Dezső Sima
Fall 2008
(Ver. 1.0) Sima Dezső, 2008
DP/MP System Architectures
Contents
2. Intel’s DP servers•
3. Intel’s MP servers
•
1. The evolution of Intel’s basic microarchitectures•
•
4. AMD’s servers
1. The evolution of Intel’s basic microarchitectures
1. The evolution of Intel’s basic microarchitectures (1)
Figure: Intel’s Tick-Tock development model [22]
1. The evolution of Intel’s basic microarchitectures (2)
Figure: The speed of changes in Intel’s Tick-Tock development model [24]
1. The evolution of Intel’s basic microarchitectures (3)
Figure: Key enhancements introduced into the Core2 microarchitecture (vs the Pentium4) [22]
• Wide dynamic execution - 4-wide decode/rename/retire
• Advanced digital media processing - 128-bit wide SSE execution unit
• Improved graphics/MM - New SSE 4.1 instructions
• Smart memory access - Memory disambiguation (spec. loads) -Hardware prefetching
• Advanced smart cache - Low latency, high BW shared L2 cache
1. The evolution of Intel’s basic microarchitectures (4)
Figure: Key enhancements introduced into the Penryn microarchitecture (vs the Core) [23]
1. The evolution of Intel’s basic microarchitectures (5)
Figure: Improvements introduced into the Nehalem microarchitecture (vs Penryn) [22]
1. The evolution of Intel’s basic microarchitectures (6)
Figure: Hyperthreading inthe Nehalem microarchitecture [22]
1. The evolution of Intel’s basic microarchitectures (7)
2-level cache hierarchy 3-level cache hierarchy
Figure: 3-level cache hierarchy of Nehalem [22]
1. The evolution of Intel’s basic microarchitectures (8)
Figure: Nehalem’s innovations in the system architecture [22]
1. The evolution of Intel’s basic microarchitectures (9)
Figure: Nehalem’s innovations in the system architecture [22]
QickPath Interconnect
3.2 GHz DDR20-bit (16-bit data 4-bit CRC) on each lane
12.8 GT/s on each direction
Fastest FSB
Formerly: Common System interconnect (CSI)
400 MHz QDR 8 Byte 12.8 GT/s bidirectional
HyperTransport Bus
HT 1.0: 0.8 GHz DDR 2-Byte 3.2 GT/s on each direction
HT 2.0: 1.0 GHz DDR 2-Byte 4.0 GT/s on each direction
HT 3.0: 2.6 GHz DDR 2-Byte 10.4 GT/s on each direction
Typical speed and width figures in AMD’s systems
1. The evolution of Intel’s basic microarchitectures (10)
2. Intel’s DP Servers
Figure: Typical configuration of an early DP-server motherboard based on Intel’s E7500/E7501 (Plunas) chipset
P4
ICH3-S
FWH
E7500/E7501 SDRAM
SDRAM
SDRAMinterface
SDRAMinterface
DDR 200/266
registered, ECC opt.
Ultra ATA/100
PCI v.2.2
USB v. 1.1GPIO
FSB
LPC
HI 1.5
P4
(with RASUM)
HI 2.0
PCI-X v.2.2
Prestonia Prestonia
MCH
400/533 MHz
8/12/16 GB
HI 2.0
HI 2.0
PCI-Xbridge
SATA c.
GbE c.
PCI-X v.2.2
SATA
GbE
Video c.
MbE c.
PCI v.2.2
LAN
(5 ports)
SVGA
MbE
SIO
FD KB MS SP PP
SCSI c.SCSI
(1-2 slots)
(1-2 slots)
(3 slots)
3200-4264
1600-2128
1600-2128
266
133
1.5
2*100
~5
1066
1066
1066
(2 ports)
2. Intel’s DP servers (1)
Figure: Typical configuration of an advanced early DP-server motherboard based on Intel’s E7520 (Lindenhurst) chipset
ICH5R
FWH
E7520 SDRAM
SDRAM
SDRAMinterface
SDRAMinterface
DDR 266/333, DDR2 400
registered, ECC opt.
Ultra ATA/100
PCI v.2.3
USB v. 2.0
SATA
AC' 97 v.2.3
GPIO
FSB
LPC
HI 1.5
(with RASUM)
PCI E. x8PCI-X v.1.0b
NoconaPaxville DP
NoconaPaxville DP
MCH
800 MHz
16/24/32 GB
PCI E. x8
PCI E. x8
PCI-Xbridge
SCSI c.
GbE c.
PCI-X v.1.0bPCI E. x8(or 2x x4)
SCSI
GbE
Video c.
MbE c.
PCI v.2.3
LAN
(4 ports)
SVGA
MbE
SIO
FD KB MS SP PP
60
3200
2128-3200
2128-3200
266
133
~1.4
2*100
2*150
~5
4000
4000
4000
(2 ports)
(2 ports)
2. Intel’s DP servers (2)
P4 P4
2. Intel’s DP servers (3)
Paxville DP 2.8
2xIrwindale cores/90 nm
Figure: Intel’s Pentium 4 based DC DP server processors [33], [34]
http://www.xbitlabs.com/articles/cpu/display/opteron-xeon-workstation_5.html
Nocona PaxvilleIrwindaleNocona
(L2 enlarged to 2MB) (2 x Irwindale cores)
6/2004
90 nm112 mm2
125 mtrs
mPGA 604
2/2005
90 nm135 mm2
169 mtrs
mPGA 604
10/2005
90 nm2 x 135 mm2
2 x 169 mtrs
Xeon DP 2.8Xeon MP 7020-7041
mPGA 604
Figure: Genealogy of the Xeon Paxville core
(DP enhanced Prescott) (DP enhanced Prescott 2M)
http://www.theinquirer.net/default.aspx?article=16879http://www.gamepc.com/labs/view_content.asp?id=x36o252&page=2
Sources:
Intel’s first 64-bit Xeon
In contrast: correspondingdesktop processors have the LGA 775 socket.
2. Intel’s DP servers (4)
2. Intel’s DP servers (5)
Xeon 5000(Dempsey)Paxville DP 2.8
2xIrwindale cores/90 nm 2xCedar Mill/65 nm(65 nm shrink of the Irwindale)
Figure: Intel’s Pentium 4 based DC DP server processors [33], [34]
2. Intel’s DP servers (6)
Xeon 5100(Woodcrest)
Core2-based/65 nm
Xeon 5300(Clowertown)
Core2-based/65 nm2xXeon 5100
Figure: Intel’s Core2 based DC/QC DP server processors [33], [35], [36]
2. Intel’s DP servers (7)
Figure: Intel’s Penryn based QC DP server processor/45 nm (Source: Intel)
Xeon 5400(Harpertown)
2. Intel’s DP servers (8)
Figure: Contrasting the die shots of the Xeon 5400 and 5300 processors [24]
2. Intel’s DP servers (9)
Series---
(Paxville DP)5000
(Dempsey)5100
(Woodcrest)5200
(Wolfdale)5300
(Clovertown)5400
(Harpertown)
Dual/Quad-Core DC DC DC DC QC QC
Models Xeon DP 2.8 5030-5080 5110-5160E5205/E5260/
X5275E5310-5345/
X5355E5405-E5472, X5450-
X5482
Microarchitecture
Pentium 4 Pentium 4 Core2 Penryn Core2 Penryn
Core 2*Irwindale dies 2*Cedar dies Single die 2*Woodcrest dies 2*Penryn
Intro. 10/2005 5/2006 6/2006 11/2007 11/2006 11/2007
Techology 90 nm 65 nm 65 nm 45 nm 65 nm 45 nm
Die size 2*135 mm2 2*81 mm2 143 mm2 2*143 mm2 2*107 mm2
Nr. of transistors 2*169 mtrs 2*188 mtrs 291 mtrs 2*291 mtrs 2*410 mtrs
Fc [GHz] 2.8 2.6-3.73 1.6-3.0 1.86-3.40 1.6-2.66 2.00-3.20
L2 2*2 MB 2*2 MB 4 MB 6 MB 2*4 MB 2*6 MB
FSB [MT/s] 800 667/1066 1066/1333 1333/1600 1066/1333 1333/1600
TDP [W] 135 95/130 65/80 65/80 80/120 80/120/150
Socket PGA 604 LGA 771 LGA 771 LGA771 LGA 771 LGA 771
EM64T
HT --- --- --- ---
ED
VT
EIST (5140 or above)
La Grande --- ---
AMT2 --- ---
Flex Migration --- --- ---
Table: Intel’s DC, QC DP servers
2. Intel’s DP servers (10)
Gainstown
(Q1/2009) (Q1/2010?)
Nehalem-based/45 nm Westmere_based/32 nm(Socket 1366)
???
Figure: Intel’s future DP server processors [21]
(Both 2-way multithreaded)
Figure : Intel’s late Pentium4 based and subsequent DP server platforms
DP Platforms
Xeon DP 2.8 DC
10/2005
DP Cores
DP Chipsets
2. Intel’s DP servers (11)
90 nm/2*169 mtrs2*2 MB L2800 MT/sPGA604
7520
6/2004
(Lindenhurst)
800 MT/s2 x DDR/DDR2
16 GB
Pentium4-based (90/65 nm)
/Paxville DP) DC
Figure: Evolution of Intel’s DP servers
800MT/s
6.4 GB/s
7520
(Lindenhurst)
Nocona
Paxville DC
SC/DC
Nocona
Paxville
SC/DC
24 LanesPCIe
7.5GB/s
Dual DDR2 400 MT/s6.4 GB/s
2. Intel’s DP servers (12)
Single
Figure: Typical configuration of an advanced early DP-server motherboard based on Intel’s E7520 (Lindenhurst) chipset
ICH5R
FWH
E7520 SDRAM
SDRAM
SDRAMinterface
SDRAMinterface
DDR 266/333, DDR2 400
registered, ECC opt.
Ultra ATA/100
PCI v.2.3
USB v. 2.0
SATA
AC' 97 v.2.3
GPIO
FSB
LPC
HI 1.5
(with RASUM)
PCI E. x8PCI-X v.1.0b
NoconaPaxville DP
NoconaPaxville DP
MCH
800 MHz
16/24/32 GB
PCI E. x8
PCI E. x8
PCI-Xbridge
SCSI c.
GbE c.
PCI-X v.1.0bPCI E. x8(or 2x x4)
SCSI
GbE
Video c.
MbE c.
PCI v.2.3
LAN
(4 ports)
SVGA
MbE
SIO
FD KB MS SP PP
60
3200
2128-3200
2128-3200
266
133
~1.4
2*100
2*150
~5
4000
4000
4000
(2 ports)
(2 ports)
2. Intel’s DP servers (13)
P4 P4
Figure : Intel’s late Pentium4 based and subsequent DP server platforms
DP Platforms
Xeon DP 2.8 DC
10/2005
DP Cores Xeon 5100 Xeon 5300Xeon 5000
11/20066/20065/2006
DP Chipsets
(Dempsey) DC (Woodcrest) DC (Clowertown) QC
5000
06/2006
5000P 5000V/Z
6/2006
(Blackford) (Blackford V/Z)
2xFSB1066MT/s
4 x FBDIMM(DDR2)64GB
2 x FBDIMM(DDR2)16GB
2. Intel’s DP servers (11)
(Bensley)
65 nm/291 mtrs4 MB L2
667/1066 MT/sLGA771
Pentium4/Core2-based (65 nm)
65 nm/2*188 mtrs2*2 MB L2
667/1066 MT/sLGA771
65 nm/2*291 mtrs2*4 MB L2
667/1066 MT/sLGA771
90 nm/2*169 mtrs2*2 MB L2800 MT/sPGA604
7520
6/2004
(Lindenhurst)
800 MT/s2 x DDR/DDR2
16 GB
Pentium4-based (90/65 nm)
/Paxville DP) DC
Figure: Evolution of Intel’s DP servers
800MT/s
6.4 GB/s
7520
(Lindenhurst)
Nocona
Paxville
SC/DC
Nocona
Paxville
SC/DC
24 LanesPCIe
7.5GB/s
Dual1066MT/s17.1 GB/s
DempseyWoodcrestClowertown
DC
5000
(Blackford)24 Lanes
PCIe7.5GB/s
DempseyWoodcrestClowertown
DC
Dual DDR2 400 MT/s6.4 GB/s
Quad FB-DIMM 533 MT/s17.1 GB/s
2. Intel’s DP servers (14)
Single
2. Intel’s DP servers (15)
http://www.tyan.com/tempest/training/s5370.pdf
Intel’s Bensley platform [30] (Actually the block diagram of Tyan’s S5370 DP server)
FB-DIMM DDR2
64 GB
5000P
SBE2
Xeon DC/QC
5000 DC5100 DC5300 QC
Figure: Bensley DP motherboard, with the 5000 (Blackford) chipset (Supermicro X7DB8+) for the Xeon 5000 DC/QC DP processor families [7]
2. Intel’s DP servers (16)
Table: Latency and bandwidth scaling of the Intel 5000 platform (2006) vs the earlier generation (2004) [1]
2. Intel’s DP servers (17)
Figure : Intel’s late Pentium4 based and subsequent DP server platforms
DP Platforms
Xeon DP 2.8 DC
10/2005
DP Cores Xeon 5100 Xeon 5300 Xeon 5400Xeon 5000
11/200711/20066/20065/2006
DP Chipsets
(Dempsey) DC (Woodcrest) DC (Clowertown) QC (Harpertown) QC
5000
06/2006
5000P 5000V/Z
5100
6/2006
(Blackford) (Blackford V/Z)
10/2007
2xFSB1066MT/s
4 x FBDIMM(DDR2)64GB
2 x FBDIMM(DDR2)16GB
5100
10/2007
(San Clemente)
2xFSB1333/1066 MT/s
2 x DDR232/48 GB
2. Intel’s DP servers (11)
(Bensley) (Cranberry Lake)
65 nm/291 mtrs4 MB L2
667/1066 MT/sLGA771
Pentium4/Core2-based (65 nm) Penryn-based (45 nm)
65 nm/2*188 mtrs2*2 MB L2
667/1066 MT/sLGA771
65 nm/2*291 mtrs2*4 MB L2
667/1066 MT/sLGA771
45 nm/850 mtrs2*6 MB L2
1066/1333 MT/sLGA771
90 nm/2*169 mtrs2*2 MB L2800 MT/sPGA604
Xeon 5200
(Harpertown) DC
45 nm/850 mtrs2*6 MB L2
1066/1333 MT/sLGA771
7520
6/2004
(Lindenhurst)
800 MT/s2 x DDR/DDR2
16 GB
Pentium4-based (90/65 nm)
/Paxville DP) DC
2. Intel’s DP servers (18)
Figure: The Cranberry Lake platform [19]
Xeon 5400 (QC)Xeon 5200 (DC)
5100 chipset
2. Intel’s DP servers (19)
Figure: Intel’s forthcoming Nehalem-based DP server system architecture [31]
QuickPath Interconnect
Integrated memory controller
3. Intel’s MP servers
3. Intel’s MP servers (1)
Figure: Intel’s Pentium4 based Xeon MP processors [17], [18]
Tulsa
90 nm 65 nm 65 nm
CDM: Cedar Mill core
Potomac Paxville MP
3. Intel’s MP servers (2)
Figure: Intel’s Core2 /Penryn based Xeon MP processors [19], [20]
65 nm
45 nm
Core2 based
Penryn based
Table: Dual- and Quad-Core Xeon MP-lines
1 Concerning the L2 cache size, there is a contradiction in Intel’s dokumentation; whereas according to the data sheets models of the 7000 series include 1 or 2 MB L2 caches the comparison charts for all models shows 1 MB large L2 caches.
3. Intel’s MP servers (3)
Series7000
(Paxville MP)7100
(Tulsa)7200
(Tigerton DC)7300
(Tigerton QC)
7400(Dunnington
QC)
7400(Dunnington
6C)
Dual/Quad-Core DC DC 2xSC 2xDC QC 6C
Models 7020-70417110M-7140M / 7110N-7150N
E7210/E7220E7310/E7320/E7330/
E7340/X7350E7420-E7440 E7450/X7460
Microarchitecture Netburst Netburst Core 2 Penryn
Core2xIrwindale
diesCedar Mill-based
single die2xSC Woodcrest
dies2xWoodcrest dies
Intro. 11/2005 8/2006 9/2007 9/2008
Techology 90 nm 65 nm 65 nm 45 nm
Die size 2*135 mm2 435 mm2 2*143 mm2 503 mm2
Nr. of transistors 2*169 mtrs 1328 mtrs 2*291 mtrs 1900 mtrs
Fc [GHz] 2.66-3.0 2.5-3.5 2.4/2.93 1.6/2.13/2.4/2.4/2.93 2.13-2.40 2.40/2.66
L2 2*1/2 MB1 2*1 MB 2*4 MB 2*2/2*2/2*3/2*4/2*4 MB 3*2 MB 3*3 MB
L3 --- 4/8/16 MB --- --- 8/12/16 MB 12/16 MB
FSB [MT/s] 667/800 667/800 1066 1066
TDP [W] 95/150 95/150 80 80/80/80/80/130 90 90/130
Socket mPGA604 mPGA604 mPGA604 mPGA 604
EM64T
HT --- ---
ED
VT
EIST
La Grande --- --- n.a.
AMT2 --- --- (Except E7310) n.a.
3. Intel’s MP servers (4)
Figure: Intel’s Nehalem based MP server processor [21]
Figure: Evolution of Intel’s Xeon MP-based system architecture (until the appearance of Nehalem)
Preceding NBs
Xeon MP1 Xeon MP1 Xeon MP1 Xeon MP1
3. Intel’s MP servers (5)
SC SC SC SC
1 Xeon MP before Potomac
Typically HI 1.5(266 MB/s)
3. Intel’s MP servers (6)
Figure: Former Pentium II/III MP systemarchitecture [32]
MP Platforms
Xeon 7000
11/2005
MP Cores Xeon 7100
8/2006
MP Chipsets
3/2005 4/2006
8500 8501
(Paxville MP DC) (Tulsa DC)
(Twin Castle) (?)
Figure : Intel’s Xeon-based MP server platforms
2xFSB667 MT/s
4 x XMB(2 x DDR2)
32GB
2xFSB800 MT/s
4 x XMB(2 x DDR2)
32GB
Truland
65 nm/1328 mtrs
2x1 MB L216/8/4 MB L3
800/667 MT/smPGA 604
P4-based/65 nm
3/2005
Xeon MP
3/2005
(Potomac SC)
90 nm/2x169 mtrs
2x1 (2) MB L2-
800/667 MT/smPGA 604
90 nm/675 mtrs
1 MB L28/4 MB L3
667 MT/smPGA 604
P4-based/90 nm
Truland
3. Intel’s MP servers (7)
Figure: Evolution of Intel’s Xeon MP-based system architecture (until the appearance of Nehalem)
Preceding NBs
Xeon MP1 Xeon MP1 Xeon MP1 Xeon MP1
(Twin Castle)
XMB
XMB
XMB
XMB
3. Intel’s MP servers (8)
8500
SC SC SC SC
28 PCIe lanes + HI 1.5
Truland
Caneland
1 Xeon MP before Potomac
Potomac2
Paxville MP3
DC/SC
Potomac2
Paxville MP3
DC/SC
Potomac2
Paxville MP3
DC/SC
Potomac2
Paxville MP3
DC/SC
(266 MT/s)Typically HI 1.5
(266 MB/s) (7 GT/s)
eXxternalMemoryBridge
IndependentMemory Interface
5.33 GB inbound BW2.67 GB outbound BW simultaneously
Figure: Intel’s 8501 chipset for MP servers (4/ 2006) [4]
Xeon DC MP 7000(4/2005) or later
DC/QC MP 7000 processors
Intelligent MCDual mem. channelsDDR 266/333/4004 DIMM/channel
(North Bridge)
3. Intel’s MP servers (9)
Serial link
7000/7100
FB-DIMM DDR2
64 GB
Figure: Quad socket Intel E8501 chipset based motherboard (Supermicro X6QT8) for the Xeon 7000/7100 DC MP processor families [7]
Xeon DC
E8501 NB
ICH5R SB
3. Intel’s MP servers (10)
Figure Bandwith bottlenecks in Intel’s 8501 MP server platform [2]
3. Intel’s MP servers (11)
MP Platforms
Xeon 7000
11/2005
MP Cores Xeon 7200 Xeon 7300Xeon 7100
9/20078/2006
MP Chipsets
3/2005 4/2006 9/2007
8500 8501 7300
(Paxville MP DC) (Tulsa DC) (Tigerton DC) (Tigerton) QC
Caneland
9/2007
(Clarksboro)(Twin Castle) (?)
Figure : Intel’s Xeon-based MP server platforms
2xFSB667 MT/s
4 x XMB(2 x DDR2)
32GB
2xFSB800 MT/s
4 x XMB(2 x DDR2)
32GB
4xFSB1066 MT/s
4 x FBDIMM(DDR2)512GB
Truland
Xeon 7400
9/2008
(Dunnington 6C)
65 nm/1328 mtrs
2x1 MB L216/8/4 MB L3
800/667 MT/smPGA 604
65 nm/2x291 mtrs
2x4 MB L2-
1066 MT/smPGA 604
65 nm/2x291 mtrs
2x(4/3/2) MB L2-
1066 MT/smPGA 604
45 nm/1900 mtrs
9/6 MB L216/12/8 MB L3
1066 MT/smPGA 604
P4-based/65 nm Core2-based/65 nm Core2-based/45 nm
3/2005
Xeon MP
3/2005
(Potomac SC)
90 nm/2x169 mtrs
2x1 (2) MB L2-
800/667 MT/smPGA 604
90 nm/675 mtrs
1 MB L28/4 MB L3
667 MT/smPGA 604
P4-based/90 nm
Truland Caneland
7300
3. Intel’s MP servers (12)
Figure: Evolution of Intel’s Xeon MP-based system architecture (until the appearance of Nehalem)
Preceding NBs
Xeon MP1 Xeon MP1 Xeon MP1 Xeon MP1
(Clarksboro)
Tigerton Tigerton Tigerton Tigerton
(Twin Castle)
XMB
XMB
XMB
XMB
3. Intel’s MP servers (13)
8500
6C/QC/DC 6C/QC/DC 6C/QC/DC 6C/QC/DC
SC SC SC SC
FB-DIMM(DDR2)
28 PCIe lanes + HI 1.5
Dunnington Dunnington Dunnington Dunnington
8 PCI-E lanes + ESI
Truland
Caneland
7300
1 Xeon MP before Potomac
Potomac2
Paxville MP3
DC/SC
Potomac2
Paxville MP3
DC/SC
Potomac2
Paxville MP3
DC/SC
Potomac2
Paxville MP3
DC/SC
• Cransfield SC)• Tulsa (DC)
3 Supports also
2 First x86-64 MP processor
(266 MT/s)Typically HI 1.5
(266 MB/s) (7 GT/s)
(2 GT/s) (1 GT/s)
Figure: Intel’s four socket 7300 (Caneland) platform, based on the 7300 (Clarksboro) chipset for the Xeon 7200/7300 DC/QC MP families (9/2007) [6]
FB-DIMM
up to 512 GB
7200 (Tigerton DC, Core2), DC
Xeon
7300 (Tigerton QC, Core2), QC
3. Intel’s MP servers (14)
FB-DIMM DDR2
192 GB
ATI ES1000 Graphics with 32MB video memory
7200 DC 7300 QC(Tigerton)
Xeon
Figure: Caneland MP motherboard, with the 7300 (Clarksboro) chipset (Supermicro X7QC3) for the Xeon 7200/7300 DC/QC MP processor families [7]
SBE2 SB
7300 NB
3. Intel’s MP servers (15)
Figure: Performance comparison of the Caneland platform with a quad core Xeon (7300 family) vs the Bensley platform with a dual core Xeon 7140M [13]
3. Intel’s MP servers (16)
3. Intel’s MP servers (17)
FB-DIMM(DDR2)
QPI
Figure: Intel’s Nehalem based MP server system architecture [22]
4. AMD’s servers
UP: Opteron 100/1000, DP: Opteron 200/2000 MP: Opteron 800/8000
CPU0
1MB L2 Cache
CPU1
System Request Interface
Crossbar Switch
MemoryController HT
1MB L2 Cache
CPU0
1MB L2 Cache
CPU1
System Request Interface
Crossbar Switch
MemoryController 0 1 2
1MB L2 Cache
HyperTransport™
2 x 72 bit 2 x 72 bit 800/8000: 3 coherent links200/2000: 1 coherent link
Figure: Basic structure of the Opteron families [8]
4. AMD’s servers (1)
AMD’s 4P/8P Direct Connect server architecture [2]
4. AMD’s servers (2)
Figure: Block diagram of a DP QC motherboard (Asus KFSN4-DRE/SAS)
for AMD Opteron 2300 QC family [10]
4. AMD’s servers (3)
Figure: DP motherboard (Asus KFSN4-DRE/SAS) for the AMD Opteron 2300 QC family [10]
DDR2
64 GB
2300
Opteron QC DP
nForce 2200 chipset
4. AMD’s servers (4)
Figure: Block diagram of a QP QC motherboard (ASUS KFN5-Q/SAS) for AMD’s Opteron 8000 DC/QC familes [10]
4. AMD’s servers (5)
Figure: 4-socket motherboard (ASUS KFN5-Q/SAS) for the AMD Opteron 8000 DC/QC familes [10]
8300
Opteron QC MP
nForce 3600 chipset
DDR2
64 GB
4. AMD’s servers (6)
4. AMD’s servers (7)
Figure: Simplified block diagram of the QC Barcelona [25]
4. AMD’s servers (8)
Figure: Die shot and floor plan of Barcelona [27]
4. AMD’s servers (9)
Figure: Cache architectures of AMD’s QC Barcelona and Shanghai processors [25], [26]
Barcelona (65 nm)
Shanghai (65 nm)
4. AMD’s servers (10)
Figure: Die shot of Shanghai [29]
Pin to pin compatible
with Barcelona
6 MB shared L3
4. AMD’s servers (11)
Figure: AMD’s roadmap for DP/MP platforms (2000/8000 Series) [28]
(Virtualisation)
References
[1]: Radhakrisnan S., Sundaram C. and Cheng K., „The Blackford Northbridge Chipset for the Intel 5000,” IEEE Micro, March/April 2007, pp. 22-33
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