Warren E. Maule

IBM second-generation RISC machine organization

A highly concurrent second-generation RISC (reduced-instruction-set computer) that combines a powerful RISC architecture with sophisticated hardware design techniques to achieve a short cycle time and a low cycles-per-instruction (CPI) ratio is described. Like earlier RISC processors, this design uses a register-oriented instruction set, the CPU is hardwired rather than microcoded, and it features a pipelined implementation. Unlike earlier RISC processors, however, several advanced architectural and implementation features are used, including separate instruction and data caches, zero-cycle branches, multiple-instruction dispatch, and simultaneous execution of fixed- and floating-point instructions. The CPU has a four-word data bus to main memory, a four-word instruction-fetch bus from the I-cache arrays, and a two-word data bus between the D-cache and floating-point unit. The CPU has a full 64-b floating-point engine, and thirty-two 64-b floating point registers in addition to thirty-two 32-b fixed-point registers. In a single cycle, four instructions can be executed simultaneously.<<ETX>>

Server-class DDR3 SDRAM memory buffer chip

IBM System i®, System p®, and System z® servers require an efficient ultrareliable high-performance memory subsystem. The fourth-generation IBM advanced memory buffer (AMB) chip provides industry-leading performance, scalability, and reliability for the double-data-rate 3 (DDR3) synchronous dynamic random access memory (SDRAM) subsystems employed across a wide range of server platforms. The new IBM AMB employs a cyclic redundancy code-protected packet-protocol-based 6.4-Gb/s host channel, as well as dual 9-byte/10-byte wide 800 to 1,333-Mb/s SDRAM interfaces with dynamic calibration for optimal signal integrity under varied device and system environmental conditions. Applications support industry-standard dual inline memory module (DIMM) and low-latency high-capacity proprietary DIMM packages in conventional multichannel and redundant array of independent memory system architectures. A fully configured daisy-chain topology contains up to 256 GB of memory per host channel. This paper describes the IBM AMB chip architecture, design, and key engineering aspects.