představení produktové řady oracle sparc s7

Copyright © 2016, Oracle and/or its affiliates. All rights reserved. |

Oracle’s SPARC S7 Servers

Josef Šlahůnek Oracle Sales Consulting Systems September 14th, 2016 Phone: 602 731 728 E-Mail: [email protected]


Safe Harbor Statement

The following is intended to outline our general product direction. It is intended for information purposes only, and may not be incorporated into any contract. It is not a commitment to deliver any material, code, or functionality, and should not be relied upon in making purchasing decisions. The development, release, and timing of any features or functionality described for Oracle’s products remains at the sole discretion of Oracle.

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SPARC S7 Servers: Technical Deep Dive

Overview

SPARC S7 Processor Overview

Server Details

Reliability, Availability, and Serviceability (RAS) and System Management

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Oracle’s SPARC S7 servers extend the world’s most advanced systems for enterprise computing into scale-out and cloud applications, with unique capabilities for information security, core efficiency and data analytics acceleration.

SPARC S7 Processor–Based Systems

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Copyright © 2016, Oracle and/or its affiliates. All rights reserved. | 6

Oracle SPARC Portfolio • Higher Performance as X86

• Better security

• SWoC

• Greater Application consolidation

• From small to big

• Cloud

SPARC T5-4 64-cores @ 3.6GHz

2TB Memory


4TB Memory

SPARC S7-2 8/16-cores @ 4.3GHz

1TB Memory

SPARC M7-16

SPARC

SuperCluster

M7

SPARC T5-2 16/32-cores @

3.6GHz

1TB Memory

SPARC S7-2L

8/16-cores @ 4.3GHz

1TB Memory


1TB Memory


2TB Memory


4TB Memory

SPARC M7-8 256-cores @ 4.2GHz

8TB Memory

512-cores @ 4.2GHz

16TB Memory

Fujitsu M10


(1) Maximum memory capacity is based on 64 GB DIMMs.

SPARC S7 Servers

SPARC S7-2 Server SPARC S7-2L Server

Processors 1 or 2 2

Max Cores/Threads 16 / 128 16 / 128

Max Memory 1 1 TB 1 TB

Form Factor 1U 2U

Max Disk Drives 8 26

PCIe Slots Available 3 6

Integrated Ethernet 4x 10GBase-T 4x 10GBase-T

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SPARC S7 Processor–Based Servers

• Oracle’s SPARC S7 processor: – Software in Silicon features: Same as in Oracle’s SPARC M7 processor – System-on-a-chip design: DDR4 interfaces and PCIe controller

• DDR4-2400 memory for high performance

• Internal SAS-3 Host Bus Adapter

• Onboard support for NVMe flash drives

• x8-capable PCIe 3.0 slots

• Oracle Integrated Lights Out Manager (Oracle ILOM) management

• Oracle Solaris 11.3 or later required – Oracle Solaris 10 1/13 supported in guest domains

Key Characteristics

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Two Systems, Five Enclosures, Shared Design

SPARC S7-2 and SPARC S7-2L Servers

SPARC S7-2L, 2U 12x 3.5-inch and 2x 2.5-inch drives 2U; 2 processors; 16 DIMMs; 1,024 GB DDR4; 6 PCIe 3.0 slots; ~100 TB storage (12x 3.5-inch drives plus 2x 2.5-inch SAS-3 drives)

SPARC S7-2L, 2U 26x 2.5-inch drives 2U; 2 processors; 16 DIMMs; 1,024 GB DDR4; 6 PCIe 3.0 slots; 39 TB storage (24x plus 2x 2.5-inch SAS-3 drives, 4x NVMe-enabled bays)

SPARC S7-2L, 2U 8x 2.5-inch drives 2U; 2 processors; 16 DIMMs; 1,024 GB DDR4; 6 PCIe 3.0 slots; 17 TB storage (8x 2.5-inch SAS-3 drives, 4x NVMe-enabled bays)

SPARC S7-2, 1U 8x 2.5-inch drives 1U; 1 or 2 processors; 16 DIMMs; 1,024 GB DDR4; 3 PCIe 3.0 slots; 17 TB storage (8x 2.5-inch SAS-3 drives, 4x NVMe-enabled bays)

SPARC S7-2L, 2U 12x 2.5-inch NVMe flash drives 2U; 2 processors; 16 DIMMs; 1,024 GB DDR4; 4 PCIe 3.0 slots; 38 TB NVMe flash storage (12x 2.5-inch NVMe drives)

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• Software in Silicon features – Silicon Secured Memory

– Cryptographic accelerators

– 4 DAX units, 16 DAX engines

• 8 cores at 4.27 GHz

• 64 hardware threads per processor

• Dynamic threading supporting critical threads

• Up to 8 DDR4 DIMMs per processor

• 2-way fully connected glueless symmetric multiprocessing (SMP)

• Technology: TSMC 20nm

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SPARC S7: Full Integration, Simplicity 1-Processor SPARC T7 Server

2-Processor SPARC S7 Server

16 DIMM Slots

PCIe Controller

DDR4 Interfaces 16 DIMM Slots

10GEth PCIe Slots Disks 10GEth PCIe Slots Disks

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Balanced Design Grows all Key Attributes for Efficiency

Continually Increasing Performance

SPARC T5 SPARC M7 SPARC S7

Processor Cores 16 32 8

Cache per Core 0.5 MB 2 MB 2 MB

Memory Bandwidth per Core 5.0 GB/s 5.3 GB/s 6.0 GB/s

Memory Access 163 ns 131 ns 97 ns

I/O Bandwidth 32 GB/s 145 GB/s 32 GB/s

Processor Frequency 3.60 GHz 4.13 GHz 4.27 GHz

Year 2013 2015 2016

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Copyright © 2016, Oracle and/or its affiliates. All rights reserved. | Copyright © 2016, Oracle and/or its affiliates. All rights reserved. |

SPARC Innovation is Continually Increasing Core Performance

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x86 per core performance is stalled

Co

re P

erfo

rma

nce

vs.

x86

E5

v2

2.0x

1.8x

1.6x

1.4x

1.2x

1.0x

.8x

2013 2015 2014 2016

x86: flat for four generations

M7

S7

SPARC: Database & Java


Faster than the Latest from HPE

Dramatically Improve Java Application Efficiency

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2,402

4,112 1.7x Faster Java S7-2 4.27 GHz S7 Core

x86 2.2 GHz E5 v4 Core

HPE DL360 G9

SPARC S7-2 (16-core) 65,790 SPECjbb2015-MultiJVM max-jOPS, 35,812 SPECjbb2015-MultiJVM critical-jOPS; HP ProLiant DL360 Gen9 (44-core) 105,690 SPECjbb2015-MultiJVM max-jOPS, 52,952 SPECjbb2015-MultiJVM critical-jOPS

Max jOPS / Core


Open Source OLTP Database Benchmark

Outstanding Leadership in Database Performance

S7-2 4.27 GHz S7 Core

X86 2.2 GHz E5 v4 Core

1.6x Faster Database

Transactions per minute, per Core

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NoSQL Big Data Benchmark

Dramatically Scale your Big Data Workloads

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Yahoo Cloud Serving Benchmark

11.4 K Ops

21.3 K Ops 1.9x Faster NoSQL S7-2 4.27 GHz S7 Core

X86 2.2 GHz E5 v4 Core


SPARC S7 Processor: Software in Silicon Features

Feature Benefits

Secu

rity

in

Sili

con

Silicon Secured Memory •Prevention of malicious memory access attacks •Protection against silent data corruption in memory •Faster and higher-quality code development

Cryptographic Acceleration

•End-to-end security at full speeds •Encryption of everything always •Secured network and database transactions

SQL

in

Silic

on

In-Memory Query Acceleration

•Analytics performed on live OLTP data •Reduced number of systems needed for analytics and reporting

In-Line Decompression •Reduced memory footprint and lower TCO • Increased in-memory databases and performance

Same Benefits as in the SPARC M7 Processor

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Revolutionary Hardwired Protection Against Data Corruption

Security in Silicon: Silicon Secured Memory

• SPARC S7 processor stops memory corruption

– Helps stop malicious code from accessing secure data

–When access is denied, the problem is reported

• Hidden “color” bits added to pointers and to memory

• Pointer color must match content color or access is aborted

• Can be used in production code with near-zero impact on performance

Memory Pointers

Memory Content

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Core Core Core Core

SQL in Silicon: In-Memory Query Acceleration

• The SPARC S7 processor includes on-chip Data Analytics Accelerator (DAX) units

– Independently process streams of database column elements placed in system memory

– Example: Find all values that match “California”

– 4 accelerator units per chip, with 4 pipelines each

• Free processor cores to run higher-level SQL functions or other applications

• Read data directly from memory, process it, and place results in cache for core usage

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SPARC S7

Cache

DAX DAX DAX DAX

Core Core Core Core


SQL in Silicon: In-Line Decompression

• The key to placing more data in memory

• The performance of decompression on

today’s processors is a huge bottleneck

• Solution: DAX unit runs decompression at

memory speeds

– Equivalent to eight decompression PCI cards and 30 CPU cores

• Increases useable memory

Process

Decompress

DAX

Data Stream

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Security in Silicon: Cryptographic Acceleration

• Eight cryptographic accelerators per SPARC S7 processor, one in each core

• Wire-speed encryption capabilities for secure data center operation without a performance penalty

• Support for 15 industry-standard cryptographic algorithms plus random number generation

• Easy to deploy via Oracle Solaris Cryptographic Framework

• Oracle Database 11.2.0.3 or later: Acceleration is automatic with Oracle Database Enterprise Edition when Transparent Data Encryption is enabled

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S7 advantage increases on highest security ciphers

Much Faster End-To-End Encryption

SPARC S7 Core

x86 E5 v4 Core

2.3 x Faster

AES 256-CFB: Popular for Cloud, DB

SHA 512: Important for Financial Operations

2.0 GB/s

0.9 GB/s

3.0 GB/s

0.4 GB/s

7.5x Faster SPARC S7 Core

x86 E5 v4 Core

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Simple, Comprehensive Security Auditing

• Quickly and easily test system configuration for compliance and security best-practices

Extensible compliance framework with standard profiles

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SPARC S7 Makes Enterprise-Wide Security Practical Comprehensive Security Designed In, Not Bolted On

8 Cores and 8 Cryptographic

Accelerators per Chip

Protection from attacks against data

in memory, on media or transmitted over the

network with virtually no performance impact

Silicon Secured Memory

Encryption Accelerators

Access Control, Read-Only

VMs

Compliance Reporting,

Remote Audits

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Get started at: https://community.oracle.com/community/softwareinsilicon/overview

Oracle Software in Silicon Cloud for Developers Free Access for Universities, Researchers, Customers, and Partners

• Access Oracle Solaris Zones with Security in Silicon and DAX technology

• Open APIs and documentation

• Example Apache Spark integration

• Use cases and code examples

• Prebuilt templates that can be extended and customized

• 30 GB storage to upload your test data and applications

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https://community.oracle.com/community/softwareinsilicon/overview


SPARC S7-2 Server System Details

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SPARC S7-2 Server: Overview • 1U chassis, fits into 900 mm–deep rack • One or two SPARC S7 processors (up to 16 cores/128 threads) • Up to 1,024 GB of DDR4-2400 memory

– 4, 8, or 16 DIMMs per system – 16 GB, 32 GB, or 64 GB per DIMM

• Eight 2.5-inch hot-pluggable disk drive bays – Up to 8 SAS HDDs/SSDs – Up to 4 NVMe SSDs – Mixing SAS and NVMe drives is supported

• One internal 12 Gb/sec SAS-3 HBA • Onboard support for NVMe SSDs • Four 10GBASE-T ports (one onboard quad-port NIC) • 3+11 low-profile PCIe 3.0 x8 slots (2 with physical x16 support) • Serial and Ethernet management ports, 2 USB ports • Four hot-swappable N+1 redundant fan modules (top loading) • Two 800 W/1,200 W 2 (output) hot-pluggable power supplies (N+1)

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1) One PCIe slot (#4) is internal and reserved for the SAS HBA 2) Power supply output: 800 W when operating at 100–120 VAC, 1,200 W at 200–240 VAC


SPARC S7-2L Server System Details

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SPARC S7-2L Server: Overview • 2U chassis, fits into 900 mm–deep rack • Two SPARC S7 processors (16 cores/128 threads) • Up to 1,024 GB of DDR4-2400 memory

– 8 or 16 DIMMs per system – 16 GB, 32 GB, or 64 GB per DIMM

• Four types of disk drive cage options – Eight 2.5-inch drive bays1

– 24 front and 2 rear 2.5-inch drive bays1,2 – Twelve 2.5-inch NVMe drive bays (no SAS drives) – Twelve 3.5-inch and two 2.5-inch drive bays2 (no NVMe drives)

• One internal 12 Gb/sec SAS-3 HBA3 • Four 10GBASE-T ports (one onboard quad-port NIC) • 6+14 low-profile PCIe 3.0 x8 slots (2 with physical x16 support) • Serial and Ethernet management ports, 2 USB ports • Four hot-swappable N+1 redundant fan modules (top loading) • Two 1,200 W (output) hot-pluggable power supplies (N+1)

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1) Four drive bays are NVMe-enabled, mixing SAS and NVMe drives is supported 2) All drive bays are supported by the single internal 12 Gb/sec SAS-3 HBA 3) Not included in the 12x NVMe drive configuration 4) One PCIe slot (#7) is internal and reserved for the SAS HBA or an NVMe PCIe switch


• Oracle’s SPARC S7 processor

– 4.27 GHz, 16 cores/128 threads

• 8 DDR4s per socket, 16 DDR4s per system

– 128 GB min (8x 16 GB DIMMS)

– 512 GB max (16x 32 GB DIMMS)

• I/O functions

– 6x LP PCIe 3.0 slots

– 4x 10GBase-T Ethernet ports

– 3x USB ports (two front, one rear)

• Storage

– 8x SFF HDD/SSD, four of which can be NVMe, plus 1x DVD

– Supported: HDD: 1.2 TB, SSD: 400 GB, NVME: 1.6 TB

• Software

– Oracle Solaris 11.3

• On-board LOM (Intel XL710):

– 10 Gigabit Ethernet (GbE) controller

– PCI Express (PCIe) 3.0, x8 including direct I/O optimizations via TLP Processing Hints (TPH)

– SR-IOV: up to 128 virtual devices per physical device

– Excellent small-packet performance for network appliances and NFV

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Netra SPARC S7-2

Rear View

8x SFF (up to 8x HDD/SSD, up to 4x NVMe) + DVD

Front View

2x 1,200 W PSUs AC/DC, 6x PCI-e slots, 4x 10 GbE


RAS and System Management

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SPARC S7-2 and S7-2L Servers: Availability Features

Redundant, hot-swappable power supplies and cooling fans

Memory error protection, message retry in hardware,

cyclic redundancy check (CRC)

Dual PCIe root complexes and cross-connected PCIe switches Power-On

Self-Test

Internal NVMe drives supported by two separate PCIe buses for isolation

Hot-pluggable drives

Front and rear system indicator LEDs

Redundant I/O controller (cards) with MPxIO for storage devices and IPMP for network devices

Fault Management Architecture (FMA)

Oracle Solaris ZFS for file system resilience (RAID)


SPARC S7 Processor–Based Servers: Memory

• Memory error protection – Error correction within a single DRAM device – Triple-bit error detection across DRAM devices

• Memory page retirement upon exceeding threshold • Memory channel interconnect – Cyclic redundancy check (CRC) –Message retry in hardware

• Memory “scrubber” – Periodic event to prevent multiple soft errors in one line

• Cache protection – All single-bit errors corrected – Squash double-bit errors in cache with cache bypass

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Oracle ILOM on SPARC S7 Processor–Based Servers

• SPARC S7 processor–based servers use Oracle ILOM 3.2.6

• Oracle ILOM looks/behaves just like Oracle ILOM on other platforms

–Management interfaces: CLI, BUI, IPMI, SNMP

– Remote host management

– Inventory and component management

– System monitoring and alert/fault management

– User account management

– Power consumption management

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Integrated Lights Out Management


Oracle Enterprise Manager Ops Center: Screenshot

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Management of Applications to OS to Virtualization to Disk

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Oracle’s SPARC S7 servers extend the world’s most advanced systems for enterprise computing into scale-out and cloud applications, with unique capabilities for information security, core efficiency and data analytics acceleration.

SPARC S7 Processor–Based Systems

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Required Benchmark Disclosure Statement • Additional Info: http://blogs.oracle.com/bestperf • Copyright 2016, Oracle &/or its affiliates. All rights reserved. Oracle & Java are registered trademarks of Oracle &/or its affiliates.Other names may be trademarks of their respective owners

• SPEC and the benchmark name SPECjEnterprise are registered trademarks of the Standard Performance Evaluation Corporation. Results from www.spec.org as of 6/29/2016. SPARC S7-2, 14,400.78 SPECjEnterprise2010 EjOPS (unsecure); SPARC S7-2, 14,121.47 SPECjEnterprise2010 EjOPS (secure); Oracle Server X6-2, 27,509.59 SPECjEnterprise2010 EjOPS (unsecure); IBM Power S824, 22,543.34 SPECjEnterprise2010 EjOPS (unsecure); IBM x3650 M5, 19,282.14 SPECjEnterprise2010 EjOPS (unsecure).

• SPEC and the benchmark name SPECjbb are registered trademarks of Standard Performance Evaluation Corporation (SPEC). Results from http://www.spec.org as of 6/29/2016. SPARC S7-2 (16-core) 65,790 SPECjbb2015-MultiJVM max-jOPS, 35,812 SPECjbb2015-MultiJVM critical-jOPS; IBM Power S812LC (10-core) 44,883 SPECjbb2015-MultiJVM max-jOPS, 13,032 SPECjbb2015-MultiJVM critical-jOPS; SPARC T7-1 (32-core) 120,603 SPECjbb2015-MultiJVM max-jOPS, 60,280 SPECjbb2015-MultiJVM critical-jOPS; Huawei RH2288H v3 (44-core) 121,381 SPECjbb2015-MultiJVM max-jOPS, 38,595 SPECjbb2015-MultiJVM critical-jOPSHP ProLiant DL360 Gen9 (44-core) 120,674 SPECjbb2015-MultiJVM max-jOPS, 29,013 SPECjbb2015-MultiJVM critical-jOPS; HP ProLiant DL380 Gen9 (44-core) 105,690 SPECjbb2015-MultiJVM max-jOPS, 52,952 SPECjbb2015-MultiJVM critical-jOPS;; Cisco UCS C220 M4 (44-core) 94,667 SPECjbb2015-MultiJVM max-jOPS, 71,951 SPECjbb2015-MultiJVM critical-jOPS; Huawei RH2288H V3(36-core) 98,673 SPECjbb2015-MultiJVM max-jOPS, 28,824 SPECjbb2015-MultiJVM critical-jOPs; Lenovo x240 M5 (36-core) 80,889 SPECjbb2015-MultiJVM max-jOPS,43,654 SPECjbb2015-MultiJVM critical-jOPS; SPARC T5-2 (32-core) 80,889 SPECjbb2015-MultiJVM max-jOPS, 37,422 SPECjbb2015-MultiJVM critical-jOPS; SPARC S7-2 (16-core) 66,612 SPECjbb2015-Distributed max-jOPS, 36,922 SPECjbb2015-Distributed critical-jOPS; HP ProLiant DL380 Gen9 (44-core) 120,674 SPECjbb2015-Distributed max-jOPS, 39,615 SPECjbb2015-Distributed critical-jOPS; HP ProLiant DL360 Gen9 (44-core) 106,337 SPECjbb2015-Distributed max-jOPS, 55,858 SPECjbb2015-Distributed critical-jOPS; HP ProLiant DL580 Gen9 (96-core) 219,406 SPECjbb2015-Distributed max-jOPS, 72,271 SPECjbb2015-Distributed critical-jOPS; Lenovo Flex System x3850 X6 (96-core) 194,068 SPECjbb2015-Distributed max-jOPS, 132,111 SPECjbb2015-Distributed critical-jOPS.

• SPEC and the benchmark name SPECjEnterprise are registered trademarks of the Standard Performance Evaluation Corporation. Results from www.spec.org as of 10/25/2015. SPARC T7-1, 25,818.85 SPECjEnterprise2010 EjOPS (unsecure); SPARC T7-1, 25,093.06 SPECjEnterprise2010 EjOPS (secure); Oracle Server X5-2, 21,504.30 SPECjEnterprise2010 EjOPS (unsecure); IBM Power S824, 22,543.34 SPECjEnterprise2010 EjOPS (unsecure); IBM x3650 M5, 19,282.14 SPECjEnterprise2010 EjOPS (unsecure).

• SPEC and the benchmark names SPECfp and SPECint are registered trademarks of the Standard Performance Evaluation Corporation. Results as of October 25, 2015 from www.spec.org and this report. 1 chip resultsSPARC T7-1: 1200 SPECint_rate2006, 1120 SPECint_rate_base2006, 832 SPECfp_rate2006, 801 SPECfp_rate_base2006; SPARC T5-1B: 489 SPECint_rate2006, 440 SPECint_rate_base2006, 369 SPECfp_rate2006, 350 SPECfp_rate_base2006; Fujitsu SPARC M10-4S: 546 SPECint_rate2006, 479 SPECint_rate_base2006, 462 SPECfp_rate2006, 418 SPECfp_rate_base2006. IBM Power 710 Express: 289 SPECint_rate2006, 255 SPECint_rate_base2006, 248 SPECfp_rate2006, 229 SPECfp_rate_base2006; Fujitsu CELSIUS C740: 715 SPECint_rate2006, 693 SPECint_rate_base2006; NEC Express5800/R120f-1M: 474 SPECfp_rate2006, 460 SPECfp_rate_base2006.

• Two-tier SAP Sales and Distribution (SD) standard application benchmarks, SAP Enhancement Package 5 for SAP ERP 6.0 as of 5/16/16:SPARC M7-8, 8 processors / 256 cores / 2048 threads,SPARC M7, 4.133 GHz, 130000 SD Users, 713480 SAPS, Solaris 11, Oracle 12cSAP, Certification Number: 2016020, SPARC T7-2 (2 processors, 64 cores, 512 threads) 30,800 SAP SD users, 2 x 4.13 GHz SPARC M7, 1 TB memory, Oracle Database 12c, Oracle Solaris 11, Cert# 2015050. HPE Integrity Superdome X (16 processors, 288 cores, 576 threads) 100,000 SAP SD users, 16 x 2.5 GHz Intel Xeon Processor E7-8890 v3 4096 GB memory, SQL Server 2014, Windows Server 2012 R2 Datacenter Edition, Cert# 2016002 . IBM Power System S824 (4 processors, 24 cores, 192 threads) 21,212 SAP SD users, 4 x 3.52 GHz POWER8, 512 GB memory, DB2 10.5, AIX 7, Cert#201401. Dell PowerEdge R730 (2 processors, 36 cores, 72 threads) 16,500 SAP SD users, 2 x 2.3 GHz Intel Xeon Processor E5-2699 v3 256 GB memory, SAP ASE 16, RHEL 7, Cert#2014033. HP ProLiant DL380 Gen9 (2 processors, 36 cores, 72 threads) 16,101 SAP SD users, 2 x 2.3 GHz Intel Xeon Processor E5-2699 v3 256 GB memory, SAP ASE 16, RHEL 6.5, Cert#2014032. SAP, R/3, reg TM of SAP AG in Germany and other countries. More info www.sap.com/benchmark

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