1e4f69d78Ssfencevma/*************************************************************************************** 2e4f69d78Ssfencevma* Copyright (c) 2020-2021 Institute of Computing Technology, Chinese Academy of Sciences 3e4f69d78Ssfencevma* Copyright (c) 2020-2021 Peng Cheng Laboratory 4e4f69d78Ssfencevma* 5e4f69d78Ssfencevma* XiangShan is licensed under Mulan PSL v2. 6e4f69d78Ssfencevma* You can use this software according to the terms and conditions of the Mulan PSL v2. 7e4f69d78Ssfencevma* You may obtain a copy of Mulan PSL v2 at: 8e4f69d78Ssfencevma* http://license.coscl.org.cn/MulanPSL2 9e4f69d78Ssfencevma* 10e4f69d78Ssfencevma* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND, 11e4f69d78Ssfencevma* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT, 12e4f69d78Ssfencevma* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE. 13e4f69d78Ssfencevma* 14e4f69d78Ssfencevma* See the Mulan PSL v2 for more details. 15e4f69d78Ssfencevma***************************************************************************************/ 16e4f69d78Ssfencevma 17e4f69d78Ssfencevmapackage xiangshan.mem 18e4f69d78Ssfencevma 19e4f69d78Ssfencevmaimport chisel3._ 20e4f69d78Ssfencevmaimport chisel3.util._ 21e4f69d78Ssfencevmaimport chipsalliance.rocketchip.config._ 22e4f69d78Ssfencevmaimport xiangshan._ 23e4f69d78Ssfencevmaimport xiangshan.backend.rob.RobPtr 24e4f69d78Ssfencevmaimport xiangshan.cache._ 25e4f69d78Ssfencevmaimport xiangshan.frontend.FtqPtr 26e4f69d78Ssfencevmaimport xiangshan.mem.mdp._ 27e4f69d78Ssfencevmaimport utils._ 28e4f69d78Ssfencevmaimport utility._ 29e4f69d78Ssfencevma 30e4f69d78Ssfencevmaclass LoadQueueRAW(implicit p: Parameters) extends XSModule 31e4f69d78Ssfencevma with HasDCacheParameters 32e4f69d78Ssfencevma with HasCircularQueuePtrHelper 33e4f69d78Ssfencevma with HasLoadHelper 34e4f69d78Ssfencevma with HasPerfEvents 35e4f69d78Ssfencevma{ 36e4f69d78Ssfencevma val io = IO(new Bundle() { 37e4f69d78Ssfencevma val redirect = Flipped(ValidIO(new Redirect)) 38e4f69d78Ssfencevma val query = Vec(LoadPipelineWidth, Flipped(new LoadViolationQueryIO)) 39e4f69d78Ssfencevma val storeIn = Vec(StorePipelineWidth, Flipped(Valid(new LsPipelineBundle))) 40e4f69d78Ssfencevma val rollback = Output(Valid(new Redirect)) 41e4f69d78Ssfencevma val stAddrReadySqPtr = Input(new SqPtr) 42e4f69d78Ssfencevma val stIssuePtr = Input(new SqPtr) 43e4f69d78Ssfencevma val lqFull = Output(Bool()) 44e4f69d78Ssfencevma }) 45e4f69d78Ssfencevma 46e4f69d78Ssfencevma println("LoadQueueRAW: size " + LoadQueueRAWSize) 47e4f69d78Ssfencevma // LoadQueueRAW field 48e4f69d78Ssfencevma // +-------+--------+-------+-------+-----------+ 49e4f69d78Ssfencevma // | Valid | uop |PAddr | Mask | Datavalid | 50e4f69d78Ssfencevma // +-------+--------+-------+-------+-----------+ 51e4f69d78Ssfencevma // 52e4f69d78Ssfencevma // Field descriptions: 53e4f69d78Ssfencevma // Allocated : entry has been allocated already 54e4f69d78Ssfencevma // MicroOp : inst's microOp 55e4f69d78Ssfencevma // PAddr : physical address. 56e4f69d78Ssfencevma // Mask : data mask 57e4f69d78Ssfencevma // Datavalid : data valid 58e4f69d78Ssfencevma // 59e4f69d78Ssfencevma val allocated = RegInit(VecInit(List.fill(LoadQueueRAWSize)(false.B))) // The control signals need to explicitly indicate the initial value 60e4f69d78Ssfencevma val uop = Reg(Vec(LoadQueueRAWSize, new MicroOp)) 61e4f69d78Ssfencevma val paddrModule = Module(new LqPAddrModule( 62e4f69d78Ssfencevma gen = UInt(PAddrBits.W), 63e4f69d78Ssfencevma numEntries = LoadQueueRAWSize, 64e4f69d78Ssfencevma numRead = LoadPipelineWidth, 65e4f69d78Ssfencevma numWrite = LoadPipelineWidth, 66e4f69d78Ssfencevma numWBank = LoadQueueNWriteBanks, 67e4f69d78Ssfencevma numWDelay = 2, 68e4f69d78Ssfencevma numCamPort = StorePipelineWidth 69e4f69d78Ssfencevma )) 70e4f69d78Ssfencevma paddrModule.io := DontCare 71e4f69d78Ssfencevma val maskModule = Module(new LqMaskModule( 72e4f69d78Ssfencevma gen = UInt(8.W), 73e4f69d78Ssfencevma numEntries = LoadQueueRAWSize, 74e4f69d78Ssfencevma numRead = LoadPipelineWidth, 75e4f69d78Ssfencevma numWrite = LoadPipelineWidth, 76e4f69d78Ssfencevma numWBank = LoadQueueNWriteBanks, 77e4f69d78Ssfencevma numWDelay = 2, 78e4f69d78Ssfencevma numCamPort = StorePipelineWidth 79e4f69d78Ssfencevma )) 80e4f69d78Ssfencevma maskModule.io := DontCare 81e4f69d78Ssfencevma val datavalid = RegInit(VecInit(List.fill(LoadQueueRAWSize)(false.B))) 82e4f69d78Ssfencevma 83e4f69d78Ssfencevma // freeliset: store valid entries index. 84e4f69d78Ssfencevma // +---+---+--------------+-----+-----+ 85e4f69d78Ssfencevma // | 0 | 1 | ...... | n-2 | n-1 | 86e4f69d78Ssfencevma // +---+---+--------------+-----+-----+ 87e4f69d78Ssfencevma val freeList = Module(new FreeList( 88e4f69d78Ssfencevma size = LoadQueueRAWSize, 89e4f69d78Ssfencevma allocWidth = LoadPipelineWidth, 90e4f69d78Ssfencevma freeWidth = 4, 91e4f69d78Ssfencevma moduleName = "LoadQueueRAW freelist" 92e4f69d78Ssfencevma )) 93e4f69d78Ssfencevma freeList.io := DontCare 94e4f69d78Ssfencevma 95e4f69d78Ssfencevma // LoadQueueRAW enqueue 96e4f69d78Ssfencevma val canEnqueue = io.query.map(_.req.valid) 97e4f69d78Ssfencevma val cancelEnqueue = io.query.map(_.req.bits.uop.robIdx.needFlush(io.redirect)) 98e4f69d78Ssfencevma val allAddrCheck = io.stIssuePtr === io.stAddrReadySqPtr 99e4f69d78Ssfencevma val hasAddrInvalidStore = io.query.map(_.req.bits.uop.sqIdx).map(sqIdx => { 100e4f69d78Ssfencevma Mux(!allAddrCheck, isBefore(io.stAddrReadySqPtr, sqIdx), false.B) 101e4f69d78Ssfencevma }) 102e4f69d78Ssfencevma val needEnqueue = canEnqueue.zip(hasAddrInvalidStore).zip(cancelEnqueue).map { case ((v, r), c) => v && r && !c } 103e4f69d78Ssfencevma val bypassPAddr = Reg(Vec(LoadPipelineWidth, UInt(PAddrBits.W))) 104e4f69d78Ssfencevma val bypassMask = Reg(Vec(LoadPipelineWidth, UInt(8.W))) 105e4f69d78Ssfencevma 106e4f69d78Ssfencevma // Allocate logic 107e4f69d78Ssfencevma val enqValidVec = Wire(Vec(LoadPipelineWidth, Bool())) 108e4f69d78Ssfencevma val enqIndexVec = Wire(Vec(LoadPipelineWidth, UInt())) 109e4f69d78Ssfencevma 110e4f69d78Ssfencevma // Enqueue 111e4f69d78Ssfencevma for ((enq, w) <- io.query.map(_.req).zipWithIndex) { 112e4f69d78Ssfencevma paddrModule.io.wen(w) := false.B 113e4f69d78Ssfencevma maskModule.io.wen(w) := false.B 114e4f69d78Ssfencevma freeList.io.doAllocate(w) := false.B 115e4f69d78Ssfencevma 116e4f69d78Ssfencevma freeList.io.allocateReq(w) := needEnqueue(w) 117e4f69d78Ssfencevma 118e4f69d78Ssfencevma // Allocate ready 119*bd65812fSsfencevma enqValidVec(w) := freeList.io.canAllocate(w) 120*bd65812fSsfencevma enqIndexVec(w) := freeList.io.allocateSlot(w) 121e4f69d78Ssfencevma enq.ready := Mux(needEnqueue(w), enqValidVec(w), true.B) 122e4f69d78Ssfencevma 123e4f69d78Ssfencevma val enqIndex = enqIndexVec(w) 124e4f69d78Ssfencevma when (needEnqueue(w) && enq.ready) { 125e4f69d78Ssfencevma val debug_robIdx = enq.bits.uop.robIdx.asUInt 126e4f69d78Ssfencevma XSError(allocated(enqIndex), p"LoadQueueRAW: You can not write an valid entry! check: ldu $w, robIdx $debug_robIdx") 127e4f69d78Ssfencevma 128e4f69d78Ssfencevma freeList.io.doAllocate(w) := true.B 129e4f69d78Ssfencevma 130e4f69d78Ssfencevma // Allocate new entry 131e4f69d78Ssfencevma allocated(enqIndex) := true.B 132e4f69d78Ssfencevma 133e4f69d78Ssfencevma // Write paddr 134e4f69d78Ssfencevma paddrModule.io.wen(w) := true.B 135e4f69d78Ssfencevma paddrModule.io.waddr(w) := enqIndex 136e4f69d78Ssfencevma paddrModule.io.wdata(w) := enq.bits.paddr 137e4f69d78Ssfencevma bypassPAddr(w) := enq.bits.paddr 138e4f69d78Ssfencevma 139e4f69d78Ssfencevma // Write mask 140e4f69d78Ssfencevma maskModule.io.wen(w) := true.B 141e4f69d78Ssfencevma maskModule.io.waddr(w) := enqIndex 142e4f69d78Ssfencevma maskModule.io.wdata(w) := enq.bits.mask 143e4f69d78Ssfencevma bypassMask(w) := enq.bits.mask 144e4f69d78Ssfencevma 145e4f69d78Ssfencevma // Fill info 146e4f69d78Ssfencevma uop(enqIndex) := enq.bits.uop 147e4f69d78Ssfencevma datavalid(enqIndex) := enq.bits.datavalid 148e4f69d78Ssfencevma } 149e4f69d78Ssfencevma } 150e4f69d78Ssfencevma 151e4f69d78Ssfencevma for ((query, w) <- io.query.map(_.resp).zipWithIndex) { 152e4f69d78Ssfencevma query.valid := RegNext(io.query(w).req.valid) 153e4f69d78Ssfencevma query.bits.replayFromFetch := RegNext(false.B) 154e4f69d78Ssfencevma } 155e4f69d78Ssfencevma 156e4f69d78Ssfencevma // LoadQueueRAW deallocate 157e4f69d78Ssfencevma val freeMaskVec = Wire(Vec(LoadQueueRAWSize, Bool())) 158e4f69d78Ssfencevma 159e4f69d78Ssfencevma // init 160e4f69d78Ssfencevma freeMaskVec.map(e => e := false.B) 161e4f69d78Ssfencevma 162e4f69d78Ssfencevma // when the stores that "older than" current load address were ready. 163e4f69d78Ssfencevma // current load will be released. 164e4f69d78Ssfencevma for (i <- 0 until LoadQueueRAWSize) { 165e4f69d78Ssfencevma val deqNotBlock = Mux(!allAddrCheck, !isBefore(io.stAddrReadySqPtr, uop(i).sqIdx), true.B) 166e4f69d78Ssfencevma val needCancel = uop(i).robIdx.needFlush(io.redirect) 167e4f69d78Ssfencevma 168e4f69d78Ssfencevma when (allocated(i) && (deqNotBlock || needCancel)) { 169e4f69d78Ssfencevma allocated(i) := false.B 170e4f69d78Ssfencevma freeMaskVec(i) := true.B 171e4f69d78Ssfencevma } 172e4f69d78Ssfencevma } 173e4f69d78Ssfencevma 174e4f69d78Ssfencevma // if need replay deallocate entry 175e4f69d78Ssfencevma val lastCanAccept = RegNext(VecInit(needEnqueue.zip(enqValidVec).map(x => x._1 && x._2))) 176e4f69d78Ssfencevma val lastAllocIndex = RegNext(enqIndexVec) 177e4f69d78Ssfencevma 178e4f69d78Ssfencevma for ((release, w) <- io.query.map(_.release).zipWithIndex) { 179e4f69d78Ssfencevma val releaseValid = release && lastCanAccept(w) 180e4f69d78Ssfencevma val releaseIndex = lastAllocIndex(w) 181e4f69d78Ssfencevma 182e4f69d78Ssfencevma when (allocated(releaseIndex) && releaseValid) { 183e4f69d78Ssfencevma allocated(releaseIndex) := false.B 184e4f69d78Ssfencevma freeMaskVec(releaseIndex) := true.B 185e4f69d78Ssfencevma } 186e4f69d78Ssfencevma } 187e4f69d78Ssfencevma freeList.io.free := freeMaskVec.asUInt 188e4f69d78Ssfencevma 189e4f69d78Ssfencevma io.lqFull := freeList.io.empty 190e4f69d78Ssfencevma 191e4f69d78Ssfencevma /** 192e4f69d78Ssfencevma * Store-Load Memory violation detection 193e4f69d78Ssfencevma * Scheme 1(Current scheme): flush the pipeline then re-fetch from the load instruction (like old load queue). 194e4f69d78Ssfencevma * Scheme 2 : re-fetch instructions from the first instruction after the store instruction. 195e4f69d78Ssfencevma * 196e4f69d78Ssfencevma * When store writes back, it searches LoadQueue for younger load instructions 197e4f69d78Ssfencevma * with the same load physical address. They loaded wrong data and need re-execution. 198e4f69d78Ssfencevma * 199e4f69d78Ssfencevma * Cycle 0: Store Writeback 200e4f69d78Ssfencevma * Generate match vector for store address with rangeMask(stPtr, enqPtr). 201e4f69d78Ssfencevma * Cycle 1: Select oldest load from select group. 202e4f69d78Ssfencevma * Cycle x: Redirect Fire 203e4f69d78Ssfencevma * Choose the oldest load from LoadPipelineWidth oldest loads. 204e4f69d78Ssfencevma * Prepare redirect request according to the detected violation. 205e4f69d78Ssfencevma * Fire redirect request (if valid) 206e4f69d78Ssfencevma */ 207e4f69d78Ssfencevma // SelectGroup 0 SelectGroup 1 SelectGroup y 208e4f69d78Ssfencevma // stage 0: lq lq lq ...... lq lq lq ....... lq lq lq 209e4f69d78Ssfencevma // | | | | | | | | | 210e4f69d78Ssfencevma // stage 1: lq lq lq ...... lq lq lq ....... lq lq lq 211e4f69d78Ssfencevma // \ | / ...... \ | / ....... \ | / 212e4f69d78Ssfencevma // stage 2: lq lq lq 213e4f69d78Ssfencevma // \ | / ....... \ | / ........ \ | / 214e4f69d78Ssfencevma // stage 3: lq lq lq 215e4f69d78Ssfencevma // ... 216e4f69d78Ssfencevma // ... 217e4f69d78Ssfencevma // | 218e4f69d78Ssfencevma // stage x: lq 219e4f69d78Ssfencevma // | 220e4f69d78Ssfencevma // rollback req 221e4f69d78Ssfencevma 222e4f69d78Ssfencevma // select logic 223e4f69d78Ssfencevma val SelectGroupSize = RollbackGroupSize 224e4f69d78Ssfencevma val lgSelectGroupSize = log2Ceil(SelectGroupSize) 225e4f69d78Ssfencevma val TotalSelectCycles = scala.math.ceil(log2Ceil(LoadQueueRAWSize).toFloat / lgSelectGroupSize).toInt + 1 226e4f69d78Ssfencevma 227e4f69d78Ssfencevma def selectPartialOldest[T <: XSBundleWithMicroOp](valid: Seq[Bool], bits: Seq[T]): (Seq[Bool], Seq[T]) = { 228e4f69d78Ssfencevma assert(valid.length == bits.length) 229e4f69d78Ssfencevma if (valid.length == 0 || valid.length == 1) { 230e4f69d78Ssfencevma (valid, bits) 231e4f69d78Ssfencevma } else if (valid.length == 2) { 232e4f69d78Ssfencevma val res = Seq.fill(2)(Wire(ValidIO(chiselTypeOf(bits(0))))) 233e4f69d78Ssfencevma for (i <- res.indices) { 234e4f69d78Ssfencevma res(i).valid := valid(i) 235e4f69d78Ssfencevma res(i).bits := bits(i) 236e4f69d78Ssfencevma } 237e4f69d78Ssfencevma val oldest = Mux(valid(0) && valid(1), Mux(isAfter(bits(0).uop.robIdx, bits(1).uop.robIdx), res(1), res(0)), Mux(valid(0) && !valid(1), res(0), res(1))) 238e4f69d78Ssfencevma (Seq(oldest.valid), Seq(oldest.bits)) 239e4f69d78Ssfencevma } else { 240e4f69d78Ssfencevma val left = selectPartialOldest(valid.take(valid.length / 2), bits.take(bits.length / 2)) 241e4f69d78Ssfencevma val right = selectPartialOldest(valid.takeRight(valid.length - (valid.length / 2)), bits.takeRight(bits.length - (bits.length / 2))) 242e4f69d78Ssfencevma selectPartialOldest(left._1 ++ right._1, left._2 ++ right._2) 243e4f69d78Ssfencevma } 244e4f69d78Ssfencevma } 245e4f69d78Ssfencevma 246e4f69d78Ssfencevma def selectOldest[T <: XSBundleWithMicroOp](valid: Seq[Bool], bits: Seq[T]): (Seq[Bool], Seq[T]) = { 247e4f69d78Ssfencevma assert(valid.length == bits.length) 248e4f69d78Ssfencevma val numSelectGroups = scala.math.ceil(valid.length.toFloat / SelectGroupSize).toInt 249e4f69d78Ssfencevma 250e4f69d78Ssfencevma // group info 251e4f69d78Ssfencevma val selectValidGroups = 252e4f69d78Ssfencevma if (valid.length <= SelectGroupSize) { 253e4f69d78Ssfencevma Seq(valid) 254e4f69d78Ssfencevma } else { 255e4f69d78Ssfencevma (0 until numSelectGroups).map(g => { 256e4f69d78Ssfencevma if (valid.length < (g + 1) * SelectGroupSize) { 257e4f69d78Ssfencevma valid.takeRight(valid.length - g * SelectGroupSize) 258e4f69d78Ssfencevma } else { 259e4f69d78Ssfencevma (0 until SelectGroupSize).map(j => valid(g * SelectGroupSize + j)) 260e4f69d78Ssfencevma } 261e4f69d78Ssfencevma }) 262e4f69d78Ssfencevma } 263e4f69d78Ssfencevma val selectBitsGroups = 264e4f69d78Ssfencevma if (bits.length <= SelectGroupSize) { 265e4f69d78Ssfencevma Seq(bits) 266e4f69d78Ssfencevma } else { 267e4f69d78Ssfencevma (0 until numSelectGroups).map(g => { 268e4f69d78Ssfencevma if (bits.length < (g + 1) * SelectGroupSize) { 269e4f69d78Ssfencevma bits.takeRight(bits.length - g * SelectGroupSize) 270e4f69d78Ssfencevma } else { 271e4f69d78Ssfencevma (0 until SelectGroupSize).map(j => bits(g * SelectGroupSize + j)) 272e4f69d78Ssfencevma } 273e4f69d78Ssfencevma }) 274e4f69d78Ssfencevma } 275e4f69d78Ssfencevma 276e4f69d78Ssfencevma // select logic 277e4f69d78Ssfencevma if (valid.length <= SelectGroupSize) { 278e4f69d78Ssfencevma val (selValid, selBits) = selectPartialOldest(valid, bits) 279e4f69d78Ssfencevma (Seq(RegNext(selValid(0) && !selBits(0).uop.robIdx.needFlush(io.redirect))), Seq(RegNext(selBits(0)))) 280e4f69d78Ssfencevma } else { 281e4f69d78Ssfencevma val select = (0 until numSelectGroups).map(g => { 282e4f69d78Ssfencevma val (selValid, selBits) = selectPartialOldest(selectValidGroups(g), selectBitsGroups(g)) 283e4f69d78Ssfencevma (RegNext(selValid(0) && !selBits(0).uop.robIdx.needFlush(io.redirect)), RegNext(selBits(0))) 284e4f69d78Ssfencevma }) 285e4f69d78Ssfencevma selectOldest(select.map(_._1), select.map(_._2)) 286e4f69d78Ssfencevma } 287e4f69d78Ssfencevma } 288e4f69d78Ssfencevma 289e4f69d78Ssfencevma def detectRollback(i: Int) = { 290e4f69d78Ssfencevma paddrModule.io.violationMdata(i) := io.storeIn(i).bits.paddr 291e4f69d78Ssfencevma maskModule.io.violationMdata(i) := io.storeIn(i).bits.mask 292e4f69d78Ssfencevma 293e4f69d78Ssfencevma val bypassPaddrMask = RegNext(VecInit((0 until LoadPipelineWidth).map(j => bypassPAddr(j)(PAddrBits-1, 3) === io.storeIn(i).bits.paddr(PAddrBits-1, 3)))) 294e4f69d78Ssfencevma val bypassMMask = RegNext(VecInit((0 until LoadPipelineWidth).map(j => (bypassMask(j) & io.storeIn(i).bits.mask).orR))) 295e4f69d78Ssfencevma val bypassMaskUInt = (0 until LoadPipelineWidth).map(j => 296e4f69d78Ssfencevma Fill(LoadQueueRAWSize, RegNext(RegNext(io.query(j).req.fire))) & Mux(bypassPaddrMask(j) && bypassMMask(j), UIntToOH(RegNext(RegNext(enqIndexVec(j)))), 0.U(LoadQueueRAWSize)) 297e4f69d78Ssfencevma ).reduce(_|_) 298e4f69d78Ssfencevma 299e4f69d78Ssfencevma val addrMaskMatch = RegNext(paddrModule.io.violationMmask(i).asUInt & maskModule.io.violationMmask(i).asUInt) | bypassMaskUInt 300e4f69d78Ssfencevma val entryNeedCheck = RegNext(VecInit((0 until LoadQueueRAWSize).map(j => { 301e4f69d78Ssfencevma allocated(j) && isAfter(uop(j).robIdx, io.storeIn(i).bits.uop.robIdx) && datavalid(j) && !uop(j).robIdx.needFlush(io.redirect) 302e4f69d78Ssfencevma }))) 303e4f69d78Ssfencevma val lqViolationSelVec = VecInit((0 until LoadQueueRAWSize).map(j => { 304e4f69d78Ssfencevma addrMaskMatch(j) && entryNeedCheck(j) 305e4f69d78Ssfencevma })) 306e4f69d78Ssfencevma 307e4f69d78Ssfencevma val lqViolationSelUopExts = uop.map(uop => { 308e4f69d78Ssfencevma val wrapper = Wire(new XSBundleWithMicroOp) 309e4f69d78Ssfencevma wrapper.uop := uop 310e4f69d78Ssfencevma wrapper 311e4f69d78Ssfencevma }) 312e4f69d78Ssfencevma 313e4f69d78Ssfencevma // select logic 314e4f69d78Ssfencevma val lqSelect = selectOldest(lqViolationSelVec, lqViolationSelUopExts) 315e4f69d78Ssfencevma 316e4f69d78Ssfencevma // select one inst 317e4f69d78Ssfencevma val lqViolation = lqSelect._1(0) 318e4f69d78Ssfencevma val lqViolationUop = lqSelect._2(0).uop 319e4f69d78Ssfencevma 320e4f69d78Ssfencevma XSDebug( 321e4f69d78Ssfencevma lqViolation, 322e4f69d78Ssfencevma "need rollback (ld wb before store) pc %x robidx %d target %x\n", 323e4f69d78Ssfencevma io.storeIn(i).bits.uop.cf.pc, io.storeIn(i).bits.uop.robIdx.asUInt, lqViolationUop.robIdx.asUInt 324e4f69d78Ssfencevma ) 325e4f69d78Ssfencevma 326e4f69d78Ssfencevma (lqViolation, lqViolationUop) 327e4f69d78Ssfencevma } 328e4f69d78Ssfencevma 329e4f69d78Ssfencevma // select rollback (part1) and generate rollback request 330e4f69d78Ssfencevma // rollback check 331e4f69d78Ssfencevma // Lq rollback seq check is done in s3 (next stage), as getting rollbackLq MicroOp is slow 332e4f69d78Ssfencevma val rollbackLqWb = Wire(Vec(StorePipelineWidth, Valid(new MicroOpRbExt))) 333e4f69d78Ssfencevma val stFtqIdx = Wire(Vec(StorePipelineWidth, new FtqPtr)) 334e4f69d78Ssfencevma val stFtqOffset = Wire(Vec(StorePipelineWidth, UInt(log2Up(PredictWidth).W))) 335e4f69d78Ssfencevma for (w <- 0 until StorePipelineWidth) { 336e4f69d78Ssfencevma val detectedRollback = detectRollback(w) 337e4f69d78Ssfencevma rollbackLqWb(w).valid := detectedRollback._1 && DelayN(io.storeIn(w).valid && !io.storeIn(w).bits.miss, TotalSelectCycles) 338e4f69d78Ssfencevma rollbackLqWb(w).bits.uop := detectedRollback._2 339e4f69d78Ssfencevma rollbackLqWb(w).bits.flag := w.U 340e4f69d78Ssfencevma stFtqIdx(w) := DelayN(io.storeIn(w).bits.uop.cf.ftqPtr, TotalSelectCycles) 341e4f69d78Ssfencevma stFtqOffset(w) := DelayN(io.storeIn(w).bits.uop.cf.ftqOffset, TotalSelectCycles) 342e4f69d78Ssfencevma } 343e4f69d78Ssfencevma 344e4f69d78Ssfencevma val rollbackLqWbValid = rollbackLqWb.map(x => x.valid && !x.bits.uop.robIdx.needFlush(io.redirect)) 345e4f69d78Ssfencevma val rollbackLqWbBits = rollbackLqWb.map(x => x.bits) 346e4f69d78Ssfencevma 347e4f69d78Ssfencevma // select rollback (part2), generate rollback request, then fire rollback request 348e4f69d78Ssfencevma // Note that we use robIdx - 1.U to flush the load instruction itself. 349e4f69d78Ssfencevma // Thus, here if last cycle's robIdx equals to this cycle's robIdx, it still triggers the redirect. 350e4f69d78Ssfencevma 351e4f69d78Ssfencevma // select uop in parallel 352e4f69d78Ssfencevma val lqs = selectPartialOldest(rollbackLqWbValid, rollbackLqWbBits) 353e4f69d78Ssfencevma val rollbackUopExt = lqs._2(0) 354e4f69d78Ssfencevma val rollbackUop = rollbackUopExt.uop 355e4f69d78Ssfencevma val rollbackStFtqIdx = stFtqIdx(rollbackUopExt.flag) 356e4f69d78Ssfencevma val rollbackStFtqOffset = stFtqOffset(rollbackUopExt.flag) 357e4f69d78Ssfencevma 358e4f69d78Ssfencevma // check if rollback request is still valid in parallel 359d2b20d1aSTang Haojin io.rollback.bits := DontCare 360e4f69d78Ssfencevma io.rollback.bits.robIdx := rollbackUop.robIdx 361e4f69d78Ssfencevma io.rollback.bits.ftqIdx := rollbackUop.cf.ftqPtr 362e4f69d78Ssfencevma io.rollback.bits.stFtqIdx := rollbackStFtqIdx 363e4f69d78Ssfencevma io.rollback.bits.ftqOffset := rollbackUop.cf.ftqOffset 364e4f69d78Ssfencevma io.rollback.bits.stFtqOffset := rollbackStFtqOffset 365e4f69d78Ssfencevma io.rollback.bits.level := RedirectLevel.flush 366e4f69d78Ssfencevma io.rollback.bits.interrupt := DontCare 367e4f69d78Ssfencevma io.rollback.bits.cfiUpdate := DontCare 368e4f69d78Ssfencevma io.rollback.bits.cfiUpdate.target := rollbackUop.cf.pc 369e4f69d78Ssfencevma io.rollback.bits.debug_runahead_checkpoint_id := rollbackUop.debugInfo.runahead_checkpoint_id 370e4f69d78Ssfencevma // io.rollback.bits.pc := DontCare 371e4f69d78Ssfencevma 372e4f69d78Ssfencevma io.rollback.valid := VecInit(rollbackLqWbValid).asUInt.orR 373e4f69d78Ssfencevma 374e4f69d78Ssfencevma // perf cnt 375e4f69d78Ssfencevma val canEnqCount = PopCount(io.query.map(_.req.fire)) 376e4f69d78Ssfencevma val validCount = freeList.io.validCount 377e4f69d78Ssfencevma val allowEnqueue = validCount <= (LoadQueueRAWSize - LoadPipelineWidth).U 378e4f69d78Ssfencevma 379e4f69d78Ssfencevma QueuePerf(LoadQueueRAWSize, validCount, !allowEnqueue) 380e4f69d78Ssfencevma XSPerfAccumulate("enqs", canEnqCount) 381e4f69d78Ssfencevma XSPerfAccumulate("stld_rollback", io.rollback.valid) 382e4f69d78Ssfencevma val perfEvents: Seq[(String, UInt)] = Seq( 383e4f69d78Ssfencevma ("enq ", canEnqCount), 384e4f69d78Ssfencevma ("stld_rollback", io.rollback.valid), 385e4f69d78Ssfencevma ) 386e4f69d78Ssfencevma generatePerfEvent() 387e4f69d78Ssfencevma // end 388e4f69d78Ssfencevma}