Tuesday Feb 18, 2014

SPARC T5-2 Produces SPECjbb2013-MultiJVM World Record for 2-Chip Systems

The SPECjbb2013 benchmark shows modern Java application performance. Oracle's SPARC T5-2 set a two-chip world record, which is 1.8x faster than the best two-chip x86-based server. Using Oracle Solaris and Oracle Java, Oracle delivered this two-chip world record result on the MultiJVM SPECjbb2013 metric.

  • The SPARC T5-2 server achieved 114,492 SPECjbb2013-MultiJVM max-jOPS and 43,963 SPECjbb2013-MultiJVM critical-jOPS on the SPECjbb2013 benchmark. This result is a two-chip world record.

  • The SPARC T5-2 server running SPECjbb2013 is 1.8x faster than the Cisco UCS C240 M3 server (2.7 GHz Intel Xeon E5-2697 v2) based on both the SPECjbb2013-MultiJVM max-jOPS and SPECjbb2013-MultiJVM critical-jOPS metrics.

  • The SPARC T5-2 server running SPECjbb2013 is 2x faster than the HP ProLiant ML350p Gen8 server (2.7 GHz Intel Xeon E5-2697 v2) based on SPECjbb2013-MultiJVM max-jOPS and 1.3x faster based on SPECjbb2013-MultiJVM critical-jOPS.

  • The new Oracle results were obtained using Oracle Solaris 11 along with Oracle Java SE 8 on the SPARC T5-2 server.

  • The SPARC T5-2 server running SPECjbb2013 on a per chip basis is 1.3x faster than the NEC Express5800/A040b server (2.8 GHz Intel Xeon E7-4890 v2) based on both the SPECjbb2013-MultiJVM max-jOPS and SPECjbb2013-MultiJVM critical-jOPS metrics.

  • There are no IBM POWER7 or POWER7+ based server results on the SPECjbb2013 benchmark. IBM has published IBM POWER7+ based servers on the SPECjbb2005 which was retired by SPEC in 2013.

Performance Landscape

Results of SPECjbb2013 from www.spec.org as of March 6, 2014. These are the leading 2-chip SPECjbb2013 MultiJVM results.

SPECjbb2013 - 2-Chip MultiJVM Results
System Processor SPECjbb2013-MultiJVM JDK
max-jOPS critical-jOPS
SPARC T5-2 2xSPARC T5, 3.6 GHz 114,492 43,963 Oracle Java SE 8
Cisco UCS C240 M3 2xIntel E5-2697 v2, 2.7 GHz 63,079 23,797 Oracle Java SE 7u45
HP ProLiant ML350p Gen8 2xIntel E5-2697 v2, 2.7 GHz 62,393 24,310 Oracle Java SE 7u45
IBM System x3650 M4 BD 2xIntel E5-2695 v2, 2.4 GHz 59,124 22,275 IBM SDK V7 SR6 (*)
HP ProLiant ML350p Gen8 2xIntel E5-2697 v2, 2.7 GHz 57,594 32,103 Oracle Java SE 7u40
HP ProLiant BL460c Gen8 2xIntel E5-2697 v2, 2.7 GHz 56,367 30,078 Oracle Java SE 7u40
Sun Server X4-2, DDR3-1600 2xIntel E5-2697 v2, 2.7 GHz 52,664 20,553 Oracle Java SE 7u40
HP ProLiant DL360e Gen8 2xIntel E5-2470 v2, 2.4 GHz 48,772 17,915 Oracle Java SE 7u40

* IBM SDK V7 SR6 – IBM SDK, Java Technology Edition, Version 7, Service Refresh 6

The following table compares the SPARC T5 processor to the Intel E7 v2 processor.

SPECjbb2013 - Results Using JDK 8
Per Chip Comparison
System SPECjbb2013-MultiJVM SPECjbb2013-MultiJVM/Chip JDK
max-jOPS critical-jOPS max-jOPS critical-jOPS
SPARC T5-2
2xSPARC T5, 3.6 GHz
114,492 43,963 57,246 21,981 Oracle Java SE 8
NEC Express5800/A040b
4xIntel E7-4890 v2, 2.8 GHz
177,753 65,529 44,438 16,382 Oracle Java SE 8

SPARC per Chip Advantage 1.29x 1.34x

Configuration Summary

System Under Test:

SPARC T5-2 server
2 x SPARC T5, 3.60 GHz
512 GB memory (32 x 16 GB dimms)
Oracle Solaris 11.1
Oracle Java SE 8

Benchmark Description

The SPECjbb2013 benchmark has been developed from the ground up to measure performance based on the latest Java application features. It is relevant to all audiences who are interested in Java server performance, including JVM vendors, hardware developers, Java application developers, researchers and members of the academic community.

From SPEC's press release, "SPECjbb2013 replaces SPECjbb2005. The new benchmark has been developed from the ground up to measure performance based on the latest Java application features. It is expected to be used widely by all those interested in Java server performance, including JVM vendors, hardware developers, Java application developers, researchers and members of the academic community."

SPECjbb2013 features include:

  • A usage model based on a world-wide supermarket company with an IT infrastructure that handles a mix of point-of-sale requests, online purchases and data-mining operations.
  • Both a pure throughput metric and a metric that measures critical throughput under service-level agreements (SLAs) specifying response times ranging from 10ms to 500ms.
  • Support for multiple run configurations, enabling users to analyze and overcome bottlenecks at multiple layers of the system stack, including hardware, OS, JVM and application layers.
  • Exercising new Java 7 features and other important performance elements, including the latest data formats (XML), communication using compression, and messaging with security.
  • Support for virtualization and cloud environments.

See Also

Disclosure Statement

SPEC and the benchmark name SPECjbb are registered trademarks of Standard Performance Evaluation Corporation (SPEC). Results as of 3/6/2014, see http://www.spec.org for more information.  SPARC T5-2 114,492 SPECjbb2013-MultiJVM max-jOPS, 43,963 SPECjbb2013-MultiJVM critical-jOPS; NEC Express5800/A040b 177,753 SPECjbb2013-MultiJVM max-jOPS, 65,529 SPECjbb2013-MultiJVM critical-jOPS; Cisco UCS c240 M3 63,079 SPECjbb2013-MultiJVM max-jOPS, 23,797 SPECjbb2013-MultiJVM critical-jOPS; HP ProLiant ML350p Gen8 62,393 SPECjbb2013-MultiJVM max-jOPS, 24,310 SPECjbb2013-MultiJVM critical-jOPS; IBM System X3650 M4 BD 59,124 SPECjbb2013-MultiJVM max-jOPS, 22,275 SPECjbb2013-MultiJVM critical-jOPS; HP ProLiant ML350p Gen8 57,594 SPECjbb2013-MultiJVM max-jOPS, 32,103 SPECjbb2013-MultiJVM critical-jOPS; HP ProLiant BL460c Gen8 56,367 SPECjbb2013-MultiJVM max-jOPS, 30,078 SPECjbb2013-MultiJVM critical-jOPS; Sun Server X4-2 52,664 SPECjbb2013-MultiJVM max-jOPS, 20,553 SPECjbb2013-MultiJVM critical-jOPS; HP ProLiant DL360e Gen8 48,772 SPECjbb2013-MultiJVM max-jOPS, 17,915 SPECjbb2013-MultiJVM critical-jOPS.

Thursday Sep 26, 2013

SPARC T5-2 Server Beats x86 Server on Oracle Database Transparent Data Encryption

Database security is becoming increasingly important. Oracle Database Advanced Security Transparent Data Encryption (TDE) stops would-be attackers from bypassing the database and reading sensitive information from storage by enforcing data-at-rest encryption in the database layer. Oracle's SPARC T5-2 server outperformed x86 systems when running Oracle Database 12c with Transparent Data Encryption.

  • The SPARC T5-2 server sustained more than 8.0 GB/sec of read bandwidth while decrypting using Transparent Data Encryption (TDE) in Oracle Database 12c. This was the bandwidth available on the system and matched the rate for querying the non-encrypted data.

  • The SPARC T5-2 server achieves about 1.5x higher decryption rate per socket using Oracle Database 12c with TDE than a Sun Server X4-2 system.

  • The SPARC T5-2 server achieves more than double the decryption rate per socket using Oracle Database 12c with TDE than a Sun Server X3-2 system.

Performance Landscape

Table of Size 250 GB Encrypted with AES-128-CFB
Full Table Scan with Degree of Parallelism 128
System Chips Table Data Format SPARC T5-2 Advantage
Clear Encrypted
SPARC T5-2 2 8.4 GB/sec 8.3 GB/sec 1.0
Sun Server X4-2L 2 8.2 GB/sec 5.6 GB/sec 1.5

SPARC T5-2 1 8.4 GB/sec 4.2 GB/sec 1.0
Sun Server X4-2L 1 8.2 GB/sec 2.8 GB/sec 1.5
Sun Server X3-2L 1 8.2 GB/sec 2.0 GB/sec 2.1

Configuration Summary

Systems Under Test:

SPARC T5-2
2 x SPARC T5 processors, 3.6 GHz
256 GB memory
Oracle Solaris 11.1
Oracle Database 12c

Sun Server X3-2L
2 x Intel Xeon E5-2690 processor, 2.90 GHz
64 GB memory
Oracle Solaris 11.1
Oracle Database 12c

Sun Server X4-2L
2 x Intel Xeon E5-2697 v2 processor, 2.70 GHz
256 GB memory
Oracle Solaris 11.1
Oracle Database 12c

Storage:

Flash Storage

Benchmark Description

The purpose of the benchmark is to show the query performance of a database using data encryption to keep the data secure. The benchmark creates a 250 GB table. It is loaded both into a clear text (no encryption) tablespace and an AES-128 encrypted tablespace. Full table scans of the tables were timed.

Key Points and Best Practices

The Oracle Database feature, Transparent Data Encryption (TDE), simplifies the encryption of data within datafiles, preventing unauthorized access to it from the operating system. Transparent Data Encryption allows encryption of the entire contents of a tablespace.

With hardware acceleration of the encryption routines, the SPARC T5-2 server can achieve nearly the same query rate whether the table is encrypted or not up to a limit of about 4 GB/sec per chip.

See Also

Disclosure Statement

Copyright 2013, Oracle and/or its affiliates. All rights reserved. Oracle and Java are registered trademarks of Oracle and/or its affiliates. Other names may be trademarks of their respective owners. Results as of 23 September 2013.

Wednesday Sep 25, 2013

SPARC T5-8 Delivers World Record Oracle OLAP Perf Version 3 Benchmark Result on Oracle Database 12c

Oracle's SPARC T5-8 server delivered world record query performance for systems running Oracle Database 12c for the Oracle OLAP Perf Version 3 benchmark.

  • The query throughput on the SPARC T5-8 server is 1.7x higher than that of an 8-chip Intel Xeon E7-8870 server. Both systems had sub-second average response times.

  • The SPARC T5-8 server with the Oracle Database demonstrated the ability to support at least 700 concurrent users querying OLAP cubes (with no think time), processing 2.33 million analytic queries per hour with an average response time of less than 1 second per query. This performance was enabled by keeping the entire cube in-memory utilizing the 4 TB of memory on the SPARC T5-8 server.

  • Assuming a 60 second think time between query requests, the SPARC T5-8 server can support approximately 39,450 concurrent users with the same sub-second response time.

  • The workload uses a set of realistic Business Intelligence (BI) queries that run against an OLAP cube based on a 4 billion row fact table of sales data. The 4 billion rows are partitioned by month spanning 10 years.

  • The combination of the Oracle Database 12cwith the Oracle OLAP option running on a SPARC T5-8 server supports live data updates occurring concurrently with minimally impacted user query executions.

Performance Landscape

Oracle OLAP Perf Version 3 Benchmark
Oracle cube base on 4 billion fact table rows
10 years of data partitioned by month
System Queries/
hour
Users Average Response
Time (sec)
0 sec think time 60 sec think time
SPARC T5-8 2,329,000 700 39,450 <1 sec
8-chip Intel Xeon E7-8870 1,354,000 120 22,675 <1 sec

Configuration Summary

SPARC T5-8:

1 x SPARC T5-8 server with
8 x SPARC T5 processors, 3.6 GHz
4 TB memory
Data Storage and Redo Storage
Flash Storage
Oracle Solaris 11.1 (11.1.8.2.0)
Oracle Database 12c Release 1 (12.1.0.1) with Oracle OLAP option

Sun Server X2-8:

1 x Sun Server X2-8 with
8 x Intel Xeon E7-8870 processors, 2.4 GHz
1 TB memory
Data Storage and Redo Storage
Flash Storage
Oracle Solaris 10 10/12
Oracle Database 12c Release 1 (12.1.0.1) with Oracle OLAP option

Benchmark Description

The Oracle OLAP Perf Version 3 benchmark is a workload designed to demonstrate and stress the ability of the OLAP Option to deliver fast query, near real-time updates and rich calculations using a multi-dimensional model in the context of the Oracle data warehousing.

The bulk of the benchmark entails running a number of concurrent users, each issuing typical multidimensional queries against an Oracle cube. The cube has four dimensions: time, product, customer, and channel. Each query user issues approximately 150 different queries. One query chain may ask for total sales in a particular region (e.g South America) for a particular time period (e.g. Q4 of 2010) followed by additional queries which drill down into sales for individual countries (e.g. Chile, Peru, etc.) with further queries drilling down into individual stores, etc. Another query chain may ask for yearly comparisons of total sales for some product category (e.g. major household appliances) and then issue further queries drilling down into particular products (e.g. refrigerators, stoves. etc.), particular regions, particular customers, etc.

While the core of every OLAP Perf benchmark is real world query performance, the benchmark itself offers numerous execution options such as varying data set sizes, number of users, numbers of queries for any given user and cube update frequency. Version 3 of the benchmark is executed with a much larger number of query streams than previous versions and used a cube designed for near real-time updates. The results produced by version 3 of the benchmark are not directly comparable to results produced by previous versions of the benchmark.

The near real-time update capability is implemented along the following lines. A large Oracle cube, H, is built from a 4 billion row star schema, containing data up until the end of last business day. A second small cube, D, is then created which will contain all of today's new data coming in from outside the world. It will be updated every L minutes with the data coming in within the last L minutes. A third cube, R, joins cubes H and D for reporting purposes much like a view might join data from two tables. Calculations are installed into cube R. The use of a reporting cube which draws data from different storage cubes is a common practice.

Query users are never locked out of query operations while new data is added to the update cube. The point of the demonstration is to show that an Oracle OLAP system can be designed which results in data being no more than L minutes out of date, where L may be as low as just a few minutes. This is what is meant by near real-time analytics.

Key Points and Best Practices

  • Building and querying cubes with the Oracle OLAP option requires a large temporary tablespace. Normally temporary tablespaces would reside on disk storage. However, because the SPARC T5-8 server used in this benchmark had 4 TB of main memory, it was possible to use main memory for the OLAP temporary tablespace. This was accomplished by using a temporary, memory-based file system (TMPFS) for the temporary tablespace datafiles.

  • Since typical business intelligence users are often likely to issue similar queries, either with the same or different constants in the where clauses, setting the init.ora parameter "cursor_sharing" to "force" provides for additional query throughput and a larger number of potential users.

  • Assuming the normal Oracle Database initialization parameters (e.g. SGA, PGA, processes etc.) are appropriately set, out of the box performance for the Oracle OLAP workload should be close to what is reported here. Additional performance resulted from using memory for the OLAP temporary tablespace setting "cursor_sharing" to force.

  • Oracle OLAP Cube update performance was optimized by running update processes in the FX class with a priority greater than 0.

  • The maximum lag time between updates to the source fact table and data availability to query users (what was referred to as L in the benchmark description) was less than 3 minutes for the benchmark environment on the SPARC T5-8 server.

See Also

Disclosure Statement

Copyright 2013, Oracle and/or its affiliates. All rights reserved. Oracle and Java are registered trademarks of Oracle and/or its affiliates. Other names may be trademarks of their respective owners. Results as of 09/22/2013.

SPARC T5 Encryption Performance Tops Intel E5-2600 v2 Processor

The cryptography benchmark suite was developed by Oracle to measure security performance on important AES security modes. Oracle's SPARC T5 processor with it security software in silicon is faster than x86 servers that have the AES-NI instructions. In this test, the performance of on-processor encryption operations is measured (32 KB encryptions). Multiple threads are used to measure each processors maximum throughput. The SPARC T5-8 shows dramatically faster encryption.

  • A SPARC T5 processor running Oracle Solaris 11.1 is 2.7 times faster executing AES-CFB 256-bit key encryption (in cache) than the Intel E5-2697 v2 processor (with AES-NI) running Oracle Linux 6.3. AES-CFB encryption is used by Oracle Database for Transparent Data Encryption (TDE) which provides security for database storage.

  • On the AES-CFB 128-bit key encryption, the SPARC T5 processor is 2.5 times faster than the Intel E5-2697 v2 processor (with AES-NI) running Oracle Linux 6.3 for in-cache encryption. AES-CFB mode is used by Oracle Database for Transparent Data Encryption (TDE) which provides security for database storage.

  • The IBM POWER7+ has three hardware security units for 8-core processors, but IBM has not publicly shown any measured performance results on AES-CFB or other encryption modes.

Performance Landscape

Presented below are results for running encryption using the AES cipher with the CFB, CBC, CCM and GCM modes for key sizes of 128, 192 and 256. Decryption performance was similar and is not presented. Results are presented as MB/sec (10**6).

Encryption Performance – AES-CFB

Performance is presented for in-cache AES-CFB128 mode encryption. Multiple key sizes of 256-bit, 192-bit and 128-bit are presented. The encryption was performance on 32 KB of pseudo-random data (same data for each run).

AES-CFB
Microbenchmark Performance (MB/sec)
Processor GHz Chips Performance Software Environment
AES-256-CFB
SPARC T5 3.60 2 54,396 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2697 v2 2.70 2 19,960 Oracle Linux 6.3, IPP/AES-NI
Intel E5-2690 2.90 2 12,823 Oracle Linux 6.3, IPP/AES-NI
AES-192-CFB
SPARC T5 3.60 2 61,000 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2697 v2 2.70 2 23,217 Oracle Linux 6.3, IPP/AES-NI
Intel E5-2690 2.90 2 14,928 Oracle Linux 6.3, IPP/AES-NI
AES-128-CFB
SPARC T5 3.60 2 68,695 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2697 v2 2.70 2 27,740 Oracle Linux 6.3, IPP/AES-NI
Intel E5-2690 2.90 2 17,824 Oracle Linux 6.3, IPP/AES-NI

Encryption Performance – AES-GCM

Performance is presented for in-cache AES-GCM mode encryption with authentication. Multiple key sizes of 256-bit, 192-bit and 128-bit are presented. The encryption/authentication was performance on 32 KB of pseudo-random data (same data for each run).

AES-GCM
Microbenchmark Performance (MB/sec)
Processor GHz Chips Performance Software Environment
AES-256-GCM
SPARC T5 3.60 2 34,101 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2697 v2 2.70 2 15,338 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2690 2.90 2 13,520 Oracle Linux 6.3, IPP/AES-NI
AES-192-GCM
SPARC T5 3.60 2 36,852 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2697 v2 2.70 2 15,768 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2690 2.90 2 14,159 Oracle Linux 6.3, IPP/AES-NI
AES-128-GCM
SPARC T5 3.60 2 39,003 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2697 v2 2.70 2 16,405 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2690 2.90 2 14,877 Oracle Linux 6.3, IPP/AES-NI

Encryption Performance – AES-CCM

Performance is presented for in-cache AES-CCM mode encryption with authentication. Multiple key sizes of 256-bit, 192-bit and 128-bit are presented. The encryption/authentication was performance on 32 KB of pseudo-random data (same data for each run).

AES-CCM
Microbenchmark Performance (MB/sec)
Processor GHz Chips Performance Software Environment
AES-256-CCM
SPARC T5 3.60 2 29,431 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2697 v2 2.70 2 19,447 Oracle Linux 6.3, IPP/AES-NI
Intel E5-2690 2.90 2 12,493 Oracle Linux 6.3, IPP/AES-NI
AES-192-CCM
SPARC T5 3.60 2 33,715 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2697 v2 2.70 2 22,634 Oracle Linux 6.3, IPP/AES-NI
Intel E5-2690 2.90 2 14,507 Oracle Linux 6.3, IPP/AES-NI
AES-128-CCM
SPARC T5 3.60 2 39,188 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2697 v2 2.70 2 26,951 Oracle Linux 6.3, IPP/AES-NI
Intel E5-2690 2.90 2 17,256 Oracle Linux 6.3, IPP/AES-NI

Encryption Performance – AES-CBC

Performance is presented for in-cache AES-CBC mode encryption. Multiple key sizes of 256-bit, 192-bit and 128-bit are presented. The encryption was performance on 32 KB of pseudo-random data (same data for each run).

AES-CBC
Microbenchmark Performance (MB/sec)
Processor GHz Chips Performance Software Environment
AES-256-CBC
SPARC T5 3.60 2 56,933 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2697 v2 2.70 2 19,962 Oracle Linux 6.3, IPP/AES-NI
Intel E5-2690 2.90 2 12,822 Oracle Linux 6.3, IPP/AES-NI
AES-192-CBC
SPARC T5 3.60 2 63,767 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2697 v2 2.70 2 23,224 Oracle Linux 6.3, IPP/AES-NI
Intel E5-2690 2.90 2 14,915 Oracle Linux 6.3, IPP/AES-NI
AES-128-CBC
SPARC T5 3.60 2 72,508 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2697 v2 2.70 2 27,733 Oracle Linux 6.3, IPP/AES-NI
Intel E5-2690 2.90 2 17,823 Oracle Linux 6.3, IPP/AES-NI

Configuration Summary

SPARC T5-2 server
2 x SPARC T5 processor, 3.6 GHz
512 GB memory
Oracle Solaris 11.1 SRU 4.2

Sun Server X4-2L server
2 x E5-2697 v2 processors, 2.70 GHz
256 GB memory
Oracle Linux 6.3

Sun Server X3-2 server
2 x E5-2690 processors, 2.90 GHz
128 GB memory
Oracle Linux 6.3

Benchmark Description

The benchmark measures cryptographic capabilities in terms of general low-level encryption, in-cache (32 KB encryptions) and on-chip using various ciphers, including AES-128-CFB, AES-192-CFB, AES-256-CFB, AES-128-CBC, AES-192-CBC, AES-256-CBC, AES-128-CCM, AES-192-CCM, AES-256-CCM, AES-128-GCM, AES-192-GCM and AES-256-GCM.

The benchmark results were obtained using tests created by Oracle which use various application interfaces to perform the various ciphers. They were run using optimized libraries for each platform to obtain the best possible performance.

See Also

Disclosure Statement

Copyright 2013, Oracle and/or its affiliates. All rights reserved. Oracle and Java are registered trademarks of Oracle and/or its affiliates. Other names may be trademarks of their respective owners. Results as of 9/23/2013.

Monday Sep 23, 2013

SPARC T5-2 Delivers Best 2-Chip MultiJVM SPECjbb2013 Result

SPECjbb2013 is a new benchmark designed to show modern Java server performance. Oracle's SPARC T5-2 set a world record as the fastest two-chip system beating just introduced two-chip x86-based servers. Oracle, using Oracle Solaris and Oracle JDK, delivered this two-chip world record result on the MultiJVM SPECjbb2013 metric. SPECjbb2013 is the replacement for SPECjbb2005 (SPECjbb2005 will soon be retired by SPEC).

  • Oracle's SPARC T5-2 server achieved 81,084 SPECjbb2013-MultiJVM max-jOPS and 39,129 SPECjbb2013-MultiJVM critical-jOPS on the SPECjbb2013 benchmark. This result is a two chip world record.

  • There are no IBM POWER7 or POWER7+ based server results on the SPECjbb2013 benchmark. IBM has published IBM POWER7+ based servers on the SPECjbb2005 which will soon be retired by SPEC.

  • The 2-chip SPARC T5-2 server running SPECjbb2013 is 30% faster than the 2-chip Cisco UCS B200 M3 server (2.7 GHz E5-2697 v2 Ivy Bridge-based) based on SPECjbb2013-MultiJVM max-jOPS.

  • The 2-chip SPARC T5-2 server running SPECjbb2013 is 66% faster than the 2-chip Cisco UCS B200 M3 server (2.7 GHz E5-2697 v2 Ivy Bridge-based) based on SPECjbb2013-MultiJVM critical-jOPS.

  • These results were obtained using Oracle Solaris 11 along with Java Platform, Standard Edition, JDK 7 Update 40 on the SPARC T5-2 server.

From SPEC's press release, "SPECjbb2013 replaces SPECjbb2005. The new benchmark has been developed from the ground up to measure performance based on the latest Java application features. It is expected to be used widely by all those interested in Java server performance, including JVM vendors, hardware developers, Java application developers, researchers and members of the academic community."

Performance Landscape

Results of SPECjbb2013 from www.spec.org as of September 22, 2013 and this report.

SPECjbb2013
System Processor SPECjbb2013-MultiJVM JDK
type # max-jOPS critical-jOPS
SPARC T5-2 SPARC T5, 3.6 GHz 2 81,084 39,129 Oracle JDK 7u40
Cisco UCS B200 M3, DDR3-1866 Intel E5-2697 v2, 2.7 GHz 2 62,393 23,505 Oracle JDK 7u40
Sun Server X4-2, DDR3-1600 Intel E5-2697 v2, 2.7 GHz 2 52,664 20,553 Oracle JDK 7u40
Cisco UCS C220 M3 Intel E5-2690, 2.9 GHz 2 41,954 16,545 Oracle JDK 7u11

The above table represents all of the published results on www.spec.org. SPEC allows for self publication of SPECjbb2013 results. See below for locations where full reports were made available.

Configuration Summary

System Under Test:

SPARC T5-2 server
2 x SPARC T5, 3.60 GHz
512 GB memory (32 x 16 GB dimms)
Oracle Solaris 11.1
Oracle JDK 7 Update 40

Benchmark Description

The SPECjbb2013 benchmark has been developed from the ground up to measure performance based on the latest Java application features. It is relevant to all audiences who are interested in Java server performance, including JVM vendors, hardware developers, Java application developers, researchers and members of the academic community.

SPECjbb2013 replaces SPECjbb2005. New features include:

  • A usage model based on a world-wide supermarket company with an IT infrastructure that handles a mix of point-of-sale requests, online purchases and data-mining operations.
  • Both a pure throughput metric and a metric that measures critical throughput under service-level agreements (SLAs) specifying response times ranging from 10ms to 500ms.
  • Support for multiple run configurations, enabling users to analyze and overcome bottlenecks at multiple layers of the system stack, including hardware, OS, JVM and application layers.
  • Exercising new Java 7 features and other important performance elements, including the latest data formats (XML), communication using compression, and messaging with security.
  • Support for virtualization and cloud environments.

See Also

Disclosure Statement

SPEC and the benchmark name SPECjbb are registered trademarks of Standard Performance Evaluation Corporation (SPEC). Results as of 9/23/2013, see http://www.spec.org for more information. SPARC T5-2 81,084 SPECjbb2013-MultiJVM max-jOPS, 39,129 SPECjbb2013-MultiJVM critical-jOPS, result from https://blogs.oracle.com/BestPerf/resource/jbb2013/sparct5-922.pdf Cisco UCS B200 M3 62,393 SPECjbb2013-MultiJVM max-jOPS, 23,505 SPECjbb2013-MultiJVM critical-jOPS, result from http://www.cisco.com/en/US/prod/collateral/ps10265/le_41704_pb_specjbb2013b200.pdf; Sun Server X4-2 52,664 SPECjbb2013-MultiJVM max-jOPS, 20,553 SPECjbb2013-MultiJVM critical-jOPS, result from https://blogs.oracle.com/BestPerf/entry/20130918_x4_2_specjbb2013; Cisco UCS C220 M3 41,954 SPECjbb2013-MultiJVM max-jOPS, 16,545 SPECjbb2013-MultiJVM critical-jOPS result from www.spec.org.

Wednesday Sep 18, 2013

Sun Server X4-2 Performance Running SPECjbb2013 MultiJVM Benchmark

Oracle's Sun Server X4-2 system, using Oracle Solaris and Oracle JDK, produced a SPECjbb2013 benchmark (MultiJVM metric) result. This benchmark was designed by the industry to showcase Java server performance.

  • The Sun Server X4-2 system is 24% faster than the fastest published Intel Xeon E5-2600 (Sandy Bridge) based two socket system's (Dell PowerEdge R720's) SPECjbb2013-MultiJVM max-jOPS.

  • The Sun Server X4-2 is 22% faster than the fastest published Intel Xeon E5-2600 (Sandy Bridge) based two socket system's (Dell PowerEdge R720's) SPECjbb2013-MultiJVM critical-jOPS.

  • The Sun Server X4-2 runs SPECjbb2013 (MultiJVM metric) at 70% of the published T5-2 SPECjbb2013-MultiJVM max-jOPS.

  • The Sun Server X4-2 runs SPECjbb2013 (MultiJVM metric) at 88% of the published T5-2 SPECjbb2013-MultiJVM critical-jOPS.

  • The combination of Oracle Solaris 11.1 and Oracle JDK 7 update 40 delivered a result of 52,664 SPECjbb2013-MultiJVM max-jOPS and 20,553 SPECjbb2013-MultiJVM critical-jOPS on the SPECjbb2013 benchmark.

From SPEC's press release, "SPECjbb2013 replaces SPECjbb2005. The new benchmark has been developed from the ground up to measure performance based on the latest Java application features. It is expected to be used widely by all those interested in Java server performance, including JVM vendors, hardware developers, Java application developers, researchers and members of the academic community."

Performance Landscape

Top two-socket results of SPECjbb2013 MultiJVM as of October 8, 2013.

SPECjbb2013
System Processor DDR3 SPECjbb2013-MultiJVM OS JDK
max-jOPS critical-jOPS
SPARC T5-2 2 x 3.6 GHz SPARC T5 1600 75,658 23,334 Solaris 11.1 7u17
Cisco UCS B200 M3 2 x 2.7 GHz Intel E5-2697 v2 1866 62,393 23,505 RHEL 6.4 7u40
Sun Server X4-2 2 x 2.7 GHz Intel E5-2697 v2 1600 52,664 20,553 Solaris 11.1 7u40
Dell PowerEdge R720 2 x 2.9 GHz Intel Xeon E5-2690 1600 42,431 16,779 RHEL 6.4 7u21

The above table includes published results from www.spec.org.

Configuration Summary

System Under Test:

Sun Server X4-2
2 x Intel E5-2697 v2, 2.7 GHz
Hyper-Threading enabled
Turbo Boost enabled
128 GB memory (16 x 8 GB dimms)
Oracle Solaris 11.1 (11.1.4.2.0)
Oracle JDK 7u40

Benchmark Description

The SPECjbb2013 benchmark has been developed from the ground up to measure performance based on the latest Java application features. It is relevant to all audiences who are interested in Java server performance, including JVM vendors, hardware developers, Java application developers, researchers and members of the academic community.

SPECjbb2013 replaces SPECjbb2005. New features include:

  • A usage model based on a world-wide supermarket company with an IT infrastructure that handles a mix of point-of-sale requests, online purchases and data-mining operations.
  • Both a pure throughput metric and a metric that measures critical throughput under service-level agreements (SLAs) specifying response times ranging from 10ms to 500ms.
  • Support for multiple run configurations, enabling users to analyze and overcome bottlenecks at multiple layers of the system stack, including hardware, OS, JVM and application layers.
  • Exercising new Java 7 features and other important performance elements, including the latest data formats (XML), communication using compression, and messaging with security.
  • Support for virtualization and cloud environments.

See Also

Disclosure Statement

SPEC and the benchmark name SPECjbb are registered trademarks of Standard Performance Evaluation Corporation (SPEC). Results from http://www.spec.org as of 10/8/2013. SPARC T5-2, 75,658 SPECjbb2013-MultiJVM max-jOPS, 23,334 SPECjbb2013-MultiJVM critical-jOPS; Cisco UCS B200 M3 62,393 SPECjbb2013-MultiJVM max-jOPS, 23,505 SPECjbb2013-MultiJVM critical-jOPS; Dell PowerEdge R720 42,431 SPECjbb2013-MultiJVM max-jOPS, 16,779 SPECjbb2013-MultiJVM critical-jOPS; Sun Server X4-2 52,664 SPECjbb2013-MultiJVM max-jOPS, 20,553 SPECjbb2013-MultiJVM critical-jOPS.

Friday Mar 29, 2013

SPARC T5 System Performance for Encryption Microbenchmark

The cryptography benchmark suite was internally developed by Oracle to measure the maximum throughput of in-memory, on-chip encryption operations that a system can perform. Multiple threads are used to achieve the maximum throughput. Systems powered by Oracle's SPARC T5 processor show outstanding performance on the tested encryption operations, beating Intel processor based systems.

  • A SPARC T5 processor running Oracle Solaris 11.1 runs from 2.4x to 4.4x faster on AES 256-bit key encryption than the Intel E5-2690 processor running in-memory encryption of 32 KB blocks using CFB128, CBC, CCM and GCM modes fully hardware subscribed.

  • AES CFB mode is used by the Oracle Database 11g for Transparent Data Encryption (TDE) which provides security to database storage.

Performance Landscape

Presented below are results for running encryption using the AES cipher with the CFB, CBC, CCM and GCM modes for key sizes of 128, 192 and 256. Decryption performance was similar and is not presented. Results are presented as MB/sec (10**6).

Encryption Performance – AES-CFB

Performance is presented for in-memory AES-CFB128 mode encryption. Multiple key sizes of 256-bit, 192-bit and 128-bit are presented. The encryption was performance on 32 KB of pseudo-random data (same data for each run).

AES-CFB
Microbenchmark Performance (MB/sec)
Processor GHz Chips Performance Software Environment
AES-256-CFB
SPARC T5 3.60 2 54,396 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2690 2.90 2 12,823 IPP/AES-NI
AES-192-CFB
SPARC T5 3.60 2 61,000 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2690 2.90 2 14,928 IPP/AES-NI
AES-128-CFB
SPARC T5 3.60 2 68,695 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2690 2.90 2 17,824 IPP/AES-NI

Encryption Performance – AES-CBC

Performance is presented for in-memory AES-CBC mode encryption. Multiple key sizes of 256-bit, 192-bit and 128-bit are presented. The encryption was performance on 32 KB of pseudo-random data (same data for each run).

AES-CBC
Microbenchmark Performance (MB/sec)
Processor GHz Chips Performance Software Environment
AES-256-CBC
SPARC T5 3.60 2 56,933 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2690 2.90 2 12,822 IPP/AES-NI
AES-192-CBC
SPARC T5 3.60 2 63,767 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2690 2.90 2 14,915 IPP/AES-NI
AES-128-CBC
SPARC T5 3.60 2 72,508 Oracle Solaris 11.1, libsoftcrypto + libumem
SPARC T4 2.85 2 31,085 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel X5690 3.47 2 20,721 IPP/AES-NI
Intel E5-2690 2.90 2 17,823 IPP/AES-NI

Encryption Performance – AES-CCM

Performance is presented for in-memory AES-CCM mode encryption with authentication. Multiple key sizes of 256-bit, 192-bit and 128-bit are presented. The encryption/authentication was performance on 32 KB of pseudo-random data (same data for each run).

AES-CCM
Microbenchmark Performance (MB/sec)
Processor GHz Chips Performance Software Environment
AES-256-CCM
SPARC T5 3.60 2 29,431 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2690 2.90 2 12,493 IPP/AES-NI
AES-192-CCM
SPARC T5 3.60 2 33,715 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2690 2.90 2 14,507 IPP/AES-NI
AES-128-CCM
SPARC T5 3.60 2 39,188 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2690 2.90 2 17,256 IPP/AES-NI

Encryption Performance – AES-GCM

Performance is presented for in-memory AES-GCM mode encryption with authentication. Multiple key sizes of 256-bit, 192-bit and 128-bit are presented. The encryption/authentication was performance on 32 KB of pseudo-random data (same data for each run).

AES-GCM
Microbenchmark Performance (MB/sec)
Processor GHz Chips Performance Software Environment
AES-256-GCM
SPARC T5 3.60 2 34,101 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2690 2.90 2 13,520 IPP/AES-NI
AES-192-GCM
SPARC T5 3.60 2 36,852 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2690 2.90 2 14,159 IPP/AES-NI
AES-128-GCM
SPARC T5 3.60 2 39,003 Oracle Solaris 11.1, libsoftcrypto + libumem
Intel E5-2690 2.90 2 14,877 IPP/AES-NI

Configuration Summary

SPARC T5-2 server
2 x SPARC T5 processor, 3.6 GHz
512 GB memory
Oracle Solaris 11.1 SRU 4.2

Sun Server X3-2 server
2 x E5-2690 processors, 2.90 GHz
128 GB memory

Benchmark Description

The benchmark measures cryptographic capabilities in terms of general low-level encryption, in-memory and on-chip using various ciphers, including AES-128-CFB, AES-192-CFB, AES-256-CFB, AES-128-CBC, AES-192-CBC, AES-256-CBC, AES-128-CCM, AES-192-CCM, AES-256-CCM, AES-128-GCM, AES-192-GCM and AES-256-GCM.

The benchmark results were obtained using tests created by Oracle which use various application interfaces to perform the various ciphers. They were run using optimized libraries for each platform to obtain the best possible performance.

See Also

Disclosure Statement

Copyright 2013, Oracle and/or its affiliates. All rights reserved. Oracle and Java are registered trademarks of Oracle and/or its affiliates. Other names may be trademarks of their respective owners. Results as of 3/26/2013.

Tuesday Mar 26, 2013

SPARC T5-2 Achieves SPECjbb2013 Benchmark World Record Result

Oracle, using Oracle Solaris and Oracle JDK, delivered a two socket server world record result on the SPECjbb2013 benchmark, Multi-JVM metric. This benchmark was designed by the industry to showcase Java server performance. SPECjbb2013 is the replacement for SPECjbb2005 (SPECjbb2005 will soon be retired by SPEC).

  • Oracle's SPARC T5-2 server achieved 75,658 SPECjbb2013-MultiJVM max-jOPS and 23,268 SPECjbb2013-MultiJVM critical-jOPS on the SPECjbb2013 benchmark. This result is a two chip world record. (Oracle has submitted this result for review by SPEC.)

  • There are no IBM POWER7 or POWER7+ based server results on the SPECjbb2013 benchmark. IBM has published IBM POWER7+ based servers on the SPECjbb2005 which will soon be retired by SPEC.

  • The SPARC T5-2 server running is 1.9x faster than the 2-chip HP ProLiant ML350p server (2.9 GHz E5-2690 Sandy Bridge-based) based on SPECjbb2013-MultiJVM max-jOPS.

  • The 2-chip SPARC T5-2 server is 15% faster than the 4-chip HP ProLiant DL560p server (2.7 GHz E5-4650 Sandy Bridge-based) based on SPECjbb2013-MultiJVM max-jOPS.

  • The 2-chip SPARC T5-2 server is 6.1x faster than the 1-chip HP ProLiant ML310e Gen8 (3.6 GHZ E3-1280v2 Ivy Bridge based) based on SPECjbb2013-MultiJVM max-jOPS.

  • The Sun Server X3-2 system running Oracle Solaris 11 is 5% faster than the HP ProLiant ML350p Gen8 server running Windows Server 2008 based on SPECjbb2013-MultiJVM max-jOPS.

  • Oracle's SPARC T4-2 server achieved 34,804 SPECjbb2013-MultiJVM max-jOPS and 10,101 SPECjbb2013-MultiJVM critical-jOPS on the SPECjbb2013 benchmark.
    (Oracle has submitted this result for review by SPEC.)

  • Oracle's Sun Server X3-2 system achieved 41,954 SPECjbb2013-MultiJVM max-jOPS and 13,305 SPECjbb2013-MultiJVM critical-jOPS on the SPECjbb2013 benchmark. (Oracle has submitted this result for review by SPEC.)

  • Oracle's Sun Server X2-4 system achieved 65,211 SPECjbb2013-MultiJVM max-jOPS and 22,057 SPECjbb2013-MultiJVM critical-jOPS on the SPECjbb2013 benchmark. (Oracle has submitted this result for review by SPEC.)

  • SPECjbb2013 demonstrates better performance on Oracle hardware and software, engineered to work together, than alternatives from HP.

  • These results were obtained using Oracle Solaris 11 along with Java Platform, Standard Edition, JDK 7 Update 17 on the SPARC T5-2 server, SPARC T4-2 server, Sun Server X3-2 and Sun Server X2-4.

From SPEC's press release, "SPECjbb2013 replaces SPECjbb2005. The new benchmark has been developed from the ground up to measure performance based on the latest Java application features. It is expected to be used widely by all those interested in Java server performance, including JVM vendors, hardware developers, Java application developers, researchers and members of the academic community."

Performance Landscape

Results of SPECjbb2013 from www.spec.org as of March 26, 2013 and this report.

SPECjbb2013
System Processor SPECjbb2013-MultiJVM OS JDK
max-jOPS critical-jOPS
SPARC T5-2 2 x SPARC T5 75,658 23,334 Oracle Solaris 11.1 Oracle JDK 7u17
HP DL560p Gen8 4 x Intel E5-4650 66,007 16,577 Windows 2008 R2 Oracle JDK 7u15
Sun Server X2-4 4 x Intel E7-4870 65,211 22,057 Oracle Solaris 11.1 Oracle JDK 7u17
Sun Server X3-2 2 x Intel E5-2690 41,954 13,305 Oracle Solaris 11.1 Oracle JDK 7u17
HP ML350p Gen8 2 x Intel E5-2690 40,047 12,308 Windows 2008 R2 Oracle JDK 7u15
SPARC T4-2 2 x SPARC T4 34,804 10,101 Oracle Solaris 11.1 Oracle JDK 7u17
Supermicro X8DTN+ 2 x Intel E5690 20,977 6,188 RHEL 6.3 Oracle JDK 7u11
HP ML310e Gen8 1 x Intel E3-1280v2 12,315 2,908 Windows 2008 R2 Oracle JDK 7u15
Intel R1304BT 1 x Intel 1260L 6,198 1,722 Windows 2008 R2 Oracle JDK 7u11

The above table represents all of the published results on www.spec.org. SPEC allows for self publication of SPECjbb2013 results.

Configuration Summary

Systems Under Test:

SPARC T5-2 server
2 x SPARC T5, 3.60 GHz
512 GB memory (32 x 16 GB dimms)
Oracle Solaris 11.1
Oracle JDK 7 Update 17

Sun Server X2-4
4 x Intel Xeon E7-4870, 2.40 GHz
Hyper-Threading enabled
Turbo Boost enabled
128 GB memory (32 x 4 GB dimms)
Oracle Solaris 11.1
Oracle JDK 7 Update 17

Sun Server X3-2
2 x Intel E5-2690, 2.90 GHz
Hyper-Threading enabled
Turbo Boost enabled
128 GB memory (32 x 4 GB dimms)
Oracle Solaris 11.1
Oracle JDK 7 Update 17

SPARC T4-2 server
2 x SPARC T4, 2.85 GHz
256 GB memory (32 x 8 GB dimms)
Oracle Solaris 11.1
Oracle JDK 7 Update 17

Benchmark Description

The SPECjbb2013 benchmark has been developed from the ground up to measure performance based on the latest Java application features. It is relevant to all audiences who are interested in Java server performance, including JVM vendors, hardware developers, Java application developers, researchers and members of the academic community.

SPECjbb2013 replaces SPECjbb2005. New features include:

  • A usage model based on a world-wide supermarket company with an IT infrastructure that handles a mix of point-of-sale requests, online purchases and data-mining operations.
  • Both a pure throughput metric and a metric that measures critical throughput under service-level agreements (SLAs) specifying response times ranging from 10ms to 500ms.
  • Support for multiple run configurations, enabling users to analyze and overcome bottlenecks at multiple layers of the system stack, including hardware, OS, JVM and application layers.
  • Exercising new Java 7 features and other important performance elements, including the latest data formats (XML), communication using compression, and messaging with security.
  • Support for virtualization and cloud environments.

See Also

Disclosure Statement

SPEC and the benchmark name SPECjbb are registered trademarks of Standard Performance Evaluation Corporation (SPEC). Results as of 3/26/2013, see http://www.spec.org for more information. SPARC T5-2 75,658 SPECjbb2013-MultiJVM max-jOPS, 23,334 SPECjbb2013-MultiJVM critical-jOPS. Sun Server X2-4 65,211 SPECjbb2013-MultiJVM max-jOPS, 22,057 SPECjbb2013-MultiJVM critical-jOPS. Sun Server X3-2 41,954 SPECjbb2013-MultiJVM max-jOPS, 13,305 SPECjbb2013-MultiJVM critical-jOPS. SPARC T4-2 34,804 SPECjbb2013-MultiJVM max-jOPS, 10,101 SPECjbb2013-MultiJVM critical-jOPS. HP ProLiant DL560p Gen8 66,007 SPECjbb2013-MultiJVM max-jOPS, 16,577 SPECjbb2013-MultiJVM critical-jOPS. HP ProLiant ML350p Gen8 40,047 SPECjbb2013-MultiJVM max-jOPS, 12,308 SPECjbb2013-MultiJVM critical-jOPS. Supermicro X8DTN+ 20,977 SPECjbb2013-MultiJVM max-jOPS, 6,188 SPECjbb2013-MultiJVM critical-jOPS. HP ProLiant ML310e Gen8 12,315 SPECjbb2013-MultiJVM max-jOPS, 2,908 SPECjbb2013-MultiJVM critical-jOPS. Intel R1304BT 6,198 SPECjbb2013-MultiJVM max-jOPS, 1,722 SPECjbb2013-MultiJVM critical-jOPS.

SPARC T5 Systems Deliver SPEC CPU2006 Rate Benchmark Multiple World Records

Oracle's SPARC T5 processor based systems delivered world record performance on the SPEC CPU2006 rate benchmarks. This was accomplished with Oracle Solaris 11.1 and Oracle Solaris Studio 12.3 software.

SPARC T5-8

  • The SPARC T5-8 server delivered world record SPEC CPU2006 rate benchmark results for systems with eight processors.

  • The SPARC T5-8 server achieved scores of 3750 SPECint_rate2006, 3490 SPECint_rate_base2006, 3020 SPECfp_rate2006, and 2770 SPECfp_rate_base2006.

  • The SPARC T5-8 server beat the 8 processor IBM Power 760 with POWER7+ processors by 1.7x on the SPECint_rate2006 benchmark and 2.2x on the SPECfp_rate2006 benchmark.

  • The SPARC T5-8 server beat the 8 processor IBM Power 780 with POWER7 processors by 35% on the SPECint_rate2006 benchmark and 14% on the SPECfp_rate2006 benchmark.

  • The SPARC T5-8 server beat the 8 processor HP DL980 G7 with Intel Xeon E7-4870 processors by 1.7x on the SPECint_rate2006 benchmark and 2.1x on the SPECfp_rate2006 benchmark.

SPARC T5-1B

  • The SPARC T5-1B server module delivered world record SPEC CPU2006 rate benchmark results for systems with one processor.

  • The SPARC T5-1B server module achieved scores of 467 SPECint_rate2006, 436 SPECint_rate_base2006, 369 SPECfp_rate2006, and 350 SPECfp_rate_base2006.

  • The SPARC T5-1B server module beat the 1 processor IBM Power 710 Express with a POWER7 processor by 62% on the SPECint_rate2006 benchmark and 49% on the SPECfp_rate2006 benchmark.

  • The SPARC T5-1B server module beat the 1 processor NEC Express5800/R120d-1M with an Intel Xeon E5-2690 processor by 31% on the SPECint_rate2006 benchmark. The SPARC T5-1B server module beat the 1 processor Huawei RH2288 V2 with an Intel Xeon E5-2690 processor by 44% on the SPECfp_rate2006 benchmark.

  • The SPARC T5-1B server module beat the 1 processor Supermicro A+ 1012G-MTF with an AMD Operton 6386 SE processor by 51% on the SPECint_rate2006 benchmark and 65% on the SPECfp_rate2006 benchmark.

Performance Landscape

Complete benchmark results are at the SPEC website, SPEC CPU2006 Results. The tables below provide the new Oracle results, as well as, select results from other vendors.

SPEC CPU2006 Rate Results – Eight Processors
System Processor ch/co/th * Peak Base
SPECint_rate2006
SPARC T5-8 SPARC T5, 3.6 GHz 8/128/1024 3750 3490
IBM Power 780 POWER7, 3.92 GHz 8/64/256 2770 2420
HP DL980 G7 Xeon E7-4870, 2.4 GHz 8/80/160 2180 2070
IBM Power 760 POWER7+, 3.42 GHz 8/48/192 2170 1480
Dell PowerEdge C6145 Opteron 6180 SE, 2.5 GHz 8/96/96 1670 1440
SPECfp_rate2006
SPARC T5-8 SPARC T5, 3.6 GHz 8/128/1024 3020 2770
IBM Power 780 POWER7, 3.92 GHz 8/64/256 2640 2410
HP DL980 G7 Xeon E7-4870, 2.4 GHz 8/80/160 1430 1380
IBM Power 760 POWER7+, 3.42 GHz 8/48/192 1400 1130
Dell PowerEdge C6145 Opteron 6180 SE, 2.5 GHz 8/96/96 1310 1200

* ch/co/th — chips / cores / threads enabled

SPEC CPU2006 Rate Results – One Processor
System Processor ch/co/th * Peak Base
SPECint_rate2006
SPARC T5-1B SPARC T5, 3.6 GHz 1/16/128 467 436
NEC Express5800/R120d-1M Xeon E5-2690, 2.9 GHz 1/8/16 357 343
Supermicro A+ 1012G-MTF Opteron 6386 SE, 2.8 GHz 1/16/16 309 269
IBM Power 710 Express POWER7, 3.556 GHz 1/8/32 289 255
SPECfp_rate2006
SPARC T5-1B SPARC T5, 3.6 GHz 1/16/128 369 350
Huawei RH2288 V2 Xeon E5-2690, 2.9 GHz 1/8/16 257 250
IBM Power 710 Express POWER7, 3.556 GHz 1/8/32 248 229
Supermicro A+ 1012G-MTF Opteron 6386 SE, 2.8 GHz 1/16/16 223 199

* ch/co/th — chips / cores / threads enabled

Configuration Summary

Systems Under Test:

SPARC T5-8
8 x 3.6 GHz SPARC T5 processors
4 TB memory (128 x 32 GB dimms)
2 TB on 8 x 600 GB 10K RPM SAS disks, arranged as 4 x 2-way mirrors
Oracle Solaris 11.1 (SRU 4.6)
Oracle Solaris Studio 12.3 1/13 PSE

SPARC T5-1B
1 x 3.6 GHz SPARC T5 processor
256 GB memory (16 x 16 GB dimms)
157 GB on 2 x 300 GB 10K RPM SAS disks (mirrored)
Oracle Solaris 11.1 (SRU 3.4)
Oracle Solaris Studio 12.3 1/13 PSE

Benchmark Description

SPEC CPU2006 is SPEC's most popular benchmark. It measures:

  • Speed — single copy performance of chip, memory, compiler
  • Rate — multiple copy (throughput)

The benchmark is also divided into integer intensive applications and floating point intensive applications:

  • integer: 12 benchmarks derived from real applications such as perl, gcc, XML processing, and pathfinding
  • floating point: 17 benchmarks derived from real applications, including chemistry, physics, genetics, and weather.

It is also divided depending upon the amount of optimization allowed:

  • base: optimization is consistent per compiled language, all benchmarks must be compiled with the same flags per language.
  • peak: specific compiler optimization is allowed per application.

The overall metrics for the benchmark which are commonly used are:

  • SPECint_rate2006, SPECint_rate_base2006: integer, rate
  • SPECfp_rate2006, SPECfp_rate_base2006: floating point, rate
  • SPECint2006, SPECint_base2006: integer, speed
  • SPECfp2006, SPECfp_base2006: floating point, speed

See Also

Disclosure Statement

SPEC and the benchmark names SPECfp and SPECint are registered trademarks of the Standard Performance Evaluation Corporation. Results as of March 26, 2013 from www.spec.org and this report. SPARC T5-8: 3750 SPECint_rate2006, 3490 SPECint_rate_base2006, 3020 SPECfp_rate2006, 2770 SPECfp_rate_base2006; SPARC T5-1B: 467 SPECint_rate2006, 436 SPECint_rate_base2006, 369 SPECfp_rate2006, 350 SPECfp_rate_base2006.

SPARC T5-8 Delivers Oracle OLAP World Record Performance

Oracle's SPARC T5-8 server delivered world record query performance with near real-time analytic capability using the Oracle OLAP Perf Version 3 workload running Oracle Database 11g Release 2 on Oracle Solaris 11.

  • The maximum query throughput on the SPARC T5-8 server is 1.6x higher than that of the 8-chip Intel Xeon E7-8870 server. Both systems had sub-second response time.

  • The SPARC T5-8 server with the Oracle Database demonstrated the ability to support at least 600 concurrent users querying OLAP cubes (with no think time), processing 2.93 million analytic queries per hour with an average response time of 0.66 seconds per query. This performance was enabled by keeping the entire cube in-memory utilizing the 4 TB of memory on the SPARC T5-8 server.

  • Assuming a 60 second think time between query requests, the SPARC T5-8 server can support approximately 49,450 concurrent users with the same 0.66 sec response time.

  • The SPARC T5-8 server delivered 4.3x times the maximum query throughput of a SPARC T4-4 server.

  • The workload uses a set of realistic BI queries that run against an OLAP cube based on a 4 billion row fact table of sales data. The 4 billion rows are partitioned by month spanning 10 years.

  • The combination of the Oracle Database with the Oracle OLAP option running on a SPARC T5-8 server supports live data updates occurring concurrently with minimally impacted user query executions.

Performance Landscape

Oracle OLAP Perf Version 3 Benchmark
Oracle cube base on 4 billion fact table rows
10 years of data partitioned by month
System Queries/
hour
Users* Average Response
Time (sec)
0 sec think time 60 sec think time
SPARC T5-8 2,934,000 600 49,450 0.66
8-chip Intel Xeon E7-8870 1,823,000 120 30,500 0.19
SPARC T4-4 686,500 150 11,580 0.71

Configuration Summary and Results

SPARC T5-8 Hardware Configuration:

1 x SPARC T5-8 server with
8 x SPARC T5 processors, 3.6 GHz
4 TB memory
Data Storage and Redo Storage
1 x Sun Storage F5100 Flash Array (with 80 FMODs)
Oracle Solaris 11.1
Oracle Database 11g Release 2 (11.2.0.3) with Oracle OLAP option

Sun Server X2-8 Hardware Configuration:

1 x Sun Server X2-8 with
8 x Intel Xeon E7-8870 processors, 2.4 GHz
512 GB memory
Data Storage and Redo Storage
3 x StorageTek 2540/2501 array pairs
Oracle Solaris 10 10/12
Oracle Database 11g Release 2 (11.2.0.2) with Oracle OLAP option

SPARC T4-4 Hardware Configuration:

1 x SPARC T4-4 server with
4 x SPARC T4 processors, 3.0 GHz
1 TB memory
Data Storage
1 x Sun Fire X4275 (using COMSTAR)
2 x Sun Storage F5100 Flash Array (each with 80 FMODs)
Redo Storage
1 x Sun Fire X4275 (using COMSTAR with 8 HDD)
Oracle Solaris 11 11/11
Oracle Database 11g Release 2 (11.2.0.3) with Oracle OLAP option

Benchmark Description

The Oracle OLAP Perf Version 3 benchmark is a workload designed to demonstrate and stress the ability of the OLAP Option to deliver fast query, near real-time updates and rich calculations using a multi-dimensional model in the context of the Oracle data warehousing.

The bulk of the benchmark entails running a number of concurrent users, each issuing typical multidimensional queries against an Oracle cube. The cube has four dimensions: time, product, customer, and channel. Each query user issues approximately 150 different queries. One query chain may ask for total sales in a particular region (e.g South America) for a particular time period (e.g. Q4 of 2010) followed by additional queries which drill down into sales for individual countries (e.g. Chile, Peru, etc.) with further queries drilling down into individual stores, etc. Another query chain may ask for yearly comparisons of total sales for some product category (e.g. major household appliances) and then issue further queries drilling down into particular products (e.g. refrigerators, stoves. etc.), particular regions, particular customers, etc.

While the core of every OLAP Perf benchmark is real world query performance, the benchmark itself offers numerous execution options such as varying data set sizes, number of users, numbers of queries for any given user and cube update frequency. Version 3 of the benchmark is executed with a much larger number of query streams than previous versions and used a cube designed for near real-time updates. The results produced by version 3 of the benchmark are not directly comparable to results produced by previous versions of the benchmark.

The near real-time update capability is implemented along the following lines. A large Oracle cube, H, is built from a 4 billion row star schema, containing data up until the end of last business day. A second small cube, D, is then created which will contain all of today's new data coming in from outside the world. It will be updated every L minutes with the data coming in within the last L minutes. A third cube, R, joins cubes H and D for reporting purposes much like a view might join data from two tables. Calculations are installed into cube R. The use of a reporting cube which draws data from different storage cubes is a common practice.

Query users are never locked out of query operations while new data is added to the update cube. The point of the demonstration is to show that an Oracle OLAP system can be designed which results in data being no more than L minutes out of date, where L may be as low as just a few minutes. This is what is meant by near real-time analytics.

Key Points and Best Practices

  • Update performance of the D cube was optimized by running update processes in the FX class with a priority greater than 0. The maximum lag time between updates to the source fact table and data availability to query users (what was referred to as L in the benchmark description) was less than 3 minutes for the benchmark environment on the SPARC T5-8 server.

  • Building and querying cubes with the Oracle OLAP option requires a large temporary tablespace. Normally temporary tablespaces would reside on disk storage. However, because the SPARC T5-8 server used in this benchmark had 4 TB of main memory, it was possible to use main memory for the OLAP temporary tablespace. This was done by using files in /tmp for the temporary tablespace datafiles.

  • Since typical BI users are often likely to issue similar queries, either with the same, or different, constants in the where clauses, setting the init.ora parameter "cursor_sharing" to "force" provides for additional query throughput and a larger number of potential users.

  • Assuming the normal Oracle initialization parameters (e.g. SGA, PGA, processes etc.) are appropriately set, out of the box performance for the OLAP Perf workload should be close to what is reported here. Additional performance resulted from (a)using memory for the OLAP temporary tablespace (b)setting "cursor_sharing" to force.

  • For a given number of query users with zero think time, the main measured metrics are the average query response time and the query throughput. A derived metric is the maximum number of users the system can support, with the same response time, assuming some non-zero think time. The calculation of this maximum is from the well-known "response-time law"

      N = (rt + tt) * tp

    where rt is the average response time, tt is the think time and tp is the measured throughput.

    Setting tt to 60 seconds, rt to 0.66 seconds and tp to 815 queries/sec (2,934,000 queries/hour), the above formula shows that the SPARC T5-8 server will support 49,450 concurrent users with a think time of 60 seconds and an average response time of 0.66 seconds.

    For more information about the "response-time law" see chapter 3 from the book "Quantitative System Performance" cited below.

See Also

Disclosure Statement

Copyright 2013, Oracle and/or its affiliates. All rights reserved. Oracle and Java are registered trademarks of Oracle and/or its affiliates. Other names may be trademarks of their respective owners. Results as of 03/26/2013.

Friday Feb 22, 2013

Oracle Produces World Record SPECjbb2013 Result with Oracle Solaris and Oracle JDK

Oracle, using Oracle Solaris and Oracle JDK, delivered a world record result on the SPECjbb2013 benchmark (Composite metric). This benchmark was designed by the industry to showcase Java server performance. SPECjbb2013 is the replacement for SPECjbb2005 (SPECjbb2005 will soon be retired by SPEC).

  • Oracle Solaris is 1.8x faster on the SPECjbb2013-Composite max-jOPS metric than the Red Hat Enterprise Linux result.

  • Oracle Solaris is 2.2x faster on the SPECjbb2013-Composite critical-jOPS metric than the Red Hat Enterprise Linux result.

  • The combination of Oracle Solaris 11.1 and Oracle JDK 7 update 15 delivered a result of 37,007 SPECjbb2013-Composite max-jOPS and 13,812 SPECjbb2013-Composite critical-jOPS on the SPECjbb2013 benchmark.
    (Oracle has submitted this result for review by SPEC and it is currently under review.)

From SPEC's press release, "SPECjbb2013 replaces SPECjbb2005. The new benchmark has been developed from the ground up to measure performance based on the latest Java application features. It is expected to be used widely by all those interested in Java server performance, including JVM vendors, hardware developers, Java application developers, researchers and members of the academic community."

Performance Landscape

Results of SPECjbb2013 from www.spec.org as of February 22, 2013 and this report.

SPECjbb2013
System Processor SPECjbb2013-Composite OS JDK
max-jOPS critical-jOPS
Sun Server X2-4 4 x Intel E7-4870 37,007 13,812 Solaris 11.1 Oracle JDK 7u15
Supermicro X8DTN+ 2 x Intel E5690 20,977 6,188 RHEL 6.3 Oracle JDK 7u11
Intel R1304BT 1 x Intel 1260L 6,198 1,722 Windows 2008 R2 Oracle JDK 7u11

The above table represents all of the published results on www.spec.org. SPEC allows for self publication of SPECjbb2013 results. AnandTech has taken advantage of this and has some result on their website which were run on Intel Xeon E5-2660, AMD Opteron 6380, AMD Opteron 6376 systems. These information be viewed at: www.anandtech.com. Unfortunately AnandTech did not follow SPEC's Fair Use requirements in disclosing information about their runs, so it is not possible to include the results in the table above.

SPECjbb2013
System Processor SPECjbb2013-MultiJVM OS JDK
max-jOPS critical-jOPS
HP ProLiant DL560p Gen8 4 x Intel E5-4650 66,007 16,577 Windows Server 2008 Oracle JDK 7u15
HP ProLiant ML350p Gen8 2 x Intel E5-2690 40,047 12,308 Windows Server 2008 Oracle JDK 7u15
HP ProLiant ML310e Gen8 1 x Intel E3-1280v2 12,315 2,908 Windows 2008 R2 Oracle JDK 7u15

Configuration Summary

System Under Test:

Sun Server X2-4
4 x Intel Xeon E7-4870, 2.40 GHz
Hyper-Threading enabled
Turbo Boost enabled
128 GB memory (32 x 4 GB dimms)
Oracle Solaris 11.1
Oracle JDK 7 update 15

Benchmark Description

The SPECjbb2013 benchmark has been developed from the ground up to measure performance based on the latest Java application features. It is relevant to all audiences who are interested in Java server performance, including JVM vendors, hardware developers, Java application developers, researchers and members of the academic community.

SPECjbb2013 replaces SPECjbb2005. New features include:

  • A usage model based on a world-wide supermarket company with an IT infrastructure that handles a mix of point-of-sale requests, online purchases and data-mining operations.
  • Both a pure throughput metric and a metric that measures critical throughput under service-level agreements (SLAs) specifying response times ranging from 10ms to 500ms.
  • Support for multiple run configurations, enabling users to analyze and overcome bottlenecks at multiple layers of the system stack, including hardware, OS, JVM and application layers.
  • Exercising new Java 7 features and other important performance elements, including the latest data formats (XML), communication using compression, and messaging with security.
  • Support for virtualization and cloud environments.

See Also

Disclosure Statement

SPEC and the benchmark name SPECjbb are registered trademarks of Standard Performance Evaluation Corporation (SPEC). Results as of 2/22/2013, see http://www.spec.org for more information. Sun Server X2-4 37007 SPECjbb2013-Composite max-jOPS, 13812 SPECjbb2013-Composite critical-jOPS.

Friday Feb 08, 2013

Improved Oracle Solaris 10 1/13 Secure Copy Performance for High Latency Networks

With Oracle Solaris 10 1/13, the performance of secure copy or scp is significantly improved for high latency networks.

  • Oracle Solaris 10 1/13 enabling a TCP receive window size up to 1 MB has up to 8 times faster transfer times over the latency range 50 - 200 msec compared to the previous Oracle Solaris 10 8/11.

  • The default TCP receive window size of 48 KB delivered similar performance in both Oracle Solaris 10 1/13 and Oracle Solaris 10 8/11.

  • In this study, settings above 1 MB for the TCP receive window size delivered similar performance to the 1 MB results.

  • The tuning of the TCP receive window has been available in Oracle Solaris for some time. This improved performance is available with Oracle Solaris 10 1/13 and Oracle Solaris 11.

Performance Landscape

T4-4_SSH_SCP.png

X4170M2_SSH_SCP.png

Configuration Summary

Test Systems:

SPARC T4-4 server
4 x SPARC T4 processor 3.0 GHz
1 TB memory
Oracle Solaris 10 1/13
Oracle Solaris 10 8/11

Sun Fire X4170 M2
2 x Intel Xeon X5675 3.06 GHz
48 GB memory
Oracle Solaris 10 1/13
Oracle Solaris 10 8/11

Driver System:

Sun Fire X4170 M2
2 x Intel Xeon X5675 3.06 GHz
48 GB memory
Oracle Solaris 10

Router / Programmable Delay System:

Sun Fire X4170 M2
2 x Intel Xeon X5675 3.06 GHz
48 GB memory
Oracle Solaris 10

Switch in between the router and the 2 test systems

Cisco linksys SR2024C

Benchmark Description

This benchmark measures the scp performance between two systems with variable router delays in the network between the two systems. A file size of 48 MB was used while measuring the affects of varying the latency (network delays) and varying the TCP receive window size.

Key Points and Best Practices

  • The WAN emulator (aka. hxbt) is used in the router to achieve delays. Verification of network function and characteristics confirmed after setting the simulator using Netperf latency and bandwidth tests between driver and test system.

  • Transfers performed over 1 GbE private, dedicated network.

  • Files were transferred to and from /tmp (i.e. in memory) on the test systems to minimize effect of filesystem performance and variability on the measurements.

  • Larger TCP receive windows than default can be enabled using the system-wide parameter tcp_recv_hiwat (e.g. to enable 1024 KB windows using this method, use the command: ndd -set /dev/tcp tcp_recv_hiwat 1048576). To make this change persistent the command will have to be added to system startup scripts.

  • sshd on target system must be restarted before any benefit can be observed after increasing the enabled tcp receive buffer size. (e.g: can restart with the command /usr/sbin/svcadm restart svc:/network/ssh:default)

  • Note that tcp_recv_hiwat is a system-wide variable that adjusts the entire TCP stack. Care, therefore, must be taken to make sure that changes do not adversely affect your environment.

  • Geographically distant servers can be affected by connection latencies of the kind presented here.

See Also

Disclosure Statement

Copyright 2013, Oracle and/or its affiliates. All rights reserved. Oracle and Java are registered trademarks of Oracle and/or its affiliates. Other names may be trademarks of their respective owners. Results as of 2/08/2013.

Tuesday Aug 28, 2012

SPARC T4-2 Produces World Record Oracle Essbase Aggregate Storage Benchmark Result

Significance of Results

Oracle's SPARC T4-2 server configured with a Sun Storage F5100 Flash Array and running Oracle Solaris 10 with Oracle Database 11g has achieved exceptional performance for the Oracle Essbase Aggregate Storage Option benchmark. The benchmark has upwards of 1 billion records, 15 dimensions and millions of members. Oracle Essbase is a multi-dimensional online analytical processing (OLAP) server and is well-suited to work well with SPARC T4 servers.

  • The SPARC T4-2 server (2 cpus) running Oracle Essbase 11.1.2.2.100 outperformed the previous published results on Oracle's SPARC Enterprise M5000 server (4 cpus) with Oracle Essbase 11.1.1.3 on Oracle Solaris 10 by 80%, 32% and 2x performance improvement on Data Loading, Default Aggregation and Usage Based Aggregation, respectively.

  • The SPARC T4-2 server with Sun Storage F5100 Flash Array and Oracle Essbase running on Oracle Solaris 10 achieves sub-second query response times for 20,000 users in a 15 dimension database.

  • The SPARC T4-2 server configured with Oracle Essbase was able to aggregate and store values in the database for a 15 dimension cube in 398 minutes with 16 threads and in 484 minutes with 8 threads.

  • The Sun Storage F5100 Flash Array provides more than a 20% improvement out-of-the-box compared to a mid-size fiber channel disk array for default aggregation and user-based aggregation.

  • The Sun Storage F5100 Flash Array with Oracle Essbase provides the best combination for large Oracle Essbase databases leveraging Oracle Solaris ZFS and taking advantage of high bandwidth for faster load and aggregation.

  • Oracle Fusion Middleware provides a family of complete, integrated, hot pluggable and best-of-breed products known for enabling enterprise customers to create and run agile and intelligent business applications. Oracle Essbase's performance demonstrates why so many customers rely on Oracle Fusion Middleware as their foundation for innovation.

Performance Landscape

System Data Size
(millions of items)
Database
Load
(minutes)
Default
Aggregation
(minutes)
Usage Based
Aggregation
(minutes)
SPARC T4-2, 2 x SPARC T4 2.85 GHz 1000 149 398* 55
Sun M5000, 4 x SPARC64 VII 2.53 GHz 1000 269 526 115
Sun M5000, 4 x SPARC64 VII 2.4 GHz 400 120 448 18

* – 398 mins with CALCPARALLEL set to 16; 484 mins with CALCPARALLEL threads set to 8

Configuration Summary

Hardware Configuration:

1 x SPARC T4-2
2 x 2.85 GHz SPARC T4 processors
128 GB memory
2 x 300 GB 10000 RPM SAS internal disks

Storage Configuration:

1 x Sun Storage F5100 Flash Array
40 x 24 GB flash modules
SAS HBA with 2 SAS channels
Data Storage Scheme Striped - RAID 0
Oracle Solaris ZFS

Software Configuration:

Oracle Solaris 10 8/11
Installer V 11.1.2.2.100
Oracle Essbase Client v 11.1.2.2.100
Oracle Essbase v 11.1.2.2.100
Oracle Essbase Administration services 64-bit
Oracle Database 11g Release 2 (11.2.0.3)
HP's Mercury Interactive QuickTest Professional 9.5.0

Benchmark Description

The objective of the Oracle Essbase Aggregate Storage Option benchmark is to showcase the ability of Oracle Essbase to scale in terms of user population and data volume for large enterprise deployments. Typical administrative and end-user operations for OLAP applications were simulated to produce benchmark results.

The benchmark test results include:

  • Database Load: Time elapsed to build a database including outline and data load.
  • Default Aggregation: Time elapsed to build aggregation.
  • User Based Aggregation: Time elapsed of the aggregate views proposed as a result of tracked retrieval queries.

Summary of the data used for this benchmark:

  • 40 flat files, each of size 1.2 GB, 49.4 GB in total
  • 10 million rows per file, 1 billion rows total
  • 28 columns of data per row
  • Database outline has 15 dimensions (five of them are attribute dimensions)
  • Customer dimension has 13.3 million members
  • 3 rule files

Key Points and Best Practices

  • The Sun Storage F5100 Flash Array has been used to accelerate the application performance.

  • Setting data load threads (DLTHREADSPREPARE) to 64 and Load Buffer to 6 improved dataloading by about 9%.

  • Factors influencing aggregation materialization performance are "Aggregate Storage Cache" and "Number of Threads" (CALCPARALLEL) for parallel view materialization. The optimal values for this workload on the SPARC T4-2 server were:

      Aggregate Storage Cache: 32 GB
      CALCPARALLEL: 16

     

See Also

Disclosure Statement

Copyright 2012, Oracle and/or its affiliates. All rights reserved. Oracle and Java are registered trademarks of Oracle and/or its affiliates. Other names may be trademarks of their respective owners. Results as of 28 August 2012.

Thursday Apr 12, 2012

Sun Fire X4270 M3 SAP Enhancement Package 4 for SAP ERP 6.0 (Unicode) Two-Tier Standard Sales and Distribution (SD) Benchmark

Oracle's Sun Fire X4270 M3 server (now known as Sun Server X3-2L) achieved 8,320 SAP SD Benchmark users running SAP enhancement package 4 for SAP ERP 6.0 with unicode software using Oracle Database 11g and Oracle Solaris 10.

  • The Sun Fire X4270 M3 server using Oracle Database 11g and Oracle Solaris 10 beat both IBM Flex System x240 and IBM System x3650 M4 server running DB2 9.7 and Windows Server 2008 R2 Enterprise Edition.

  • The Sun Fire X4270 M3 server running Oracle Database 11g and Oracle Solaris 10 beat the HP ProLiant BL460c Gen8 server using SQL Server 2008 and Windows Server 2008 R2 Enterprise Edition by 6%.

  • The Sun Fire X4270 M3 server using Oracle Database 11g and Oracle Solaris 10 beat Cisco UCS C240 M3 server running SQL Server 2008 and Windows Server 2008 R2 Datacenter Edition by 9%.

  • The Sun Fire X4270 M3 server running Oracle Database 11g and Oracle Solaris 10 beat the Fujitsu PRIMERGY RX300 S7 server using SQL Server 2008 and Windows Server 2008 R2 Enterprise Edition by 10%.

Performance Landscape

SAP-SD 2-Tier Performance Table (in decreasing performance order).

SAP ERP 6.0 Enhancement Pack 4 (Unicode) Results
(benchmark version from January 2009 to April 2012)

System OS
Database
Users SAP
ERP/ECC
Release
SAPS SAPS/
Proc
Date
Sun Fire X4270 M3
2xIntel Xeon E5-2690 @2.90GHz
128 GB
Oracle Solaris 10
Oracle Database 11g
8,320 2009
6.0 EP4
(Unicode)
45,570 22,785 10-Apr-12
IBM Flex System x240
2xIntel Xeon E5-2690 @2.90GHz
128 GB
Windows Server 2008 R2 EE
DB2 9.7
7,960 2009
6.0 EP4
(Unicode)
43,520 21,760 11-Apr-12
HP ProLiant BL460c Gen8
2xIntel Xeon E5-2690 @2.90GHz
128 GB
Windows Server 2008 R2 EE
SQL Server 2008
7,865 2009
6.0 EP4
(Unicode)
42,920 21,460 29-Mar-12
IBM System x3650 M4
2xIntel Xeon E5-2690 @2.90GHz
128 GB
Windows Server 2008 R2 EE
DB2 9.7
7,855 2009
6.0 EP4
(Unicode)
42,880 21,440 06-Mar-12
Cisco UCS C240 M3
2xIntel Xeon E5-2690 @2.90GHz
128 GB
Windows Server 2008 R2 DE
SQL Server 2008
7,635 2009
6.0 EP4
(Unicode)
41,800 20,900 06-Mar-12
Fujitsu PRIMERGY RX300 S7
2xIntel Xeon E5-2690 @2.90GHz
128 GB
Windows Server 2008 R2 EE
SQL Server 2008
7,570 2009
6.0 EP4
(Unicode)
41,320 20,660 06-Mar-12

Complete benchmark results may be found at the SAP benchmark website http://www.sap.com/benchmark.

Configuration and Results Summary

Hardware Configuration:

Sun Fire X4270 M3
2 x 2.90 GHz Intel Xeon E5-2690 processors
128 GB memory
Sun StorageTek 6540 with 4 * 16 * 300GB 15Krpm 4Gb FC-AL

Software Configuration:

Oracle Solaris 10
Oracle Database 11g
SAP enhancement package 4 for SAP ERP 6.0 (Unicode)

Certified Results (published by SAP):

Number of benchmark users:
8,320
Average dialog response time:
0.95 seconds
Throughput:

Fully processed order line:
911,330

Dialog steps/hour:
2,734,000

SAPS:
45,570
SAP Certification:
2012014

Benchmark Description

The SAP Standard Application SD (Sales and Distribution) Benchmark is a two-tier ERP business test that is indicative of full business workloads of complete order processing and invoice processing, and demonstrates the ability to run both the application and database software on a single system. The SAP Standard Application SD Benchmark represents the critical tasks performed in real-world ERP business environments.

SAP is one of the premier world-wide ERP application providers, and maintains a suite of benchmark tests to demonstrate the performance of competitive systems on the various SAP products.

See Also

Disclosure Statement

Two-tier SAP Sales and Distribution (SD) standard SAP SD benchmark based on SAP enhancement package 4 for SAP ERP 6.0 (Unicode) application benchmark as of 04/11/12: Sun Fire X4270 M3 (2 processors, 16 cores, 32 threads) 8,320 SAP SD Users, 2 x 2.90 GHz Intel Xeon E5-2690, 128 GB memory, Oracle 11g, Solaris 10, Cert# 2012014. IBM Flex System x240 (2 processors, 16 cores, 32 threads) 7,960 SAP SD Users, 2 x 2.90 GHz Intel Xeon E5-2690, 128 GB memory, DB2 9.7, Windows Server 2008 R2 EE, Cert# 2012016. IBM System x3650 M4 (2 processors, 16 cores, 32 threads) 7,855 SAP SD Users, 2 x 2.90 GHz Intel Xeon E5-2690, 128 GB memory, DB2 9.7, Windows Server 2008 R2 EE, Cert# 2012010. Cisco UCS C240 M3 (2 processors, 16 cores, 32 threads) 7,635 SAP SD Users, 2 x 2.90 GHz Intel Xeon E5-2690, 128 GB memory, SQL Server 2008, Windows Server 2008 R2 DE, Cert# 2012011. Fujitsu PRIMERGY RX300 S7 (2 processors, 16 cores, 32 threads) 7,570 SAP SD Users, 2 x 2.90 GHz Intel Xeon E5-2690, 128 GB memory, SQL Server 2008, Windows Server 2008 R2 EE, Cert# 2012008. HP ProLiant DL380p Gen8 (2 processors, 16 cores, 32 threads) 7,865 SAP SD Users, 2 x 2.90 GHz Intel Xeon E5-2690, 128 GB memory, SQL Server 2008, Windows Server 2008 R2 EE, Cert# 2012012.

SAP, R/3, reg TM of SAP AG in Germany and other countries. More info www.sap.com/benchmark

Tuesday Apr 10, 2012

World Record Oracle E-Business Suite 12.1.3 Standard Extra-Large Payroll (Batch) Benchmark on Sun Server X3-2L

Oracle's Sun Server X3-2L (formerly Sun Fire X4270 M3) server set a world record running the Oracle E-Business Suite 12.1.3 Standard Extra-Large Payroll (Batch) benchmark.

  • This is the first published result using Oracle E-Business 12.1.3.

  • The Sun Server X3-2L result ran the Extra-Large Payroll workload in 19 minutes.

Performance Landscape

This is the first published result for the Payroll Extra-Large model using Oracle E-Business 12.1.3 benchmark.

Batch Workload: Payroll Extra-Large Model
System Employees/Hr Elapsed Time
Sun Server X3-2L 789,515 19 minutes

Configuration Summary

Hardware Configuration:

Sun Server X3-2L
2 x Intel Xeon E5-2690, 2.9 GHz
128 GB memory
8 x 100 GB SSD for data
1 x 300 GB SSD for log

Software Configuration:

Oracle Linux 5.7
Oracle E-Business Suite R12 (12.1.3)
Oracle Database 11g (11.2.0.3)

Benchmark Description

The Oracle E-Business Suite Standard R12 Benchmark combines online transaction execution by simulated users with concurrent batch processing to model a typical scenario for a global enterprise. This benchmark ran one Batch component, Payroll, in the Extra-Large size. The goal of the benchmark proposal is to execute and achieve best batch-payroll performance using X-Large configuragion.

Results can be published in four sizes and use one or more online/batch modules

  • X-large: Maximum online users running all business flows between 10,000 to 20,000; 750,000 order to cash lines per hour and 250,000 payroll checks per hour.
    • Order to Cash Online -- 2400 users
      • The percentage across the 5 transactions in Order Management module is:
        • Insert Manual Invoice -- 16.66%
        • Insert Order -- 32.33%
        • Order Pick Release -- 16.66%
        • Ship Confirm -- 16.66%
        • Order Summary Report -- 16.66%
    • HR Self-Service -- 4000 users
    • Customer Support Flow -- 8000 users
    • Procure to Pay -- 2000 users
  • Large: 10,000 online users; 100,000 order to cash lines per hour and 100,000 payroll checks per hour.
  • Medium: up to 3000 online users; 50,000 order to cash lines per hour and 10,000 payroll checks per hour.
  • Small: up to 1000 online users; 10,000 order to cash lines per hour and 5,000 payroll checks per hour.

See Also

Disclosure Statement

Oracle E-Business X-Large Batch-Payroll benchmark, Sun Server X3-2L, 2.90 GHz, 2 chips, 16 cores, 32 threads, 128 GB memory, elapsed time 19.0 minutes, 789,515 Employees/HR, Oracle Linux 5.7, Oracle E-Business Suite 12.1.3, Oracle Database 11g Release 2, Results as of 7/10/2012.

About

BestPerf is the source of Oracle performance expertise. In this blog, Oracle's Strategic Applications Engineering group explores Oracle's performance results and shares best practices learned from working on Enterprise-wide Applications.

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