The new Galaxy S21 series of devices have been out commercially for a week now, and we’ve managed to get our hands on two Galaxy S21 Ultras – one with Qualcomm’s new Snapdragon 888 SoC, and one with Samsung’s new Exynos 2100 SoC. Both chipsets this year are more similar than ever, both now sporting similar CPU configurations, and both being produced on a new Samsung 5nm (5LPE) process node.

Ahead of our full device review of the Galaxy S21 Ultra (and the smaller Galaxy S21), today we’re focusing on the first test results of the new generation of SoCs, putting them through their paces, and pitting them against each other in the new 2021 competitive landscape.

The Snapdragon 888

Qualcomm Snapdragon Flagship SoCs 2020-2021
SoC Snapdragon 865

Snapdragon 888

CPU 1x Cortex-A77
@ 2.84GHz 1x512KB pL2

3x Cortex-A77
@ 2.42GHz 3x256KB pL2

4x Cortex-A55
@ 1.80GHz 4x128KB pL2

4MB sL3
1x Cortex-X1
@ 2.84GHz 1x1024KB pL2

3x Cortex-A78
@ 2.42GHz 3x512KB pL2

4x Cortex-A55
@ 1.80GHz 4x128KB pL2

4MB sL3
GPU Adreno 650 @ 587 MHz Adreno 660 @ 840MHz
DSP / NPU Hexagon 698

15 TOPS AI
(Total CPU+GPU+HVX+Tensor)
Hexagon 780

26 TOPS AI
(Total CPU+GPU+HVX+Tensor)
Memory
Controller
4x 16-bit CH

@ 2133MHz LPDDR4X / 33.4GB/s
or
@ 2750MHz LPDDR5  /  44.0GB/s

3MB system level cache
4x 16-bit CH

@ 3200MHz LPDDR5  /  51.2GB/s

3MB system level cache
ISP/Camera Dual 14-bit Spectra 480 ISP

1x 200MP or 64MP with ZSL
or
2x 25MP with ZSL



4K video & 64MP burst capture
Triple 14-bit Spectra 580 ISP

1x 200MP or 84MP with ZSL
or
64+25MP with ZSL
or
3x 28MP with ZSL

4K video & 64MP burst capture
Encode/
Decode
8K30 / 4K120 10-bit H.265

Dolby Vision, HDR10+, HDR10, HLG

720p960 infinite recording
8K30 / 4K120 10-bit H.265

Dolby Vision, HDR10+, HDR10, HLG

720p960 infinite recording
Integrated Modem none
(Paired with external X55 only)


(LTE Category 24/22)
DL = 2500 Mbps
7x20MHz CA, 1024-QAM
UL = 316 Mbps
3x20MHz CA, 256-QAM

(5G NR Sub-6 + mmWave)
DL = 7000 Mbps
UL = 3000 Mbps
X60 integrated


(LTE Category 24/22)
DL = 2500 Mbps
7x20MHz CA, 1024-QAM
UL = 316 Mbps
3x20MHz CA, 256-QAM

(5G NR Sub-6 + mmWave)
DL = 7500 Mbps
UL = 3000 Mbps
Mfc. Process TSMC
7nm (N7P)
Samsung
5nm (5LPE)
     

Starting off with the new Snapdragon 888 SoC, Qualcomm’s new flagship model makes iterative steps this generation, with the biggest changes of the new design actually being in the form of the new Hexagon 780 accelerator, which fuses together traditional scalar and vector DSP operations with tensor execution engines within one single IP block.

Of course, we’re also seeing upgrades elsewhere in the architecture, with the Snapdragon 888 being among the first SoCs to use Arm’s new Cortex-X1 CPU IP, promising large performance gains relative to last generation Cortex-A77 cores. The single X1 cores in the Snapdragon 888 clocks in at 2.84GHz – the same as the previous generation Snapdragon 865’s prime Cortex-A77 cores, and less than the 3.1GHz and 3.2GHz Snapdragon 865+ and recently announced Snapdragon 870 SoCs.

Alongside the X1, we find three Cortex-A78 cores at 2.42GHz, again the same clocks as the previous generation 865 SoCs, but this time around with double the L2 caches at 512KB.

The Cortex-A55 little cores remain identical this generation, clocking in at 1.8GHz.

Although we had been expecting 8MB L3 cache flagship SoCs this year, it does look like Qualcomm opted to remain at 4MB for this generation – but at least the company dons the X1 core with the maximum 1MB L2 cache configuration.

On the GPU side of things, Qualcomm’s new Adreno 660 GPU now clocks in up to a peak 840MHz – a whopping 43% higher frequency than the Snapdragon 865 GPU. The company’s performance claims here are also astonishing, promising a +35% boost in performance. We’ll have to see how this all ends up in terms of power consumption and long-term performance in the later dedicated GPU section.

What’s quite different for the Snapdragon 888 this year is that Qualcomm has moved from a TSMC N7P process node to Samsung’s new 5LPE node – the generally wildcard in this whole situation as we haven’t had any prior experience with this new 5nm node.

The Exynos 2100

Samsung Exynos SoCs Specifications
SoC

Exynos 990

Exynos 2100

CPU 2x Exynos M5
@ 2.73GHz 2MB sL2
3MB sL3

2x Cortex-A76
@ 2.50GHz 2x256KB pL2

4x Cortex-A55
@ 2.00GHz 4x64KB pL2

1MB sL3
1x Cortex-X1
@ 2.91GHz 1x512KB pL2

3x Cortex-A78
@ 2.81GHz 3x512KB pL2

4x Cortex-A55
@ 2.20GHz 4x64KB pL2

4MB sL3
GPU Mali G77MP11 @ 800 MHz Mali G78MP14 @ 854 MHz
Memory
Controller
4x 16-bit CH

@ 2750MHz LPDDR5  /  44.0GB/s

2MB System Cache
4x 16-bit CH

3200MHz LPDDR5  /  51.2GB/s

6MB System Cache
ISP Single: 108MP
Dual: 24.8MP+24.8MP
Single: 200MP
Dual: 32MP+32MP

(Up to quad simultaneous camera)
NPU Dual NPU + DSP + CPU + GPU
15 TOPs
Triple NPU + DSP + CPU + GPU
26 TOPs
Media 8K30 & 4K120 encode & decode
H.265/HEVC, H.264, VP9
8K30 & 4K120 encode &
8K60 decode


H.265/HEVC, H.264, VP9
AV1 Decode
Modem Exynos Modem External 

(LTE Category 24/22)
DL = 3000 Mbps
8x20MHz CA, 1024-QAM
UL = 422 Mbps
?x20MHz CA, 256-QAM

(5G NR Sub-6)
DL = 5100 Mbps

(5G NR mmWave)
DL = 7350 Mbps
Exynos Modem Integrated

(LTE Category 24/18)
DL = 3000 Mbps
8x20MHz CA, 1024-QAM
UL = 422 Mbps
4x20MHz CA, 256-QAM

(5G NR Sub-6)
DL = 5100 Mbps
UL = 1920Mbps

(5G NR mmWave)
DL = 7350 Mbps
UL = 3670 Mbps
Mfc. Process Samsung
7nm (7LPP)
Samsung
5nm (5LPE)

On the Samsung LSI side of things, we find the brand-new Exynos 2100. Unlike the Snapdragon 888’s more incremental changes in terms of SoC design, the new Exynos is a rather large departure for Samsung’s SoC division as this is the first flagship design in many years that no longer uses Samsung’s own in-house CPU microarchitecture, but rather reverts back to using Arm Cortex cores, which in this case is also the new Cortex-X1 and Cortex-A78 cores.

From a high-level, the CPU configuration of the Exynos 2100 looks nigh identical to that of the Snapdragon 888, as both are 1+3+4 designs with X1, A78 and A55 cores. The differences are in the details:

The X1 cores on the Exynos 2100 clock slightly higher at up to 2.91GHz, while the Cortex-A78 clock in significantly higher than the Snapdragon as they reach 2.81GHz. The Cortex-A55 cores are also quite aggressive in terms of frequency as they now reach 2.20GHz – so overall across the board higher clocks than the Snapdragon variant.

Where the Exynos isn’t as aggressive though is in its cache configurations. Most importantly, the X1 cores here only feature 512KB of L2 cache, which is a bit weird given the all-out-performance philosophy of the new CPU. The Cortex-A78s also see the usage of 512KB L2 caches, while the little A55 cores feature 64KB L2’s – less than the Snapdragon counterparts.

Much like the Snapdragon, the L3 cache also falls in at 4MB rather than the 8MB we would have hoped for this generation, however Samsung does surprise us with the usage of an estimated 6-8MB system level cache, up from the 2MB design in the Exynos 990.

On the GPU side of things, we see a Mali-G78MP14 at up to 854MHz. That’s 27% more cores and 6.7% higher frequency, and the company is also boasting massive performance gains as it touts a 40% generational improvement.

Let them fight

In today piece, we’ll be mostly focusing around CPU and GPU performance, as an especially interesting comparison will be to see how the two designs do against each other, given that they both now use Arm’s newest Cortex-X1 cores and both are sporting the same manufacturing node.

The GPU comparisons will also be interesting – and maybe quite controversial, as the results won’t be what many people will have been expecting.

While we would have liked to showcase AI performance of the two SoCs – unfortunately the software situation on the Galaxy S21’s right now means that neither SoC are fully taking advantage of their new accelerators, so that’s a topic to revisit in a few months’ time once the proper frameworks have been updated by Samsung.

Table Of Contents

5nm / 5LPE: What Do We Know?
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121 Comments

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  • Kishoreshack - Monday, February 8, 2021 - link

    Soo next year are we gonna have Snapdragon flagship at a better process node or not?
    There is absolutely no compulsion for Qualcomm to push for a better process node
    Apple will run with things
    Reply
  • SarahKerrigan - Monday, February 8, 2021 - link

    Oof. Those numbers are rough, and not a good look at all for 5lpe.

    Wonder if we'll see X1/A78 on N5 any time soon. With Hisilicon out of the picture, who would even be the obvious candidate for that? Mediatek?
    Reply
  • Spunjji - Monday, February 8, 2021 - link

    Mediatek would be an odd candidate, given their tendency to focus on area efficiency, but it'd be a nice surprise if they branched out a bit! Reply
  • lmcd - Monday, February 8, 2021 - link

    Yea they'd definitely skip the X1 core. Which honestly might be the correct move based on results, the X1 is better but maybe not enough better to justify the die space. Reply
  • Spunjji - Thursday, February 11, 2021 - link

    It certainly seems like it would make more sense on an SoC design aimed at larger devices. Reply
  • geoxile - Monday, February 8, 2021 - link

    My experience with Samsung Electronics was heavy use of outsourcing and indian workers, on their software side. I wouldn't be surprised if that's the case for their hardware too. Very poor results for their 5lpe vs TSMC's N7. They're becoming obsessed with cutting costs. Reply
  • iphonebestgamephone - Monday, February 8, 2021 - link

    Why would being indian be the reason? Reply
  • jospoortvliet - Wednesday, February 10, 2021 - link

    It wouldn't but they aren't local to South Korea, and India has a lot of IT competence so it is a place many companies outsource to.... and outsourcing usually doesn't help quality. Reply
  • iphonebestgamephone - Monday, February 15, 2021 - link

    You get what you pay for ofc. Reply
  • iphonebestgamephone - Monday, February 15, 2021 - link

    If its like you said and tsmc outsourced indians too, they are just better because they paid for the better workers. Reply

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