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Pipelining III

Pipelining III. Andreas Klappenecker CPSC321 Computer Architecture. Administrative Issues. Talk by Laszlo Kish Quantum Computing Seminar, Thursday 10:00am-11:00am, HRBB 302 Projects: Get started!!!. Pipelined Datapath. Pipeline separation registers, width varies. Control Lines.

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Pipelining III

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  1. Pipelining III Andreas Klappenecker CPSC321 Computer Architecture

  2. Administrative Issues • Talk by Laszlo Kish • Quantum Computing Seminar, Thursday 10:00am-11:00am, HRBB 302 • Projects: Get started!!!

  3. Pipelined Datapath Pipeline separation registers, width varies

  4. Control Lines • Instruction fetch: • control signal to read instruction memory and to write PC are always asserted - nothing special here • Instruction decode/register file read: • same thing happens every clock cycle, so no optional control lines to set • Execution/address calculation • RegDst selects the result register, • ALUOp selects the ALU operation • ALUSrc selects Read data 2 or sign-extd. immediate

  5. Pipelined Datapath w/ Controls Signals

  6. Control Lines • Memory access • Branch set by branch equal • MemRead set by load instructions • MemWrite set by store instructions • Write back • MemtoReg send ALU result or memory value • RegWrite selects register

  7. Pipelined Datapath w/ Controls Signals

  8. Pipeline Control • Pass control signals along just like the data

  9. Datapath with Control

  10. Data Hazards • Assume that the compiler has to guarantee that no hazards occur • Where do we insert the “nops” ? sub $2, $1, $3 and $12, $2, $5 or $13, $6, $2 add $14, $2, $2 sw $15, 100($2)

  11. Dependencies Data hazard: a dependency that “goes backward in time”

  12. Resolution of Data Hazards • Solution sub $2, $1, $3 nop nop and $12, $2, $5 or $13, $6, $2 add $14, $2, $2 sw $15, 100($2) • Problem: this slows us down!

  13. Forwarding Do not wait until result have been written • Use temporary results! • Use register file forwarding to handle read/write to same register • ALU forwarding

  14. Forwarding

  15. Forwarding

  16. Obstructions to Forwarding • Load word can still cause a hazard: an instruction trying to read a register following a load instruction writing to the same register. • Need a hazard detection unit to “stall” pipeline

  17. Stalling • We can stall the pipeline by keeping an instruction in the same stage

  18. Hazard Detection Unit • Stall by letting an instruction that won’t write anything go forward

  19. Branch Hazards • When we decide to branch, other instructions are in thepipeline! • We are predicting “branch not taken” • need to add hardware for flushing instructions if we are wrong

  20. Flushing • Move branch decision from 4th pipeline stage to the second • only one instruction following the branch will be in the pipeline • IF.Flush turns fetched instruction into a nop by zeroing the IF/ID pipeline register

  21. Flushing Instructions

  22. Improving Performance • Try and avoid stalls by reordering instructions • Add a “branch delay slot” • the next instruction after a branch is always executed • rely on compiler to “fill” the slot with something useful • Superscalar: start more than one instruction in the same cycle

  23. Dynamic Scheduling • The hardware performs the “scheduling” • hardware tries to find instructions to execute • out of order execution is possible • speculative execution and dynamic branch prediction • All modern processors are very complicated • DEC Alpha 21264: 9 stage pipeline, 6 instruction issue • PowerPC and Pentium: branch history table • Compiler technology important • This class has given you the background you need to learn more - read Chapter 6! • More material will be posted!

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