Burst IO Performance

Our burst IO tests operate at queue depth 1 and perform several short data transfers interspersed with idle time. The random read and write tests consist of 32 bursts of up to 64MB each. The sequential read and write tests use eight bursts of up to 128MB each. For more details, please see the overview of our 2021 Consumer SSD Benchmark Suite.

QD1 Burst IO Performance
Random Read Random Write
Sequential Read Sequential Write

The WD Black SN850 turns in excellent scores on almost all of the burst IO tests. For random reads, it edges out the Intel SSD 670p to set a new record for flash-based SSDs, and even when testing beyond the bounds of any possible SLC caching it is only 2% slower than the MLC-based Samsung 970 PRO. For random writes the WD Black SN850 is slightly slower than the Phison E16 drive, but otherwise is s clear step up in performance from the rest of the field. When testing sequential transfers on a small slice of the drive, the SN850 is substantially faster than everything else, but when testing across 80% of the drive its sequential read performance drops dramatically and is beat by the Samsung 980 PRO and several of the faster PCIe 3.0 drives.

Sustained IO Performance

Our sustained IO tests exercise a range of queue depths and transfer more data than the burst IO tests, but still have limits to keep the duration somewhat realistic. The primary scores we report are focused on the low queue depths that make up the bulk of consumer storage workloads. For more details, please see the overview of our 2021 Consumer SSD Benchmark Suite.

Sustained IO Performance
Random Read Throughput Power Efficiency
Random Write Throughput Power Efficiency
Sequential Read Throughput Power Efficiency
Sequential Write Throughput Power Efficiency

On the longer random read test, the WD Black SN850 doesn't quite stand out from the best performance offered by other drives with newer flash. But on the other three workloads the SN850 is clearly superior, with significant performance leads over the rest of the competition. Its power consumption is consistently on the high side and in some cases it is drawing more than any of the other drives, but the performance is high enough that the efficiency scores are all good.

Random Read
Random Write
Sequential Read
Sequential Write

For random reads, the SN850 eventually ramps up to around 4GB/s or 1M IOPS at the end of the test, which is significantly faster than any other drive that we've tested so far on this new test suite. However, when testing across 80% of the drive instead of just a 32GB slice, the random read performance falls to roughly the same level as the Samsung 980 PRO.

For random writes, the SN850's performance scales up a bit quicker than the 980 PRO, but it hits a throughput limit sooner and the 980 PRO ends up being much faster for random writes to the SLC cache at high queue depth.

For sequential reads, the SN850 ends up slightly faster than the 980 PRO, but when testing across 80% of the drive the Samsung reaches full performance with a lower queue depth. For sequential writes the SN850 is again a bit faster than the 980 PRO and this time it doesn't need higher queue depths to reach full speed, but it also starts running out of SLC cache before the test is over while the 980 PRO maintains full performance through the end of the test.

Random Read Latency

This test illustrates how drives with higher throughput don't always offer better IO latency and Quality of Service (QoS), and that latency often gets much worse when a drive is pushed to its limits. This test is more intense than real-world consumer workloads and the results can be a bit noisy, but large differences that show up clearly on a log scale plot are meaningful. For more details, please see the overview of our 2021 Consumer SSD Benchmark Suite.

The WD Black SN850 starts off this test with good random read latency, but around 80k IOPS it shifts gears and latency spikes alarmingly. It actually improves a few times later in the test so by the time the drive is approaching its throughput limit, it is only a bit slower than the Samsung 980 PRO.

Trace Tests: AnandTech Storage Bench and PCMark 10 Advanced Synthetic Tests: Block Sizes and Cache Size Effects
POST A COMMENT

82 Comments

View All Comments

  • Duncan Macdonald - Thursday, March 18, 2021 - link

    For people who want performance and endurance above price, it would be nice if one of the major manufacturers made a variant with a firmware change that used the NAND in SLC mode only. This would reduce the capacity to 1/3 of the usual TLC mode but would give the same speed as SLC cache mode for the whole of the drive. (No hardware change would be needed - just different firmware for the controller.) Reply
  • jamesindevon - Friday, March 19, 2021 - link

    You could get something like the Sabrent Rocket Q, and leave 75% of it unpartitioned. The Anandtech review makes it clear that in that mode, it will use the other 25% as SLC.
    https://www.anandtech.com/show/16136/qlc-8tb-ssd-r...
    Reply
  • ichaya - Friday, March 19, 2021 - link

    I was looking for something just like this, it's this or Optane, and if QLC/TLC drive manufacturers did offer this in firmware or partitioning, Optane for consumers might as well be dead. Reply
  • FunBunny2 - Friday, March 19, 2021 - link

    "firmware change that used the NAND in SLC mode only"

    I seem to recall, likely here, that SLC mode for [M/T/Q]LC NAND isn't near the performance of 'real' SLC NAND. anyone?
    Reply
  • Fujikoma - Monday, March 29, 2021 - link

    SLC=2/MLC=4/TLC=8/QLC=16... would be 1/4. Personally would be happy if they offered MLC for the enthusiast versions. Reply
  • eastcoast_pete - Thursday, March 18, 2021 - link

    Thanks Billy!
    One aspect of this and the other PCIe 4.0 drives I have been wondering about is: do they really need 4 lanes to reach their full speed? The reason for my question is that I can imagine situations (e.g. Intel's Rocket Lake) where only 20 or even fewer total 4.0 lanes are available, and having 2 lanes more left for other uses might make a difference. So, are those 4 PCIe 4.0 lanes per drive really needed for full speed of this and similar SSDs?
    Reply
  • James5mith - Thursday, March 18, 2021 - link

    Yes. 4x PCIe4.0 lanes is ~8GB/s full duplex bandwidth (2GB/s per lane). These drives are hitting 7+GB/s of bandwidth at max utilization. Reply
  • James5mith - Thursday, March 18, 2021 - link

    I've been Really enjoying the performance of my new Sabrent Rocket 4 Plus. I think Anandtech should add it to the comparisons for PCIe 4.0 drives going forward. Reply
  • James5mith - Thursday, March 18, 2021 - link

    https://www.sabrent.com/product/SB-RKT4P-4TB/4tb-r... Reply
  • Unashamed_unoriginal_username_x86 - Thursday, March 18, 2021 - link

    ... Is this astroturfing? Reply

Log in

Don't have an account? Sign up now