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CSE 340 Computer Architecture Summer 2014 Basic MIPS Pipelining Review.

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Presentation on theme: "CSE 340 Computer Architecture Summer 2014 Basic MIPS Pipelining Review."— Presentation transcript:

1 CSE 340 Computer Architecture Summer 2014 Basic MIPS Pipelining Review

2 Review: Single Cycle vs. Multiple Cycle Timing Clk Cycle 1 Multiple Cycle Implementation: IFetchDecExecMemWB Cycle 2Cycle 3Cycle 4Cycle 5Cycle 6Cycle 7Cycle 8Cycle 9Cycle 10 IFetchDecExecMem lwsw IFetch R-type Clk Single Cycle Implementation: lwsw Waste Cycle 1Cycle 2 multicycle clock slower than 1/5 th of single cycle clock due to stage register overhead 2CSE340, ACH

3 How Can We Make It Even Faster? Split the multiple instruction cycle into smaller and smaller steps  Start fetching and executing the next instruction before the current one has completed l Pipelining – (all?) modern processors are pipelined for performance l Remember the performance equation: CPU time = CPI * CC * IC  Fetch (and execute) more than one instruction at a time l Superscalar processing – stay tuned 3CSE340, ACH

4 A Pipelined MIPS Processor Start the next instruction before the current one has completed – improves throughput - total amount of work done in a given time – instruction latency (execution time, delay time, response time - time from the start of an instruction to its completion) is not reduced Cycle 1Cycle 2Cycle 3Cycle 4Cycle 5 IFetchDecExecMemWB lw Cycle 7Cycle 6Cycle 8 sw IFetchDecExecMemWB R-type IFetchDecExecMemWB -clock cycle (pipeline stage time) is limited by the slowest stage -for some instructions, some stages are wasted cycles 4CSE340, ACH

5 Single Cycle, Multiple Cycle, vs. Pipeline Multiple Cycle Implementation: Clk Cycle 1 IFetchDecExecMemWB Cycle 2Cycle 3Cycle 4Cycle 5Cycle 6Cycle 7Cycle 8Cycle 9Cycle 10 IFetchDecExecMem lwsw IFetch R-type lw IFetchDecExecMemWB Pipeline Implementation: IFetchDecExecMemWB sw IFetchDecExecMemWB R-type Clk Single Cycle Implementation: lwsw Waste Cycle 1Cycle 2 5CSE340, ACH

6 MIPS Pipeline Datapath Modifications What do we need to add/modify in our MIPS datapath? – State registers between each pipeline stage to isolate them 6CSE340, ACH

7 Pipelining the MIPS ISA What makes it easy – all instructions are the same length (32 bits) can fetch in the 1 st stage and decode in the 2 nd stage – few instruction formats (three) with symmetry across formats can begin reading register file in 2 nd stage – memory operations can occur only in loads and stores can use the execute stage to calculate memory addresses – each MIPS instruction writes at most one result (i.e., changes the machine state) and does so near the end of the pipeline (MEM and WB) What makes it hard – structural hazards: what if we had only one memory? – control hazards: what about branches? – data hazards: what if an instruction’s input operands depend on the output of a previous instruction? 7CSE340, ACH

8 Graphically Representing MIPS Pipeline Can help with answering questions like: – How many cycles does it take to execute this code? – What is the ALU doing during cycle 4? – Is there a hazard, why does it occur, and how can it be fixed? ALU IM Reg DMReg 8CSE340, ACH

9 Why Pipeline? For Performance! I n s t r. O r d e r Time (clock cycles) Inst 0 Inst 1 Inst 2 Inst 4 Inst 3 ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg Once the pipeline is full, one instruction is completed every cycle, so CPI = 1 Time to fill the pipeline 9CSE340, ACH

10 Can Pipelining Get Us Into Trouble? Yes: Pipeline Hazards – structural hazards: attempt to use the same resource by two different instructions at the same time – data hazards: attempt to use data before it is ready An instruction’s source operand(s) are produced by a prior instruction still in the pipeline – control hazards: attempt to make a decision about program control flow before the condition has been evaluated and the new PC target address calculated branch instructions  Can always resolve hazards by waiting l pipeline control must detect the hazard l and take action to resolve hazards 10CSE340, ACH

11 I n s t r. O r d e r Time (clock cycles) lw Inst 1 Inst 2 Inst 4 Inst 3 ALU Mem Reg MemReg ALU Mem Reg MemReg ALU Mem Reg MemReg ALU Mem Reg MemReg ALU Mem Reg MemReg A Single Memory Would Be a Structural Hazard Reading data from memory Reading instruction from memory  Fix with separate instr and data memories (I$ and D$) 11CSE340, ACH

12 How About Register File Access? I n s t r. O r d e r Time (clock cycles) add $1, Inst 1 Inst 2 add $2,$1, ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg 12CSE340, ACH

13 How About Register File Access? I n s t r. O r d e r Time (clock cycles) Inst 1 Inst 2 ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg Fix register file access hazard by doing reads in the second half of the cycle and writes in the first half add $1, add $2,$1, clock edge that controls register writing clock edge that controls loading of pipeline state registers 13CSE340, ACH

14 Register Usage Can Cause Data Hazards I n s t r. O r d e r add $1, sub $4,$1,$5 and $6,$1,$7 xor $4,$1,$5 or $8,$1,$9 ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg Dependencies backward in time cause hazards  Read before write data hazard 14CSE340, ACH

15 Register Usage Can Cause Data Hazards ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg Dependencies backward in time cause hazards add $1, sub $4,$1,$5 and $6,$1,$7 xor $4,$1,$5 or $8,$1,$9  Read before write data hazard 15CSE340, ACH

16 Loads Can Cause Data Hazards I n s t r. O r d e r lw $1,4($2) sub $4,$1,$5 and $6,$1,$7 xor $4,$1,$5 or $8,$1,$9 ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg Dependencies backward in time cause hazards  Load-use data hazard 16CSE340, ACH

17 stall One Way to “Fix” a Data Hazard I n s t r. O r d e r add $1, ALU IM Reg DMReg sub $4,$1,$5 and $6,$1,$7 ALU IM Reg DMReg ALU IM Reg DMReg Can fix data hazard by waiting – stall – but impacts CPI 17CSE340, ACH

18 Another Way to “Fix” a Data Hazard I n s t r. O r d e r add $1, ALU IM Reg DMReg sub $4,$1,$5 and $6,$1,$7 ALU IM Reg DMReg ALU IM Reg DMReg Fix data hazards by forwarding results as soon as they are available to where they are needed xor $4,$1,$5 or $8,$1,$9 ALU IM Reg DMReg ALU IM Reg DMReg 18CSE340, ACH

19 Another Way to “Fix” a Data Hazard ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg Fix data hazards by forwarding results as soon as they are available to where they are needed ALU IM Reg DMReg ALU IM Reg DMReg I n s t r. O r d e r add $1, sub $4,$1,$5 and $6,$1,$7 xor $4,$1,$5 or $8,$1,$9 19CSE340, ACH

20 Forwarding with Load-use Data Hazards I n s t r. O r d e r lw $1,4($2) sub $4,$1,$5 and $6,$1,$7 xor $4,$1,$5 or $8,$1,$9 ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg 20CSE340, ACH

21 Forwarding with Load-use Data Hazards ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg Will still need one stall cycle even with forwarding I n s t r. O r d e r lw $1,4($2) sub $4,$1,$5 and $6,$1,$7 xor $4,$1,$5 or $8,$1,$9 21CSE340, ACH

22 Branch Instructions Cause Control Hazards I n s t r. O r d e r lw Inst 4 Inst 3 beq ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg ALU IM Reg DMReg Dependencies backward in time cause hazards 22CSE340, ACH

23 stall One Way to “Fix” a Control Hazard I n s t r. O r d e r beq ALU IM Reg DMReg lw ALU IM Reg DMReg ALU Inst 3 IM Reg DM Fix branch hazard by waiting – stall – but affects CPI 23CSE340, ACH

24 Corrected Datapath to Save RegWrite Addr Need to preserve the destination register address in the pipeline state registers 24CSE340, ACH

25 Corrected Datapath to Save RegWrite Addr Need to preserve the destination register address in the pipeline state registers 25CSE340, ACH

26 MIPS Pipeline Control Path Modifications All control signals can be determined during Decode – and held in the state registers between pipeline stages Control 26CSE340, ACH

27 Other Pipeline Structures Are Possible What about the (slow) multiply operation? – Make the clock twice as slow or … – let it take two cycles (since it doesn’t use the DM stage) ALU IM Reg DMReg MUL ALU IM Reg DM1Reg DM2  What if the data memory access is twice as slow as the instruction memory? l make the clock twice as slow or … l let data memory access take two cycles (and keep the same clock rate) 27CSE340, ACH

28 Sample Pipeline Alternatives ARM7 StrongARM-1 XScale ALU IM1 IM2 DM1 Reg DM2 IM Reg EX PC update IM access decode reg access ALU op DM access shift/rotate commit result (write back) ALU IM Reg DMReg SHFT PC update BTB access start IM access IM access decode reg 1 access shift/rotate reg 2 access ALU op start DM access exception DM write reg write 28CSE340, ACH

29 Summary All modern day processors use pipelining Pipelining doesn’t help latency of single task, it helps throughput of entire workload Potential speedup: a CPI of 1 and fast a CC Pipeline rate limited by slowest pipeline stage – Unbalanced pipe stages makes for inefficiencies – The time to “fill” pipeline and time to “drain” it can impact speedup for deep pipelines and short code runs Must detect and resolve hazards – Stalling negatively affects CPI (makes CPI less than the ideal of 1) 29CSE340, ACH

30 Next Lecture and Reminders Next lecture – Overcoming data hazards Reading assignment – PH, Chapter 6.4-6.5 30CSE340, ACH

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