Xeon E5-2680 v2 vs Ryzen 7 3800X

Description

The E5-2680 v2 is based on Ivy Bridge architecture while the 3800X is based on Zen 2.

Using the multithread performance as a reference, the E5-2680 v2 gets a score of 551.1 k points while the 3800X gets 440.5 k points.

Summarizing, the E5-2680 v2 is 1.3 times faster than the 3800X. To get a proper comparison between both models, take a look to the data shown below.

Specs

E5-2680 v2

3800X

CPUID

306e4

870f10

Core

Ivy Bridge-EP

Matisse

Architecture

Ivy Bridge

Zen 2

Base frecuency

2.8 GHz

3.9 GHz

Boost frecuency

3.6 GHz

4.5 GHz

Socket

LGA 2011

AM4

Cores/Threads

10 /20

8/16

TDP

115 W

105 W

Cache L1 (d+i)

10x32+10x32 kB

8x32+8x32 kB

Cache L2

10x256 kB

8x512 kB

Cache L3

25600 kB

32768 kB

Date

September 2013

July 2019

Mean monothread perf.

28.23k points

75.81k points

Mean multithread perf.

551.1k points

497.74k points

SSE3 optimized benchmark

The benchmark in mode I (SSE) is optimized for the use of SIMD instructions with 128 bits register and the SSE set up to version 3. Nearly every modern CPU has support for this mode.

Monothread

E5-2680 v2

3800X

Test#1 (Integers)

11.96k

17.17k (x1.44)

Test#2 (FP)

10.73k

25.32k (x2.36)

Test#3 (Generic, ZIP)

4.59k

8.36k (x1.82)

Test#1 (Memory)

4.31k

27.86k (x6.47)

TOTAL

31.6k

78.71k (x2.49)

Multithread

E5-2680 v2

3800X

Test#1 (Integers)

218.24k

136.06k (x0.62)

Test#2 (FP)

206.92k

195.06k (x0.94)

Test#3 (Generic, ZIP)

100.37k

97.81k (x0.97)

Test#1 (Memory)

11.45k

12.91k (x1.13)

TOTAL

536.99k

441.85k (x0.82)

AVX optimized benchmark

The benchmark in mode II (AVX) is optimized to used 256 bits registers beside the first version of the Advanced Vector Extensions (AVX). The first AVX compatible CPU was released in 2011.

Monothread

E5-2680 v2

3800X

Test#1 (Integers)

10.55k

16.76k (x1.59)

Test#2 (FP)

10.02k

25.16k (x2.51)

Test#3 (Generic, ZIP)

3.99k

8.76k (x2.19)

Test#1 (Memory)

3.66k

24.3k (x6.64)

TOTAL

28.23k

74.98k (x2.66)

Multithread

E5-2680 v2

3800X

Test#1 (Integers)

215.04k

131.36k (x0.61)

Test#2 (FP)

230.43k

198.51k (x0.86)

Test#3 (Generic, ZIP)

96.87k

97.27k (x1)

Test#1 (Memory)

8.76k

13.4k (x1.53)

TOTAL

551.1k

440.54k (x0.8)

Performance/W

E5-2680 v2

3800X

Test#1 (Integers)

1870 points/W

1251 points/W

Test#2 (FP)

2004 points/W

1891 points/W

Test#3 (Generic, ZIP)

842 points/W

926 points/W

Test#1 (Memory)

76 points/W

128 points/W

TOTAL

4792 points/W

4196 points/W

Performance/GHz

E5-2680 v2

3800X

Test#1 (Integers)

2931 points/GHz

3724 points/GHz

Test#2 (FP)

2784 points/GHz

5592 points/GHz

Test#3 (Generic, ZIP)

1109 points/GHz

1946 points/GHz

Test#1 (Memory)

1017 points/GHz

5401 points/GHz

TOTAL

7841 points/GHz

16662 points/GHz

Monothread performance graph

Monothread performance graphics gives the performance vs time. They are useful to measure the time it takes to the CPU to reach the maximum performance.

Usually, CPU's performance will be steady during these tests but if it has a slow frequency strategy, the first samples will show a lower score.

Test#1 (Integers) [points vs time]

Test#2 (FP) [points vs time]

Test#3 (Generic, ZIP) [points vs time]

Test#1 (Memory) [points vs time]

Multithread performance graph

Multithread graphs measure the performance against a heavy load during certain time.

If CPU's TDP doesn't limit the frequency and the machine is properly cooled, performance should remain steady vs time. Otherwise, the performance score will oscillate or decrease over time.

Test#1 (Integers) [points vs time]

Test#2 (FP) [points vs time]

Test#3 (Generic, ZIP) [points vs time]

Test#1 (Memory) [points vs time]

Hardlimit Benchmark Central - Ver. 3.11.4