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The AMD Athlon ™ Processor: Future Directions Fred Weber Vice President, Engineering Computation Products Group.

Published byWeston Perkes Modified over 9 years ago

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Presentation on theme: "The AMD Athlon ™ Processor: Future Directions Fred Weber Vice President, Engineering Computation Products Group."— Presentation transcript:

1 The AMD Athlon ™ Processor: Future Directions Fred Weber Vice President, Engineering Computation Products Group

2 AGP PCI DRAM System Logic Forward Clocks AMD Athlon ™ Processor L2 CACHE Snoops/SysCMD Requests DATA 72b AMD Athlon ™ Processor L2 CACHE Snoops/SysCMD Requests DATA 72b Workstation & Server Capabilities  200 MHz FSB (1.6GB/sec) that can scale to 400 MHz (3.2GB/sec) per processor  Backside L2 Cache interface supports up to 8MB  Up to 24 Outstanding Transactions per Processor  13-Pin Address Bus  13-Pin Snoop Bus  72-Pin Data Bus w/ ECC  Scales to 43-bit Physical Address

3  Processor Scalability  1MB and 2MB Full Speed, 16-way associative L2 Cache  266MHz Front Side Bus  System Scalability: 2-way; 4 to 8 way multiprocessing  AMD: 2 processor design  266MHz Front Side Bus with DDR DRAM (PC-2100 ™ )  4X AGP-Pro, PCI 66/64  Multi-way: Infrastructure development underway (API and HotRail)  Reliability  ECC Protected L2 Cache, DRAM and Front Side Bus  Execution Signature Generation Product Features In 2000

4 LDT The System Bus of the Future

5 AMD’s System Bus Initiative: Lightning Data Transport (LDT)  Goals  Simplify design and flexibility with a single data link for “in- chassis” connection to I/O, multi-processing and co- processors  Improve system performance with increased I/O performance and scalable bandwidth  Enable flexibility of system I/O technologies through a modular bridge architecture  Complement externally visible bus standards

6 AMD’s LDT: I/O  I/O can be daisy chained  Multiple bridges on a single I/O link  Multiple “pass through” devices can be interconnected  Bridges are independent (reusable for many designs)  The System I/O SANIC (HCA) is independent of the memory controller PCI 33/32 SIO SANIC LDT DRAM AMD Athlon ™ EV6 Bus North Bridge AGP PCI 66/64 PCI-X Southbridge PCI 66/64 PCI-X

7 AMD’s LDT: Multiprocessing  Coherent link provides scalable multiprocessing  Memory capacity scales  Memory bandwidth scales  I/O capacity scales  I/O bandwidth scales LDT AMD Athlon ™ EV6 Bus North Bridge AMD Athlon ™ AMD Athlon ™ EV6 Bus North Bridge AMD Athlon ™ AMD Athlon ™ EV6 Bus AMD Athlon ™ AMD Athlon ™ EV6 Bus AMD Athlon ™ Multiple LDT System Links (I/O) Multiple LDT System Links (I/O) DRAM North Bridge DRAM North Bridge

8 LDT Features  Unidirectional point-to-point links in each direction  Differential signaling with source synchronous clock forwarding  Variable widths negotiated at initialization  Upstream and downstream links can be of different size  16/16-bit link provides 6.4 GB/sec each way  Multiple logical channels in each link  Guaranteed isochronous bandwidth  In-band system management and legacy signal transport  PCI like configuration mechanism Up to 1.6 Gbits/sec per pin Isochronous Transfer Receive Priority to ensure They Arrive On Time Ctrl Clk Ctrl Clk 8, 16 or 32 - bits in each direction

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