CS计算机代考程序代写 c++ cache computer architecture mips Pipelining 1

Pipelining 1
CS 154: Computer Architecture Lecture #14
Winter 2020
Ziad Matni, Ph.D.
Dept. of Computer Science, UCSB

Administrative
• Talk is on MONDAY, MARCH 9th in our usual class • Will take attendance…
• We “only” have 3 more lectures…L please everybody control your emotions… • Pipelining and start w/ Memory Caching
• Final Exam info:
• Tuesday, March 17th at 12:00 (not 12:30!!!) in this classroom
• Arrive 10 mins early – randomized seating…
• Cumulative Exam
• Will allow some notes – exact details to follow
• Study guide/example Qs will be issued by this weekend
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Lecture Outline
• Data Hazards in Pipelining
• Pipeline Designs and Operation
• Examples with some Instructions
• Diagramming Pipelined Instructions
• Control Lines for Pipelines
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Comparison of Per-Instruction Time
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Hazards
• Situations that prevent starting the next instruction in the next cycle
• Structure hazards
• A required resource is busy
• Data hazard
• Need to wait for previous instruction to complete its data read/write
• Control hazard
• Deciding on control action depends on previous instruction
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Structure Hazards
• Conflict for use of a resource
• In MIPS pipeline with a single memory
• Load/store requires data access
• Instruction fetch would have to stall for that cycle • Would cause a pipeline “bubble”
• Hence, pipelined datapaths require separate instruction/data memories
• Or separate instruction/data caches
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Data Hazards
• An instruction depends on completion of data access by a previous instruction
Example 1:
add $s0, $t0, $t1 sub $t2, $s0, $t3
“Forwarding”: possible if destination stage is later in time than source stage
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Forwarding: Use result
when it is computed
• Don’t wait for it to be stored
in a register
• Requires extra connections
in the datapath

Data Hazards
Example 2:
lw $s0, 20($t1) sub $t2, $s0, $t3
Cannot “forward” back in time!!
“Forwarding”: not possible in this example, UNLESS …
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Data Hazards
Example 2:
lw $s0, 20($t1) sub $t2, $s0, $t3
“Forwarding”: not possible in this example, UNLESS we put in a stalling instruction (aka pipeline stall or bubble) between them
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Code Scheduling to Avoid Stalls
• Reorder code to avoid use of load result in the next instruction
• Example: C++ code for Original
lw $tl, 0($t0)
lw $t2, 4($t0)
add $t3, $tl, $t2
sw $t3, 12($t0)
lw $t4, 8($t0)
add $t5, $tl, $t4
sw $t5, 16($t0)
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a = b + e; c = b + f;
Re-Ordered
lw $tl, 0($t0) lw $t2, 4($t0) lw $t4, 8($t0) add $t3, $tl, $t2 sw $t3, 12 ($t0) add $t5, $tl,$t4 sw $t5, 16 ($t0)
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Move here and save 2 cycles

Control Hazard
• Comes from need to make a decision based on the results of one instruction while others are executing
• Think of the laundry example if we were worried that the soap amount was enough based on how clean the loads come out…
• Branch determines flow of control
• Fetching next instruction depends on branch outcome
• Pipeline can’t always fetch correct instruction because it is still working on ID stage of branch
• In MIPS pipeline
• Need to compare registers and compute target early in the pipeline • Needs added hardware to do it in ID stage
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Possible Solution: Stall on Branch
• Wait until branch outcome is determined before fetching next instruction
• Since the pipeline cannot possibly know what the next instruction should be, since it only just received the branch instruction from memory
This is the instruction after branching:
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Better Solution: Predict the Branch!
• Predict outcome of branch
• Only stalls if prediction is wrong
• This option does not slow down the pipeline when it’s correct!
• In MIPS pipeline,
it is simplest to predict if branches are not taken
• When correct, the pipeline proceeds at full speed
• When branches are taken, then the pipeline purposely stalls • Fetch instruction after branch, with no delay
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MIPS with Predict Not Taken
Prediction Correct
that “branch not needed”
Prediction Incorrect
that “branch not needed” (simplified e.g.)
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MIPS with Predict Not Taken
Prediction Correct
that “branch not needed”
Prediction Incorrect
that “branch not needed” (simplified e.g.)
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More-Realistic Branch Predictions
• Static branch prediction
• Based on “typical” branch behavior
• Example: loop and if-statement branches • Predict backward branches taken
• Predict forward branches not taken
• Not the best, but better than always predicting no-branch… • Dynamic branch prediction
• Hardware measures actual branch behavior • e.g., it record recent history of each branch
• Assume future behavior will continue the trend
• When wrong, stall while re-fetching, and update history • Tends to be accurate ~90% of the time
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Pipeline Summary
• Pipelining improves performance by increasing instruction throughput
• Executes multiple instructions in parallel • Each instruction still has the same latency
• Subject to hazards
• Structure, data, control
• Instruction set design affects complexity of pipeline implementation
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MIPS Pipelined Datapath: Requirements
Based on Single-Cycle Datapath Design…
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Example
• Instructions executed using the single-cycle datapath assuming pipelined execution.
• In laundry analogy, we might have a basket between each pair of stages to hold the clothes for the next step
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MIPS Pipelined Datapath
Need registers between stages to hold information produced in previous cycle
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MIPS Pipelined Datapath for lw instruction: IF
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• •
Highlight the right half of registers or memory when they are being read
Highlight the left half when they are being written

MIPS Pipelined Datapath for lw instruction: IF
• •
Highlight the right half of registers or memory when they are being read
Highlight the left half when they are being written
• Instruction is read from memory using the address in the PC
• Placed in the IF/ID pipeline register.
• PC address is incremented by 4 and then written back into the PC to be ready for the next clock cycle.
• Incremented address is also saved in the IF/ID pipeline register
• It could be needed later for an instruction, such as beq
(i.e. for prediction)
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MIPS Pipelined Datapath for lw instruction: ID
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MIPS Pipelined Datapath for lw instruction: ID
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• Instruction portion of the IF/ID pipeline register supplies the:
• 16b immed. field (then sign extended)
• 2 register numbers to read
• All three values are stored in the ID/EX pipeline reg. (along w/ PC address)
• Transfer everything that might be needed by any instruction during a later clock cycle.

MIPS Pipelined Datapath for lw instruction: EX
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• Instruction reads the contents of register 1 and the sign-extended immediate from the ID/EX pipeline register and adds them using the ALU.
• Sum is placed in the EX/MEM pipeline register.
MIPS Pipelined Datapath for lw instruction: EX
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MIPS Pipelined Datapath for lw instruction: MEM
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MIPS Pipelined Datapath for lw instruction: MEM
• Instruction reads the data memory using the address from the EX/MEM pipeline register
• Loads the data into the MEM/WB pipeline register.
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MIPS Pipelined Datapath for lw instruction: WB
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MIPS Pipelined Datapath for lw instruction: WB
• Instruction reads data from the MEM/WB pipeline register.
• Writes it back into the register file.
What could be wrong here?
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• The instruction in the IF/ID pipeline register supplies the write register number (rd), BUT the “writing” occurs at the end of the load instruction!
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• We need to preserve the rd number in the load instruction…

Corrected Pipelined Datapath
Otherwise load instruction wouldn’t work properly…
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Summary (so far)
• To pass something from an early pipe stage to a later pipe stage, the information must be placed in a pipeline register
• Otherwise, the information is lost when the next instruction enters that pipeline stage.
• Each logical component of the datapath can be used only within a single pipeline stage.
• We have seen 2 types of representations:
• multiple-clock-cycle pipeline diagrams • single-clock-cycle pipeline diagrams
Overview, fewer details Full details
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Multiple-Clock-Cycle Pipeline Diagrams of Five Instructions
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Single-Clock-Cylce Pipeline Diagram of Five Instructions Corresponding to Clock Cycle 5
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Simplified Pipeline Control Diagram (seems familiar?)
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Control Lines for the Last 3 Pipeline Stages
These are derived from the instruction
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Same control signals that we learned earlier, but this time they are “ferried” across the pipelines
See tables in Fig. 4.48, 4.49 in textbook

YOUR TO-DOs for the Week
• Finish Lab 7 by Sunday
• New Lab 8 (last one!) will be issued later on
this week
• Due next week, which is last week of classes…L
3/3/20
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