Sparc m6 32 in-memory infrastructure for the entire enterprise

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The New Oracle SPARC M6-32:
In-Memory Infrastructure for
the Entire Enterprise
Gary Combs
Principal Product Manager
Roman Zajcew
Senior Principal Software Engineer

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.

Program Agenda
 SPARC Strategy
 SPARC M6-32 Details
 Target Workloads
 Conclusion

Oracle’s Unique Advantage: Design Innovation
Extreme Performance, Efficiency and Optimization for Software
System
Software

Oracle SPARC Hardware Strategy
•Long-term Roadmap. Software in Silicon.INNOVATION
Leadership in all Enterprise Business ApplicationsPERFORMANCE
Simplified Administration, Designed-in Virtualization,
Scalable Data Management, Advanced Protection
BUILT FOR CLOUD
COMPUTING
Only Oracle provides a true integrated stack with
management visibility throughout the software and
hardware layers
INTEGRATED
SOFTWARE AND
HARDWARE STACK

Co-Engineered – True Silicon to App
Innovation at every level, “SW in Silicon” & co-engineering lifestyle
SPARC
Innovate
Accelerate
True co-engineering puts SPARC on the fastest path to delivered enterprise performance

Processor Cadence
 Oracle’s fast processor cadence
– Earlier processor cadence was every 5 years. Now every 2 years.
– IBM stuck with 3+ year cadence – hard for them to innovate correctly

SPARC M6-32 Details

SPARC M6-32 Server
 Extreme performance
– 2X the processor cores of an M5-32
– 2X the throughput performance of an M5-32
– In memory Oracle database queries 7X faster
 Highest efficiency: built-in, no-cost virtualization
– Flexible physical and logical system partitioning
– Continuous availability design to eliminate downtime
– All of your existing apps just run, faster
 Best for in-memory computing
– 2X more memory per processor of any datacenter server
– Terabytes per second of memory bandwidth
Run Your Applications In Memory For Unparalleled Performance
2XCORES AND THROUGHPUT
OF SPARC M5 SERVER
384CORES

Powered By Oracle Processor Technology
SPARC M6: Higher Density and Performance per Processor
 New: 12 S3 cores @ 3.6GHz
 Large 48MB shared L3 Cache
 Scalable to 32 processors in M6-32
 Integrated 2x8 PCIe 3.0
 Integrated ISA-based crypto
acceleration
 4.1 Terabits/s total link bandwidth
2X
THROUGHPUT
OF M5

SPARC M6 Continues On-Chip Encryption Leadership
On-Chip
Accelerators
Common Use
Examples
Mainly Used SPARC T4/T5/M5/M6
IBM Power7+
Only 3 cryptos for 8
cores
Intel
Westmere
/SandyBridge
Asymmetric /Public
Key Encryption
Web Browsers, phone
calls, VPN, Secure FTP
To protect data or
files in transit
RSA, DH, DSA, ECC RSA, ECC RSA, ECC
Symmetric Key /
Bulk Encryption
Databases, credit card
and social security
numbers, private info
To protect data or
files at rest or stored:
disks, backup tapes,
etc.
AES, DES, 3DES,
Camellia, Kasumi
AES (Modes: ECB,
CBC, CTR, CCM, CCA,
GCM, GCA, GMAC,
CM, F8, XBC-MAC-96;
Key lengths: 128b,192b,
256b) (Lacks AES-CFB
used by Oracle
database!!)
AES
Message Digest /
Hash Functions
Data lookup &
authentication, digital
signatures, message
authentication codes
(MAC)
To compress/create a
short summary from a
data chunk and not
expose it; To detect
duplicate or corrupt
data
CRC32c, MD5, SHA-1,
SHA-2 (SHA-224, SHA-
256, SHA-384, SHA-512)
MD5, SHA-1, Partial
SHA-2 (SHA-256, SHA-
512), HMAC
supported for SHA (?)
none
Random Number
Generation
Ubiquitous To generate keys Supported Supported
none till Ivy
Bridge

SPARC M6 CPU Block Diagram
2x8PCIe3.0@8GBps
16GBpseachdirection
8 threads per
Core
IO
Subsystem
Memory
Control
Coherency2x4Switch
Memory
Control
Coherency Links
12.8 Gbps per lane
- 12 lanes per link
(1075 Gbps)
12 x 5 Crossbar (~620GBps bandwidth)
C0 C1 C2 C3 C4 C5
L3$ B0
L3$ B0
1MB,16-way
L3$ B0
12MB,16-way
L3$ B2
12MB,16-way
L3$ B1
12MB,16-way
L3$ B3
12MB,16-way
128 KB L2$
16 KB L1I$
16 KB L1D$
FGU
Crypto
SPARC
S3 Core
DDR3 – 1066 MHz DDR3 – 1066 MHz
BoBBoB BoBBoB
DDR3 – 1066 MHz DDR3 – 1066 MHz
BoBBoB BoBBoB
Coherence Unit Coherence Unit
Scalability Links
12 Gbps per lane
– 4 lanes per link
(144 Gbps) SLC
SLC
SLC
SLC
SLC
SLC
Link 0
Link 1
Link 2
Link 3
Link 4
Link 5
Link 6
C6 C7 C8 C9 C10 C11

4 Critical Features
2x8PCIe3.0@8GBps
16GBpseachdirection
8 threads per
Core
IO
Subsystem
Memory
Control
Coherency2x4Switch
Memory
Control
Coherency Links
12.8 Gbps per lane
- 12 lanes per link
(1075 Gbps)
12 x 5 Crossbar (~620GBps bandwidth)
C0 C1 C2 C3 C4 C5
L3$ B0
L3$ B0
1MB,16-way
L3$ B0
12MB,16-way
L3$ B2
12MB,16-way
L3$ B1
12MB,16-way
L3$ B3
12MB,16-way
128 KB L2$
16 KB L1I$
16 KB L1D$
FGU
Crypto
SPARC
S3 Core
DDR3 – 1066 MHz DDR3 – 1066 MHz
BoBBoB BoBBoB
DDR3 – 1066 MHz DDR3 – 1066 MHz
BoBBoB BoBBoB
Coherence Unit Coherence Unit
Scalability Links
12 Gbps per lane
– 4 lanes per link
(144 Gbps) SLC
SLC
SLC
SLC
SLC
SLC
Link 0
Link 1
Link 2
Link 3
Link 4
Link 5
Link 6
C6 C7 C8 C9 C10 C11
1TB per cpu
Scale to
32 cpus
8-way Local
Coherency Group
48MB of L3$

M6: A Major Leap Forward in the High-end
Built to a Different Scale
 Scale to 8-way with local
coherency

M6: A Major Leap Forward in the High-end
Built to a Different Scale
 384 cores
 3,072 threads
 32 TBs of memory
 1.4 TB/s of memory bandwidth
 3 TB/s of system bandwidth
 1 TB/s of I/O bandwidth

Dynamic System Domains
on M6-32
 M6-32 supports Dynamic System Domains
(also known as PDoms)
 PDom building blocks are known as Domain
Configuration Units (DCU)
 M6-32 has four DCUs
 A DCU has:
– I/O, CPUs, and memory
 Each PDom consists of one to four DCUs
– DCUs within a PDom communicate using
Central Coherency and Data Switches
DCU0
DCU1 DCU2
DCU3

Central Coherency Directory And Data Switches
12 13 14 15
3
IO Switch
Board 1
IO Switch
Board 0
0
1
0
1
0
1
0
1
DCU 3
Disks
0-3
Disks
4-7
0 1 2 3
0
IO Switch
Board 1
IO Switch
Board 0
0
1
0
1
0
1
0
1
DCU 0
Disks
0-3
Disks
4-7
4 5 6 7
1
IO Switch
Board 1
IO Switch
Board 0
0
1
0
1
0
1
0
1
DCU 1
Disks
0-3
Disks
4-7
8 9 10 11
2
IO Switch
Board 1
IO Switch
Board 0
0
1
0
1
0
1
0
1
DCU 2
Disks
0-3
Disks
4-7
M6-32 PDom Assignment Example: 1 Domain
PDom 1

Central Coherency Directory And Data Switches
12 13 14 15
3
IO Switch
Board 1
IO Switch
Board 0
0
1
0
1
0
1
0
1
DCU 3
Disks
0-3
Disks
4-7
0 1 2 3
0
IO Switch
Board 1
IO Switch
Board 0
0
1
0
1
0
1
0
1
DCU 0
Disks
0-3
Disks
4-7
4 5 6 7
1
IO Switch
Board 1
IO Switch
Board 0
0
1
0
1
0
1
0
1
DCU 1
Disks
0-3
Disks
4-7
8 9 10 11
2
IO Switch
Board 1
IO Switch
Board 0
0
1
0
1
0
1
0
1
DCU 2
Disks
0-3
Disks
4-7
M6-32 PDom Assignment Example: 3 Domains
PDom 1 PDom 3
PDom 2

SPARC M6-32 Virtualization Infrastructure
SPARC M6 Platform
Dynamic Domain
Oracle VM Server for SPARC
Oracle Solaris 11 Oracle Solaris 10
Solaris
11
Zone
Solaris
10 Zone
Solaris
Legacy
Zone
Solaris
10
Zone
Dynamic Domain
Oracle Solaris 11
Solaris 11 Zone
No-cost virtualization to improve system utilization
Dynamic Domain
Oracle VM Server for SPARC
Oracle Solaris 10
Solaris
Legacy
Zone
Solaris
10
Zone

Key SPARC M6-32 System Advantages
Maximizing Uptime for Mission-Critical Applications
Feature Attribute Benefit
3.6 GHz clock Faster single threaded processing
Faster response time, rapid batch processing for
quicker results
PCIe Gen 3.0 IO Subsystem
Over 4x faster bandwidth for
system IO traffic
Improved speed for database processing
48MB on chip L3 Cache
Reduced memory accesses by
processor
Improved performance for database, DSS and data
warehouse applications
Binary compatibility
Existing SPARC Solaris
applications run unmodified
Legacy apps just run
Built-in Virtualization with Oracle
VM Server for SPARC
Flexible logical partitioning and live
application mobility
3 layers of virtualization at no cost
Oracle Solaris 11
Reliable, secure and streamlined
operation
Robust and scalable OS

Software in Silicon
 SPARC’s built-In virtualization
 Industry-leading security: Database TDE, ZFS, network
 Database & Java
– DB block checking (accelerates Oracle Database 12c)
– Pause Instruction for Java busy wait/lock contention
– Fused “compare&branch” Java tight loop acceleration
 SPARC’s advanced threading model – Critical Threads
SPARC fast tracking Software in Silicon
Oracle Accelerators
Database Performance
Application Performance
Compression
Security
Interconnect
Data Protection
Future

Target Workloads

Presentation
Business
Logic
Presentation
Business
Logic
Business
Logic
Database
SPARC M6-32: Mission-critical Deployments
Consolidate Database and Application Tiers
SPARC M6-32
Data ClientWebApplication
Database

SPARC M6-32 Near-linear Query Scaling
SPARC has been scaling to over 64 processors for over 20 years!
0
4
8
12
16
20
24
28
32
0 4 8 12 16 20 24 28 32
Scaling
Number of Processors (chips)
M6-32 query
Linear
SPARC M6-32, Oracle Database 12c
& Solaris 11 near-linear scaling
Oracle Solaris easily scales to 3,072 threads!

SPARC M6-32 Memory Bandwidth
Compute often constrained by delivered memory bandwidth
0 8 16 24 32
MemoryBandwidth
#Chips
SPARC M6-32
IBM Power7/7+
Delivered Memory Bandwidth Scaling
Forget the “peak” hype
See benchmark disclosure slide
“IBM starves computation,
Compute limited by data movement”

Large Memory Advantage Benchmark
 Dramatic performance in-memory
performance increase
 Queries cached in large memory on the
M5-32 32-processor results
 Query Comparisons use 8TB for large
memory and 1TB for small memory
 Scan rate uses 12TB for large
memory and 4TB for small memory
Large memory accelerates database performance
0
1
2
3
4
5
6
7
8
Scan-rate Query1 Query2
RelativePerformance
Small Memory
Large Memory

SPARC M6-32 – Large Database Operation
Benefits
• Large memory and IO eliminates performance bottlenecks
• Ease of management in single system
Unique Features
• Built-in storage and IO capabilities (unlike IBM)
• Redundant system components for highest uptime
• Ease of transition with guaranteed compatibility
Targets
• Back-end Financial processing and Billing environments
• Telco billing and OSS
• Mission critical ERP/CRM deployments
SPARC M6-32 as a platform for massive multi-terabyte database operation or the consolidation of
several large 100+ gigabyte database instances

SPARC M6-32 – In-Memory OLTP Database
Benefits
• 24/7 availability and on-line servicing for fast recovery
• Reduced cost of traditional storage – DB is in memory
Unique Features
• Massive memory footprint - up to 32TB for consolidation
• Large IO for faster response times to users
• Upgrade path for future performance needs
Targets
• Reservation systems and order-entry applications
• Banking and billing applications, call centers
SPARC M6-32 delivers the key requirements for high throughput, insert/update-intensive OLTP
systems that are characterized by concurrent access to huge volumes of data

Add Memory
 New Oracle Solaris Optimized Shared
Memory (OSM) interface – replaces DISM
 Works with Oracle DB Automatic Memory
Management (AMM)
 Dynamic, NUMA- aware
granule based shared memory
 Bring Oracle Database instances up 2x
faster
Most Efficient SGA online resizing
Increased Uptime
New with Oracle Database 12c
Dynamically resize your Database
SGA online without a reboot
Logical Domain
Oracle DB
SGA

M6-32 Target Environments: Large-scale Consolidation
• Consolidating large Oracle Applications & Database
• Data warehouse & BI application using Oracle-OLAP (8TB)
• PeopleSoft HR SS/Payroll (4TB)
• E-Business Order-Management (4TB)
• Oracle VM for SPARC – Solaris 11 & Solaris 10 mixed
• Oracle 12c pluggable databases
• 32 TB memory fully-utilized
Ability to consolidate large-memory enterprise VMs efficiently

Consolidation Bottleneck
 Processors double in performance every 1-2 years
 5:1 to 10:1 consolidation ratio achieved easily with new SPARC
processors
 What doesn’t consolidate so easily? MEMORY !
 What limits the number of Virtual Partitions? MEMORY !
Memory Requirements

In Memory Opportunities
 Some applications need more than faster CPUs
 HDD -> SDD -> Flash -> Memory
 For some applications, every second counts…. every 0.5 second
counts…. every 0.01 second counts….
 Need a system that scales for both processing AND memory
Every gain counts!

 Changes business dynamics
 Quickly discover growth opportunities
 Make smarter decisions
 Reduce corporate costs
 Accelerate time-consuming workflows
 Business-critical applications and workflows often take hours
or days to execute
 Financial Close
 Cost Management
 Projections
 Planning
 Oracle In-Memory applications leverage DRAM and Flash
memories to run 10~20 times faster
Oracle's Family of In-Memory Apps (Phase I)
Transform Business Process In Ways Never
Before PossibleProduct In-Memory Applications
Cost Management
Policy Analytics
Next Best Action
Project Discovery
Financial Position Analyzer
Financial Allocations Analyzer
Labor Rules and Monitoring
Sales Advisor
Project Portfolio Management
Virtual Close
Consumption-Driven Planning
Performance-Driven Planning
Logistics Command Center

Fastest Architecture for In-Memory Database
No Need to Distribute Queries Across Servers or Coordinate Transactions
Big Memory Machine with
Dual Format In-Memory
Database
REAL TIME
 BOTH row and column
in-memory formats
 Simultaneously active
and transactionally
consistent
In-Memory Database Architecture

Conclusion

Why SPARC M6-32 for Mission-critical Apps
1) Reliability: SPARC M6-32 systems have the best uptime
2) Performance: Benchmarks demonstrate performance
3) Roadmap: Exciting path to future performance gains
4) Solaris: Industry’s best operating system for Oracle and Partner applications
5) Compatibility: Preserves investment in software to avoid costly and
complex migrations
6) Security: No-cost integrated software and hardware features
7) Single Vendor: Easier to deal with one company
8) Solutions: Better value from Oracle integration
9) Virtualization: No cost, low overhead partitioning
10) Large Memory: In-memory application deployment and dense VM deployment

Graphic Section Divider

Required Benchmark Disclosure Statement
Copyright 2013, 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..
TPC Benchmark C, tpmC, and TPC-C are trademarks of the Transaction Processing Performance Council (TPC). SPARC T5-8 (8/128/1024) with Oracle Database 11g Release
2 Enterprise Edition with Partitioning, 8,552,523 tpmC, $0.55 USD/tpmC, available 9/25/2013, New Order 90th% Response Time 0.410sec. IBM Power 780 Cluster (24/192/768)
with DB2 ESE 9.7, 10,366,254 tpmC, $1.38 USD/tpmC, available 10/13/2010, New Order 90th% Response Time 2.10 sec. IBM x3850 X5 (4/40/80) with DB2 ESE 9.7, 3,014,684
tpmC, $0.59 USD/tpmC, available 7/11/2011. IBM x3850 X5 (4/32/64) with DB2 ESE 9.7, 2,308,099 tpmC, $0.60 USD/tpmC, available 5/20/2011. IBM Flex x240 (2/16/32) with
DB2 ESE 9.7, 1,503,544 tpmC, $0.53 USD/tpmC, available 8/16/2012. IBM Power 780 (2/8/32) with IBM DB2 9.5, 1,200,011 tpmC, $0.69 USD/tpmC, available 10/13/2010.
Source: http://www.tpc.org/tpcc, results as of 3/26/2013.
 SPEC and the benchmark name SPECjEnterprise are registered trademarks of the Standard Performance Evaluation Corporation. Results from www.spec.org as of 3/26/2013.
SPARC T5-8, 57,422.17 SPECjEnterprise2010 EjOPS; SPARC T4-4, 40,104.86 SPECjEnterprise2010 EjOPS; Sun Server X2-8, 27,150.05 SPECjEnterprise2010 EjOPS; Cisco
UCS B440 M2, 26,118.67 SPECjEnterprise2010 EjOPS; IBM Power 780, 16,646.34 SPECjEnterprise2010 EjOPS. IBM PowerLinux 7R2, 13,161.07 SPECjEnterprise2010
EjOPS. Sun Server X4-2, 11,259.88 SPECjEnterprise2010 EjOPS. SPARC T5-8 (SPARC T5-8 Server base package, 8xSPARC T5 16-core processors, 128x16GB-1066 DIMMS,
2x600GB 10K RPM 2.5. SAS-2 HDD, 4x Power Cables) List Price $268,742. IBM Power 780 (IBM Power 780:9179 Model MHB, 8x3.86GHz 16-core, 64x one processor
activation, 4xCEC Enclosure with IBM Bezel, I/O Backplane and System Midplane,16x 0/32GB DDR3 Memory (4x8GB) DIMMS-1066MHz Power7 CoD Memory, 12x Activation of
1 GB DDR3 Power7 Memory, 5x Activation of 100GB DDR3 Power7 Memory, 1x Disk/Media Backplane. 2x 146.8GB SAS 15K RPM 2.5. HDD (AIX/Linux only), 4x AC Power
Supply 1725W) List Price $992,023. Source: Oracle.com and IBM.com, collected 03/18/2013. SPEC and the benchmark name SPECjEnterprise are registered trademarks of the
Standard Performance Evaluation Corporation. Results from www.spec.org as of 5/1/2013. SPARC T5-8, 27,843.57 SPECjEnterprise2010 EjOPS; IBM Power 780, 10,902.30
SPECjEnterprise2010 EjOPS. Oracle server(4 app: 4db) only hardware list price is $298,494, and total hardware plus software list price is $1,565,092. Oracle server(5 app: 3db)
only hardware list price is $304,914, and total hardware plus software list price is $1,487,792. http://www.oracle.com as of 9/20/2013. IBM server only HW list price is $803,613
and HW+SW cost of $1,943,162.00 and IBM PowerLinux 7R2 server total hardware plus software cost of $819,451.00 based on public pricing from http://www.ibm.com as of
9/20/2013.
SPEC and the benchmark name SPECjbb are registered trademarks of Standard Performance Evaluation Corporation (SPEC). Results from www.spec.org as of 9/22/2013
unless cited below. SPARC T5-2 81,084 SPECjbb2013-MultiJVM max-jOPS, 39,129 SPECjbb2013-MultiJVM critical-jOPS; Sun Server X2-4 65,211 SPECjbb2013-MultiJVM
max-jOPS, 22,057 SPECjbb2013-MultiJVM critical-jOPS; Cisco UCS B200 M3 62,393 SPECjbb2013-MultiJVM max-jOPS, 23,505 SPECjbb2013-MultiJVM critical-jOPS, result
from 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 www.oracle.com/benchmarks; Sun Server X3-2 41,954 SPECjbb2013-MultiJVM max-jOPS, 13,305 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.
Must be in SPARC T5 & M6 Presos with Benchmark Results (1 of 2)

Required Benchmark Disclosure Statement
Copyright 2013, 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..
Two-tier SAP Sales and Distribution (SD) Standard Application benchmarks SAP Enhancement package 5 for SAP ERP 6.0 as of 3/26/13:SPARC M5-32 (32 processors, 192
cores, 1536 threads) 85,050 SAP SD users, 32 x 3.6 GHz SPARC M5, 4 TB memory, Oracle Database 11g, Oracle Solaris 11, Cert# 2013009. SPARC T5-8 (8 processors, 128
cores, 1024 threads) 40,000 SAP SD users, 8 x 3.6 GHz SPARC T5, 2 TB memory, Oracle Database 11g, Oracle Solaris 11, Cert# 2013008. IBM Power 760 (8 processors, 48
cores, 192 threads) 25,488 SAP SD users, 8 x 3.41 GHz IBM POWER7+, 1024 GB memory, DB2 10, AIX 7.1, Cert#2013004. Two-tier SAP Sales and Distribution (SD) Standard
Application benchmarks SAP Enhancement package 4 for SAP ERP 6.0 as of 4/30/12:IBM Power 795 (32 processors, 256 cores, 1024 threads) 126,063 SAP SD users, 32 x 4
GHz IBM POWER7, 4 TB memory, DB2 9.7, AIX7.1, Cert#2010046. SPARC Enterprise Server M9000 (64 processors, 256 cores, 512 threads) 32,000 SAP SD users, 64 x 2.88
GHz SPARC64 VII, 1152 GB memory, Oracle Database 10g, Oracle Solaris 10, Cert# 2009046. SAP, R/3, reg TM of SAP AG in Germany and other countries. More info
www.sap.com/benchmark
 SPEC & benchmark names SPECfp, 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: 489
SPECint_rate2006, 441 SPECint_rate_base2006, 369 SPECfp_rate2006, 350 SPECfp_rate_base2006. IBM Power 780 8-chip 3.92GHz: 2640 SPECint_rate2006. IBM Power
710 Express 1-chip 3.556GHz: 289 SPECint_rate2006.
TPC Benchmark, TPC-H, QphH, QthH, QppH are trademarks of the Transaction Processing Performance Council (TPC). Results as of 6/7/13, prices are in USD. SPARC T5-4
www.tpc.org/3288; SPARC T4-4 www.tpc.org/3278; SPARC Enterprise M9000 www.tpc.org/3262; SPARC Enterprise M9000 www.tpc.org/3258; IBM Power 780
www.tpc.org/3277; HP ProLiant DL980 www.tpc.org/3285.
SPC Results as of September 10, 2013, for more information go to http://www.storageperformance.org/results SPC-2. Results for Oracle ZFS Storage ZS3-4 are 17,244.22 SPC-
2 MBPS™, $22.53 SPC-2 Price-Performance. Full results at http://www.storageperformance.org/results/benchmark_results_spc2#b00067. Results for IBM DS8870 are
15,423.66 SPC-2 MBPS, $131.21 SPC-2 Price-Performance. Full results at http://www.storageperformance.org/results/benchmark_results_spc2#b00062. Results for HP P9500
XP Disk Array are 13,147.87 SPC-2 MBPS, $88.34 SPC-2 Price-Performance. Full results at http://www.storageperformance.org/results/benchmark_results_spc2#b00056.
SPEC SFS SPEC & benchmark names SPECfp, SPECint are registered trademarks of the Standard Performance Evaluation Corporation. Results as of September 10, 2013,
for more information see www.spec.org. For details on performance and price comparisons see http://www.oracle.com/us/solutions/performance-scalability/sun-storage-gateway-
160373.html
Must be in SPARC T5 & M6 Presos with Benchmark Results (2 of 2)

Sparc m6 32 in-memory infrastructure for the entire enterprise

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Sparc m6 32 in-memory infrastructure for the entire enterprise