OpenRadioss

OpenRadioss is an open-source AGPL-licensed finite element solver for dynamic event analysis OpenRadioss is based on Altair Radioss and open-sourced in 2022. This open-source finite element solver is benchmarked with various example models available from https://www.openradioss.org/models/ and https://github.com/OpenRadioss/ModelExchange/tree/main/Examples. This test is currently using a reference OpenRadioss binary build offered via GitHub.

To run this test with the Phoronix Test Suite, the basic command is: phoronix-test-suite benchmark openradioss.

Project Site

openradioss.org

Source Repository

github.com

Test Created

13 October 2022

Last Updated

24 September 2023

Test Maintainer

Michael Larabel

Test Type

Processor

Average Install Time

8 Seconds

Average Run Time

7 Minutes, 25 Seconds

Test Dependencies

OpenMPI

Accolades

30k+ Downloads

Supported Platforms

Supported Architectures

x86_64

* Uploading of benchmark result data to OpenBenchmarking.org is always optional (opt-in) via the Phoronix Test Suite for users wishing to share their results publicly.
** Data based on those opting to upload their test results to OpenBenchmarking.org and users enabling the opt-in anonymous statistics reporting while running benchmarks from an Internet-connected platform.
Data updated weekly as of 2 December 2024.

Revision History

pts/openradioss-1.1.1 [View Source] Sun, 24 Sep 2023 12:11:10 GMT
Add Taurus 10M model.

pts/openradioss-1.1.0 [View Source] Sat, 16 Sep 2023 18:43:37 GMT
Update against latest OpenRadioss upstream, add Chrysler Neon 1M test for bigger systems too.

pts/openradioss-1.0.0 [View Source] Thu, 13 Oct 2022 13:52:11 GMT
Initial commit of OpenRadioss benchmark.

Suites Using This Test

HPC - High Performance Computing

Performance Metrics

Analyze Test Configuration:

OpenRadioss 2023.09.15

Model: Chrysler Neon 1M

OpenBenchmarking.org metrics for this test profile configuration based on 869 public results since 16 September 2023 with the latest data as of 29 November 2024.

Below is an overview of the generalized performance for components where there is sufficient statistically significant data based upon user-uploaded results. It is important to keep in mind particularly in the Linux/open-source space there can be vastly different OS configurations, with this overview intended to offer just general guidance as to the performance expectations.

Component

Percentile Rank

# Compatible Public Results

Seconds (Average)

2 x AMD EPYC 9755 128-Core

100th

2 x AMD EPYC 9655 96-Core

99th

49 ^{+/- 1}

2 x AMD EPYC 9684X 96-Core

98th

52 ^{+/- 4}

2 x AMD EPYC 9575F 64-Core

97th

2 x AMD EPYC 9965 192-Core

95th

2 x AMD EPYC 9654 96-Core

93rd

70 ^{+/- 4}

AMD EPYC 9755 128-Core

91st

Intel Xeon 6980P

89th

81 ^{+/- 2}

2 x AMD EPYC 9554 64-Core

89th

84 ^{+/- 4}

AMD EPYC 9684X 96-Core

88th

85 ^{+/- 5}

2 x INTEL XEON PLATINUM 8592

87th

86 ^{+/- 2}

AMD EPYC 9655 96-Core

84th

90 ^{+/- 1}

2 x AMD EPYC 9754 128-Core

83rd

91 ^{+/- 11}

AMD EPYC 9965 192-Core

82nd

AMD EPYC 9655P 96-Core

81st

93 ^{+/- 4}

AMD EPYC 9575F 64-Core

79th

114 ^{+/- 7}

2 x Intel Xeon Platinum 8490H

78th

115 ^{+/- 1}

2 x Intel Xeon Max 9468

77th

121 ^{+/- 8}

2 x Intel Xeon Max 9480

76th

125 ^{+/- 6}

Mid-Tier

75th

> 129

AMD Ryzen Threadripper PRO 7995WX 96-Cores

75th

156 ^{+/- 1}

INTEL XEON PLATINUM 8592

74th

157

AMD EPYC 9654 96-Core

72nd

173 ^{+/- 5}

2 x AMD EPYC 7713 64-Core

72nd

174

2 x Intel Xeon Platinum 8380

70th

183 ^{+/- 1}

AMD EPYC 9554 64-Core

70th

184 ^{+/- 21}

Intel Xeon Platinum 8490H

67th

207 ^{+/- 1}

Intel Xeon Max 9480

66th

213

AMD EPYC 9754 128-Core

66th

218 ^{+/- 8}

Intel Xeon Max 9468

64th

221 ^{+/- 18}

2 x Intel Xeon Platinum 8280

63rd

257 ^{+/- 1}

AMD EPYC 8534P 64-Core

60th

297 ^{+/- 1}

AMD EPYC 8534PN 64-Core

59th

299 ^{+/- 3}

2 x AMD EPYC 7303 16-Core

57th

306 ^{+/- 3}

Intel Xeon Platinum 8380

55th

343

AMD EPYC 7663P 56-Core

55th

344 ^{+/- 1}

AMD EPYC 8324P 32-Core

53rd

384 ^{+/- 2}

AMD EPYC 8534PN 32-Core

52nd

386 ^{+/- 6}

Median

50th

449

AMD EPYC 7601 32-Core

50th

499 ^{+/- 1}

AMD Ryzen Threadripper 3970X 32-Core

48th

550 ^{+/- 2}

AMD Ryzen Threadripper PRO 5965WX 24-Cores

47th

579 ^{+/- 29}

Intel Core Ultra 5 245K

46th

596 ^{+/- 6}

AMD Ryzen Threadripper 3990X 64-Core

45th

670 ^{+/- 2}

Intel Core i9-14900K

43rd

698 ^{+/- 8}

AMD Ryzen 9 9950X 16-Core

43rd

701 ^{+/- 16}

Intel Core i9-13900K

41st

715 ^{+/- 3}

AMD Ryzen 9 9900X 12-Core

39th

727 ^{+/- 3}

AMD Ryzen 9 7950X3D 16-Core

39th

753 ^{+/- 44}

AMD Ryzen 9 7900X3D 12-Core

38th

759

AMD Ryzen 9 7950X 16-Core

37th

763 ^{+/- 5}

AMD Ryzen 7 9800X3D 8-Core

36th

777 ^{+/- 14}

AMD Ryzen 7 9700X 8-Core

34th

819 ^{+/- 2}

AMD EPYC 4584PX 16-Core

33rd

823

AMD Ryzen 9 7900 12-Core

32nd

841 ^{+/- 52}

AMD Ryzen 7 8700G

32nd

857

Intel Xeon Silver 4216

31st

868 ^{+/- 4}

Intel Core i9-10980XE

31st

879 ^{+/- 9}

AMD Ryzen 7 7800X3D 8-Core

30th

883

AMD Ryzen 7 7700X 8-Core

30th

884

AMD Ryzen 7 7700 8-Core

29th

888

AMD EPYC 4564P 16-Core

29th

897 ^{+/- 11}

AMD Ryzen 9 7900X 12-Core

28th

902 ^{+/- 96}

AMD Ryzen 5 9600X 6-Core

28th

905 ^{+/- 5}

AMD EPYC 4464P 12-Core

27th

936

Intel Core i5-14600K

26th

947

Low-Tier

25th

> 953

Intel Core i5-13600K

25th

956

AMD EPYC 4344P 8-Core

25th

967

AMD EPYC 4484PX 12-Core

24th

979

Intel Xeon E E-2488

24th

984

AMD Ryzen 7 8845HS

21st

1009 ^{+/- 11}

AMD Ryzen 5 7600X 6-Core

21st

1010

AMD EPYC 4364P 8-Core

21st

1018 ^{+/- 28}

AMD Ryzen 5 7600 6-Core

20th

1027 ^{+/- 4}

AMD Ryzen AI 9 HX 370

20th

1031 ^{+/- 58}

AMD Ryzen 5 8400F 6-Core

20th

1034 ^{+/- 19}

AMD Ryzen 5 8600G

19th

1069 ^{+/- 142}

AMD Ryzen AI 9 365

18th

1109 ^{+/- 2}

AMD EPYC 4244P 6-Core

17th

1127

Intel Core i5-14500

17th

1143 ^{+/- 95}

Intel Core i3-14100

17th

1249

AMD Ryzen 7 7840HS

16th

1286

AMD Ryzen 7 PRO 7840U

15th

1397 ^{+/- 4}

AMD Ryzen Z1 Extreme

14th

1420 ^{+/- 24}

Intel Core i5-14400F

14th

1422 ^{+/- 45}

Intel Core i5-13400

12th

1459

AMD EPYC 4124P 4-Core

12th

1462 ^{+/- 1}

Intel Core Ultra 7 155H

11th

1496 ^{+/- 134}

AMD Ryzen 7 5800X3D 8-Core

11th

1502

AMD Ryzen 7 7840U

11th

1505 ^{+/- 220}

AMD Ryzen 9 5900X 12-Core

11th

1529

AMD EPYC 7F32 8-Core

10th

1534 ^{+/- 15}

AMD Ryzen 7 5800X 8-Core

10th

1545 ^{+/- 95}

AMD Ryzen 9 3900XT 12-Core

9th

1611 ^{+/- 1}

Intel Core i7-5960X

8th

1612

AMD Ryzen 9 5950X 16-Core

8th

1641

AMD Ryzen 5 5600X 6-Core

8th

1648

AMD Ryzen 5 5500

7th

1696

AMD Ryzen 5 5500U

5th

2139 ^{+/- 2}

Intel Core i7-1185G7

4th

2228 ^{+/- 7}

Intel Core i7-1280P

4th

2265 ^{+/- 89}

Intel Core i7-1165G7

3rd

2302 ^{+/- 18}

AMD Ryzen 9 5900HX

2nd

2341 ^{+/- 22}

AMD Ryzen 5 4500U

1st

2418 ^{+/- 15}

Intel Core i7-1065G7

1st

2932 ^{+/- 17}

Based on OpenBenchmarking.org data, the selected test / test configuration (OpenRadioss 2023.09.15 - Model: Chrysler Neon 1M) has an average run-time of 35 minutes. By default this test profile is set to run at least 3 times but may increase if the standard deviation exceeds pre-defined defaults or other calculations deem additional runs necessary for greater statistical accuracy of the result.

Based on public OpenBenchmarking.org results, the selected test / test configuration has an average standard deviation of 0.3%.

Does It Scale Well With Increasing Cores?

Yes, based on the automated analysis of the collected public benchmark data, this test / test settings does generally scale well with increasing CPU core counts. Data based on publicly available results for this test / test settings, separated by vendor, result divided by the reference CPU clock speed, grouped by matching physical CPU core count, and normalized against the smallest core count tested from each vendor for each CPU having a sufficient number of test samples and statistically significant data.

Notable Instruction Set Usage

Notable instruction set extensions supported by this test, based on an automatic analysis by the Phoronix Test Suite / OpenBenchmarking.org analytics engine.

Instruction Set

Support

Instructions Detected

SSE2 (SSE2)

Used by default on supported hardware.

MOVDQA MOVD MOVAPD ADDSD ANDPD MULSD MAXSD DIVSD MINSD COMISD UNPCKLPD MOVUPD MOVLPD MULPD MOVHPD UNPCKHPD ADDPD SHUFPD MAXPD SUBSD SQRTSD XORPD PSHUFD UCOMISD DIVPD CVTSD2SS CVTSS2SD SUBPD PUNPCKLQDQ MOVDQU CVTSI2SD PSRLDQ ORPD SQRTPD MINPD CMPNLTSD ANDNPD CMPLEPD CVTDQ2PD PMULUDQ CMPLTSD CMPLESD CVTTSD2SI PADDQ CVTTPD2DQ PSLLDQ CMPLTPD CMPNEQPD CMPNLESD CVTPS2PD CVTPD2PS CMPEQPD MOVMSKPD

Last automated analysis: 18 September 2023

This test profile binary relies on the shared libraries libdl.so.2, librt.so.1, libmpi.so.40, libm.so.6, libgomp.so.1, libquadmath.so.0, libpthread.so.0, libc.so.6, libopen-rte.so.40, libopen-pal.so.40, libhwloc.so.15, libz.so.1, libudev.so.1.

Tested CPU Architectures

This benchmark has been successfully tested on the below mentioned architectures. The CPU architectures listed is where successful OpenBenchmarking.org result uploads occurred, namely for helping to determine if a given test is compatible with various alternative CPU architectures.

CPU Architecture

Kernel Identifier

Verified On

Intel / AMD x86 64-bit

x86_64

(Many Processors)