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Maria-Cristina Marinescu Martin Rinard Laboratory for Computer Science Massachusetts Institute of Technology High-level Specification and Efficient Implementation of Pipelined Circuits
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Overall Goal Modular, Asynchronous, Sequential Specification Efficient, Synchronous, Parallel Implementation in Synthesizable Verilog
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Specification Language Concepts State (Registers, Memory) Queues (Conceptually Unbounded Length) Modules Read inputs from queues and state Write outputs to queues and state
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Module Example 100 84 0 43 r2 r3 r0 r1 Register File Input Queue Output Queue Register Operand Fetch Module,
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Module Example 100 84 0 43 r2 r3 r0 r1 Register File Input Queue Output Queue Register Operand Fetch Module, r1
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Module Example 100 84 0 43 r2 r3 r0 r1 Register File Input Queue Output Queue Register Operand Fetch Module, r143
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Module Example 100 84 0 43 r2 r3 r0 r1 Register File Input Queue Output Queue Register Operand Fetch Module,,
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Module Behavior Each module has a set of update rules Each Update Rule Consists of Precondition Action (set of updates) Rule is enabled (and can execute) if precondition is true in current state When rule executes, atomically applies updates in action to produce new state
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Update Rules in Example “If an increment instruction is at the head of the input queue and there is no RAW hazard, then atomically remove the instruction from the queue, fetch the value from the register file, and append the instruction with the register value into the output queue” = head(iq) and notin(oq, ) iq = tail(iq), oq = append(oq, ); “If a jump on zero instruction is at the head of the input queue and there is no RAW hazard, then atomically remove the instruction from the queue, fetch the value from the register file, and append the instruction with the register value into the output queue” = head(iq) and notin(oq, ) iq = tail(iq), oq = append(oq, );
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From Modules to Systems System is a set of Modules Access same Registers and Memories Also communicate via Queues Behavior of System Update rules from all Modules Queues Provide Modularity Decouple Modules Enable Independent Development Promote Reusable Modular Designs
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Example System Specification Instruction Fetch Module TRUE iq = append(iq,im[pc]), pc = pc + 1; Register Operand Fetch Module = head(iq) and notin(rq, ) iq = tail(iq), rq = append(rq, ); = head(iq) and notin(rq, ) iq = tail(iq), rq = append(rq, ); Compute and Writeback Module = head(rq) rf = rf[r = v+1], rq = tail(rq); = head(rq) and (v == 0) pc = l, iq = nil, rq = nil; = head(rq) and (v !=0) rq = tail(rq);
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Abstract Model of Execution Conceptually, system execution is a sequence of rule executions while TRUE choose an enabled rule execute rule obtain new state Concepts in Abstract Execution Model Rules execute atomically Rules execute asynchronously Rules execute sequentially Unbounded Queues
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Synthesis Algorithm
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Key Challenge Specification Language Sequential, atomic, asynchronous semantics Conceptually unbounded queues Implemented Circuit Coordinated parallel execution Finite length queues
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Initial Synthesis Algorithm Symbolically Execute Rules in Order Each rule starts with result from previous rule Obtain Expressions for New Values of Registers, Memories, and Queues Generate Combinational Circuit that Produces New Values Each clock cycle circuit computes new values, writes new values back Every rule gets a chance to execute, every clock cycle! Rule 1Rule 2Rule 3 SE0SE1SE2SE3
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Properties of Initial Algorithm Preserves Semantics of Specification Independent Rules Execute Concurrently But May Have Long Clock Cycle Output of each preceding rule fed in as input to next rule Data traverses ALL rules (and pipeline stages) in a single cycle! Solution: Relaxation
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Relaxation for each rule R i with precondition P i for each variable instance v i in precondition P i replace v i with its earliest safe version... R k-1 : P k-1 -> v k =...... R i : P i (v i,...) ->...... v k safe for v i if either P i [v k /v i ] implies P i (P i,P k-1 ) mutually exclusive 01 2 3 => 01 3 2
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Relaxation Result Relaxation exposes additional parallelism Queues separate pipeline stages Items traverse one stage per clock cycle Safety: If a rule executes in new system Then it also executes in old system And it generates same result Liveness: After relaxation, all rules test initial state If rule enabled in old system but not in new system, then Some rule executes in new system
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Global Scheduling Issue: Conceptually unbounded queues Finite hardware buffers Solution: Modify append rules s.t. no queue exceeds its specified length Challenge: Schedule maximum number of rules Rules can insert into full queues if within length at the end of clock cycle
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Global Scheduling Assumption: queues start within length at beginning of cycle Goal: generate circuit that makes queues remain within length at end of cycle Basic Approach: Before enabled rule executes Be sure will be room for result in output queues at end of clock cycle Key Idea: a rule can insert into a queue as long as enough following rules remove from it
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GS: Basic Concepts Rule-Queue Graph Nodes of 2 types: rules and queues Edge from rule node to queue node if rule inserts into queue Edge from queue node to rule node if rule removes from queue In Example: 1 2 3 4 5 6 iqrq
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Acyclic Rule-Queue Graphs Process Rules in Topological Sort Order Augment execution precondition If rule inserts into a queue, require that either there is room in queue when rule executes or future rules will execute and remove items to make room in queue Each queue has counter of number of elements in queue at start of cycle Combinational logic tracks queue insertions and deletions GS algorithm generates the control signals for the combinational logic
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Pipeline Implications Counter becomes presence bit for single element queues Additional preconditions can be viewed as pipeline stall logic Design can be written to generate pipeline forwarding/bypassing instead of stall
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Global Scheduling: Example IQ 0 IQ 1 tail(IQ 1 ) IQ 0 IQ 2 P0 P1[IQ 0 /IQ 1 ] P2[IQ 0 /IQ 2 ] ~ P1[IQ 0 /IQ 1 ], ~ P2[IQ 0 /IQ 2 ] IQ 2 IQ 3 nil P4 IQ 5 For length(iq) = 1, length(rq) = 1 R0 executes and appends to iq if: P1’ || P2’ || P4’ OR iq 0 = nil R4 doesn’t insert into queues => P4’ = P4 Apply same rationale for R1 & R2: R1 executes and appends to rq if: P4 || P3’ || P5’ rq 0 = nil R3 and R5 don’t insert into queues => P3’ = P3, P5’ = P5 GS1(rq) = GS2(rq) = (rq 0 = nil) || P4 || P3 || P5 GS0(iq) = (iq 0 = nil) || P4 || (P1 || P2) [(rq 0 = nil) || P3 || P5] = = (iq 0 = nil) || P4 || P1 || P2
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Cyclic Rule-Queue Graphs Cyclic Graphs lead to Cyclic Dependences Rule 1 depends on rule 2 to remove an item from a queue But rule 2 depends on rule 1 to remove an item from another queue Algorithm from acyclic case would generate recursive preconditions Queue x rule 2 Queue y rule 1
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Cyclic R-Q Graphs: Example Let P1’ = P1 GS1 Assumption: R1 executes (P1’ = TRUE) Find group of rules that must fire together P1’ = P1 [(x=nil) || P2’] = = P1 [(x=nil) || P2 [(y=nil) || P1’]] No need to explore P1’ further (P1’ = TRUE) => P1’ = P1 [(x=nil) || P2] Queue x rule 2 Queue y rule 1
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Solution to Cyclic Dependence Problem Key Idea: no deadlock if we can coordinate removals and insertions from/to all queues in cycle s.t. removals make room for insertions Groups of rules must execute together Use depth-first search on rule-queue graph to find cyclic groups Augment preconditions to allow all rules in cycle to execute together Extensions include paths into and out of cyclic group
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Cyclic R-Q Graphs: Algorithm SymbolicExecution(Ri, CrtPath) for each queue q that Ri inserts into for each rule Rj that inserts/removes in/from q newRj = if Rj CrtPath then TRUE rule already examined else SymbolicExecution(Rj) newCrtPath = if Rj CrtPath then CrtPath else CrtPath Rj replace Rj’ with newRj in GSi(q) GSi = GSi(q) Ri’ = Ri GSi q
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Symbolic Execution Substitute out all intermediate versions of variables Obtain expression for last version of each variable Each expression defines new value of corresponding variable
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Optimizations Optimize expressions from symbolic execution CSE: avoid unnecessary replication of HW Mutual Exclusion Testing: Eliminate computation of values that never occur in practice as result of mutually exclusive preconditions
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Verilog Generation Synthesize HW directly from expressions: Each queue as one or more registers Each memory variable as library block Each state variable as one or more registers, depending on type Each expression as combinational logic that feeds back into corresponding registers
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Experimental Results We have implemented synthesis system Used system to generate synthesizable Verilog for several specifications (map effort medium, area effort low) Benchmark Cycle (MHz) Area Bubblesort 107.06 5434 Butterfly 104.42 5411 Filter 105.01 3757 Architecture Cycle (MHz) Area RISC Pipelined Processor 88.89 23195.25 SCU RTL 98 DSP 90.91 22999.50
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Conclusion Starting Point: (Good for Designer) Modular, Asynchronous, Sequential Specification with Conceptually Infinite Queues Ending Point: (Good for Implementation) Efficient, Synchronous, Globally Scheduled, Parallel Implementation with Finite Queues in Synthesizable Verilog Variety of Techniques: Symbolic Execution Global Scheduling
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