1/*************************************************************************************** 2* Copyright (c) 2020-2021 Institute of Computing Technology, Chinese Academy of Sciences 3* Copyright (c) 2020-2021 Peng Cheng Laboratory 4* 5* XiangShan is licensed under Mulan PSL v2. 6* You can use this software according to the terms and conditions of the Mulan PSL v2. 7* You may obtain a copy of Mulan PSL v2 at: 8* http://license.coscl.org.cn/MulanPSL2 9* 10* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND, 11* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT, 12* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE. 13* 14* See the Mulan PSL v2 for more details. 15***************************************************************************************/ 16 17package xiangshan.backend.rob 18 19import chipsalliance.rocketchip.config.Parameters 20import chisel3.ExcitingUtils._ 21import chisel3._ 22import chisel3.util._ 23import xiangshan._ 24import utils._ 25import xiangshan.frontend.FtqPtr 26import difftest._ 27 28class RobPtr(implicit p: Parameters) extends CircularQueuePtr[RobPtr]( 29 p => p(XSCoreParamsKey).RobSize 30) with HasCircularQueuePtrHelper { 31 32 def needFlush(redirect: Valid[Redirect]): Bool = { 33 val flushItself = redirect.bits.flushItself() && this === redirect.bits.robIdx 34 redirect.valid && (flushItself || isAfter(this, redirect.bits.robIdx)) 35 } 36 37 override def cloneType = (new RobPtr).asInstanceOf[this.type] 38} 39 40object RobPtr { 41 def apply(f: Bool, v: UInt)(implicit p: Parameters): RobPtr = { 42 val ptr = Wire(new RobPtr) 43 ptr.flag := f 44 ptr.value := v 45 ptr 46 } 47} 48 49class RobCSRIO(implicit p: Parameters) extends XSBundle { 50 val intrBitSet = Input(Bool()) 51 val trapTarget = Input(UInt(VAddrBits.W)) 52 val isXRet = Input(Bool()) 53 54 val fflags = Output(Valid(UInt(5.W))) 55 val dirty_fs = Output(Bool()) 56 val perfinfo = new Bundle { 57 val retiredInstr = Output(UInt(3.W)) 58 } 59} 60 61class RobLsqIO(implicit p: Parameters) extends XSBundle { 62 val lcommit = Output(UInt(log2Up(CommitWidth + 1).W)) 63 val scommit = Output(UInt(log2Up(CommitWidth + 1).W)) 64 val pendingld = Output(Bool()) 65 val pendingst = Output(Bool()) 66 val commit = Output(Bool()) 67 val storeDataRobWb = Input(Vec(StorePipelineWidth, Valid(new RobPtr))) 68} 69 70class RobEnqIO(implicit p: Parameters) extends XSBundle { 71 val canAccept = Output(Bool()) 72 val isEmpty = Output(Bool()) 73 // valid vector, for robIdx gen and walk 74 val needAlloc = Vec(RenameWidth, Input(Bool())) 75 val req = Vec(RenameWidth, Flipped(ValidIO(new MicroOp))) 76 val resp = Vec(RenameWidth, Output(new RobPtr)) 77} 78 79class RobDispatchData(implicit p: Parameters) extends RobCommitInfo 80 81class RobDeqPtrWrapper(implicit p: Parameters) extends XSModule with HasCircularQueuePtrHelper { 82 val io = IO(new Bundle { 83 // for commits/flush 84 val state = Input(UInt(2.W)) 85 val deq_v = Vec(CommitWidth, Input(Bool())) 86 val deq_w = Vec(CommitWidth, Input(Bool())) 87 val exception_state = Flipped(ValidIO(new RobExceptionInfo)) 88 // for flush: when exception occurs, reset deqPtrs to range(0, CommitWidth) 89 val intrBitSetReg = Input(Bool()) 90 val hasNoSpecExec = Input(Bool()) 91 val commitType = Input(CommitType()) 92 val misPredBlock = Input(Bool()) 93 val isReplaying = Input(Bool()) 94 // output: the CommitWidth deqPtr 95 val out = Vec(CommitWidth, Output(new RobPtr)) 96 val next_out = Vec(CommitWidth, Output(new RobPtr)) 97 }) 98 99 val deqPtrVec = RegInit(VecInit((0 until CommitWidth).map(_.U.asTypeOf(new RobPtr)))) 100 101 // for exceptions (flushPipe included) and interrupts: 102 // only consider the first instruction 103 val intrEnable = io.intrBitSetReg && !io.hasNoSpecExec && !CommitType.isLoadStore(io.commitType) 104 val exceptionEnable = io.deq_w(0) && io.exception_state.valid && !io.exception_state.bits.flushPipe && io.exception_state.bits.robIdx === deqPtrVec(0) 105 val redirectOutValid = io.state === 0.U && io.deq_v(0) && (intrEnable || exceptionEnable) 106 107 // for normal commits: only to consider when there're no exceptions 108 // we don't need to consider whether the first instruction has exceptions since it wil trigger exceptions. 109 val commit_exception = io.exception_state.valid && !isAfter(io.exception_state.bits.robIdx, deqPtrVec.last) 110 val canCommit = VecInit((0 until CommitWidth).map(i => io.deq_v(i) && io.deq_w(i) && !io.misPredBlock && !io.isReplaying)) 111 val normalCommitCnt = PriorityEncoder(canCommit.map(c => !c) :+ true.B) 112 // when io.intrBitSetReg or there're possible exceptions in these instructions, 113 // only one instruction is allowed to commit 114 val allowOnlyOne = commit_exception || io.intrBitSetReg 115 val commitCnt = Mux(allowOnlyOne, canCommit(0), normalCommitCnt) 116 117 val commitDeqPtrVec = VecInit(deqPtrVec.map(_ + commitCnt)) 118 val deqPtrVec_next = Mux(io.state === 0.U && !redirectOutValid, commitDeqPtrVec, deqPtrVec) 119 120 deqPtrVec := deqPtrVec_next 121 122 io.next_out := deqPtrVec_next 123 io.out := deqPtrVec 124 125 when (io.state === 0.U) { 126 XSInfo(io.state === 0.U && commitCnt > 0.U, "retired %d insts\n", commitCnt) 127 } 128 129} 130 131class RobEnqPtrWrapper(implicit p: Parameters) extends XSModule with HasCircularQueuePtrHelper { 132 val io = IO(new Bundle { 133 // for input redirect 134 val redirect = Input(Valid(new Redirect)) 135 // for enqueue 136 val allowEnqueue = Input(Bool()) 137 val hasBlockBackward = Input(Bool()) 138 val enq = Vec(RenameWidth, Input(Bool())) 139 val out = Output(new RobPtr) 140 }) 141 142 val enqPtr = RegInit(0.U.asTypeOf(new RobPtr)) 143 144 // enqueue 145 val canAccept = io.allowEnqueue && !io.hasBlockBackward 146 val dispatchNum = Mux(canAccept, PopCount(io.enq), 0.U) 147 148 when (io.redirect.valid) { 149 enqPtr := io.redirect.bits.robIdx + Mux(io.redirect.bits.flushItself(), 0.U, 1.U) 150 }.otherwise { 151 enqPtr := enqPtr + dispatchNum 152 } 153 154 io.out := enqPtr 155 156} 157 158class RobExceptionInfo(implicit p: Parameters) extends XSBundle { 159 // val valid = Bool() 160 val robIdx = new RobPtr 161 val exceptionVec = ExceptionVec() 162 val flushPipe = Bool() 163 val replayInst = Bool() // redirect to that inst itself 164 val singleStep = Bool() 165 val crossPageIPFFix = Bool() 166 167 def has_exception = exceptionVec.asUInt.orR || flushPipe || singleStep || replayInst 168 // only exceptions are allowed to writeback when enqueue 169 def can_writeback = exceptionVec.asUInt.orR || singleStep 170} 171 172class ExceptionGen(implicit p: Parameters) extends XSModule with HasCircularQueuePtrHelper { 173 val io = IO(new Bundle { 174 val redirect = Input(Valid(new Redirect)) 175 val flush = Input(Bool()) 176 val enq = Vec(RenameWidth, Flipped(ValidIO(new RobExceptionInfo))) 177 val wb = Vec(5, Flipped(ValidIO(new RobExceptionInfo))) 178 val out = ValidIO(new RobExceptionInfo) 179 val state = ValidIO(new RobExceptionInfo) 180 }) 181 182 val current = Reg(Valid(new RobExceptionInfo)) 183 184 // orR the exceptionVec 185 val lastCycleFlush = RegNext(io.flush) 186 val in_enq_valid = VecInit(io.enq.map(e => e.valid && e.bits.has_exception && !lastCycleFlush)) 187 val in_wb_valid = io.wb.map(w => w.valid && w.bits.has_exception && !lastCycleFlush) 188 189 // s0: compare wb(1),wb(2) and wb(3),wb(4) 190 val wb_valid = in_wb_valid.zip(io.wb.map(_.bits)).map{ case (v, bits) => v && !(bits.robIdx.needFlush(io.redirect) || io.flush) } 191 val csr_wb_bits = io.wb(0).bits 192 val load_wb_bits = Mux(!in_wb_valid(2) || in_wb_valid(1) && isAfter(io.wb(2).bits.robIdx, io.wb(1).bits.robIdx), io.wb(1).bits, io.wb(2).bits) 193 val store_wb_bits = Mux(!in_wb_valid(4) || in_wb_valid(3) && isAfter(io.wb(4).bits.robIdx, io.wb(3).bits.robIdx), io.wb(3).bits, io.wb(4).bits) 194 val s0_out_valid = RegNext(VecInit(Seq(wb_valid(0), wb_valid(1) || wb_valid(2), wb_valid(3) || wb_valid(4)))) 195 val s0_out_bits = RegNext(VecInit(Seq(csr_wb_bits, load_wb_bits, store_wb_bits))) 196 197 // s1: compare last four and current flush 198 val s1_valid = VecInit(s0_out_valid.zip(s0_out_bits).map{ case (v, b) => v && !(b.robIdx.needFlush(io.redirect) || io.flush) }) 199 val compare_01_valid = s0_out_valid(0) || s0_out_valid(1) 200 val compare_01_bits = Mux(!s0_out_valid(0) || s0_out_valid(1) && isAfter(s0_out_bits(0).robIdx, s0_out_bits(1).robIdx), s0_out_bits(1), s0_out_bits(0)) 201 val compare_bits = Mux(!s0_out_valid(2) || compare_01_valid && isAfter(s0_out_bits(2).robIdx, compare_01_bits.robIdx), compare_01_bits, s0_out_bits(2)) 202 val s1_out_bits = RegNext(compare_bits) 203 val s1_out_valid = RegNext(s1_valid.asUInt.orR) 204 205 val enq_valid = RegNext(in_enq_valid.asUInt.orR && !io.redirect.valid && !io.flush) 206 val enq_bits = RegNext(ParallelPriorityMux(in_enq_valid, io.enq.map(_.bits))) 207 208 // s2: compare the input exception with the current one 209 // priorities: 210 // (1) system reset 211 // (2) current is valid: flush, remain, merge, update 212 // (3) current is not valid: s1 or enq 213 val current_flush = current.bits.robIdx.needFlush(io.redirect) || io.flush 214 val s1_flush = s1_out_bits.robIdx.needFlush(io.redirect) || io.flush 215 when (reset.asBool) { 216 current.valid := false.B 217 }.elsewhen (current.valid) { 218 when (current_flush) { 219 current.valid := Mux(s1_flush, false.B, s1_out_valid) 220 } 221 when (s1_out_valid && !s1_flush) { 222 when (isAfter(current.bits.robIdx, s1_out_bits.robIdx)) { 223 current.bits := s1_out_bits 224 }.elsewhen (current.bits.robIdx === s1_out_bits.robIdx) { 225 current.bits.exceptionVec := (s1_out_bits.exceptionVec.asUInt | current.bits.exceptionVec.asUInt).asTypeOf(ExceptionVec()) 226 current.bits.flushPipe := s1_out_bits.flushPipe || current.bits.flushPipe 227 current.bits.replayInst := s1_out_bits.replayInst || current.bits.replayInst 228 current.bits.singleStep := s1_out_bits.singleStep || current.bits.singleStep 229 } 230 } 231 }.elsewhen (s1_out_valid && !s1_flush) { 232 current.valid := true.B 233 current.bits := s1_out_bits 234 }.elsewhen (enq_valid && !(io.redirect.valid || io.flush)) { 235 current.valid := true.B 236 current.bits := enq_bits 237 } 238 239 io.out.valid := s1_out_valid || enq_valid && enq_bits.can_writeback 240 io.out.bits := Mux(s1_out_valid, s1_out_bits, enq_bits) 241 io.state := current 242 243} 244 245class RobFlushInfo(implicit p: Parameters) extends XSBundle { 246 val ftqIdx = new FtqPtr 247 val robIdx = new RobPtr 248 val ftqOffset = UInt(log2Up(PredictWidth).W) 249 val replayInst = Bool() 250} 251 252class Rob(numWbPorts: Int)(implicit p: Parameters) extends XSModule with HasCircularQueuePtrHelper { 253 val io = IO(new Bundle() { 254 val redirect = Input(Valid(new Redirect)) 255 val enq = new RobEnqIO 256 val flushOut = ValidIO(new Redirect) 257 val exception = ValidIO(new ExceptionInfo) 258 // exu + brq 259 val exeWbResults = Vec(numWbPorts, Flipped(ValidIO(new ExuOutput))) 260 val commits = new RobCommitIO 261 val lsq = new RobLsqIO 262 val bcommit = Output(UInt(log2Up(CommitWidth + 1).W)) 263 val robDeqPtr = Output(new RobPtr) 264 val csr = new RobCSRIO 265 val robFull = Output(Bool()) 266 }) 267 268 println("Rob: size:" + RobSize + " wbports:" + numWbPorts + " commitwidth:" + CommitWidth) 269 270 // instvalid field 271 // val valid = RegInit(VecInit(List.fill(RobSize)(false.B))) 272 val valid = Mem(RobSize, Bool()) 273 // writeback status 274 // val writebacked = Reg(Vec(RobSize, Bool())) 275 val writebacked = Mem(RobSize, Bool()) 276 val store_data_writebacked = Mem(RobSize, Bool()) 277 // data for redirect, exception, etc. 278 // val flagBkup = RegInit(VecInit(List.fill(RobSize)(false.B))) 279 val flagBkup = Mem(RobSize, Bool()) 280 281 // data for debug 282 // Warn: debug_* prefix should not exist in generated verilog. 283 val debug_microOp = Mem(RobSize, new MicroOp) 284 val debug_exuData = Reg(Vec(RobSize, UInt(XLEN.W)))//for debug 285 val debug_exuDebug = Reg(Vec(RobSize, new DebugBundle))//for debug 286 287 // pointers 288 // For enqueue ptr, we don't duplicate it since only enqueue needs it. 289 val enqPtr = Wire(new RobPtr) 290 val deqPtrVec = Wire(Vec(CommitWidth, new RobPtr)) 291 292 val walkPtrVec = Reg(Vec(CommitWidth, new RobPtr)) 293 val validCounter = RegInit(0.U(log2Ceil(RobSize + 1).W)) 294 val allowEnqueue = RegInit(true.B) 295 296 val enqPtrVec = VecInit((0 until RenameWidth).map(i => enqPtr + PopCount(io.enq.needAlloc.take(i)))) 297 val deqPtr = deqPtrVec(0) 298 val walkPtr = walkPtrVec(0) 299 300 val isEmpty = enqPtr === deqPtr 301 val isReplaying = io.redirect.valid && RedirectLevel.flushItself(io.redirect.bits.level) 302 303 /** 304 * states of Rob 305 */ 306 val s_idle :: s_walk :: s_extrawalk :: Nil = Enum(3) 307 val state = RegInit(s_idle) 308 309 /** 310 * Data Modules 311 * 312 * CommitDataModule: data from dispatch 313 * (1) read: commits/walk/exception 314 * (2) write: enqueue 315 * 316 * WritebackData: data from writeback 317 * (1) read: commits/walk/exception 318 * (2) write: write back from exe units 319 */ 320 val dispatchData = Module(new SyncDataModuleTemplate(new RobDispatchData, RobSize, CommitWidth, RenameWidth)) 321 val dispatchDataRead = dispatchData.io.rdata 322 323 val exceptionGen = Module(new ExceptionGen) 324 val exceptionDataRead = exceptionGen.io.state 325 val fflagsDataRead = Wire(Vec(CommitWidth, UInt(5.W))) 326 327 io.robDeqPtr := deqPtr 328 329 /** 330 * Enqueue (from dispatch) 331 */ 332 // special cases 333 val hasBlockBackward = RegInit(false.B) 334 val hasNoSpecExec = RegInit(false.B) 335 val doingSvinval = RegInit(false.B) 336 // When blockBackward instruction leaves Rob (commit or walk), hasBlockBackward should be set to false.B 337 // To reduce registers usage, for hasBlockBackward cases, we allow enqueue after ROB is empty. 338 when (isEmpty) { hasBlockBackward:= false.B } 339 // When any instruction commits, hasNoSpecExec should be set to false.B 340 when (io.commits.valid.asUInt.orR && state =/= s_extrawalk) { hasNoSpecExec:= false.B } 341 342 io.enq.canAccept := allowEnqueue && !hasBlockBackward 343 io.enq.resp := enqPtrVec 344 val canEnqueue = VecInit(io.enq.req.map(_.valid && io.enq.canAccept)) 345 val timer = GTimer() 346 for (i <- 0 until RenameWidth) { 347 // we don't check whether io.redirect is valid here since redirect has higher priority 348 when (canEnqueue(i)) { 349 // store uop in data module and debug_microOp Vec 350 debug_microOp(enqPtrVec(i).value) := io.enq.req(i).bits 351 debug_microOp(enqPtrVec(i).value).debugInfo.dispatchTime := timer 352 debug_microOp(enqPtrVec(i).value).debugInfo.enqRsTime := timer 353 debug_microOp(enqPtrVec(i).value).debugInfo.selectTime := timer 354 debug_microOp(enqPtrVec(i).value).debugInfo.issueTime := timer 355 debug_microOp(enqPtrVec(i).value).debugInfo.writebackTime := timer 356 when (io.enq.req(i).bits.ctrl.blockBackward) { 357 hasBlockBackward := true.B 358 } 359 when (io.enq.req(i).bits.ctrl.noSpecExec) { 360 hasNoSpecExec := true.B 361 } 362 // the begin instruction of Svinval enqs so mark doingSvinval as true to indicate this process 363 when(!Cat(io.enq.req(i).bits.cf.exceptionVec).orR && FuType.isSvinvalBegin(io.enq.req(i).bits.ctrl.fuType,io.enq.req(i).bits.ctrl.fuOpType,io.enq.req(i).bits.ctrl.flushPipe)) 364 { 365 doingSvinval := true.B 366 } 367 // the end instruction of Svinval enqs so clear doingSvinval 368 when(!Cat(io.enq.req(i).bits.cf.exceptionVec).orR && FuType.isSvinvalEnd(io.enq.req(i).bits.ctrl.fuType,io.enq.req(i).bits.ctrl.fuOpType,io.enq.req(i).bits.ctrl.flushPipe)) 369 { 370 doingSvinval := false.B 371 } 372 // when we are in the process of Svinval software code area , only Svinval.vma and end instruction of Svinval can appear 373 assert( !doingSvinval || (FuType.isSvinval(io.enq.req(i).bits.ctrl.fuType,io.enq.req(i).bits.ctrl.fuOpType,io.enq.req(i).bits.ctrl.flushPipe) || FuType.isSvinvalEnd(io.enq.req(i).bits.ctrl.fuType,io.enq.req(i).bits.ctrl.fuOpType,io.enq.req(i).bits.ctrl.flushPipe))) 374 } 375 } 376 val dispatchNum = Mux(io.enq.canAccept, PopCount(Cat(io.enq.req.map(_.valid))), 0.U) 377 io.enq.isEmpty := RegNext(isEmpty && dispatchNum === 0.U) 378 379 // debug info for enqueue (dispatch) 380 XSDebug(p"(ready, valid): ${io.enq.canAccept}, ${Binary(Cat(io.enq.req.map(_.valid)))}\n") 381 XSInfo(dispatchNum =/= 0.U, p"dispatched $dispatchNum insts\n") 382 383 384 /** 385 * Writeback (from execution units) 386 */ 387 for (i <- 0 until numWbPorts) { 388 when (io.exeWbResults(i).valid) { 389 val wbIdx = io.exeWbResults(i).bits.uop.robIdx.value 390 debug_microOp(wbIdx).cf.exceptionVec := io.exeWbResults(i).bits.uop.cf.exceptionVec 391 debug_microOp(wbIdx).ctrl.flushPipe := io.exeWbResults(i).bits.uop.ctrl.flushPipe 392 debug_microOp(wbIdx).ctrl.replayInst := io.exeWbResults(i).bits.uop.ctrl.replayInst 393 debug_microOp(wbIdx).diffTestDebugLrScValid := io.exeWbResults(i).bits.uop.diffTestDebugLrScValid 394 debug_exuData(wbIdx) := io.exeWbResults(i).bits.data 395 debug_exuDebug(wbIdx) := io.exeWbResults(i).bits.debug 396 debug_microOp(wbIdx).debugInfo.enqRsTime := io.exeWbResults(i).bits.uop.debugInfo.enqRsTime 397 debug_microOp(wbIdx).debugInfo.selectTime := io.exeWbResults(i).bits.uop.debugInfo.selectTime 398 debug_microOp(wbIdx).debugInfo.issueTime := io.exeWbResults(i).bits.uop.debugInfo.issueTime 399 debug_microOp(wbIdx).debugInfo.writebackTime := io.exeWbResults(i).bits.uop.debugInfo.writebackTime 400 401 val debug_Uop = debug_microOp(wbIdx) 402 XSInfo(true.B, 403 p"writebacked pc 0x${Hexadecimal(debug_Uop.cf.pc)} wen ${debug_Uop.ctrl.rfWen} " + 404 p"data 0x${Hexadecimal(io.exeWbResults(i).bits.data)} ldst ${debug_Uop.ctrl.ldest} pdst ${debug_Uop.pdest} " + 405 p"skip ${io.exeWbResults(i).bits.debug.isMMIO} robIdx: ${io.exeWbResults(i).bits.uop.robIdx}\n" 406 ) 407 } 408 } 409 val writebackNum = PopCount(io.exeWbResults.map(_.valid)) 410 XSInfo(writebackNum =/= 0.U, "writebacked %d insts\n", writebackNum) 411 412 413 /** 414 * RedirectOut: Interrupt and Exceptions 415 */ 416 val deqDispatchData = dispatchDataRead(0) 417 val debug_deqUop = debug_microOp(deqPtr.value) 418 419 // For MMIO instructions, they should not trigger interrupts since they may be sent to lower level before it writes back. 420 // However, we cannot determine whether a load/store instruction is MMIO. 421 // Thus, we don't allow load/store instructions to trigger an interrupt. 422 val intrBitSetReg = RegNext(io.csr.intrBitSet) 423 val intrEnable = intrBitSetReg && !hasNoSpecExec && !CommitType.isLoadStore(deqDispatchData.commitType) 424 val deqHasExceptionOrFlush = exceptionDataRead.valid && exceptionDataRead.bits.robIdx === deqPtr 425 val deqHasException = deqHasExceptionOrFlush && exceptionDataRead.bits.exceptionVec.asUInt.orR 426 val deqHasFlushPipe = deqHasExceptionOrFlush && exceptionDataRead.bits.flushPipe 427 val deqHasReplayInst = deqHasExceptionOrFlush && exceptionDataRead.bits.replayInst 428 val exceptionEnable = writebacked(deqPtr.value) && deqHasException 429 val isFlushPipe = writebacked(deqPtr.value) && (deqHasFlushPipe || deqHasReplayInst) 430 431 // io.flushOut will trigger redirect at the next cycle. 432 // Block any redirect or commit at the next cycle. 433 val lastCycleFlush = RegNext(io.flushOut.valid) 434 435 io.flushOut.valid := (state === s_idle) && valid(deqPtr.value) && (intrEnable || exceptionEnable || isFlushPipe) && !lastCycleFlush 436 io.flushOut.bits := DontCare 437 io.flushOut.bits.robIdx := deqPtr 438 io.flushOut.bits.ftqIdx := deqDispatchData.ftqIdx 439 io.flushOut.bits.ftqOffset := deqDispatchData.ftqOffset 440 io.flushOut.bits.level := Mux(deqHasReplayInst || intrEnable || exceptionEnable, RedirectLevel.flush, RedirectLevel.flushAfter) 441 io.flushOut.bits.interrupt := true.B 442 XSPerfAccumulate("interrupt_num", io.flushOut.valid && intrEnable) 443 XSPerfAccumulate("exception_num", io.flushOut.valid && exceptionEnable) 444 XSPerfAccumulate("flush_pipe_num", io.flushOut.valid && isFlushPipe) 445 XSPerfAccumulate("replay_inst_num", io.flushOut.valid && isFlushPipe && deqHasReplayInst) 446 447 val exceptionHappen = (state === s_idle) && valid(deqPtr.value) && (intrEnable || exceptionEnable) && !lastCycleFlush 448 io.exception.valid := RegNext(exceptionHappen) 449 io.exception.bits.uop := RegEnable(debug_deqUop, exceptionHappen) 450 io.exception.bits.uop.ctrl.commitType := RegEnable(deqDispatchData.commitType, exceptionHappen) 451 io.exception.bits.uop.cf.exceptionVec := RegEnable(exceptionDataRead.bits.exceptionVec, exceptionHappen) 452 io.exception.bits.uop.ctrl.singleStep := RegEnable(exceptionDataRead.bits.singleStep, exceptionHappen) 453 io.exception.bits.uop.cf.crossPageIPFFix := RegEnable(exceptionDataRead.bits.crossPageIPFFix, exceptionHappen) 454 io.exception.bits.isInterrupt := RegEnable(intrEnable, exceptionHappen) 455 456 XSDebug(io.flushOut.valid, 457 p"generate redirect: pc 0x${Hexadecimal(io.exception.bits.uop.cf.pc)} intr $intrEnable " + 458 p"excp $exceptionEnable flushPipe $isFlushPipe " + 459 p"Trap_target 0x${Hexadecimal(io.csr.trapTarget)} exceptionVec ${Binary(exceptionDataRead.bits.exceptionVec.asUInt)}\n") 460 461 462 /** 463 * Commits (and walk) 464 * They share the same width. 465 */ 466 val walkCounter = Reg(UInt(log2Up(RobSize + 1).W)) 467 val shouldWalkVec = VecInit((0 until CommitWidth).map(_.U < walkCounter)) 468 val walkFinished = walkCounter <= CommitWidth.U 469 470 // extra space is used when rob has no enough space, but mispredict recovery needs such info to walk regmap 471 require(RenameWidth <= CommitWidth) 472 val extraSpaceForMPR = Reg(Vec(RenameWidth, new RobDispatchData)) 473 val usedSpaceForMPR = Reg(Vec(RenameWidth, Bool())) 474 when (io.enq.needAlloc.asUInt.orR && io.redirect.valid) { 475 usedSpaceForMPR := io.enq.needAlloc 476 extraSpaceForMPR := dispatchData.io.wdata 477 XSDebug("rob full, switched to s_extrawalk. needExtraSpaceForMPR: %b\n", io.enq.needAlloc.asUInt) 478 } 479 480 // wiring to csr 481 val (wflags, fpWen) = (0 until CommitWidth).map(i => { 482 val v = io.commits.valid(i) 483 val info = io.commits.info(i) 484 (v & info.wflags, v & info.fpWen) 485 }).unzip 486 val fflags = Wire(Valid(UInt(5.W))) 487 fflags.valid := Mux(io.commits.isWalk, false.B, Cat(wflags).orR()) 488 fflags.bits := wflags.zip(fflagsDataRead).map({ 489 case (w, f) => Mux(w, f, 0.U) 490 }).reduce(_|_) 491 val dirty_fs = Mux(io.commits.isWalk, false.B, Cat(fpWen).orR()) 492 493 // when mispredict branches writeback, stop commit in the next 2 cycles 494 // TODO: don't check all exu write back 495 val misPredWb = Cat(VecInit((0 until numWbPorts).map(i => 496 io.exeWbResults(i).bits.redirect.cfiUpdate.isMisPred && io.exeWbResults(i).bits.redirectValid 497 ))).orR() 498 val misPredBlockCounter = Reg(UInt(3.W)) 499 misPredBlockCounter := Mux(misPredWb, 500 "b111".U, 501 misPredBlockCounter >> 1.U 502 ) 503 val misPredBlock = misPredBlockCounter(0) 504 505 io.commits.isWalk := state =/= s_idle 506 val commit_v = Mux(state === s_idle, VecInit(deqPtrVec.map(ptr => valid(ptr.value))), VecInit(walkPtrVec.map(ptr => valid(ptr.value)))) 507 // store will be commited iff both sta & std have been writebacked 508 val commit_w = VecInit(deqPtrVec.map(ptr => writebacked(ptr.value) && store_data_writebacked(ptr.value))) 509 val commit_exception = exceptionDataRead.valid && !isAfter(exceptionDataRead.bits.robIdx, deqPtrVec.last) 510 val commit_block = VecInit((0 until CommitWidth).map(i => !commit_w(i))) 511 val allowOnlyOneCommit = commit_exception || intrBitSetReg 512 // for instructions that may block others, we don't allow them to commit 513 for (i <- 0 until CommitWidth) { 514 // defaults: state === s_idle and instructions commit 515 // when intrBitSetReg, allow only one instruction to commit at each clock cycle 516 val isBlocked = if (i != 0) Cat(commit_block.take(i)).orR || allowOnlyOneCommit else intrEnable || deqHasException || deqHasReplayInst 517 io.commits.valid(i) := commit_v(i) && commit_w(i) && !isBlocked && !misPredBlock && !isReplaying && !lastCycleFlush 518 io.commits.info(i) := dispatchDataRead(i) 519 520 when (state === s_walk) { 521 io.commits.valid(i) := commit_v(i) && shouldWalkVec(i) 522 }.elsewhen(state === s_extrawalk) { 523 io.commits.valid(i) := (if (i < RenameWidth) usedSpaceForMPR(RenameWidth-i-1) else false.B) 524 io.commits.info(i) := (if (i < RenameWidth) extraSpaceForMPR(RenameWidth-i-1) else DontCare) 525 } 526 527 XSInfo(state === s_idle && io.commits.valid(i), 528 "retired pc %x wen %d ldest %d pdest %x old_pdest %x data %x fflags: %b\n", 529 debug_microOp(deqPtrVec(i).value).cf.pc, 530 io.commits.info(i).rfWen, 531 io.commits.info(i).ldest, 532 io.commits.info(i).pdest, 533 io.commits.info(i).old_pdest, 534 debug_exuData(deqPtrVec(i).value), 535 fflagsDataRead(i) 536 ) 537 XSInfo(state === s_walk && io.commits.valid(i), "walked pc %x wen %d ldst %d data %x\n", 538 debug_microOp(walkPtrVec(i).value).cf.pc, 539 io.commits.info(i).rfWen, 540 io.commits.info(i).ldest, 541 debug_exuData(walkPtrVec(i).value) 542 ) 543 XSInfo(state === s_extrawalk && io.commits.valid(i), "use extra space walked wen %d ldst %d\n", 544 io.commits.info(i).rfWen, 545 io.commits.info(i).ldest 546 ) 547 } 548 if (env.EnableDifftest) { 549 io.commits.info.map(info => dontTouch(info.pc)) 550 } 551 552 // sync fflags/dirty_fs to csr 553 io.csr.fflags := fflags 554 io.csr.dirty_fs := dirty_fs 555 556 // commit branch to brq 557 val cfiCommitVec = VecInit(io.commits.valid.zip(io.commits.info.map(_.commitType)).map{case(v, t) => v && CommitType.isBranch(t)}) 558 io.bcommit := Mux(io.commits.isWalk, 0.U, PopCount(cfiCommitVec)) 559 560 // commit load/store to lsq 561 val ldCommitVec = VecInit((0 until CommitWidth).map(i => io.commits.valid(i) && io.commits.info(i).commitType === CommitType.LOAD)) 562 val stCommitVec = VecInit((0 until CommitWidth).map(i => io.commits.valid(i) && io.commits.info(i).commitType === CommitType.STORE)) 563 io.lsq.lcommit := Mux(io.commits.isWalk, 0.U, PopCount(ldCommitVec)) 564 io.lsq.scommit := Mux(io.commits.isWalk, 0.U, PopCount(stCommitVec)) 565 io.lsq.pendingld := !io.commits.isWalk && io.commits.info(0).commitType === CommitType.LOAD && valid(deqPtr.value) 566 io.lsq.pendingst := !io.commits.isWalk && io.commits.info(0).commitType === CommitType.STORE && valid(deqPtr.value) 567 io.lsq.commit := !io.commits.isWalk && io.commits.valid(0) 568 569 /** 570 * state changes 571 * (1) exceptions: when exception occurs, cancels all and switch to s_idle 572 * (2) redirect: switch to s_walk or s_extrawalk (depends on whether there're pending instructions in dispatch1) 573 * (3) walk: when walking comes to the end, switch to s_walk 574 * (4) s_extrawalk to s_walk 575 */ 576 val state_next = Mux(io.redirect.valid, 577 Mux(io.enq.needAlloc.asUInt.orR, s_extrawalk, s_walk), 578 Mux(state === s_walk && walkFinished, 579 s_idle, 580 Mux(state === s_extrawalk, s_walk, state) 581 ) 582 ) 583 state := state_next 584 585 /** 586 * pointers and counters 587 */ 588 val deqPtrGenModule = Module(new RobDeqPtrWrapper) 589 deqPtrGenModule.io.state := state 590 deqPtrGenModule.io.deq_v := commit_v 591 deqPtrGenModule.io.deq_w := commit_w 592 deqPtrGenModule.io.exception_state := exceptionDataRead 593 deqPtrGenModule.io.intrBitSetReg := intrBitSetReg 594 deqPtrGenModule.io.hasNoSpecExec := hasNoSpecExec 595 deqPtrGenModule.io.commitType := deqDispatchData.commitType 596 597 deqPtrGenModule.io.misPredBlock := misPredBlock 598 deqPtrGenModule.io.isReplaying := isReplaying 599 deqPtrVec := deqPtrGenModule.io.out 600 val deqPtrVec_next = deqPtrGenModule.io.next_out 601 602 val enqPtrGenModule = Module(new RobEnqPtrWrapper) 603 enqPtrGenModule.io.redirect := io.redirect 604 enqPtrGenModule.io.allowEnqueue := allowEnqueue 605 enqPtrGenModule.io.hasBlockBackward := hasBlockBackward 606 enqPtrGenModule.io.enq := VecInit(io.enq.req.map(_.valid)) 607 enqPtr := enqPtrGenModule.io.out 608 609 val thisCycleWalkCount = Mux(walkFinished, walkCounter, CommitWidth.U) 610 // next walkPtrVec: 611 // (1) redirect occurs: update according to state 612 // (2) walk: move backwards 613 val walkPtrVec_next = Mux(io.redirect.valid && state =/= s_extrawalk, 614 Mux(state === s_walk, 615 VecInit(walkPtrVec.map(_ - thisCycleWalkCount)), 616 VecInit((0 until CommitWidth).map(i => enqPtr - (i+1).U)) 617 ), 618 Mux(state === s_walk, VecInit(walkPtrVec.map(_ - CommitWidth.U)), walkPtrVec) 619 ) 620 walkPtrVec := walkPtrVec_next 621 622 val lastCycleRedirect = RegNext(io.redirect.valid) 623 val trueValidCounter = Mux(lastCycleRedirect, distanceBetween(enqPtr, deqPtr), validCounter) 624 val commitCnt = PopCount(io.commits.valid) 625 validCounter := Mux(state === s_idle, 626 (validCounter - commitCnt) + dispatchNum, 627 trueValidCounter 628 ) 629 630 allowEnqueue := Mux(state === s_idle, 631 validCounter + dispatchNum <= (RobSize - RenameWidth).U, 632 trueValidCounter <= (RobSize - RenameWidth).U 633 ) 634 635 val currentWalkPtr = Mux(state === s_walk || state === s_extrawalk, walkPtr, enqPtr - 1.U) 636 val redirectWalkDistance = distanceBetween(currentWalkPtr, io.redirect.bits.robIdx) 637 when (io.redirect.valid) { 638 walkCounter := Mux(state === s_walk, 639 // NOTE: +& is used here because: 640 // When rob is full and the head instruction causes an exception, 641 // the redirect robIdx is the deqPtr. In this case, currentWalkPtr is 642 // enqPtr - 1.U and redirectWalkDistance is RobSize - 1. 643 // Since exceptions flush the instruction itself, flushItSelf is true.B. 644 // Previously we use `+` to count the walk distance and it causes overflows 645 // when RobSize is power of 2. We change it to `+&` to allow walkCounter to be RobSize. 646 // The width of walkCounter also needs to be changed. 647 redirectWalkDistance +& io.redirect.bits.flushItself() - commitCnt, 648 redirectWalkDistance +& io.redirect.bits.flushItself() 649 ) 650 }.elsewhen (state === s_walk) { 651 walkCounter := walkCounter - commitCnt 652 XSInfo(p"rolling back: $enqPtr $deqPtr walk $walkPtr walkcnt $walkCounter\n") 653 } 654 655 656 /** 657 * States 658 * We put all the stage bits changes here. 659 660 * All events: (1) enqueue (dispatch); (2) writeback; (3) cancel; (4) dequeue (commit); 661 * All states: (1) valid; (2) writebacked; (3) flagBkup 662 */ 663 val commitReadAddr = Mux(state === s_idle, VecInit(deqPtrVec.map(_.value)), VecInit(walkPtrVec.map(_.value))) 664 665 // enqueue logic writes 6 valid 666 for (i <- 0 until RenameWidth) { 667 when (canEnqueue(i) && !io.redirect.valid) { 668 valid(enqPtrVec(i).value) := true.B 669 } 670 } 671 // dequeue/walk logic writes 6 valid, dequeue and walk will not happen at the same time 672 for (i <- 0 until CommitWidth) { 673 when (io.commits.valid(i) && state =/= s_extrawalk) { 674 valid(commitReadAddr(i)) := false.B 675 } 676 } 677 // reset: when exception, reset all valid to false 678 when (reset.asBool) { 679 for (i <- 0 until RobSize) { 680 valid(i) := false.B 681 } 682 } 683 684 // status field: writebacked 685 // enqueue logic set 6 writebacked to false 686 for (i <- 0 until RenameWidth) { 687 when (canEnqueue(i)) { 688 writebacked(enqPtrVec(i).value) := io.enq.req(i).bits.eliminatedMove && !io.enq.req(i).bits.cf.exceptionVec.asUInt.orR 689 val isStu = io.enq.req(i).bits.ctrl.fuType === FuType.stu 690 store_data_writebacked(enqPtrVec(i).value) := !isStu 691 } 692 } 693 when (exceptionGen.io.out.valid) { 694 val wbIdx = exceptionGen.io.out.bits.robIdx.value 695 writebacked(wbIdx) := true.B 696 store_data_writebacked(wbIdx) := true.B 697 } 698 // writeback logic set numWbPorts writebacked to true 699 for (i <- 0 until numWbPorts) { 700 when (io.exeWbResults(i).valid) { 701 val wbIdx = io.exeWbResults(i).bits.uop.robIdx.value 702 val block_wb = 703 selectAll(io.exeWbResults(i).bits.uop.cf.exceptionVec, false, true).asUInt.orR || 704 io.exeWbResults(i).bits.uop.ctrl.flushPipe || 705 io.exeWbResults(i).bits.uop.ctrl.replayInst 706 writebacked(wbIdx) := !block_wb 707 } 708 } 709 // store data writeback logic mark store as data_writebacked 710 for (i <- 0 until StorePipelineWidth) { 711 when(io.lsq.storeDataRobWb(i).valid) { 712 store_data_writebacked(io.lsq.storeDataRobWb(i).bits.value) := true.B 713 } 714 } 715 716 // flagBkup 717 // enqueue logic set 6 flagBkup at most 718 for (i <- 0 until RenameWidth) { 719 when (canEnqueue(i)) { 720 flagBkup(enqPtrVec(i).value) := enqPtrVec(i).flag 721 } 722 } 723 724 725 /** 726 * read and write of data modules 727 */ 728 val commitReadAddr_next = Mux(state_next === s_idle, 729 VecInit(deqPtrVec_next.map(_.value)), 730 VecInit(walkPtrVec_next.map(_.value)) 731 ) 732 dispatchData.io.wen := canEnqueue 733 dispatchData.io.waddr := enqPtrVec.map(_.value) 734 dispatchData.io.wdata.zip(io.enq.req.map(_.bits)).foreach{ case (wdata, req) => 735 wdata.ldest := req.ctrl.ldest 736 wdata.rfWen := req.ctrl.rfWen 737 wdata.fpWen := req.ctrl.fpWen 738 wdata.wflags := req.ctrl.fpu.wflags 739 wdata.commitType := req.ctrl.commitType 740 wdata.pdest := req.pdest 741 wdata.old_pdest := req.old_pdest 742 wdata.ftqIdx := req.cf.ftqPtr 743 wdata.ftqOffset := req.cf.ftqOffset 744 wdata.pc := req.cf.pc 745 } 746 dispatchData.io.raddr := commitReadAddr_next 747 748 exceptionGen.io.redirect <> io.redirect 749 exceptionGen.io.flush := io.flushOut.valid 750 for (i <- 0 until RenameWidth) { 751 exceptionGen.io.enq(i).valid := canEnqueue(i) 752 exceptionGen.io.enq(i).bits.robIdx := io.enq.req(i).bits.robIdx 753 exceptionGen.io.enq(i).bits.exceptionVec := selectFrontend(io.enq.req(i).bits.cf.exceptionVec, false, true) 754 exceptionGen.io.enq(i).bits.flushPipe := io.enq.req(i).bits.ctrl.flushPipe 755 exceptionGen.io.enq(i).bits.replayInst := io.enq.req(i).bits.ctrl.replayInst 756 assert(exceptionGen.io.enq(i).bits.replayInst === false.B) 757 exceptionGen.io.enq(i).bits.singleStep := io.enq.req(i).bits.ctrl.singleStep 758 exceptionGen.io.enq(i).bits.crossPageIPFFix := io.enq.req(i).bits.cf.crossPageIPFFix 759 } 760 761 // TODO: don't hard code these idxes 762 val numIntWbPorts = exuParameters.AluCnt + exuParameters.LduCnt + exuParameters.MduCnt 763 // CSR is after Alu and Load 764 def csr_wb_idx = exuParameters.AluCnt + exuParameters.LduCnt 765 def atomic_wb_idx = exuParameters.AluCnt // first port for load 766 def load_wb_idxes = Seq(exuParameters.AluCnt + 1) // second port for load 767 def store_wb_idxes = io.exeWbResults.indices.takeRight(2) 768 val all_exception_possibilities = Seq(csr_wb_idx, atomic_wb_idx) ++ load_wb_idxes ++ store_wb_idxes 769 all_exception_possibilities.zipWithIndex.foreach{ case (p, i) => connect_exception(i, p) } 770 def connect_exception(index: Int, wb_index: Int) = { 771 exceptionGen.io.wb(index).valid := io.exeWbResults(wb_index).valid 772 // A temporary fix for float load writeback 773 // TODO: let int/fp load use the same two wb ports 774 if (wb_index == atomic_wb_idx || load_wb_idxes.contains(wb_index)) { 775 when (io.exeWbResults(wb_index - exuParameters.AluCnt + numIntWbPorts + exuParameters.FmacCnt).valid) { 776 exceptionGen.io.wb(index).valid := true.B 777 } 778 } 779 exceptionGen.io.wb(index).bits.robIdx := io.exeWbResults(wb_index).bits.uop.robIdx 780 val selectFunc = if (wb_index == csr_wb_idx) selectCSR _ 781 else if (wb_index == atomic_wb_idx) selectAtomics _ 782 else if (load_wb_idxes.contains(wb_index)) selectLoad _ 783 else { 784 assert(store_wb_idxes.contains(wb_index)) 785 selectStore _ 786 } 787 exceptionGen.io.wb(index).bits.exceptionVec := selectFunc(io.exeWbResults(wb_index).bits.uop.cf.exceptionVec, false, true) 788 exceptionGen.io.wb(index).bits.flushPipe := io.exeWbResults(wb_index).bits.uop.ctrl.flushPipe 789 exceptionGen.io.wb(index).bits.replayInst := io.exeWbResults(wb_index).bits.uop.ctrl.replayInst 790 exceptionGen.io.wb(index).bits.singleStep := false.B 791 exceptionGen.io.wb(index).bits.crossPageIPFFix := false.B 792 } 793 794 // 4 fmac + 2 fmisc + 1 i2f 795 val fmacWb = (0 until exuParameters.FmacCnt).map(_ + numIntWbPorts) 796 val fmiscWb = (0 until exuParameters.FmiscCnt).map(_ + numIntWbPorts + exuParameters.FmacCnt + 2) 797 val i2fWb = Seq(numIntWbPorts - 1) // last port in int 798 val fflags_wb = io.exeWbResults.zipWithIndex.filter(w => { 799 (fmacWb ++ fmiscWb ++ i2fWb).contains(w._2) 800 }).map(_._1) 801 val fflagsDataModule = Module(new SyncDataModuleTemplate( 802 UInt(5.W), RobSize, CommitWidth, fflags_wb.size) 803 ) 804 for(i <- fflags_wb.indices){ 805 fflagsDataModule.io.wen (i) := fflags_wb(i).valid 806 fflagsDataModule.io.waddr(i) := fflags_wb(i).bits.uop.robIdx.value 807 fflagsDataModule.io.wdata(i) := fflags_wb(i).bits.fflags 808 } 809 fflagsDataModule.io.raddr := VecInit(deqPtrVec_next.map(_.value)) 810 fflagsDataRead := fflagsDataModule.io.rdata 811 812 813 val instrCnt = RegInit(0.U(64.W)) 814 val fuseCommitCnt = PopCount(io.commits.valid.zip(io.commits.info).map{ case (v, i) => v && CommitType.isFused(i.commitType) }) 815 val trueCommitCnt = commitCnt +& fuseCommitCnt 816 val retireCounter = Mux(state === s_idle, trueCommitCnt, 0.U) 817 instrCnt := instrCnt + retireCounter 818 io.csr.perfinfo.retiredInstr := RegNext(retireCounter) 819 io.robFull := !allowEnqueue 820 821 /** 822 * debug info 823 */ 824 XSDebug(p"enqPtr ${enqPtr} deqPtr ${deqPtr}\n") 825 XSDebug("") 826 for(i <- 0 until RobSize){ 827 XSDebug(false, !valid(i), "-") 828 XSDebug(false, valid(i) && writebacked(i), "w") 829 XSDebug(false, valid(i) && !writebacked(i), "v") 830 } 831 XSDebug(false, true.B, "\n") 832 833 for(i <- 0 until RobSize) { 834 if(i % 4 == 0) XSDebug("") 835 XSDebug(false, true.B, "%x ", debug_microOp(i).cf.pc) 836 XSDebug(false, !valid(i), "- ") 837 XSDebug(false, valid(i) && writebacked(i), "w ") 838 XSDebug(false, valid(i) && !writebacked(i), "v ") 839 if(i % 4 == 3) XSDebug(false, true.B, "\n") 840 } 841 842 def ifCommit(counter: UInt): UInt = Mux(io.commits.isWalk, 0.U, counter) 843 844 val commitDebugUop = deqPtrVec.map(_.value).map(debug_microOp(_)) 845 XSPerfAccumulate("clock_cycle", 1.U) 846 QueuePerf(RobSize, PopCount((0 until RobSize).map(valid(_))), !allowEnqueue) 847 XSPerfAccumulate("commitUop", ifCommit(commitCnt)) 848 XSPerfAccumulate("commitInstr", ifCommit(trueCommitCnt)) 849 val commitIsMove = commitDebugUop.map(_.ctrl.isMove) 850 XSPerfAccumulate("commitInstrMove", ifCommit(PopCount(io.commits.valid.zip(commitIsMove).map{ case (v, m) => v && m }))) 851 val commitMoveElim = commitDebugUop.map(_.debugInfo.eliminatedMove) 852 XSPerfAccumulate("commitInstrMoveElim", ifCommit(PopCount(io.commits.valid zip commitMoveElim map { case (v, e) => v && e }))) 853 XSPerfAccumulate("commitInstrFused", ifCommit(fuseCommitCnt)) 854 val commitIsLoad = io.commits.info.map(_.commitType).map(_ === CommitType.LOAD) 855 val commitLoadValid = io.commits.valid.zip(commitIsLoad).map{ case (v, t) => v && t } 856 XSPerfAccumulate("commitInstrLoad", ifCommit(PopCount(commitLoadValid))) 857 val commitIsBranch = io.commits.info.map(_.commitType).map(_ === CommitType.BRANCH) 858 val commitBranchValid = io.commits.valid.zip(commitIsBranch).map{ case (v, t) => v && t } 859 XSPerfAccumulate("commitInstrBranch", ifCommit(PopCount(commitBranchValid))) 860 val commitLoadWaitBit = commitDebugUop.map(_.cf.loadWaitBit) 861 XSPerfAccumulate("commitInstrLoadWait", ifCommit(PopCount(commitLoadValid.zip(commitLoadWaitBit).map{ case (v, w) => v && w }))) 862 val commitIsStore = io.commits.info.map(_.commitType).map(_ === CommitType.STORE) 863 XSPerfAccumulate("commitInstrStore", ifCommit(PopCount(io.commits.valid.zip(commitIsStore).map{ case (v, t) => v && t }))) 864 XSPerfAccumulate("writeback", PopCount((0 until RobSize).map(i => valid(i) && writebacked(i)))) 865 // XSPerfAccumulate("enqInstr", PopCount(io.dp1Req.map(_.fire()))) 866 // XSPerfAccumulate("d2rVnR", PopCount(io.dp1Req.map(p => p.valid && !p.ready))) 867 XSPerfAccumulate("walkInstr", Mux(io.commits.isWalk, PopCount(io.commits.valid), 0.U)) 868 XSPerfAccumulate("walkCycle", state === s_walk || state === s_extrawalk) 869 val deqNotWritebacked = valid(deqPtr.value) && !writebacked(deqPtr.value) 870 val deqUopCommitType = io.commits.info(0).commitType 871 XSPerfAccumulate("waitNormalCycle", deqNotWritebacked && deqUopCommitType === CommitType.NORMAL) 872 XSPerfAccumulate("waitBranchCycle", deqNotWritebacked && deqUopCommitType === CommitType.BRANCH) 873 XSPerfAccumulate("waitLoadCycle", deqNotWritebacked && deqUopCommitType === CommitType.LOAD) 874 XSPerfAccumulate("waitStoreCycle", deqNotWritebacked && deqUopCommitType === CommitType.STORE) 875 XSPerfAccumulate("robHeadPC", io.commits.info(0).pc) 876 val dispatchLatency = commitDebugUop.map(uop => uop.debugInfo.dispatchTime - uop.debugInfo.renameTime) 877 val enqRsLatency = commitDebugUop.map(uop => uop.debugInfo.enqRsTime - uop.debugInfo.dispatchTime) 878 val selectLatency = commitDebugUop.map(uop => uop.debugInfo.selectTime - uop.debugInfo.enqRsTime) 879 val issueLatency = commitDebugUop.map(uop => uop.debugInfo.issueTime - uop.debugInfo.selectTime) 880 val executeLatency = commitDebugUop.map(uop => uop.debugInfo.writebackTime - uop.debugInfo.issueTime) 881 val rsFuLatency = commitDebugUop.map(uop => uop.debugInfo.writebackTime - uop.debugInfo.enqRsTime) 882 val commitLatency = commitDebugUop.map(uop => timer - uop.debugInfo.writebackTime) 883 def latencySum(cond: Seq[Bool], latency: Seq[UInt]): UInt = { 884 cond.zip(latency).map(x => Mux(x._1, x._2, 0.U)).reduce(_ +& _) 885 } 886 for (fuType <- FuType.functionNameMap.keys) { 887 val fuName = FuType.functionNameMap(fuType) 888 val commitIsFuType = io.commits.valid.zip(commitDebugUop).map(x => x._1 && x._2.ctrl.fuType === fuType.U ) 889 XSPerfAccumulate(s"${fuName}_instr_cnt", ifCommit(PopCount(commitIsFuType))) 890 XSPerfAccumulate(s"${fuName}_latency_dispatch", ifCommit(latencySum(commitIsFuType, dispatchLatency))) 891 XSPerfAccumulate(s"${fuName}_latency_enq_rs", ifCommit(latencySum(commitIsFuType, enqRsLatency))) 892 XSPerfAccumulate(s"${fuName}_latency_select", ifCommit(latencySum(commitIsFuType, selectLatency))) 893 XSPerfAccumulate(s"${fuName}_latency_issue", ifCommit(latencySum(commitIsFuType, issueLatency))) 894 XSPerfAccumulate(s"${fuName}_latency_execute", ifCommit(latencySum(commitIsFuType, executeLatency))) 895 XSPerfAccumulate(s"${fuName}_latency_enq_rs_execute", ifCommit(latencySum(commitIsFuType, rsFuLatency))) 896 XSPerfAccumulate(s"${fuName}_latency_commit", ifCommit(latencySum(commitIsFuType, commitLatency))) 897 if (fuType == FuType.fmac.litValue()) { 898 val commitIsFma = commitIsFuType.zip(commitDebugUop).map(x => x._1 && x._2.ctrl.fpu.ren3 ) 899 XSPerfAccumulate(s"${fuName}_instr_cnt_fma", ifCommit(PopCount(commitIsFma))) 900 XSPerfAccumulate(s"${fuName}_latency_enq_rs_execute_fma", ifCommit(latencySum(commitIsFma, rsFuLatency))) 901 XSPerfAccumulate(s"${fuName}_latency_execute_fma", ifCommit(latencySum(commitIsFma, executeLatency))) 902 } 903 } 904 905 //difftest signals 906 val firstValidCommit = (deqPtr + PriorityMux(io.commits.valid, VecInit(List.tabulate(CommitWidth)(_.U)))).value 907 908 val wdata = Wire(Vec(CommitWidth, UInt(XLEN.W))) 909 val wpc = Wire(Vec(CommitWidth, UInt(XLEN.W))) 910 911 for(i <- 0 until CommitWidth) { 912 val idx = deqPtrVec(i).value 913 wdata(i) := debug_exuData(idx) 914 wpc(i) := SignExt(commitDebugUop(i).cf.pc, XLEN) 915 } 916 val retireCounterFix = Mux(io.exception.valid, 1.U, retireCounter) 917 val retirePCFix = SignExt(Mux(io.exception.valid, io.exception.bits.uop.cf.pc, debug_microOp(firstValidCommit).cf.pc), XLEN) 918 val retireInstFix = Mux(io.exception.valid, io.exception.bits.uop.cf.instr, debug_microOp(firstValidCommit).cf.instr) 919 920 if (env.EnableDifftest) { 921 for (i <- 0 until CommitWidth) { 922 val difftest = Module(new DifftestInstrCommit) 923 difftest.io.clock := clock 924 difftest.io.coreid := hardId.U 925 difftest.io.index := i.U 926 927 val ptr = deqPtrVec(i).value 928 val uop = commitDebugUop(i) 929 val exuOut = debug_exuDebug(ptr) 930 val exuData = debug_exuData(ptr) 931 difftest.io.valid := RegNext(io.commits.valid(i) && !io.commits.isWalk) 932 difftest.io.pc := RegNext(SignExt(uop.cf.pc, XLEN)) 933 difftest.io.instr := RegNext(uop.cf.instr) 934 difftest.io.special := RegNext(CommitType.isFused(io.commits.info(i).commitType)) 935 // when committing an eliminated move instruction, 936 // we must make sure that skip is properly set to false (output from EXU is random value) 937 difftest.io.skip := RegNext(Mux(uop.eliminatedMove, false.B, exuOut.isMMIO || exuOut.isPerfCnt)) 938 difftest.io.isRVC := RegNext(uop.cf.pd.isRVC) 939 difftest.io.scFailed := RegNext(!uop.diffTestDebugLrScValid && 940 uop.ctrl.fuType === FuType.mou && 941 (uop.ctrl.fuOpType === LSUOpType.sc_d || uop.ctrl.fuOpType === LSUOpType.sc_w)) 942 difftest.io.wen := RegNext(io.commits.valid(i) && io.commits.info(i).rfWen && io.commits.info(i).ldest =/= 0.U) 943 difftest.io.wpdest := RegNext(io.commits.info(i).pdest) 944 difftest.io.wdest := RegNext(io.commits.info(i)ldest) 945 946 // runahead commit hint 947 val runahead_commit = Module(new DifftestRunaheadCommitEvent) 948 runahead_commit.io.clock := clock 949 runahead_commit.io.coreid := hardId.U 950 runahead_commit.io.index := i.U 951 runahead_commit.io.valid := difftest.io.valid && 952 (commitBranchValid(i) || commitIsStore(i)) 953 // TODO: is branch or store 954 runahead_commit.io.pc := difftest.io.pc 955 } 956 } 957 else if (env.AlwaysBasicDiff) { 958 // These are the structures used by difftest only and should be optimized after synthesis. 959 val dt_eliminatedMove = Mem(RobSize, Bool()) 960 val dt_isRVC = Mem(RobSize, Bool()) 961 val dt_exuDebug = Reg(Vec(RobSize, new DebugBundle)) 962 for (i <- 0 until RenameWidth) { 963 when (canEnqueue(i)) { 964 dt_eliminatedMove(enqPtrVec(i).value) := io.enq.req(i).bits.eliminatedMove 965 dt_isRVC(enqPtrVec(i).value) := io.enq.req(i).bits.cf.pd.isRVC 966 } 967 } 968 for (i <- 0 until numWbPorts) { 969 when (io.exeWbResults(i).valid) { 970 val wbIdx = io.exeWbResults(i).bits.uop.robIdx.value 971 dt_exuDebug(wbIdx) := io.exeWbResults(i).bits.debug 972 } 973 } 974 // Always instantiate basic difftest modules. 975 for (i <- 0 until CommitWidth) { 976 val commitInfo = io.commits.info(i) 977 val ptr = deqPtrVec(i).value 978 val exuOut = dt_exuDebug(ptr) 979 val eliminatedMove = dt_eliminatedMove(ptr) 980 val isRVC = dt_isRVC(ptr) 981 982 val difftest = Module(new DifftestBasicInstrCommit) 983 difftest.io.clock := clock 984 difftest.io.coreid := hardId.U 985 difftest.io.index := i.U 986 difftest.io.valid := RegNext(io.commits.valid(i) && !io.commits.isWalk) 987 difftest.io.special := RegNext(CommitType.isFused(commitInfo.commitType)) 988 difftest.io.skip := RegNext(Mux(eliminatedMove, false.B, exuOut.isMMIO || exuOut.isPerfCnt)) 989 difftest.io.isRVC := RegNext(isRVC) 990 difftest.io.wen := RegNext(io.commits.valid(i) && commitInfo.rfWen && commitInfo.ldest =/= 0.U) 991 difftest.io.wpdest := RegNext(commitInfo.pdest) 992 difftest.io.wdest := RegNext(commitInfo.ldest) 993 } 994 } 995 996 if (env.EnableDifftest) { 997 for (i <- 0 until CommitWidth) { 998 val difftest = Module(new DifftestLoadEvent) 999 difftest.io.clock := clock 1000 difftest.io.coreid := hardId.U 1001 difftest.io.index := i.U 1002 1003 val ptr = deqPtrVec(i).value 1004 val uop = commitDebugUop(i) 1005 val exuOut = debug_exuDebug(ptr) 1006 difftest.io.valid := RegNext(io.commits.valid(i) && !io.commits.isWalk) 1007 difftest.io.paddr := RegNext(exuOut.paddr) 1008 difftest.io.opType := RegNext(uop.ctrl.fuOpType) 1009 difftest.io.fuType := RegNext(uop.ctrl.fuType) 1010 } 1011 } 1012 1013 // Always instantiate basic difftest modules. 1014 if (env.EnableDifftest) { 1015 val dt_isXSTrap = Mem(RobSize, Bool()) 1016 for (i <- 0 until RenameWidth) { 1017 when (canEnqueue(i)) { 1018 dt_isXSTrap(enqPtrVec(i).value) := io.enq.req(i).bits.ctrl.isXSTrap 1019 } 1020 } 1021 val trapVec = io.commits.valid.zip(deqPtrVec).map{ case (v, d) => state === s_idle && v && dt_isXSTrap(d.value) } 1022 val hitTrap = trapVec.reduce(_||_) 1023 val trapCode = PriorityMux(wdata.zip(trapVec).map(x => x._2 -> x._1)) 1024 val trapPC = SignExt(PriorityMux(wpc.zip(trapVec).map(x => x._2 ->x._1)), XLEN) 1025 val difftest = Module(new DifftestTrapEvent) 1026 difftest.io.clock := clock 1027 difftest.io.coreid := hardId.U 1028 difftest.io.valid := hitTrap 1029 difftest.io.code := trapCode 1030 difftest.io.pc := trapPC 1031 difftest.io.cycleCnt := timer 1032 difftest.io.instrCnt := instrCnt 1033 } 1034 else if (env.AlwaysBasicDiff) { 1035 val dt_isXSTrap = Mem(RobSize, Bool()) 1036 for (i <- 0 until RenameWidth) { 1037 when (canEnqueue(i)) { 1038 dt_isXSTrap(enqPtrVec(i).value) := io.enq.req(i).bits.ctrl.isXSTrap 1039 } 1040 } 1041 val trapVec = io.commits.valid.zip(deqPtrVec).map{ case (v, d) => state === s_idle && v && dt_isXSTrap(d.value) } 1042 val hitTrap = trapVec.reduce(_||_) 1043 val difftest = Module(new DifftestBasicTrapEvent) 1044 difftest.io.clock := clock 1045 difftest.io.coreid := hardId.U 1046 difftest.io.valid := hitTrap 1047 difftest.io.cycleCnt := timer 1048 difftest.io.instrCnt := instrCnt 1049 } 1050 1051 val perfinfo = IO(new Bundle(){ 1052 val perfEvents = Output(new PerfEventsBundle(18)) 1053 }) 1054 val perfEvents = Seq( 1055 ("rob_interrupt_num ", io.flushOut.valid && intrEnable ), 1056 ("rob_exception_num ", io.flushOut.valid && exceptionEnable ), 1057 ("rob_flush_pipe_num ", io.flushOut.valid && isFlushPipe ), 1058 ("rob_replay_inst_num ", io.flushOut.valid && isFlushPipe && deqHasReplayInst ), 1059 ("rob_commitUop ", ifCommit(commitCnt) ), 1060 ("rob_commitInstr ", ifCommit(trueCommitCnt) ), 1061 ("rob_commitInstrMove ", ifCommit(PopCount(io.commits.valid.zip(commitIsMove).map{ case (v, m) => v && m })) ), 1062 ("rob_commitInstrFused ", ifCommit(fuseCommitCnt) ), 1063 ("rob_commitInstrLoad ", ifCommit(PopCount(commitLoadValid)) ), 1064 ("rob_commitInstrLoad ", ifCommit(PopCount(commitBranchValid)) ), 1065 ("rob_commitInstrLoadWait ", ifCommit(PopCount(commitLoadValid.zip(commitLoadWaitBit).map{ case (v, w) => v && w })) ), 1066 ("rob_commitInstrStore ", ifCommit(PopCount(io.commits.valid.zip(commitIsStore).map{ case (v, t) => v && t })) ), 1067 ("rob_walkInstr ", Mux(io.commits.isWalk, PopCount(io.commits.valid), 0.U) ), 1068 ("rob_walkCycle ", (state === s_walk || state === s_extrawalk) ), 1069 ("rob_1/4_valid ", (PopCount((0 until RobSize).map(valid(_))) < (RobSize.U/4.U)) ), 1070 ("rob_2/4_valid ", (PopCount((0 until RobSize).map(valid(_))) > (RobSize.U/4.U)) & (PopCount((0 until RobSize).map(valid(_))) <= (RobSize.U/2.U)) ), 1071 ("rob_3/4_valid ", (PopCount((0 until RobSize).map(valid(_))) > (RobSize.U/2.U)) & (PopCount((0 until RobSize).map(valid(_))) <= (RobSize.U*3.U/4.U))), 1072 ("rob_4/4_valid ", (PopCount((0 until RobSize).map(valid(_))) > (RobSize.U*3.U/4.U)) ), 1073 ) 1074 1075 for (((perf_out,(perf_name,perf)),i) <- perfinfo.perfEvents.perf_events.zip(perfEvents).zipWithIndex) { 1076 perf_out.incr_step := RegNext(perf) 1077 } 1078} 1079