandtech is disappointing here they should have been far more critical about this ssd. Reply
  • Krakadoom - Wednesday, January 27, 2021 - link

    I'm getting terrible IOPS numbers on this drive (980 pro 1 tb). Well not terrible, but noticeably worse than my 970 EVO 1 tb (not even the plus model). On the 980 pro: IOPS read at 374.511 and write at 334.228. On the 970 evo: IOPS read at 422.363 and write at 342.529.

    That's both surprising and disappointing. Would not have bought it had I known this, it's advertised as up to 1.000.000 IOPS both read and write. I'm on PCI-E gen 3, so I might as well have spent less on another 970 evo then and gotten better performance.

    Don't see anything from Samsung or anyone else about this issue, apart from there not being a Samsung driver for the 980 pro yet, so it still runs on the standard Microsoft driver, where all my other drives use the Samsung driver. Maybe that's why, but that should have been ready at launch of a flagship product.
    Reply
  • chickenballs - Sunday, February 21, 2021 - link

    for most ppl the ADATA 8200pro is more than enough and costs half as much Reply

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