Info TOP 20 of the World's Most Powerful CPU Cores - IPC/PPC comparison

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Richie Rich

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Jul 28, 2019
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Added cores:
  • A53 - little core used in some low-end smartphones in 8-core config (Snapdragon 450)
  • A55 - used as little core in every modern Android SoC
  • A72 - "high" end Cortex core used in Snapdragon 625 or Raspberry Pi 4
  • A73 - "high" end Cortex core
  • A75 - "high" end Cortex core
  • Bulldozer - infamous AMD core
Geekbench 5.1 PPC chart 6/23/2020:

Pos
Man
CPU
Core
Year
ISA
GB5 Score
GHz
PPC (score/GHz)
Relative to 9900K
Relative to Zen3
1​
Nuvia​
(Est.)​
Phoenix (Est.)​
2021​
ARMv9.0​
2001​
3.00​
667.00​
241.0%​
194.1%​
2​
Apple​
A15 (est.)​
(Est.)​
2021​
ARMv9.0​
1925​
3.00​
641.70​
231.8%​
186.8%​
3​
Apple​
A14 (est.)​
Firestorm​
2020​
ARMv8.6​
1562​
2.80​
558.00​
201.6%​
162.4%​
4​
Apple​
A13​
Lightning​
2019​
ARMv8.4​
1332​
2.65​
502.64​
181.6%​
146.3%​
5​
Apple​
A12​
Vortex​
2018​
ARMv8.3​
1116​
2.53​
441.11​
159.4%​
128.4%​
6​
ARM Cortex​
V1 (est.)​
Zeus​
2020​
ARMv8.6​
1287​
3.00​
428.87​
154.9%​
124.8%​
7​
ARM Cortex​
N2 (est.)​
Perseus​
2021​
ARMv9.0​
1201​
3.00​
400.28​
144.6%​
116.5%​
8​
Apple​
A11​
Monsoon​
2017​
ARMv8.2​
933​
2.39​
390.38​
141.0%​
113.6%​
9​
Intel​
(Est.)​
Golden Cove (Est.)​
2021​
x86-64​
1780​
4.60​
386.98​
139.8%​
112.6%​
10​
ARM Cortex​
X1​
Hera​
2020​
ARMv8.2​
1115​
3.00​
371.69​
134.3%​
108.2%​
11
AMD
5900X (Est.)
Zen 3 (Est.)
2020
x86-64
1683
4.90
343.57
124.1%
100.0%
12​
Apple​
A10​
Hurricane​
2016​
ARMv8.1​
770​
2.34​
329.06​
118.9%​
95.8%​
13​
Intel​
1065G7​
Icelake​
2019​
x86-64​
1252​
3.90​
321.03​
116.0%​
93.4%​
14​
ARM Cortex​
A78​
Hercules​
2020​
ARMv8.2​
918​
3.00​
305.93​
110.5%​
89.0%​
15​
Apple​
A9​
Twister​
2015​
ARMv8.0​
564​
1.85​
304.86​
110.1%​
88.7%​
16
AMD
3950X
Zen 2
2019
x86-64
1317
4.60
286.30
103.4%
83.3%
17​
ARM Cortex​
A77​
Deimos​
2019​
ARMv8.2​
812​
2.84​
285.92​
103.3%​
83.2%​
18​
Intel​
9900K​
Coffee LakeR​
2018​
x86-64​
1384​
5.00​
276.80​
100.0%​
80.6%​
19​
Intel​
10900K​
Comet Lake​
2020​
x86-64​
1465​
5.30​
276.42​
99.9%​
80.5%​
20​
Intel​
6700K​
Skylake​
2015​
x86-64​
1032​
4.00​
258.00​
93.2%​
75.1%​
21​
ARM Cortex​
A76​
Enyo​
2018​
ARMv8.2​
720​
2.84​
253.52​
91.6%​
73.8%​
22​
Intel​
4770K​
Haswell​
2013​
x86-64​
966​
3.90​
247.69​
89.5%​
72.1%​
23​
AMD​
1800X​
Zen 1​
2017​
x86-64​
935​
3.90​
239.74​
86.6%​
69.8%​
24​
Apple​
A13​
Thunder​
2019​
ARMv8.4​
400​
1.73​
231.25​
83.5%​
67.3%​
25​
Apple​
A8​
Typhoon​
2014​
ARMv8.0​
323​
1.40​
230.71​
83.4%​
67.2%​
26​
Intel​
3770K​
Ivy Bridge​
2012​
x86-64​
764​
3.50​
218.29​
78.9%​
63.5%​
27​
Apple​
A7​
Cyclone​
2013​
ARMv8.0​
270​
1.30​
207.69​
75.0%​
60.5%​
28​
Intel​
2700K​
Sandy Bridge​
2011​
x86-64​
723​
3.50​
206.57​
74.6%​
60.1%​
29​
ARM Cortex​
A75​
Prometheus​
2017​
ARMv8.2​
505​
2.80​
180.36​
65.2%​
52.5%​
30​
ARM Cortex​
A73​
Artemis​
2016​
ARMv8.0​
380​
2.45​
155.10​
56.0%​
45.1%​
31​
ARM Cortex​
A72​
Maya​
2015​
ARMv8.0​
259​
1.80​
143.89​
52.0%​
41.9%​
32​
Intel​
E6600​
Core2​
2006​
x86-64​
338​
2.40​
140.83​
50.9%​
41.0%​
33​
AMD​
FX-8350​
BD​
2011​
x86-64​
566​
4.20​
134.76​
48.7%​
39.2%​
34​
AMD​
Phenom 965 BE​
K10.5​
2006​
x86-64​
496​
3.70​
134.05​
48.4%​
39.0%​
35​
ARM Cortex​
A57 (est.)​
Atlas​
0​
ARMv8.0​
222​
1.80​
123.33​
44.6%​
35.9%​
36​
ARM Cortex​
A15 (est.)​
Eagle​
0​
ARMv7 32-bit​
188​
1.80​
104.65​
37.8%​
30.5%​
37​
AMD​
Athlon 64 X2 3800+​
K8​
2005​
x86-64​
207​
2.00​
103.50​
37.4%​
30.1%​
38​
ARM Cortex​
A17 (est.)​
0​
ARMv7 32-bit​
182​
1.80​
100.91​
36.5%​
29.4%​
39​
ARM Cortex​
A55​
Ananke​
2017​
ARMv8.2​
155​
1.60​
96.88​
35.0%​
28.2%​
40​
ARM Cortex​
A53​
Apollo​
2012​
ARMv8.0​
148​
1.80​
82.22​
29.7%​
23.9%​
41​
Intel​
Pentium D​
P4​
2005​
x86-64​
228​
3.40​
67.06​
24.2%​
19.5%​
42​
ARM Cortex​
A7 (est.)​
Kingfisher​
0​
ARMv7 32-bit​
101​
1.80​
56.06​
20.3%​
16.3%​

GB5-PPC-evolution.png

GB5-STperf-evolution.png

TOP10PPC_CPU_frequency_evolution_graph.png



TOP 10 - Performance Per Area comparison at ISO-clock (PPA/GHz)

Copied from locked thread. They try to avoid people to see this comparison how x86 is so bad.[/B]

Pos
Man
CPU
Core
Core Area mm2
Year
ISA
SPEC PPA/Ghz
Relative
1​
ARM Cortex​
A78​
Hercules​
1.33​
2020​
ARMv8​
9.41​
100.0%​
2​
ARM Cortex​
A77​
Deimos​
1.40​
2019​
ARMv8​
8.36​
88.8%​
3​
ARM Cortex​
A76​
Enyo​
1.20​
2018​
ARMv8​
7.82​
83.1%​
4​
ARM Cortex​
X1​
Hera​
2.11​
2020​
ARMv8​
7.24​
76.9%​
5​
Apple​
A12​
Vortex​
4.03​
2018​
ARMv8​
4.44​
47.2%​
6​
Apple​
A13​
Lightning​
4.53​
2019​
ARMv8​
4.40​
46.7%​
7​
AMD​
3950X​
Zen 2​
3.60​
2019​
x86-64​
3.02​
32.1%​



It's impressive how fast are evolving the generic Cortex cores:
  • A72 (2015) which can be found in most SBC has 1/3 of IPC of new Cortex X1 - They trippled IPC in just 5 years.
  • A73 and A75 (2017) which is inside majority of Android smart phones today has 1/2 IPC of new Cortex X1 - They doubled IPC in 3 years.

Comparison how x86 vs. Cortex cores:
  • A75 (2017) compared to Zen1 (2017) is loosing massive -34% PPC to x86. As expected.
  • A77 (2019) compared to Zen2 (2018) closed the gap and is equal in PPC. Surprising. Cortex cores caught x86 cores.
  • X1 (2020) is another +30% IPC over A77. Zen3 need to bring 30% IPC jump to stay on par with X1.

Comparison to Apple cores:
  • AMD's Zen2 core is slower than Apple's A9 from 2015.... so AMD is 4 years behind Apple
  • Intel's Sunny Cove core in Ice Lake is slower than Apple's A10 from 2016... so Intel is 3 years behind Apple
  • Cortex A77 core is slower than Apple's A9 from 2015.... but
  • New Cortex X1 core is slower than Apple's A11 from 2017 so ARM LLC is 3 years behind Apple and getting closer



GeekBench5.1 comparison from 6/22/2020:
  • added Cortex X1 and A78 performance projections from Andrei here
  • 2020 awaiting new Apple A14 Firestorm core and Zen3 core
Updated:



EDIT:
Please note to stop endless discussion about PPC frequency scaling: To have fair and clean comparison I will use only the top (high clocked) version from each core as representation for top performance.
 
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DrMrLordX

Lifer
Apr 27, 2000
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Heading over to the Geekbench site and looking at top performers, the A13 doesn't even show up as a top performer. If one browses the specific processors such as the a13 and the 3700x the comparison becomes absurd. I don't know much about particulars compared to many here but it seems to me it's bit like golf. If one goes about it right any drunk can beat the best pro out there with the right course and handicap. In the real world, not so much. I understand what you are saying but AFAIK there's not anyone using the A13 because it's faster than everything else.

As far as fixed-function hardware goes, I was being mostly pedantic. You are, of course, correct. Mind telling @Richie Rich for me?
 

Richie Rich

Senior member
Jul 28, 2019
470
229
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Great finding!

OP, can you please update the World's Most Powerful PPC CPU Top? We have all these new exciting entries!
I see your point but to avoid PPC vs. clock fluctuation lets consider only the highest clocked versions from each core. There is two good reasons for that:
  • It's realistic - as we aim to get max performance from each urach
  • Max clocks is the hard limit given by process and uarch (and I try to compare uarchs among each other). Lower clocks has no limit actually.
I've put that into initial post.
EDIT:
For Coercitiv and others to stop endless discusion about PPC frequency scaling: To have fair and clean comparison I will use only the top (high clocked) version from each core.
If you will continue ignore this rule I will consider that as a inflamatory behavior and you will be reported.


You don't make the rules for a thread. We have posted forum guidelines on what is, and what isn't allowed.
If you post something, users have the right to debate/challenge the claim.

AT Mod Usandthem
 
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Hitman928

Diamond Member
Apr 15, 2012
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I see your point but to avoid PPC vs. clock fluctuation I will use only high clocked versions from each core. I've put that into initial post.

If you will continue ignore this rule I will consider that as a inflamatory behavior and you will be reported.

Define high clocked because the examples I gave are all much higher clocked than A13 and are running at their boost target frequencies.
 
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Thunder 57

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If you will continue ignore this rule I will consider that as a inflamatory behavior and you will be reported.

Inflammatory? Don't you realize you are the one causing trouble? I'm surprised you haven't reported me. Or have you? Also, you don't get to make the rules. Go away, no one wants you here as can be seen by replies to this post.


User insults are not allowed. Stick to debating the data,
or add the user to your ignore list.

AT Mod Usandthem
 
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coercitiv

Diamond Member
Jan 24, 2014
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If you will continue ignore this rule I will consider that as a inflamatory behavior and you will be reported.
You are free to do as you wish.

Meanwhile I will continue to point out that arbitrarily seeking performance targets to subject them to normalization for the purpose of refactoring the numbers again into high performance estimates is one very crooked way of looking at CPU architectures. You're not interested in how Apple CPUs perform in phones. What you really want to talk about is how an imaginary high performance CPU built by Apple/ARM will perform relative to x86 cores. You want the big 8-16+ core 3-4Ghz Apple CPU to prove you right, but can't wait a few years for actual HPC mature silicon. So what can be done now? PPC can be done, to show the potential of a core while ignoring massive multi-core architecture changes, memory subsystem scaling, cost control and power efficiency drops with both high clocks and massive data transfers inside and outside the SOC.

You want PPC? It's fine, I applaud your initiative. It's a great time to start having this discussion, but we will have to do it fair and square, with all publicly available data and without arbitrary requirements such as "highest clocked entry only". If we are to directly compare an architecture built for sub 3GHz operation and one built for anything between 2 and 5Ghz depending on form factor and power/performance targets, then each architecture gets the best case scenario within parameters it was built for.

Having said that, please update the Ice Lake numbers with those provided by @Hitman928 - score of 1461 @ ~3880 Mhz for a PPC of 375+. The CPU is operating near the same frequency as the one in the World's Most Powerful PPC CPU Top, but with ~17% better PPC.
 

aigomorla

CPU, Cases&Cooling Mod PC Gaming Mod Elite Member
Super Moderator
Sep 28, 2005
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Why isn't the asgard computer core included in this pointless comparison, lets put in the Hal9000 while we are on it, or Mother from Aliens? :D

If were going to do pointless comparisons lets put in pointless processors.

Your mixing different platforms with different arch.
Your not going to go get a solid reliable comparison.
This is why most reputable tech sites avoid doing comparisons for what you state.
And if apple's SoC processor was that powerful, the mac server would be on them, yet last time i recall, they still went (insert intel bell melody here).

But they will probably go (insert EYPC MOAR COARS meme here) soon if not next year.
 
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lobz

Platinum Member
Feb 10, 2017
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I see your point but to avoid PPC vs. clock fluctuation lets consider only the highest clocked versions from each core. There is two good reasons for that:
  • It's realistic - as we aim to get max performance from each urach
  • Max clocks is the hard limit given by process and uarch (and I try to compare uarchs among each other). Lower clocks has no limit actually.
I've put that into initial post.

If you will continue ignore this rule I will consider that as a inflamatory behavior and you will be reported.


You don't make the rules for a thread. We have posted forum guidelines on what is, and what isn't allowed.
If you post something, users have the right to debate/challenge the claim.

AT Mod Usandthem
You could, however, create your own forum called Tim's Kitchen and claim Apple's IPC supremacy without the danger of anyone challenging your flawed logic.
 

soresu

Platinum Member
Dec 19, 2014
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SpecFP2006 is missing I see.

In that benchmark A77 (SD 865) exceeds A11 by 13%, with SpecInt2006 falling behind by just under 10%. While using considerably less power I might add. Overall I would say that ARM Ltd are not so far behind as Apple would like people to think.

SPEC-S865_575px.png
 
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soresu

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OK, just did some basic math based on Anandtech's Spec2006 scores and energy usage.

A13 vs Cortex-A77 perf in Specint2006 = 1.578x
A13 vs Cortex-A77 power in Specint2006 = 1.623x
A13 vs Cortex-A77 perf in Specfp2006 = 1.356x
A13 vs Cortex-A77 power in Specfp2006 = 1.616x

So, yes more raw performance in both fp and int, but a little more power for int, and a lot more for fp. Overall I'd say A77 wins on perf/watt.
 

lobz

Platinum Member
Feb 10, 2017
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OK, just did some basic math based on Anandtech's Spec2006 scores and energy usage.

A13 vs Cortex-A77 perf in Specint2006 = 1.578x
A13 vs Cortex-A77 power in Specint2006 = 1.623x
A13 vs Cortex-A77 perf in Specfp2006 = 1.356x
A13 vs Cortex-A77 power in Specfp2006 = 1.616x

So, yes more raw performance in both fp and int, but a little more power for int, and a lot more for fp. Overall I'd say A77 wins on perf/watt.
Any more of this nonsense and he may report you.....

Keep the discussion on the data, and not the user.

AT Mod Usandthem
 
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UsandThem

Elite Member
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In case anyone is wondering, I've already been in this thread
four times in only two pages of responses.

Going forward, I'd advise all users to keep the discussion
focused, and without insults.

AT Mod Usandthem
 

Richie Rich

Senior member
Jul 28, 2019
470
229
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You are free to do as you wish.

Meanwhile I will continue to point out that arbitrarily seeking performance targets to subject them to normalization for the purpose of refactoring the numbers again into high performance estimates is one very crooked way of looking at CPU architectures. You're not interested in how Apple CPUs perform in phones. What you really want to talk about is how an imaginary high performance CPU built by Apple/ARM will perform relative to x86 cores. You want the big 8-16+ core 3-4Ghz Apple CPU to prove you right, but can't wait a few years for actual HPC mature silicon. So what can be done now? PPC can be done, to show the potential of a core while ignoring massive multi-core architecture changes, memory subsystem scaling, cost control and power efficiency drops with both high clocks and massive data transfers inside and outside the SOC.

You want PPC? It's fine, I applaud your initiative. It's a great time to start having this discussion, but we will have to do it fair and square, with all publicly available data and without arbitrary requirements such as "highest clocked entry only". If we are to directly compare an architecture built for sub 3GHz operation and one built for anything between 2 and 5Ghz depending on form factor and power/performance targets, then each architecture gets the best case scenario within parameters it was built for.

Having said that, please update the Ice Lake numbers with those provided by @Hitman928 - score of 1461 @ ~3880 Mhz for a PPC of 375+. The CPU is operating near the same frequency as the one in the World's Most Powerful PPC CPU Top, but with ~17% better PPC.
  1. I see your point but you cannot mix two different set of PPC results together, each based on different key. My chart is based on PPC delivered at maximum performance at given platform and constraints (because we seek for max performance).
  2. However feel free to create your own table with chart based on your key. That would be also interesting to read so please do that.

OK, just did some basic math based on Anandtech's Spec2006 scores and energy usage.

A13 vs Cortex-A77 perf in Specint2006 = 1.578x
A13 vs Cortex-A77 power in Specint2006 = 1.623x
A13 vs Cortex-A77 perf in Specfp2006 = 1.356x
A13 vs Cortex-A77 power in Specfp2006 = 1.616x

So, yes more raw performance in both fp and int, but a little more power for int, and a lot more for fp. Overall I'd say A77 wins on perf/watt.
No doubt that A77 is in some ways brilliant design. I like the fact that ARM spent 17% more transistors while gained 20% int IPC gain and 35% FPU IPC gain and kept the best performance per watt ratio. But IMHO when A13 would be clocked at lower speed to achieve same performance as A77 (lets say about 1.4x lower to have balanced INT and FPU speed = 2.65 / 1.4 = 1.9 Ghz) this A13@1.9 GHz would have power consumption much lower than A77 (approximately 1.4^3 = 2.7x lower than A13@2.65 Ghz). When comparing those two CPUs at iso-performance A13@1.9=A77@2.84Ghz then power efficiency will be 2.7 / 1.6 = 1.7x more power efficiency for A13. But this is more server comparison than consumer CPU comparison. No doubt A77 would be No. 1 in TOP10 performance per watt chart.
 

Thunder 57

Platinum Member
Aug 19, 2007
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First, I am sorry for causing trouble earlier. I posted in haste and without thinking properly, and that rarely ends well.

Now I have a couple of questions.

1) Why do we care so much about PPC? They don't clock anywhere near each other. PPC is one part of the overall picture. If the Athlon 64 only clocked at 1GHz, it would've been a failure, regardless of PPC. IMHO, the argument you should be making is performance per watt.

2) If you haven't seen it already, check out DrMrLordX's post. The short version of it is that no one would call a "review" using only SPEC and GB data as a review. He posted a link to a proper review.

People want to see a wide sample of data, preferably including software they run. So one CPU may be quickest in SPEC. That's cool I guess, if you like to run SPEC all day. How about seeing a CPU be considerably faster in Handbrake? Maybe you do a good amount of transcoding. Great! Now you know you'll be saving some time. So why limit your results to SPEC and GB?
 

naukkis

Senior member
Jun 5, 2002
702
571
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1) Why do we care so much about PPC? They don't clock anywhere near each other. PPC is one part of the overall picture. If the Athlon 64 only clocked at 1GHz, it would've been a failure, regardless of PPC. IMHO, the argument you should be making is performance per watt.
Great! Now you know you'll be saving some time. So why limit your results to SPEC and GB?

As didn't Athlon64 clock to near P4 but still performed well. A13 PPC is so good that SOC in phone could rival best use all power they could desktop CPU's. That's about same kind of advantage that A64 had over P4.
 

coercitiv

Diamond Member
Jan 24, 2014
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IMHO, the argument you should be making is performance per watt.
He can't argue for performance per watt while also aiming to prove a theoretical Apple high performance CPU will be superior. The goal is best ST performance in the world, and this PPC classification is great because it "normalizes" performance and then allows the reader to dream of unicorn CPUs.

Notice how he keeps insisting on maximizing clocks within platform constraints, basically comparing x86 chips pushed to their power/thermal limits to ARM chips running on passive cooling frequencies. It's the same discussion we had in the previous threads, only this time he blatantly refuses to even update his World Top with valid results such as the EPYC score provided by me or the Ice Lake score provided by @Hitman928.

He chooses the metric - PPC - but even then feels uncomfortable when Ice Lake jumps from ~320 PPC to ~375 PPC at virtually the same clocks. That's the level of insecurity.
 

lobz

Platinum Member
Feb 10, 2017
2,057
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  1. I see your point but you cannot mix two different set of PPC results together, each based on different key. My chart is based on PPC delivered at maximum performance at given platform and constraints (because we seek for max performance).
  2. However feel free to create your own table with chart based on your key. That would be also interesting to read so please do that

This is deliberate provocation from your side. Anyone trying to debate your 'data points' is just a unwitting participant in this charade. Your chart is not based on anything else than hand-picked results that fit your agenda. Even witeken's self-praise is a more objective forum topic than this.
 

Richie Rich

Senior member
Jul 28, 2019
470
229
76
GeekBench5.1 comparison from 6/22/2020:
  • added Cortex X1 and A78 performance projections from Andrei here
  • 2020 awaiting new Apple A14 Firestorm core and Zen3 core
Updated:

Pos
Man
CPU
Core
Year
ISA
GB5 Score
GHz
PPC (score/GHz)
Relative
1​
Apple​
A13​
Lightning​
2019​
ARMv8​
1332​
2.65​
502.64​
100%​
2​
Apple​
A12​
Vortex​
2018​
ARMv8​
1116​
2.53​
441.11​
88%​
3​
Apple​
A11​
Monsoon​
2017​
ARMv8​
933​
2.39​
390.38​
78%​
4​
ARM Cortex​
X1​
Hera​
2020​
ARMv8​
1055​
3.00​
351.67​
70%​
5​
Apple​
A10​
Hurricane​
2016​
ARMv8​
770​
2.34​
329.06​
65%​
6​
Intel​
1065G7​
Icelake​
2019​
x86-64​
1252​
3.90​
321.03​
64%​
7​
Apple​
A9​
Twister​
2015​
ARMv8​
564​
1.85​
304.86​
61%​
8​
ARM Cortex​
A78​
Hercules​
2020​
ARMv8​
868​
3.00​
289.33​
58%​
9​
AMD​
3950X​
Zen 2​
2019​
x86-64​
1317​
4.60​
286.30​
57%​
10​
ARM Cortex​
A77​
Deimos​
2019​
ARMv8​
812​
2.84​
285.92​
57%​
11​
Intel​
9900K​
Skylake​
2018​
x86-64​
1384​
5.00​
276.80​
55%​
12​
AMD​
1800X​
Zen 1​
2017​
x86-64​
1073​
3.90​
275.13​
55%​
13​
ARM Cortex​
A76​
Enyo​
2018​
ARMv8​
720​
2.84​
253.52​
50%​
14​
Intel​
4770K​
Haswell​
2013​
x86-64​
966​
3.90​
247.69​
49%​
15​
Apple​
A8​
Typhoon​
2014​
ARMv8​
323​
1.40​
230.71​
46%​
16​
Intel​
3770K​
Ivy Bridge​
2012​
x86-64​
764​
3.50​
218.29​
43%​
17​
Apple​
A7​
Cyclone​
2013​
ARMv8​
270​
1.30​
207.69​
41%​
18​
Intel​
2700K​
Sandy Bridge​
2011​
x86-64​
723​
3.50​
206.57​
41%​
19​
Intel​
E6600​
Core2​
2006​
x86-64​
338​
2.40​
140.83​
28%​
20​
AMD​
Phenom 965 BE​
K10.5​
2006​
x86-64​
496​
3.70​
134.05​
27%​
21​
AMD​
Athlon 64 X2 3800+​
K8​
2005​
x86-64​
207​
2.00​
103.50​
21%​
22​
Intel​
Pentium D​
P4​
2005​
x86-64​
228​
3.40​
67.06​
13%​