/*************************************************************************************** * Copyright (c) 2020-2021 Institute of Computing Technology, Chinese Academy of Sciences * Copyright (c) 2020-2021 Peng Cheng Laboratory * * XiangShan is licensed under Mulan PSL v2. * You can use this software according to the terms and conditions of the Mulan PSL v2. * You may obtain a copy of Mulan PSL v2 at: * http://license.coscl.org.cn/MulanPSL2 * * THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND, * EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT, * MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE. * * See the Mulan PSL v2 for more details. ***************************************************************************************/ package xiangshan.mem import org.chipsalliance.cde.config.Parameters import chisel3._ import chisel3.util._ import utils._ import utility._ import xiangshan._ import xiangshan.ExceptionNO._ import xiangshan.backend.Bundles.{DynInst, MemExuInput, MemExuOutput} import xiangshan.backend.fu.PMPRespBundle import xiangshan.backend.fu.FuConfig._ import xiangshan.backend.fu.FuType import xiangshan.backend.ctrlblock.{DebugLsInfoBundle, LsTopdownInfo} import xiangshan.backend.rob.RobPtr import xiangshan.backend.ctrlblock.DebugLsInfoBundle import xiangshan.backend.fu.NewCSR._ import xiangshan.backend.fu.util.SdtrigExt import xiangshan.mem.mdp._ import xiangshan.mem.Bundles._ import xiangshan.cache._ import xiangshan.cache.wpu.ReplayCarry import xiangshan.cache.mmu._ class LoadToLsqReplayIO(implicit p: Parameters) extends XSBundle with HasDCacheParameters with HasTlbConst { // mshr refill index val mshr_id = UInt(log2Up(cfg.nMissEntries).W) // get full data from store queue and sbuffer val full_fwd = Bool() // wait for data from store inst's store queue index val data_inv_sq_idx = new SqPtr // wait for address from store queue index val addr_inv_sq_idx = new SqPtr // replay carry val rep_carry = new ReplayCarry(nWays) // data in last beat val last_beat = Bool() // replay cause val cause = Vec(LoadReplayCauses.allCauses, Bool()) // performance debug information val debug = new PerfDebugInfo // tlb hint val tlb_id = UInt(log2Up(loadfiltersize).W) val tlb_full = Bool() // alias def mem_amb = cause(LoadReplayCauses.C_MA) def tlb_miss = cause(LoadReplayCauses.C_TM) def fwd_fail = cause(LoadReplayCauses.C_FF) def dcache_rep = cause(LoadReplayCauses.C_DR) def dcache_miss = cause(LoadReplayCauses.C_DM) def wpu_fail = cause(LoadReplayCauses.C_WF) def bank_conflict = cause(LoadReplayCauses.C_BC) def rar_nack = cause(LoadReplayCauses.C_RAR) def raw_nack = cause(LoadReplayCauses.C_RAW) def misalign_nack = cause(LoadReplayCauses.C_MF) def nuke = cause(LoadReplayCauses.C_NK) def need_rep = cause.asUInt.orR } class LoadToLsqIO(implicit p: Parameters) extends XSBundle { // ldu -> lsq UncacheBuffer val ldin = DecoupledIO(new LqWriteBundle) // uncache-mmio -> ldu val uncache = Flipped(DecoupledIO(new MemExuOutput)) val ld_raw_data = Input(new LoadDataFromLQBundle) // uncache-nc -> ldu val nc_ldin = Flipped(DecoupledIO(new LsPipelineBundle)) // storequeue -> ldu val forward = new PipeLoadForwardQueryIO // ldu -> lsq LQRAW val stld_nuke_query = new LoadNukeQueryIO // ldu -> lsq LQRAR val ldld_nuke_query = new LoadNukeQueryIO } class LoadToLoadIO(implicit p: Parameters) extends XSBundle { val valid = Bool() val data = UInt(XLEN.W) // load to load fast path is limited to ld (64 bit) used as vaddr src1 only val dly_ld_err = Bool() } class LoadUnitTriggerIO(implicit p: Parameters) extends XSBundle { val tdata2 = Input(UInt(64.W)) val matchType = Input(UInt(2.W)) val tEnable = Input(Bool()) // timing is calculated before this val addrHit = Output(Bool()) } class LoadUnit(implicit p: Parameters) extends XSModule with HasLoadHelper with HasPerfEvents with HasDCacheParameters with HasCircularQueuePtrHelper with HasVLSUParameters with SdtrigExt { val io = IO(new Bundle() { // control val redirect = Flipped(ValidIO(new Redirect)) val csrCtrl = Flipped(new CustomCSRCtrlIO) // int issue path val ldin = Flipped(Decoupled(new MemExuInput)) val ldout = Decoupled(new MemExuOutput) // vec issue path val vecldin = Flipped(Decoupled(new VecPipeBundle)) val vecldout = Decoupled(new VecPipelineFeedbackIO(isVStore = false)) // misalignBuffer issue path val misalign_ldin = Flipped(Decoupled(new LsPipelineBundle)) val misalign_ldout = Valid(new LqWriteBundle) // data path val tlb = new TlbRequestIO(2) val pmp = Flipped(new PMPRespBundle()) // arrive same to tlb now val dcache = new DCacheLoadIO val sbuffer = new LoadForwardQueryIO val ubuffer = new LoadForwardQueryIO val lsq = new LoadToLsqIO val tl_d_channel = Input(new DcacheToLduForwardIO) val forward_mshr = Flipped(new LduToMissqueueForwardIO) // val refill = Flipped(ValidIO(new Refill)) val l2_hint = Input(Valid(new L2ToL1Hint)) val tlb_hint = Flipped(new TlbHintReq) // fast wakeup // TODO: implement vector fast wakeup val fast_uop = ValidIO(new DynInst) // early wakeup signal generated in load_s1, send to RS in load_s2 // trigger val fromCsrTrigger = Input(new CsrTriggerBundle) // prefetch val prefetch_train = ValidIO(new LdPrefetchTrainBundle()) // provide prefetch info to sms val prefetch_train_l1 = ValidIO(new LdPrefetchTrainBundle()) // provide prefetch info to stream & stride // speculative for gated control val s1_prefetch_spec = Output(Bool()) val s2_prefetch_spec = Output(Bool()) val prefetch_req = Flipped(ValidIO(new L1PrefetchReq)) // hardware prefetch to l1 cache req val canAcceptLowConfPrefetch = Output(Bool()) val canAcceptHighConfPrefetch = Output(Bool()) // ifetchPrefetch val ifetchPrefetch = ValidIO(new SoftIfetchPrefetchBundle) // load to load fast path val l2l_fwd_in = Input(new LoadToLoadIO) val l2l_fwd_out = Output(new LoadToLoadIO) val ld_fast_match = Input(Bool()) val ld_fast_fuOpType = Input(UInt()) val ld_fast_imm = Input(UInt(12.W)) // rs feedback val wakeup = ValidIO(new DynInst) val feedback_fast = ValidIO(new RSFeedback) // stage 2 val feedback_slow = ValidIO(new RSFeedback) // stage 3 val ldCancel = Output(new LoadCancelIO()) // use to cancel the uops waked by this load, and cancel load // load ecc error val s3_dly_ld_err = Output(Bool()) // Note that io.s3_dly_ld_err and io.lsq.s3_dly_ld_err is different // schedule error query val stld_nuke_query = Flipped(Vec(StorePipelineWidth, Valid(new StoreNukeQueryIO))) // queue-based replay val replay = Flipped(Decoupled(new LsPipelineBundle)) val lq_rep_full = Input(Bool()) // misc val s2_ptr_chasing = Output(Bool()) // provide right pc for hw prefetch // Load fast replay path val fast_rep_in = Flipped(Decoupled(new LqWriteBundle)) val fast_rep_out = Decoupled(new LqWriteBundle) // to misalign buffer val misalign_buf = Decoupled(new LqWriteBundle) // Load RAR rollback val rollback = Valid(new Redirect) // perf val debug_ls = Output(new DebugLsInfoBundle) val lsTopdownInfo = Output(new LsTopdownInfo) val correctMissTrain = Input(Bool()) }) val s1_ready, s2_ready, s3_ready = WireInit(false.B) // Pipeline // -------------------------------------------------------------------------------- // stage 0 // -------------------------------------------------------------------------------- // generate addr, use addr to query DCache and DTLB val s0_valid = Wire(Bool()) val s0_mmio_select = Wire(Bool()) val s0_nc_select = Wire(Bool()) val s0_misalign_select= Wire(Bool()) val s0_kill = Wire(Bool()) val s0_can_go = s1_ready val s0_fire = s0_valid && s0_can_go val s0_mmio_fire = s0_mmio_select && s0_can_go val s0_nc_fire = s0_nc_select && s0_can_go val s0_out = Wire(new LqWriteBundle) val s0_tlb_valid = Wire(Bool()) val s0_tlb_hlv = Wire(Bool()) val s0_tlb_hlvx = Wire(Bool()) val s0_tlb_vaddr = Wire(UInt(VAddrBits.W)) val s0_tlb_fullva = Wire(UInt(XLEN.W)) val s0_dcache_vaddr = Wire(UInt(VAddrBits.W)) val s0_is128bit = Wire(Bool()) val s0_misalign_wakeup_fire = s0_misalign_select && s0_can_go && io.misalign_ldin.bits.misalignNeedWakeUp // flow source bundle class FlowSource extends Bundle { val vaddr = UInt(VAddrBits.W) val mask = UInt((VLEN/8).W) val uop = new DynInst val try_l2l = Bool() val has_rob_entry = Bool() val rep_carry = new ReplayCarry(nWays) val mshrid = UInt(log2Up(cfg.nMissEntries).W) val isFirstIssue = Bool() val fast_rep = Bool() val ld_rep = Bool() val l2l_fwd = Bool() val prf = Bool() val prf_rd = Bool() val prf_wr = Bool() val prf_i = Bool() val sched_idx = UInt(log2Up(LoadQueueReplaySize+1).W) // Record the issue port idx of load issue queue. This signal is used by load cancel. val deqPortIdx = UInt(log2Ceil(LoadPipelineWidth).W) val frm_mabuf = Bool() // vec only val isvec = Bool() val is128bit = Bool() val uop_unit_stride_fof = Bool() val reg_offset = UInt(vOffsetBits.W) val vecActive = Bool() // 1: vector active element or scala mem operation, 0: vector not active element val is_first_ele = Bool() // val flowPtr = new VlflowPtr val usSecondInv = Bool() val mbIndex = UInt(vlmBindexBits.W) val elemIdx = UInt(elemIdxBits.W) val elemIdxInsideVd = UInt(elemIdxBits.W) val alignedType = UInt(alignTypeBits.W) val vecBaseVaddr = UInt(VAddrBits.W) //for Svpbmt NC val isnc = Bool() val paddr = UInt(PAddrBits.W) val data = UInt((VLEN+1).W) } val s0_sel_src = Wire(new FlowSource) // load flow select/gen // src 0: misalignBuffer load (io.misalign_ldin) // src 1: super load replayed by LSQ (cache miss replay) (io.replay) // src 2: fast load replay (io.fast_rep_in) // src 3: mmio (io.lsq.uncache) // src 4: nc (io.lsq.nc_ldin) // src 5: load replayed by LSQ (io.replay) // src 6: hardware prefetch from prefetchor (high confidence) (io.prefetch) // NOTE: Now vec/int loads are sent from same RS // A vec load will be splited into multiple uops, // so as long as one uop is issued, // the other uops should have higher priority // src 7: vec read from RS (io.vecldin) // src 8: int read / software prefetch first issue from RS (io.in) // src 9: load try pointchaising when no issued or replayed load (io.fastpath) // src10: hardware prefetch from prefetchor (high confidence) (io.prefetch) // priority: high to low val s0_rep_stall = io.ldin.valid && isAfter(io.replay.bits.uop.lqIdx, io.ldin.bits.uop.lqIdx) || io.vecldin.valid && isAfter(io.replay.bits.uop.lqIdx, io.vecldin.bits.uop.lqIdx) private val SRC_NUM = 11 private val Seq( mab_idx, super_rep_idx, fast_rep_idx, mmio_idx, nc_idx, lsq_rep_idx, high_pf_idx, vec_iss_idx, int_iss_idx, l2l_fwd_idx, low_pf_idx ) = (0 until SRC_NUM).toSeq // load flow source valid val s0_src_valid_vec = WireInit(VecInit(Seq( io.misalign_ldin.valid, io.replay.valid && io.replay.bits.forward_tlDchannel, io.fast_rep_in.valid, io.lsq.uncache.valid, io.lsq.nc_ldin.valid, io.replay.valid && !io.replay.bits.forward_tlDchannel && !s0_rep_stall, io.prefetch_req.valid && io.prefetch_req.bits.confidence > 0.U, io.vecldin.valid, io.ldin.valid, // int flow first issue or software prefetch io.l2l_fwd_in.valid, io.prefetch_req.valid && io.prefetch_req.bits.confidence === 0.U, ))) // load flow source ready val s0_src_ready_vec = Wire(Vec(SRC_NUM, Bool())) s0_src_ready_vec(0) := true.B for(i <- 1 until SRC_NUM){ s0_src_ready_vec(i) := !s0_src_valid_vec.take(i).reduce(_ || _) } // load flow source select (OH) val s0_src_select_vec = WireInit(VecInit((0 until SRC_NUM).map{i => s0_src_valid_vec(i) && s0_src_ready_vec(i)})) val s0_hw_prf_select = s0_src_select_vec(high_pf_idx) || s0_src_select_vec(low_pf_idx) val s0_tlb_no_query = s0_hw_prf_select || s0_sel_src.prf_i || s0_src_select_vec(fast_rep_idx) || s0_src_select_vec(mmio_idx) || s0_src_select_vec(nc_idx) s0_valid := !s0_kill && (s0_src_select_vec(nc_idx) || (( s0_src_valid_vec(mab_idx) || s0_src_valid_vec(super_rep_idx) || s0_src_valid_vec(fast_rep_idx) || s0_src_valid_vec(lsq_rep_idx) || s0_src_valid_vec(high_pf_idx) || s0_src_valid_vec(vec_iss_idx) || s0_src_valid_vec(int_iss_idx) || s0_src_valid_vec(l2l_fwd_idx) || s0_src_valid_vec(low_pf_idx) ) && !s0_src_select_vec(mmio_idx) && io.dcache.req.ready)) s0_mmio_select := s0_src_select_vec(mmio_idx) && !s0_kill s0_nc_select := s0_src_select_vec(nc_idx) && !s0_kill //judgment: is NC with data or not. //If true, it's from `io.lsq.nc_ldin` or `io.fast_rep_in` val s0_nc_with_data = s0_sel_src.isnc && !s0_kill s0_misalign_select := s0_src_select_vec(mab_idx) && !s0_kill // if is hardware prefetch or fast replay, don't send valid to tlb s0_tlb_valid := ( s0_src_valid_vec(mab_idx) || s0_src_valid_vec(super_rep_idx) || s0_src_valid_vec(lsq_rep_idx) || s0_src_valid_vec(vec_iss_idx) || s0_src_valid_vec(int_iss_idx) || s0_src_valid_vec(l2l_fwd_idx) ) && io.dcache.req.ready // which is S0's out is ready and dcache is ready val s0_try_ptr_chasing = s0_src_select_vec(l2l_fwd_idx) val s0_do_try_ptr_chasing = s0_try_ptr_chasing && s0_can_go && io.dcache.req.ready val s0_ptr_chasing_vaddr = io.l2l_fwd_in.data(5, 0) +& io.ld_fast_imm(5, 0) val s0_ptr_chasing_canceled = WireInit(false.B) s0_kill := s0_ptr_chasing_canceled // prefetch related ctrl signal io.canAcceptLowConfPrefetch := s0_src_ready_vec(low_pf_idx) && io.dcache.req.ready io.canAcceptHighConfPrefetch := s0_src_ready_vec(high_pf_idx) && io.dcache.req.ready // query DTLB io.tlb.req.valid := s0_tlb_valid io.tlb.req.bits.cmd := Mux(s0_sel_src.prf, Mux(s0_sel_src.prf_wr, TlbCmd.write, TlbCmd.read), TlbCmd.read ) io.tlb.req.bits.isPrefetch := s0_sel_src.prf io.tlb.req.bits.vaddr := s0_tlb_vaddr io.tlb.req.bits.fullva := s0_tlb_fullva io.tlb.req.bits.checkfullva := s0_src_select_vec(vec_iss_idx) || s0_src_select_vec(int_iss_idx) io.tlb.req.bits.hyperinst := s0_tlb_hlv io.tlb.req.bits.hlvx := s0_tlb_hlvx io.tlb.req.bits.size := Mux(s0_sel_src.isvec, s0_sel_src.alignedType(2,0), LSUOpType.size(s0_sel_src.uop.fuOpType)) io.tlb.req.bits.kill := s0_kill || s0_tlb_no_query // if does not need to be translated, kill it io.tlb.req.bits.memidx.is_ld := true.B io.tlb.req.bits.memidx.is_st := false.B io.tlb.req.bits.memidx.idx := s0_sel_src.uop.lqIdx.value io.tlb.req.bits.debug.robIdx := s0_sel_src.uop.robIdx io.tlb.req.bits.no_translate := s0_tlb_no_query // hardware prefetch and fast replay does not need to be translated, need this signal for pmp check io.tlb.req.bits.debug.pc := s0_sel_src.uop.pc io.tlb.req.bits.debug.isFirstIssue := s0_sel_src.isFirstIssue // query DCache io.dcache.req.valid := s0_valid && !s0_sel_src.prf_i && !s0_nc_with_data io.dcache.req.bits.cmd := Mux(s0_sel_src.prf_rd, MemoryOpConstants.M_PFR, Mux(s0_sel_src.prf_wr, MemoryOpConstants.M_PFW, MemoryOpConstants.M_XRD) ) io.dcache.req.bits.vaddr := s0_dcache_vaddr io.dcache.req.bits.vaddr_dup := s0_dcache_vaddr io.dcache.req.bits.mask := s0_sel_src.mask io.dcache.req.bits.data := DontCare io.dcache.req.bits.isFirstIssue := s0_sel_src.isFirstIssue io.dcache.req.bits.instrtype := Mux(s0_sel_src.prf, DCACHE_PREFETCH_SOURCE.U, LOAD_SOURCE.U) io.dcache.req.bits.debug_robIdx := s0_sel_src.uop.robIdx.value io.dcache.req.bits.replayCarry := s0_sel_src.rep_carry io.dcache.req.bits.id := DontCare // TODO: update cache meta io.dcache.req.bits.lqIdx := s0_sel_src.uop.lqIdx io.dcache.pf_source := Mux(s0_hw_prf_select, io.prefetch_req.bits.pf_source.value, L1_HW_PREFETCH_NULL) io.dcache.is128Req := s0_is128bit // load flow priority mux def fromNullSource(): FlowSource = { val out = WireInit(0.U.asTypeOf(new FlowSource)) out } def fromMisAlignBufferSource(src: LsPipelineBundle): FlowSource = { val out = WireInit(0.U.asTypeOf(new FlowSource)) out.vaddr := src.vaddr out.mask := src.mask out.uop := src.uop out.try_l2l := false.B out.has_rob_entry := false.B out.rep_carry := src.replayCarry out.mshrid := src.mshrid out.frm_mabuf := true.B out.isFirstIssue := false.B out.fast_rep := false.B out.ld_rep := false.B out.l2l_fwd := false.B out.prf := false.B out.prf_rd := false.B out.prf_wr := false.B out.sched_idx := src.schedIndex out.isvec := src.isvec out.is128bit := src.is128bit out.vecActive := true.B out } def fromFastReplaySource(src: LqWriteBundle): FlowSource = { val out = WireInit(0.U.asTypeOf(new FlowSource)) out.vaddr := src.vaddr out.paddr := src.paddr out.mask := src.mask out.uop := src.uop out.try_l2l := false.B out.has_rob_entry := src.hasROBEntry out.rep_carry := src.rep_info.rep_carry out.mshrid := src.rep_info.mshr_id out.frm_mabuf := src.isFrmMisAlignBuf out.isFirstIssue := false.B out.fast_rep := true.B out.ld_rep := src.isLoadReplay out.l2l_fwd := false.B out.prf := LSUOpType.isPrefetch(src.uop.fuOpType) && !src.isvec out.prf_rd := src.uop.fuOpType === LSUOpType.prefetch_r out.prf_wr := src.uop.fuOpType === LSUOpType.prefetch_w out.prf_i := false.B out.sched_idx := src.schedIndex out.isvec := src.isvec out.is128bit := src.is128bit out.uop_unit_stride_fof := src.uop_unit_stride_fof out.reg_offset := src.reg_offset out.vecActive := src.vecActive out.is_first_ele := src.is_first_ele out.usSecondInv := src.usSecondInv out.mbIndex := src.mbIndex out.elemIdx := src.elemIdx out.elemIdxInsideVd := src.elemIdxInsideVd out.alignedType := src.alignedType out.isnc := src.nc out.data := src.data out } // TODO: implement vector mmio def fromMmioSource(src: MemExuOutput) = { val out = WireInit(0.U.asTypeOf(new FlowSource)) out.mask := 0.U out.uop := src.uop out.try_l2l := false.B out.has_rob_entry := false.B out.rep_carry := 0.U.asTypeOf(out.rep_carry) out.mshrid := 0.U out.frm_mabuf := false.B out.isFirstIssue := false.B out.fast_rep := false.B out.ld_rep := false.B out.l2l_fwd := false.B out.prf := false.B out.prf_rd := false.B out.prf_wr := false.B out.prf_i := false.B out.sched_idx := 0.U out.vecActive := true.B out } def fromNcSource(src: LsPipelineBundle): FlowSource = { val out = WireInit(0.U.asTypeOf(new FlowSource)) out.vaddr := src.vaddr out.paddr := src.paddr out.mask := genVWmask(src.vaddr, src.uop.fuOpType(1,0)) out.uop := src.uop out.has_rob_entry := true.B out.sched_idx := src.schedIndex out.isvec := src.isvec out.is128bit := src.is128bit out.vecActive := src.vecActive out.isnc := true.B out.data := src.data out } def fromNormalReplaySource(src: LsPipelineBundle): FlowSource = { val out = WireInit(0.U.asTypeOf(new FlowSource)) out.mask := Mux(src.isvec, src.mask, genVWmask(src.vaddr, src.uop.fuOpType(1, 0))) out.uop := src.uop out.try_l2l := false.B out.has_rob_entry := true.B out.rep_carry := src.replayCarry out.mshrid := src.mshrid out.frm_mabuf := false.B out.isFirstIssue := false.B out.fast_rep := false.B out.ld_rep := true.B out.l2l_fwd := false.B out.prf := LSUOpType.isPrefetch(src.uop.fuOpType) && !src.isvec out.prf_rd := src.uop.fuOpType === LSUOpType.prefetch_r out.prf_wr := src.uop.fuOpType === LSUOpType.prefetch_w out.prf_i := false.B out.sched_idx := src.schedIndex out.isvec := src.isvec out.is128bit := src.is128bit out.uop_unit_stride_fof := src.uop_unit_stride_fof out.reg_offset := src.reg_offset out.vecActive := src.vecActive out.is_first_ele := src.is_first_ele out.usSecondInv := src.usSecondInv out.mbIndex := src.mbIndex out.elemIdx := src.elemIdx out.elemIdxInsideVd := src.elemIdxInsideVd out.alignedType := src.alignedType out } // TODO: implement vector prefetch def fromPrefetchSource(src: L1PrefetchReq): FlowSource = { val out = WireInit(0.U.asTypeOf(new FlowSource)) out.mask := 0.U out.uop := DontCare out.try_l2l := false.B out.has_rob_entry := false.B out.rep_carry := 0.U.asTypeOf(out.rep_carry) out.mshrid := 0.U out.frm_mabuf := false.B out.isFirstIssue := false.B out.fast_rep := false.B out.ld_rep := false.B out.l2l_fwd := false.B out.prf := true.B out.prf_rd := !src.is_store out.prf_wr := src.is_store out.prf_i := false.B out.sched_idx := 0.U out } def fromVecIssueSource(src: VecPipeBundle): FlowSource = { val out = WireInit(0.U.asTypeOf(new FlowSource)) out.mask := src.mask out.uop := src.uop out.try_l2l := false.B out.has_rob_entry := true.B // TODO: VLSU, implement replay carry out.rep_carry := 0.U.asTypeOf(out.rep_carry) out.mshrid := 0.U out.frm_mabuf := false.B // TODO: VLSU, implement first issue // out.isFirstIssue := src.isFirstIssue out.fast_rep := false.B out.ld_rep := false.B out.l2l_fwd := false.B out.prf := false.B out.prf_rd := false.B out.prf_wr := false.B out.prf_i := false.B out.sched_idx := 0.U // Vector load interface out.isvec := true.B // vector loads only access a single element at a time, so 128-bit path is not used for now out.is128bit := is128Bit(src.alignedType) out.uop_unit_stride_fof := src.uop_unit_stride_fof // out.rob_idx_valid := src.rob_idx_valid // out.inner_idx := src.inner_idx // out.rob_idx := src.rob_idx out.reg_offset := src.reg_offset // out.offset := src.offset out.vecActive := src.vecActive out.is_first_ele := src.is_first_ele // out.flowPtr := src.flowPtr out.usSecondInv := src.usSecondInv out.mbIndex := src.mBIndex out.elemIdx := src.elemIdx out.elemIdxInsideVd := src.elemIdxInsideVd out.vecBaseVaddr := src.basevaddr out.alignedType := src.alignedType out } def fromIntIssueSource(src: MemExuInput): FlowSource = { val out = WireInit(0.U.asTypeOf(new FlowSource)) val addr = io.ldin.bits.src(0) + SignExt(io.ldin.bits.uop.imm(11, 0), VAddrBits) out.mask := genVWmask(addr, src.uop.fuOpType(1,0)) out.uop := src.uop out.try_l2l := false.B out.has_rob_entry := true.B out.rep_carry := 0.U.asTypeOf(out.rep_carry) out.mshrid := 0.U out.frm_mabuf := false.B out.isFirstIssue := true.B out.fast_rep := false.B out.ld_rep := false.B out.l2l_fwd := false.B out.prf := LSUOpType.isPrefetch(src.uop.fuOpType) out.prf_rd := src.uop.fuOpType === LSUOpType.prefetch_r out.prf_wr := src.uop.fuOpType === LSUOpType.prefetch_w out.prf_i := src.uop.fuOpType === LSUOpType.prefetch_i out.sched_idx := 0.U out.vecActive := true.B // true for scala load out } // TODO: implement vector l2l def fromLoadToLoadSource(src: LoadToLoadIO): FlowSource = { val out = WireInit(0.U.asTypeOf(new FlowSource)) out.mask := genVWmask(0.U, LSUOpType.ld) // When there's no valid instruction from RS and LSQ, we try the load-to-load forwarding. // Assume the pointer chasing is always ld. out.uop.fuOpType := LSUOpType.ld out.try_l2l := true.B // we dont care out.isFirstIssue and out.rsIdx and s0_sqIdx in S0 when trying pointchasing // because these signals will be updated in S1 out.has_rob_entry := false.B out.mshrid := 0.U out.frm_mabuf := false.B out.rep_carry := 0.U.asTypeOf(out.rep_carry) out.isFirstIssue := true.B out.fast_rep := false.B out.ld_rep := false.B out.l2l_fwd := true.B out.prf := false.B out.prf_rd := false.B out.prf_wr := false.B out.prf_i := false.B out.sched_idx := 0.U out } // set default val s0_src_selector = WireInit(s0_src_valid_vec) if (!EnableLoadToLoadForward) { s0_src_selector(l2l_fwd_idx) := false.B } val s0_src_format = Seq( fromMisAlignBufferSource(io.misalign_ldin.bits), fromNormalReplaySource(io.replay.bits), fromFastReplaySource(io.fast_rep_in.bits), fromMmioSource(io.lsq.uncache.bits), fromNcSource(io.lsq.nc_ldin.bits), fromNormalReplaySource(io.replay.bits), fromPrefetchSource(io.prefetch_req.bits), fromVecIssueSource(io.vecldin.bits), fromIntIssueSource(io.ldin.bits), (if (EnableLoadToLoadForward) fromLoadToLoadSource(io.l2l_fwd_in) else fromNullSource()), fromPrefetchSource(io.prefetch_req.bits) ) s0_sel_src := ParallelPriorityMux(s0_src_selector, s0_src_format) // fast replay and hardware prefetch don't need to query tlb val int_issue_vaddr = io.ldin.bits.src(0) + SignExt(io.ldin.bits.uop.imm(11, 0), VAddrBits) val int_vec_vaddr = Mux(s0_src_valid_vec(vec_iss_idx), io.vecldin.bits.vaddr(VAddrBits - 1, 0), int_issue_vaddr) s0_tlb_vaddr := Mux( s0_src_valid_vec(mab_idx), io.misalign_ldin.bits.vaddr, Mux( s0_src_valid_vec(super_rep_idx) || s0_src_valid_vec(lsq_rep_idx), io.replay.bits.vaddr, int_vec_vaddr ) ) s0_dcache_vaddr := Mux( s0_src_select_vec(fast_rep_idx), io.fast_rep_in.bits.vaddr, Mux(s0_hw_prf_select, io.prefetch_req.bits.getVaddr(), Mux(s0_src_select_vec(nc_idx), io.lsq.nc_ldin.bits.vaddr, // not for dcache access, but for address alignment check s0_tlb_vaddr)) ) val s0_alignType = Mux(s0_sel_src.isvec, s0_sel_src.alignedType(1,0), s0_sel_src.uop.fuOpType(1, 0)) val s0_addr_aligned = LookupTree(s0_alignType, List( "b00".U -> true.B, //b "b01".U -> (s0_dcache_vaddr(0) === 0.U), //h "b10".U -> (s0_dcache_vaddr(1, 0) === 0.U), //w "b11".U -> (s0_dcache_vaddr(2, 0) === 0.U) //d )) // address align check XSError(s0_sel_src.isvec && s0_dcache_vaddr(3, 0) =/= 0.U && s0_sel_src.alignedType(2), "unit-stride 128 bit element is not aligned!") val s0_check_vaddr_low = s0_dcache_vaddr(4, 0) val s0_check_vaddr_Up_low = LookupTree(s0_alignType, List( "b00".U -> 0.U, "b01".U -> 1.U, "b10".U -> 3.U, "b11".U -> 7.U )) + s0_check_vaddr_low //TODO vec? val s0_rs_cross16Bytes = s0_check_vaddr_Up_low(4) =/= s0_check_vaddr_low(4) val s0_misalignWith16Byte = !s0_rs_cross16Bytes && !s0_addr_aligned && !s0_hw_prf_select val s0_misalignNeedWakeUp = s0_sel_src.frm_mabuf && io.misalign_ldin.bits.misalignNeedWakeUp val s0_finalSplit = s0_sel_src.frm_mabuf && io.misalign_ldin.bits.isFinalSplit s0_is128bit := s0_sel_src.is128bit || s0_misalignWith16Byte // only first issue of int / vec load intructions need to check full vaddr s0_tlb_fullva := Mux(s0_src_valid_vec(mab_idx), io.misalign_ldin.bits.fullva, Mux(s0_src_select_vec(vec_iss_idx), io.vecldin.bits.vaddr, Mux( s0_src_select_vec(int_iss_idx), io.ldin.bits.src(0) + SignExt(io.ldin.bits.uop.imm(11, 0), XLEN), s0_dcache_vaddr ) ) ) s0_tlb_hlv := Mux( s0_src_valid_vec(mab_idx), LSUOpType.isHlv(io.misalign_ldin.bits.uop.fuOpType), Mux( s0_src_valid_vec(super_rep_idx) || s0_src_valid_vec(lsq_rep_idx), LSUOpType.isHlv(io.replay.bits.uop.fuOpType), Mux( s0_src_valid_vec(int_iss_idx), LSUOpType.isHlv(io.ldin.bits.uop.fuOpType), false.B ) ) ) s0_tlb_hlvx := Mux( s0_src_valid_vec(mab_idx), LSUOpType.isHlvx(io.misalign_ldin.bits.uop.fuOpType), Mux( s0_src_valid_vec(super_rep_idx) || s0_src_valid_vec(lsq_rep_idx), LSUOpType.isHlvx(io.replay.bits.uop.fuOpType), Mux( s0_src_valid_vec(int_iss_idx), LSUOpType.isHlvx(io.ldin.bits.uop.fuOpType), false.B ) ) ) // accept load flow if dcache ready (tlb is always ready) // TODO: prefetch need writeback to loadQueueFlag s0_out := DontCare s0_out.vaddr := Mux(s0_nc_with_data, s0_sel_src.vaddr, s0_dcache_vaddr) s0_out.fullva := s0_tlb_fullva s0_out.mask := s0_sel_src.mask s0_out.uop := s0_sel_src.uop s0_out.isFirstIssue := s0_sel_src.isFirstIssue s0_out.hasROBEntry := s0_sel_src.has_rob_entry s0_out.isPrefetch := s0_sel_src.prf s0_out.isHWPrefetch := s0_hw_prf_select s0_out.isFastReplay := s0_sel_src.fast_rep s0_out.isLoadReplay := s0_sel_src.ld_rep s0_out.isFastPath := s0_sel_src.l2l_fwd s0_out.mshrid := s0_sel_src.mshrid s0_out.isvec := s0_sel_src.isvec s0_out.is128bit := s0_is128bit s0_out.isFrmMisAlignBuf := s0_sel_src.frm_mabuf s0_out.uop_unit_stride_fof := s0_sel_src.uop_unit_stride_fof s0_out.paddr := Mux(s0_src_valid_vec(nc_idx), io.lsq.nc_ldin.bits.paddr, Mux(s0_src_valid_vec(fast_rep_idx), io.fast_rep_in.bits.paddr, Mux(s0_src_select_vec(int_iss_idx) && s0_sel_src.prf_i, 0.U, io.prefetch_req.bits.paddr))) // only for nc, fast_rep, prefetch s0_out.tlbNoQuery := s0_tlb_no_query // s0_out.rob_idx_valid := s0_rob_idx_valid // s0_out.inner_idx := s0_inner_idx // s0_out.rob_idx := s0_rob_idx s0_out.reg_offset := s0_sel_src.reg_offset // s0_out.offset := s0_offset s0_out.vecActive := s0_sel_src.vecActive s0_out.usSecondInv := s0_sel_src.usSecondInv s0_out.is_first_ele := s0_sel_src.is_first_ele s0_out.elemIdx := s0_sel_src.elemIdx s0_out.elemIdxInsideVd := s0_sel_src.elemIdxInsideVd s0_out.alignedType := s0_sel_src.alignedType s0_out.mbIndex := s0_sel_src.mbIndex s0_out.vecBaseVaddr := s0_sel_src.vecBaseVaddr // s0_out.flowPtr := s0_sel_src.flowPtr s0_out.uop.exceptionVec(loadAddrMisaligned) := (!s0_addr_aligned || s0_sel_src.uop.exceptionVec(loadAddrMisaligned)) && s0_sel_src.vecActive && !s0_misalignWith16Byte s0_out.isMisalign := (!s0_addr_aligned || s0_sel_src.uop.exceptionVec(loadAddrMisaligned)) && s0_sel_src.vecActive s0_out.forward_tlDchannel := s0_src_select_vec(super_rep_idx) when(io.tlb.req.valid && s0_sel_src.isFirstIssue) { s0_out.uop.debugInfo.tlbFirstReqTime := GTimer() }.otherwise{ s0_out.uop.debugInfo.tlbFirstReqTime := s0_sel_src.uop.debugInfo.tlbFirstReqTime } s0_out.schedIndex := s0_sel_src.sched_idx //for Svpbmt Nc s0_out.nc := s0_sel_src.isnc s0_out.data := s0_sel_src.data s0_out.misalignWith16Byte := s0_misalignWith16Byte s0_out.misalignNeedWakeUp := s0_misalignNeedWakeUp s0_out.isFinalSplit := s0_finalSplit // load fast replay io.fast_rep_in.ready := (s0_can_go && io.dcache.req.ready && s0_src_ready_vec(fast_rep_idx)) // mmio io.lsq.uncache.ready := s0_mmio_fire io.lsq.nc_ldin.ready := s0_src_ready_vec(nc_idx) && s0_can_go // load flow source ready // cache missed load has highest priority // always accept cache missed load flow from load replay queue io.replay.ready := (s0_can_go && io.dcache.req.ready && (s0_src_ready_vec(lsq_rep_idx) && !s0_rep_stall || s0_src_select_vec(super_rep_idx))) // accept load flow from rs when: // 1) there is no lsq-replayed load // 2) there is no fast replayed load // 3) there is no high confidence prefetch request io.vecldin.ready := s0_can_go && io.dcache.req.ready && s0_src_ready_vec(vec_iss_idx) io.ldin.ready := s0_can_go && io.dcache.req.ready && s0_src_ready_vec(int_iss_idx) io.misalign_ldin.ready := s0_can_go && io.dcache.req.ready && s0_src_ready_vec(mab_idx) // for hw prefetch load flow feedback, to be added later // io.prefetch_in.ready := s0_hw_prf_select // dcache replacement extra info // TODO: should prefetch load update replacement? io.dcache.replacementUpdated := Mux(s0_src_select_vec(lsq_rep_idx) || s0_src_select_vec(super_rep_idx), io.replay.bits.replacementUpdated, false.B) // load wakeup // TODO: vector load wakeup? frm_mabuf wakeup? val s0_wakeup_selector = Seq( s0_misalign_wakeup_fire, s0_src_valid_vec(super_rep_idx), s0_src_valid_vec(fast_rep_idx), s0_mmio_fire, s0_nc_fire, s0_src_valid_vec(lsq_rep_idx), s0_src_valid_vec(int_iss_idx) ) val s0_wakeup_format = Seq( io.misalign_ldin.bits.uop, io.replay.bits.uop, io.fast_rep_in.bits.uop, io.lsq.uncache.bits.uop, io.lsq.nc_ldin.bits.uop, io.replay.bits.uop, io.ldin.bits.uop, ) val s0_wakeup_uop = ParallelPriorityMux(s0_wakeup_selector, s0_wakeup_format) io.wakeup.valid := s0_fire && !s0_sel_src.isvec && !s0_sel_src.frm_mabuf && ( s0_src_valid_vec(super_rep_idx) || s0_src_valid_vec(fast_rep_idx) || s0_src_valid_vec(lsq_rep_idx) || (s0_src_valid_vec(int_iss_idx) && !s0_sel_src.prf && !s0_src_valid_vec(vec_iss_idx) && !s0_src_valid_vec(high_pf_idx)) ) || s0_mmio_fire || s0_nc_fire || s0_misalign_wakeup_fire io.wakeup.bits := s0_wakeup_uop // prefetch.i(Zicbop) io.ifetchPrefetch.valid := RegNext(s0_src_select_vec(int_iss_idx) && s0_sel_src.prf_i) io.ifetchPrefetch.bits.vaddr := RegEnable(s0_out.vaddr, 0.U, s0_src_select_vec(int_iss_idx) && s0_sel_src.prf_i) XSDebug(io.dcache.req.fire, p"[DCACHE LOAD REQ] pc ${Hexadecimal(s0_sel_src.uop.pc)}, vaddr ${Hexadecimal(s0_dcache_vaddr)}\n" ) XSDebug(s0_valid, p"S0: pc ${Hexadecimal(s0_out.uop.pc)}, lId ${Hexadecimal(s0_out.uop.lqIdx.asUInt)}, " + p"vaddr ${Hexadecimal(s0_out.vaddr)}, mask ${Hexadecimal(s0_out.mask)}\n") // Pipeline // -------------------------------------------------------------------------------- // stage 1 // -------------------------------------------------------------------------------- // TLB resp (send paddr to dcache) val s1_valid = RegInit(false.B) val s1_in = Wire(new LqWriteBundle) val s1_out = Wire(new LqWriteBundle) val s1_kill = Wire(Bool()) val s1_can_go = s2_ready val s1_fire = s1_valid && !s1_kill && s1_can_go val s1_vecActive = RegEnable(s0_out.vecActive, true.B, s0_fire) val s1_nc_with_data = RegNext(s0_nc_with_data) s1_ready := !s1_valid || s1_kill || s2_ready when (s0_fire) { s1_valid := true.B } .elsewhen (s1_fire) { s1_valid := false.B } .elsewhen (s1_kill) { s1_valid := false.B } s1_in := RegEnable(s0_out, s0_fire) val s1_fast_rep_dly_kill = RegEnable(io.fast_rep_in.bits.lateKill, io.fast_rep_in.valid) && s1_in.isFastReplay val s1_fast_rep_dly_err = RegEnable(io.fast_rep_in.bits.delayedLoadError, io.fast_rep_in.valid) && s1_in.isFastReplay val s1_l2l_fwd_dly_err = RegEnable(io.l2l_fwd_in.dly_ld_err, io.l2l_fwd_in.valid) && s1_in.isFastPath val s1_dly_err = s1_fast_rep_dly_err || s1_l2l_fwd_dly_err val s1_vaddr_hi = Wire(UInt()) val s1_vaddr_lo = Wire(UInt()) val s1_vaddr = Wire(UInt()) val s1_paddr_dup_lsu = Wire(UInt()) val s1_gpaddr_dup_lsu = Wire(UInt()) val s1_paddr_dup_dcache = Wire(UInt()) val s1_exception = ExceptionNO.selectByFu(s1_out.uop.exceptionVec, LduCfg).asUInt.orR // af & pf exception were modified below. val s1_tlb_miss = io.tlb.resp.bits.miss && io.tlb.resp.valid && s1_valid val s1_tlb_fast_miss = io.tlb.resp.bits.fastMiss && io.tlb.resp.valid && s1_valid val s1_pbmt = Mux(!s1_tlb_miss, io.tlb.resp.bits.pbmt.head, 0.U(Pbmt.width.W)) val s1_nc = s1_in.nc val s1_prf = s1_in.isPrefetch val s1_hw_prf = s1_in.isHWPrefetch val s1_sw_prf = s1_prf && !s1_hw_prf val s1_tlb_memidx = io.tlb.resp.bits.memidx s1_vaddr_hi := s1_in.vaddr(VAddrBits - 1, 6) s1_vaddr_lo := s1_in.vaddr(5, 0) s1_vaddr := Cat(s1_vaddr_hi, s1_vaddr_lo) s1_paddr_dup_lsu := Mux(s1_in.tlbNoQuery, s1_in.paddr, io.tlb.resp.bits.paddr(0)) s1_paddr_dup_dcache := Mux(s1_in.tlbNoQuery, s1_in.paddr, io.tlb.resp.bits.paddr(1)) s1_gpaddr_dup_lsu := Mux(s1_in.isFastReplay, s1_in.paddr, io.tlb.resp.bits.gpaddr(0)) when (s1_tlb_memidx.is_ld && io.tlb.resp.valid && !s1_tlb_miss && s1_tlb_memidx.idx === s1_in.uop.lqIdx.value) { // printf("load idx = %d\n", s1_tlb_memidx.idx) s1_out.uop.debugInfo.tlbRespTime := GTimer() } io.tlb.req_kill := s1_kill || s1_dly_err io.tlb.req.bits.pmp_addr := s1_in.paddr io.tlb.resp.ready := true.B io.dcache.s1_paddr_dup_lsu <> s1_paddr_dup_lsu io.dcache.s1_paddr_dup_dcache <> s1_paddr_dup_dcache io.dcache.s1_kill := s1_kill || s1_dly_err || s1_tlb_miss || s1_exception io.dcache.s1_kill_data_read := s1_kill || s1_dly_err || s1_tlb_fast_miss // store to load forwarding io.sbuffer.valid := s1_valid && !(s1_exception || s1_tlb_miss || s1_kill || s1_dly_err || s1_prf) io.sbuffer.vaddr := s1_vaddr io.sbuffer.paddr := s1_paddr_dup_lsu io.sbuffer.uop := s1_in.uop io.sbuffer.sqIdx := s1_in.uop.sqIdx io.sbuffer.mask := s1_in.mask io.sbuffer.pc := s1_in.uop.pc // FIXME: remove it io.ubuffer.valid := s1_valid && s1_nc_with_data && !(s1_exception || s1_tlb_miss || s1_kill || s1_dly_err || s1_prf) io.ubuffer.vaddr := s1_vaddr io.ubuffer.paddr := s1_paddr_dup_lsu io.ubuffer.uop := s1_in.uop io.ubuffer.sqIdx := s1_in.uop.sqIdx io.ubuffer.mask := s1_in.mask io.ubuffer.pc := s1_in.uop.pc // FIXME: remove it io.lsq.forward.valid := s1_valid && !(s1_exception || s1_tlb_miss || s1_kill || s1_dly_err || s1_prf) io.lsq.forward.vaddr := s1_vaddr io.lsq.forward.paddr := s1_paddr_dup_lsu io.lsq.forward.uop := s1_in.uop io.lsq.forward.sqIdx := s1_in.uop.sqIdx io.lsq.forward.sqIdxMask := 0.U io.lsq.forward.mask := s1_in.mask io.lsq.forward.pc := s1_in.uop.pc // FIXME: remove it // st-ld violation query // if store unit is 128-bits memory access, need match 128-bit private val s1_isMatch128 = io.stld_nuke_query.map(x => (x.bits.matchLine || ((s1_in.isvec || s1_in.misalignWith16Byte) && s1_in.is128bit))) val s1_nuke_paddr_match = VecInit((0 until StorePipelineWidth).zip(s1_isMatch128).map{case (w, s) => {Mux(s, s1_paddr_dup_lsu(PAddrBits-1, 4) === io.stld_nuke_query(w).bits.paddr(PAddrBits-1, 4), s1_paddr_dup_lsu(PAddrBits-1, 3) === io.stld_nuke_query(w).bits.paddr(PAddrBits-1, 3))}}) val s1_nuke = VecInit((0 until StorePipelineWidth).map(w => { io.stld_nuke_query(w).valid && // query valid isAfter(s1_in.uop.robIdx, io.stld_nuke_query(w).bits.robIdx) && // older store s1_nuke_paddr_match(w) && // paddr match (s1_in.mask & io.stld_nuke_query(w).bits.mask).orR // data mask contain })).asUInt.orR && !s1_tlb_miss s1_out := s1_in s1_out.vaddr := s1_vaddr s1_out.fullva := io.tlb.resp.bits.fullva s1_out.vaNeedExt := io.tlb.resp.bits.excp(0).vaNeedExt s1_out.isHyper := io.tlb.resp.bits.excp(0).isHyper s1_out.paddr := s1_paddr_dup_lsu s1_out.gpaddr := s1_gpaddr_dup_lsu s1_out.isForVSnonLeafPTE := io.tlb.resp.bits.isForVSnonLeafPTE s1_out.tlbMiss := s1_tlb_miss s1_out.ptwBack := io.tlb.resp.bits.ptwBack s1_out.rep_info.debug := s1_in.uop.debugInfo s1_out.rep_info.nuke := s1_nuke && !s1_sw_prf s1_out.delayedLoadError := s1_dly_err s1_out.nc := s1_nc || Pbmt.isNC(s1_pbmt) s1_out.mmio := Pbmt.isIO(s1_pbmt) when (!s1_dly_err) { // current ori test will cause the case of ldest == 0, below will be modifeid in the future. // af & pf exception were modified // if is tlbNoQuery request, don't trigger exception from tlb resp s1_out.uop.exceptionVec(loadPageFault) := io.tlb.resp.bits.excp(0).pf.ld && s1_vecActive && !s1_tlb_miss && !s1_in.tlbNoQuery s1_out.uop.exceptionVec(loadGuestPageFault) := io.tlb.resp.bits.excp(0).gpf.ld && !s1_tlb_miss && !s1_in.tlbNoQuery s1_out.uop.exceptionVec(loadAccessFault) := io.tlb.resp.bits.excp(0).af.ld && s1_vecActive && !s1_tlb_miss && !s1_in.tlbNoQuery when (RegNext(io.tlb.req.bits.checkfullva) && (s1_out.uop.exceptionVec(loadPageFault) || s1_out.uop.exceptionVec(loadGuestPageFault) || s1_out.uop.exceptionVec(loadAccessFault))) { s1_out.uop.exceptionVec(loadAddrMisaligned) := false.B s1_out.isMisalign := false.B } } .otherwise { s1_out.uop.exceptionVec(loadPageFault) := false.B s1_out.uop.exceptionVec(loadGuestPageFault) := false.B s1_out.uop.exceptionVec(loadAddrMisaligned) := false.B s1_out.isMisalign := false.B s1_out.uop.exceptionVec(loadAccessFault) := s1_dly_err && s1_vecActive } // pointer chasing val s1_try_ptr_chasing = GatedValidRegNext(s0_do_try_ptr_chasing, false.B) val s1_ptr_chasing_vaddr = RegEnable(s0_ptr_chasing_vaddr, s0_do_try_ptr_chasing) val s1_fu_op_type_not_ld = WireInit(false.B) val s1_not_fast_match = WireInit(false.B) val s1_addr_mismatch = WireInit(false.B) val s1_addr_misaligned = WireInit(false.B) val s1_fast_mismatch = WireInit(false.B) val s1_ptr_chasing_canceled = WireInit(false.B) val s1_cancel_ptr_chasing = WireInit(false.B) val s1_redirect_reg = Wire(Valid(new Redirect)) s1_redirect_reg.bits := RegEnable(io.redirect.bits, io.redirect.valid) s1_redirect_reg.valid := GatedValidRegNext(io.redirect.valid) s1_kill := s1_fast_rep_dly_kill || s1_cancel_ptr_chasing || s1_in.uop.robIdx.needFlush(io.redirect) || (s1_in.uop.robIdx.needFlush(s1_redirect_reg) && !GatedValidRegNext(s0_try_ptr_chasing)) || RegEnable(s0_kill, false.B, io.ldin.valid || io.vecldin.valid || io.replay.valid || io.l2l_fwd_in.valid || io.fast_rep_in.valid || io.misalign_ldin.valid || io.lsq.nc_ldin.valid ) if (EnableLoadToLoadForward) { // Sometimes, we need to cancel the load-load forwarding. // These can be put at S0 if timing is bad at S1. // Case 0: CACHE_SET(base + offset) != CACHE_SET(base) (lowest 6-bit addition has an overflow) s1_addr_mismatch := s1_ptr_chasing_vaddr(6) || RegEnable(io.ld_fast_imm(11, 6).orR, s0_do_try_ptr_chasing) // Case 1: the address is not 64-bit aligned or the fuOpType is not LD s1_addr_misaligned := s1_ptr_chasing_vaddr(2, 0).orR s1_fu_op_type_not_ld := io.ldin.bits.uop.fuOpType =/= LSUOpType.ld // Case 2: this load-load uop is cancelled s1_ptr_chasing_canceled := !io.ldin.valid // Case 3: fast mismatch s1_fast_mismatch := RegEnable(!io.ld_fast_match, s0_do_try_ptr_chasing) when (s1_try_ptr_chasing) { s1_cancel_ptr_chasing := s1_addr_mismatch || s1_addr_misaligned || s1_fu_op_type_not_ld || s1_ptr_chasing_canceled || s1_fast_mismatch s1_in.uop := io.ldin.bits.uop s1_in.isFirstIssue := io.ldin.bits.isFirstIssue s1_vaddr_lo := s1_ptr_chasing_vaddr(5, 0) s1_paddr_dup_lsu := Cat(io.tlb.resp.bits.paddr(0)(PAddrBits - 1, 6), s1_vaddr_lo) s1_paddr_dup_dcache := Cat(io.tlb.resp.bits.paddr(0)(PAddrBits - 1, 6), s1_vaddr_lo) // recored tlb time when get the data to ensure the correctness of the latency calculation (although it should not record in here, because it does not use tlb) s1_in.uop.debugInfo.tlbFirstReqTime := GTimer() s1_in.uop.debugInfo.tlbRespTime := GTimer() } when (!s1_cancel_ptr_chasing) { s0_ptr_chasing_canceled := s1_try_ptr_chasing && !io.replay.fire && !io.fast_rep_in.fire && !(s0_src_valid_vec(high_pf_idx) && io.canAcceptHighConfPrefetch) && !io.misalign_ldin.fire && !io.lsq.nc_ldin.valid when (s1_try_ptr_chasing) { io.ldin.ready := true.B } } } // pre-calcuate sqIdx mask in s0, then send it to lsq in s1 for forwarding val s1_sqIdx_mask = RegEnable(UIntToMask(s0_out.uop.sqIdx.value, StoreQueueSize), s0_fire) // to enable load-load, sqIdxMask must be calculated based on ldin.uop // If the timing here is not OK, load-load forwarding has to be disabled. // Or we calculate sqIdxMask at RS?? io.lsq.forward.sqIdxMask := s1_sqIdx_mask if (EnableLoadToLoadForward) { when (s1_try_ptr_chasing) { io.lsq.forward.sqIdxMask := UIntToMask(io.ldin.bits.uop.sqIdx.value, StoreQueueSize) } } io.forward_mshr.valid := s1_valid && s1_out.forward_tlDchannel io.forward_mshr.mshrid := s1_out.mshrid io.forward_mshr.paddr := s1_out.paddr val loadTrigger = Module(new MemTrigger(MemType.LOAD)) loadTrigger.io.fromCsrTrigger.tdataVec := io.fromCsrTrigger.tdataVec loadTrigger.io.fromCsrTrigger.tEnableVec := io.fromCsrTrigger.tEnableVec loadTrigger.io.fromCsrTrigger.triggerCanRaiseBpExp := io.fromCsrTrigger.triggerCanRaiseBpExp loadTrigger.io.fromCsrTrigger.debugMode := io.fromCsrTrigger.debugMode loadTrigger.io.fromLoadStore.vaddr := s1_vaddr loadTrigger.io.fromLoadStore.isVectorUnitStride := s1_in.isvec && s1_in.is128bit loadTrigger.io.fromLoadStore.mask := s1_in.mask val s1_trigger_action = loadTrigger.io.toLoadStore.triggerAction val s1_trigger_debug_mode = TriggerAction.isDmode(s1_trigger_action) val s1_trigger_breakpoint = TriggerAction.isExp(s1_trigger_action) s1_out.uop.trigger := s1_trigger_action s1_out.uop.exceptionVec(breakPoint) := s1_trigger_breakpoint s1_out.vecVaddrOffset := Mux( s1_trigger_debug_mode || s1_trigger_breakpoint, loadTrigger.io.toLoadStore.triggerVaddr - s1_in.vecBaseVaddr, s1_in.vaddr + genVFirstUnmask(s1_in.mask).asUInt - s1_in.vecBaseVaddr ) s1_out.vecTriggerMask := Mux(s1_trigger_debug_mode || s1_trigger_breakpoint, loadTrigger.io.toLoadStore.triggerMask, 0.U) XSDebug(s1_valid, p"S1: pc ${Hexadecimal(s1_out.uop.pc)}, lId ${Hexadecimal(s1_out.uop.lqIdx.asUInt)}, tlb_miss ${io.tlb.resp.bits.miss}, " + p"paddr ${Hexadecimal(s1_out.paddr)}, mmio ${s1_out.mmio}\n") // Pipeline // -------------------------------------------------------------------------------- // stage 2 // -------------------------------------------------------------------------------- // s2: DCache resp val s2_valid = RegInit(false.B) val s2_in = Wire(new LqWriteBundle) val s2_out = Wire(new LqWriteBundle) val s2_kill = Wire(Bool()) val s2_can_go = s3_ready val s2_fire = s2_valid && !s2_kill && s2_can_go val s2_vecActive = RegEnable(s1_out.vecActive, true.B, s1_fire) val s2_isvec = RegEnable(s1_out.isvec, false.B, s1_fire) val s2_data_select = genRdataOH(s2_out.uop) val s2_data_select_by_offset = genDataSelectByOffset(s2_out.paddr(3, 0)) val s2_frm_mabuf = s2_in.isFrmMisAlignBuf val s2_pbmt = RegEnable(s1_pbmt, s1_fire) val s2_trigger_debug_mode = RegEnable(s1_trigger_debug_mode, false.B, s1_fire) val s2_nc_with_data = RegNext(s1_nc_with_data) val s2_mmio_req = Wire(Valid(new MemExuOutput)) s2_mmio_req.valid := RegNextN(io.lsq.uncache.fire, 2, Some(false.B)) s2_mmio_req.bits := RegNextN(io.lsq.uncache.bits, 2) s2_kill := s2_in.uop.robIdx.needFlush(io.redirect) s2_ready := !s2_valid || s2_kill || s3_ready when (s1_fire) { s2_valid := true.B } .elsewhen (s2_fire) { s2_valid := false.B } .elsewhen (s2_kill) { s2_valid := false.B } s2_in := RegEnable(s1_out, s1_fire) val s2_pmp = WireInit(io.pmp) val s2_isMisalign = WireInit(s2_in.isMisalign) val s2_prf = s2_in.isPrefetch val s2_hw_prf = s2_in.isHWPrefetch val s2_exception_vec = WireInit(s2_in.uop.exceptionVec) val s2_un_misalign_exception = s2_vecActive && (s2_trigger_debug_mode || ExceptionNO.selectByFuAndUnSelect(s2_exception_vec, LduCfg, Seq(loadAddrMisaligned)).asUInt.orR) val s2_check_mmio = !s2_prf && !s2_in.tlbMiss && Mux(Pbmt.isUncache(s2_pbmt), s2_in.mmio, s2_pmp.mmio) && !s2_un_misalign_exception // exception that may cause load addr to be invalid / illegal // if such exception happen, that inst and its exception info // will be force writebacked to rob val s2_actually_uncache = Pbmt.isPMA(s2_pbmt) && s2_pmp.mmio || s2_in.nc || s2_in.mmio val s2_memBackTypeMM = !s2_pmp.mmio when (!s2_in.delayedLoadError) { s2_exception_vec(loadAccessFault) := s2_vecActive && ( s2_in.uop.exceptionVec(loadAccessFault) || s2_pmp.ld || (s2_isvec || s2_frm_mabuf) && s2_actually_uncache && !s2_prf && !s2_in.tlbMiss || io.dcache.resp.bits.tag_error && GatedValidRegNext(io.csrCtrl.cache_error_enable) ) } // soft prefetch will not trigger any exception (but ecc error interrupt may // be triggered) val s2_tlb_unrelated_exceps = s2_in.uop.exceptionVec(loadAddrMisaligned) || s2_in.uop.exceptionVec(breakPoint) when (!s2_in.delayedLoadError && (s2_prf || s2_in.tlbMiss && !s2_tlb_unrelated_exceps)) { s2_exception_vec := 0.U.asTypeOf(s2_exception_vec.cloneType) s2_isMisalign := false.B } val s2_exception = s2_vecActive && (s2_trigger_debug_mode || ExceptionNO.selectByFu(s2_exception_vec, LduCfg).asUInt.orR) val s2_mis_align = s2_valid && GatedValidRegNext(io.csrCtrl.hd_misalign_ld_enable) && s2_out.isMisalign && !s2_in.misalignWith16Byte && !s2_exception_vec(breakPoint) && !s2_trigger_debug_mode && !s2_check_mmio val (s2_fwd_frm_d_chan, s2_fwd_data_frm_d_chan, s2_d_corrupt) = io.tl_d_channel.forward(s1_valid && s1_out.forward_tlDchannel, s1_out.mshrid, s1_out.paddr) val (s2_fwd_data_valid, s2_fwd_frm_mshr, s2_fwd_data_frm_mshr, s2_mshr_corrupt) = io.forward_mshr.forward() val s2_fwd_frm_d_chan_or_mshr = s2_fwd_data_valid && (s2_fwd_frm_d_chan || s2_fwd_frm_mshr) // writeback access fault caused by ecc error / bus error // * ecc data error is slow to generate, so we will not use it until load stage 3 // * in load stage 3, an extra signal io.load_error will be used to // * if pbmt =/= 0, mmio is up to pbmt; otherwise, it's up to pmp val s2_tlb_hit = RegNext(!io.tlb.resp.bits.miss && io.tlb.resp.valid && s1_valid) val s2_mmio = !s2_prf && !s2_exception && !s2_in.tlbMiss && Mux(Pbmt.isUncache(s2_pbmt), s2_in.mmio, s2_tlb_hit && s2_pmp.mmio) val s2_uncache = !s2_prf && !s2_exception && !s2_in.tlbMiss && s2_actually_uncache val s2_full_fwd = Wire(Bool()) val s2_mem_amb = s2_in.uop.storeSetHit && io.lsq.forward.addrInvalid && RegNext(io.lsq.forward.valid) val s2_tlb_miss = s2_in.tlbMiss val s2_fwd_fail = io.lsq.forward.dataInvalid && RegNext(io.lsq.forward.valid) val s2_dcache_miss = io.dcache.resp.bits.miss && !s2_fwd_frm_d_chan_or_mshr && !s2_full_fwd && !s2_in.nc val s2_mq_nack = io.dcache.s2_mq_nack && !s2_fwd_frm_d_chan_or_mshr && !s2_full_fwd && !s2_in.nc val s2_bank_conflict = io.dcache.s2_bank_conflict && !s2_fwd_frm_d_chan_or_mshr && !s2_full_fwd && !s2_in.nc val s2_wpu_pred_fail = io.dcache.s2_wpu_pred_fail && !s2_fwd_frm_d_chan_or_mshr && !s2_full_fwd && !s2_in.nc val s2_rar_nack = io.lsq.ldld_nuke_query.req.valid && !io.lsq.ldld_nuke_query.req.ready val s2_raw_nack = io.lsq.stld_nuke_query.req.valid && !io.lsq.stld_nuke_query.req.ready // st-ld violation query // NeedFastRecovery Valid when // 1. Fast recovery query request Valid. // 2. Load instruction is younger than requestors(store instructions). // 3. Physical address match. // 4. Data contains. private val s2_isMatch128 = io.stld_nuke_query.map(x => (x.bits.matchLine || ((s2_in.isvec || s2_in.misalignWith16Byte) && s2_in.is128bit))) val s2_nuke_paddr_match = VecInit((0 until StorePipelineWidth).zip(s2_isMatch128).map{case (w, s) => {Mux(s, s2_in.paddr(PAddrBits-1, 4) === io.stld_nuke_query(w).bits.paddr(PAddrBits-1, 4), s2_in.paddr(PAddrBits-1, 3) === io.stld_nuke_query(w).bits.paddr(PAddrBits-1, 3))}}) val s2_nuke = VecInit((0 until StorePipelineWidth).map(w => { io.stld_nuke_query(w).valid && // query valid isAfter(s2_in.uop.robIdx, io.stld_nuke_query(w).bits.robIdx) && // older store s2_nuke_paddr_match(w) && // paddr match (s2_in.mask & io.stld_nuke_query(w).bits.mask).orR // data mask contain })).asUInt.orR && !s2_tlb_miss || s2_in.rep_info.nuke val s2_cache_handled = io.dcache.resp.bits.handled //if it is NC with data, it should handle the replayed situation. //else s2_uncache will enter uncache buffer. val s2_troublem = !s2_exception && (!s2_uncache || s2_nc_with_data) && !s2_prf && !s2_in.delayedLoadError io.dcache.resp.ready := true.B val s2_dcache_should_resp = !(s2_in.tlbMiss || s2_exception || s2_in.delayedLoadError || s2_uncache || s2_prf) assert(!(s2_valid && (s2_dcache_should_resp && !io.dcache.resp.valid)), "DCache response got lost") // fast replay require val s2_dcache_fast_rep = (s2_mq_nack || !s2_dcache_miss && (s2_bank_conflict || s2_wpu_pred_fail)) val s2_nuke_fast_rep = !s2_mq_nack && !s2_dcache_miss && !s2_bank_conflict && !s2_wpu_pred_fail && s2_nuke val s2_fast_rep = !s2_in.isFastReplay && !s2_mem_amb && !s2_tlb_miss && !s2_fwd_fail && (s2_dcache_fast_rep || s2_nuke_fast_rep) && s2_troublem && !s2_in.misalignNeedWakeUp // need allocate new entry val s2_can_query = !s2_mem_amb && !s2_tlb_miss && !s2_fwd_fail && !s2_frm_mabuf && !s2_fast_rep && s2_troublem val s2_data_fwded = s2_dcache_miss && s2_full_fwd // For misaligned, we will keep the misaligned exception at S2 and before. // Here a judgement is made as to whether a misaligned exception needs to actually be generated. // We will generate misaligned exceptions at mmio. val s2_real_exceptionVec = WireInit(s2_exception_vec) s2_real_exceptionVec(loadAddrMisaligned) := s2_out.isMisalign && s2_check_mmio s2_real_exceptionVec(loadAccessFault) := s2_exception_vec(loadAccessFault) || s2_fwd_frm_d_chan && s2_d_corrupt || s2_fwd_frm_mshr && s2_mshr_corrupt val s2_real_exception = s2_vecActive && (s2_trigger_debug_mode || ExceptionNO.selectByFu(s2_real_exceptionVec, LduCfg).asUInt.orR) val s2_fwd_vp_match_invalid = io.lsq.forward.matchInvalid || io.sbuffer.matchInvalid || io.ubuffer.matchInvalid val s2_vp_match_fail = s2_fwd_vp_match_invalid && s2_troublem val s2_safe_wakeup = !s2_out.rep_info.need_rep && !s2_mmio && (!s2_in.nc || s2_nc_with_data) && !s2_mis_align && !s2_real_exception || s2_in.misalignNeedWakeUp // don't need to replay and is not a mmio\misalign no data val s2_safe_writeback = s2_real_exception || s2_safe_wakeup || s2_vp_match_fail || s2_in.misalignNeedWakeUp // ld-ld violation require io.lsq.ldld_nuke_query.req.valid := s2_valid && s2_can_query io.lsq.ldld_nuke_query.req.bits.uop := s2_in.uop io.lsq.ldld_nuke_query.req.bits.mask := s2_in.mask io.lsq.ldld_nuke_query.req.bits.paddr := s2_in.paddr io.lsq.ldld_nuke_query.req.bits.data_valid := Mux(s2_full_fwd || s2_fwd_data_valid || s2_nc_with_data, true.B, !s2_dcache_miss) io.lsq.ldld_nuke_query.req.bits.is_nc := s2_nc_with_data // st-ld violation require io.lsq.stld_nuke_query.req.valid := s2_valid && s2_can_query io.lsq.stld_nuke_query.req.bits.uop := s2_in.uop io.lsq.stld_nuke_query.req.bits.mask := s2_in.mask io.lsq.stld_nuke_query.req.bits.paddr := s2_in.paddr io.lsq.stld_nuke_query.req.bits.data_valid := Mux(s2_full_fwd || s2_fwd_data_valid || s2_nc_with_data, true.B, !s2_dcache_miss) io.lsq.stld_nuke_query.req.bits.is_nc := s2_nc_with_data // merge forward result // lsq has higher priority than sbuffer val s2_fwd_mask = Wire(Vec((VLEN/8), Bool())) val s2_fwd_data = Wire(Vec((VLEN/8), UInt(8.W))) s2_full_fwd := ((~s2_fwd_mask.asUInt).asUInt & s2_in.mask) === 0.U && !io.lsq.forward.dataInvalid // generate XLEN/8 Muxs for (i <- 0 until VLEN / 8) { s2_fwd_mask(i) := io.lsq.forward.forwardMask(i) || io.sbuffer.forwardMask(i) || io.ubuffer.forwardMask(i) s2_fwd_data(i) := Mux(io.lsq.forward.forwardMask(i), io.lsq.forward.forwardData(i), Mux(s2_nc_with_data, io.ubuffer.forwardData(i), io.sbuffer.forwardData(i))) } XSDebug(s2_fire, "[FWD LOAD RESP] pc %x fwd %x(%b) + %x(%b)\n", s2_in.uop.pc, io.lsq.forward.forwardData.asUInt, io.lsq.forward.forwardMask.asUInt, s2_in.forwardData.asUInt, s2_in.forwardMask.asUInt ) // s2_out := s2_in s2_out.uop.fpWen := s2_in.uop.fpWen s2_out.nc := s2_in.nc s2_out.mmio := s2_mmio s2_out.memBackTypeMM := s2_memBackTypeMM s2_out.isMisalign := s2_isMisalign s2_out.uop.flushPipe := false.B s2_out.uop.exceptionVec := s2_real_exceptionVec s2_out.forwardMask := s2_fwd_mask s2_out.forwardData := s2_fwd_data s2_out.handledByMSHR := s2_cache_handled s2_out.miss := s2_dcache_miss && s2_troublem s2_out.feedbacked := io.feedback_fast.valid s2_out.uop.vpu.vstart := Mux(s2_in.isLoadReplay || s2_in.isFastReplay, s2_in.uop.vpu.vstart, s2_in.vecVaddrOffset >> s2_in.uop.vpu.veew) // Generate replay signal caused by: // * st-ld violation check // * tlb miss // * dcache replay // * forward data invalid // * dcache miss s2_out.rep_info.mem_amb := s2_mem_amb && s2_troublem s2_out.rep_info.tlb_miss := s2_tlb_miss && s2_troublem s2_out.rep_info.fwd_fail := s2_fwd_fail && s2_troublem s2_out.rep_info.dcache_rep := s2_mq_nack && s2_troublem s2_out.rep_info.dcache_miss := s2_dcache_miss && s2_troublem s2_out.rep_info.bank_conflict := s2_bank_conflict && s2_troublem s2_out.rep_info.wpu_fail := s2_wpu_pred_fail && s2_troublem s2_out.rep_info.rar_nack := s2_rar_nack && s2_troublem s2_out.rep_info.raw_nack := s2_raw_nack && s2_troublem s2_out.rep_info.nuke := s2_nuke && s2_troublem s2_out.rep_info.full_fwd := s2_data_fwded s2_out.rep_info.data_inv_sq_idx := io.lsq.forward.dataInvalidSqIdx s2_out.rep_info.addr_inv_sq_idx := io.lsq.forward.addrInvalidSqIdx s2_out.rep_info.rep_carry := io.dcache.resp.bits.replayCarry s2_out.rep_info.mshr_id := io.dcache.resp.bits.mshr_id s2_out.rep_info.last_beat := s2_in.paddr(log2Up(refillBytes)) s2_out.rep_info.debug := s2_in.uop.debugInfo s2_out.rep_info.tlb_id := io.tlb_hint.id s2_out.rep_info.tlb_full := io.tlb_hint.full // if forward fail, replay this inst from fetch val debug_fwd_fail_rep = s2_fwd_fail && !s2_troublem && !s2_in.tlbMiss // if ld-ld violation is detected, replay from this inst from fetch val debug_ldld_nuke_rep = false.B // s2_ldld_violation && !s2_mmio && !s2_is_prefetch && !s2_in.tlbMiss // to be removed io.feedback_fast.valid := false.B io.feedback_fast.bits.hit := false.B io.feedback_fast.bits.flushState := s2_in.ptwBack io.feedback_fast.bits.robIdx := s2_in.uop.robIdx io.feedback_fast.bits.sqIdx := s2_in.uop.sqIdx io.feedback_fast.bits.lqIdx := s2_in.uop.lqIdx io.feedback_fast.bits.sourceType := RSFeedbackType.lrqFull io.feedback_fast.bits.dataInvalidSqIdx := DontCare io.ldCancel.ld1Cancel := false.B // fast wakeup val s1_fast_uop_valid = WireInit(false.B) s1_fast_uop_valid := !io.dcache.s1_disable_fast_wakeup && s1_valid && !s1_kill && !io.tlb.resp.bits.miss && !io.lsq.forward.dataInvalidFast io.fast_uop.valid := GatedValidRegNext(s1_fast_uop_valid) && (s2_valid && !s2_out.rep_info.need_rep && !s2_uncache && !(s2_prf && !s2_hw_prf)) && !s2_isvec && !s2_frm_mabuf io.fast_uop.bits := RegEnable(s1_out.uop, s1_fast_uop_valid) // io.s2_ptr_chasing := RegEnable(s1_try_ptr_chasing && !s1_cancel_ptr_chasing, false.B, s1_fire) // RegNext prefetch train for better timing // ** Now, prefetch train is valid at load s3 ** val s2_prefetch_train_valid = WireInit(false.B) s2_prefetch_train_valid := s2_valid && !s2_actually_uncache && (!s2_in.tlbMiss || s2_hw_prf) io.prefetch_train.valid := GatedValidRegNext(s2_prefetch_train_valid) io.prefetch_train.bits.fromLsPipelineBundle(s2_in, latch = true, enable = s2_prefetch_train_valid) io.prefetch_train.bits.miss := RegEnable(io.dcache.resp.bits.miss, s2_prefetch_train_valid) // TODO: use trace with bank conflict? io.prefetch_train.bits.meta_prefetch := RegEnable(io.dcache.resp.bits.meta_prefetch, s2_prefetch_train_valid) io.prefetch_train.bits.meta_access := RegEnable(io.dcache.resp.bits.meta_access, s2_prefetch_train_valid) io.prefetch_train.bits.isFinalSplit := false.B io.prefetch_train.bits.misalignWith16Byte := false.B io.prefetch_train.bits.misalignNeedWakeUp := false.B io.prefetch_train.bits.updateAddrValid := false.B io.prefetch_train.bits.isMisalign := false.B io.prefetch_train.bits.hasException := false.B io.s1_prefetch_spec := s1_fire io.s2_prefetch_spec := s2_prefetch_train_valid val s2_prefetch_train_l1_valid = WireInit(false.B) s2_prefetch_train_l1_valid := s2_valid && !s2_actually_uncache io.prefetch_train_l1.valid := GatedValidRegNext(s2_prefetch_train_l1_valid) io.prefetch_train_l1.bits.fromLsPipelineBundle(s2_in, latch = true, enable = s2_prefetch_train_l1_valid) io.prefetch_train_l1.bits.miss := RegEnable(io.dcache.resp.bits.miss, s2_prefetch_train_l1_valid) io.prefetch_train_l1.bits.meta_prefetch := RegEnable(io.dcache.resp.bits.meta_prefetch, s2_prefetch_train_l1_valid) io.prefetch_train_l1.bits.meta_access := RegEnable(io.dcache.resp.bits.meta_access, s2_prefetch_train_l1_valid) io.prefetch_train_l1.bits.isFinalSplit := false.B io.prefetch_train_l1.bits.misalignWith16Byte := false.B io.prefetch_train_l1.bits.misalignNeedWakeUp := false.B io.prefetch_train_l1.bits.updateAddrValid := false.B io.prefetch_train_l1.bits.hasException := false.B io.prefetch_train_l1.bits.isMisalign := false.B if (env.FPGAPlatform){ io.dcache.s0_pc := DontCare io.dcache.s1_pc := DontCare io.dcache.s2_pc := DontCare }else{ io.dcache.s0_pc := s0_out.uop.pc io.dcache.s1_pc := s1_out.uop.pc io.dcache.s2_pc := s2_out.uop.pc } io.dcache.s2_kill := s2_pmp.ld || s2_pmp.st || s2_actually_uncache || s2_kill val s1_ld_left_fire = s1_valid && !s1_kill && s2_ready val s2_ld_valid_dup = RegInit(0.U(6.W)) s2_ld_valid_dup := 0x0.U(6.W) when (s1_ld_left_fire && !s1_out.isHWPrefetch) { s2_ld_valid_dup := 0x3f.U(6.W) } when (s1_kill || s1_out.isHWPrefetch) { s2_ld_valid_dup := 0x0.U(6.W) } assert(RegNext((s2_valid === s2_ld_valid_dup(0)) || RegNext(s1_out.isHWPrefetch))) // Pipeline // -------------------------------------------------------------------------------- // stage 3 // -------------------------------------------------------------------------------- // writeback and update load queue val s3_valid = GatedValidRegNext(s2_valid && !s2_out.isHWPrefetch && !s2_out.uop.robIdx.needFlush(io.redirect)) val s3_in = RegEnable(s2_out, s2_fire) val s3_out = Wire(Valid(new MemExuOutput)) val s3_dcache_rep = RegEnable(s2_dcache_fast_rep && s2_troublem, false.B, s2_fire) val s3_ld_valid_dup = RegEnable(s2_ld_valid_dup, s2_fire) val s3_fast_rep = Wire(Bool()) val s3_nc_with_data = RegNext(s2_nc_with_data) val s3_troublem = GatedValidRegNext(s2_troublem) val s3_kill = s3_in.uop.robIdx.needFlush(io.redirect) val s3_vecout = Wire(new OnlyVecExuOutput) val s3_vecActive = RegEnable(s2_out.vecActive, true.B, s2_fire) val s3_isvec = RegEnable(s2_out.isvec, false.B, s2_fire) val s3_vec_alignedType = RegEnable(s2_out.alignedType, s2_fire) val s3_vec_mBIndex = RegEnable(s2_out.mbIndex, s2_fire) val s3_frm_mabuf = s3_in.isFrmMisAlignBuf val s3_mmio_req = RegNext(s2_mmio_req) val s3_pdest = RegNext(Mux(s2_valid, s2_out.uop.pdest, s2_mmio_req.bits.uop.pdest)) val s3_rfWen = RegEnable(Mux(s2_valid, s2_out.uop.rfWen, s2_mmio_req.bits.uop.rfWen), s2_valid || s2_mmio_req.valid) val s3_fpWen = RegEnable(Mux(s2_valid, s2_out.uop.fpWen, s2_mmio_req.bits.uop.fpWen), s2_valid || s2_mmio_req.valid) val s3_data_select = RegEnable(s2_data_select, 0.U(s2_data_select.getWidth.W), s2_fire) val s3_data_select_by_offset = RegEnable(s2_data_select_by_offset, 0.U.asTypeOf(s2_data_select_by_offset), s2_fire) val s3_hw_err = if (EnableAccurateLoadError) { io.dcache.resp.bits.error_delayed && GatedValidRegNext(io.csrCtrl.cache_error_enable) && s3_troublem } else { WireInit(false.B) } val s3_safe_wakeup = RegEnable(s2_safe_wakeup, s2_fire) val s3_safe_writeback = RegEnable(s2_safe_writeback, s2_fire) || s3_hw_err val s3_exception = RegEnable(s2_real_exception, s2_fire) val s3_mis_align = RegEnable(s2_mis_align, s2_fire) val s3_trigger_debug_mode = RegEnable(s2_trigger_debug_mode, false.B, s2_fire) // TODO: Fix vector load merge buffer nack val s3_vec_mb_nack = Wire(Bool()) s3_vec_mb_nack := false.B XSError(s3_valid && s3_vec_mb_nack, "Merge buffer should always accept vector loads!") s3_ready := !s3_valid || s3_kill || io.ldout.ready // forwrad last beat val s3_fast_rep_canceled = io.replay.valid && io.replay.bits.forward_tlDchannel || io.misalign_ldin.valid || !io.dcache.req.ready val s3_can_enter_lsq_valid = s3_valid && (!s3_fast_rep || s3_fast_rep_canceled) && !s3_in.feedbacked && !s3_nc_with_data && !s3_in.misalignNeedWakeUp io.lsq.ldin.valid := s3_can_enter_lsq_valid // TODO: check this --by hx // io.lsq.ldin.valid := s3_valid && (!s3_fast_rep || !io.fast_rep_out.ready) && !s3_in.feedbacked && !s3_in.lateKill io.lsq.ldin.bits := s3_in io.lsq.ldin.bits.miss := s3_in.miss // connect to misalignBuffer val toMisalignBufferValid = s3_can_enter_lsq_valid && s3_mis_align && !s3_frm_mabuf io.misalign_buf.valid := toMisalignBufferValid io.misalign_buf.bits := s3_in /* <------- DANGEROUS: Don't change sequence here ! -------> */ io.lsq.ldin.bits.data_wen_dup := s3_ld_valid_dup.asBools io.lsq.ldin.bits.replacementUpdated := io.dcache.resp.bits.replacementUpdated io.lsq.ldin.bits.missDbUpdated := GatedValidRegNext(s2_fire && s2_in.hasROBEntry && !s2_in.tlbMiss && !s2_in.missDbUpdated) io.lsq.ldin.bits.updateAddrValid := !s3_mis_align && (!s3_frm_mabuf || s3_in.isFinalSplit) || s3_exception io.lsq.ldin.bits.hasException := false.B io.s3_dly_ld_err := false.B // s3_dly_ld_err && s3_valid io.lsq.ldin.bits.dcacheRequireReplay := s3_dcache_rep val s3_vp_match_fail = GatedValidRegNext(s2_fwd_vp_match_invalid) && s3_troublem val s3_rep_frm_fetch = s3_vp_match_fail val s3_ldld_rep_inst = io.lsq.ldld_nuke_query.resp.valid && io.lsq.ldld_nuke_query.resp.bits.rep_frm_fetch && GatedValidRegNext(io.csrCtrl.ldld_vio_check_enable) val s3_flushPipe = s3_ldld_rep_inst val s3_lrq_rep_info = WireInit(s3_in.rep_info) s3_lrq_rep_info.misalign_nack := toMisalignBufferValid && !io.misalign_buf.ready val s3_lrq_sel_rep_cause = PriorityEncoderOH(s3_lrq_rep_info.cause.asUInt) val s3_replayqueue_rep_cause = WireInit(0.U.asTypeOf(s3_in.rep_info.cause)) s3_replayqueue_rep_cause(LoadReplayCauses.C_MF) := s3_mis_align && s3_lrq_rep_info.misalign_nack val s3_mab_rep_info = WireInit(s3_in.rep_info) val s3_mab_sel_rep_cause = PriorityEncoderOH(s3_mab_rep_info.cause.asUInt) val s3_misalign_rep_cause = WireInit(0.U.asTypeOf(s3_in.rep_info.cause)) s3_misalign_rep_cause := Mux( s3_in.misalignNeedWakeUp, 0.U.asTypeOf(s3_mab_rep_info.cause.cloneType), VecInit(s3_mab_sel_rep_cause.asBools) ) when (s3_exception || s3_hw_err || s3_rep_frm_fetch || s3_frm_mabuf) { s3_replayqueue_rep_cause := 0.U.asTypeOf(s3_lrq_rep_info.cause.cloneType) } .otherwise { s3_replayqueue_rep_cause := VecInit(s3_lrq_sel_rep_cause.asBools) } io.lsq.ldin.bits.rep_info.cause := s3_replayqueue_rep_cause // Int load, if hit, will be writebacked at s3 s3_out.valid := s3_valid && s3_safe_writeback && !toMisalignBufferValid s3_out.bits.uop := s3_in.uop s3_out.bits.uop.fpWen := s3_in.uop.fpWen s3_out.bits.uop.exceptionVec(loadAccessFault) := s3_in.uop.exceptionVec(loadAccessFault) && s3_vecActive s3_out.bits.uop.exceptionVec(hardwareError) := s3_hw_err && s3_vecActive s3_out.bits.uop.flushPipe := false.B s3_out.bits.uop.replayInst := false.B s3_out.bits.data := s3_in.data s3_out.bits.isFromLoadUnit := true.B s3_out.bits.debug.isMMIO := s3_in.mmio s3_out.bits.debug.isNC := s3_in.nc s3_out.bits.debug.isPerfCnt := false.B s3_out.bits.debug.paddr := s3_in.paddr s3_out.bits.debug.vaddr := s3_in.vaddr // Vector load, writeback to merge buffer // TODO: Add assertion in merge buffer, merge buffer must accept vec load writeback s3_vecout.isvec := s3_isvec s3_vecout.vecdata := 0.U // Data will be assigned later s3_vecout.mask := s3_in.mask // s3_vecout.rob_idx_valid := s3_in.rob_idx_valid // s3_vecout.inner_idx := s3_in.inner_idx // s3_vecout.rob_idx := s3_in.rob_idx // s3_vecout.offset := s3_in.offset s3_vecout.reg_offset := s3_in.reg_offset s3_vecout.vecActive := s3_vecActive s3_vecout.is_first_ele := s3_in.is_first_ele // s3_vecout.uopQueuePtr := DontCare // uopQueuePtr is already saved in flow queue // s3_vecout.flowPtr := s3_in.flowPtr s3_vecout.elemIdx := s3_in.elemIdx // elemIdx is already saved in flow queue // TODO: s3_vecout.elemIdxInsideVd := s3_in.elemIdxInsideVd s3_vecout.trigger := s3_in.uop.trigger s3_vecout.vstart := s3_in.uop.vpu.vstart s3_vecout.vecTriggerMask := s3_in.vecTriggerMask val s3_usSecondInv = s3_in.usSecondInv val s3_frm_mis_flush = s3_frm_mabuf && (io.misalign_ldout.bits.rep_info.fwd_fail || io.misalign_ldout.bits.rep_info.mem_amb || io.misalign_ldout.bits.rep_info.nuke) io.rollback.valid := s3_valid && (s3_rep_frm_fetch || s3_flushPipe || s3_frm_mis_flush) && !s3_exception io.rollback.bits := DontCare io.rollback.bits.isRVC := s3_out.bits.uop.preDecodeInfo.isRVC io.rollback.bits.robIdx := s3_out.bits.uop.robIdx io.rollback.bits.ftqIdx := s3_out.bits.uop.ftqPtr io.rollback.bits.ftqOffset := s3_out.bits.uop.ftqOffset io.rollback.bits.level := Mux(s3_rep_frm_fetch || s3_frm_mis_flush, RedirectLevel.flush, RedirectLevel.flushAfter) io.rollback.bits.cfiUpdate.target := s3_out.bits.uop.pc io.rollback.bits.debug_runahead_checkpoint_id := s3_out.bits.uop.debugInfo.runahead_checkpoint_id /* <------- DANGEROUS: Don't change sequence here ! -------> */ io.lsq.ldin.bits.uop := s3_out.bits.uop // io.lsq.ldin.bits.uop.exceptionVec(loadAddrMisaligned) := Mux(s3_in.onlyMisalignException, false.B, s3_in.uop.exceptionVec(loadAddrMisaligned)) val s3_revoke = s3_exception || io.lsq.ldin.bits.rep_info.need_rep || s3_mis_align io.lsq.ldld_nuke_query.revoke := s3_revoke io.lsq.stld_nuke_query.revoke := s3_revoke // feedback slow s3_fast_rep := RegNext(s2_fast_rep) val s3_fb_no_waiting = !s3_in.isLoadReplay && (!(s3_fast_rep && !s3_fast_rep_canceled)) && !s3_in.feedbacked // feedback: scalar load will send feedback to RS // vector load will send signal to VL Merge Buffer, then send feedback at granularity of uops io.feedback_slow.valid := s3_valid && s3_fb_no_waiting && !s3_isvec && !s3_frm_mabuf io.feedback_slow.bits.hit := !s3_lrq_rep_info.need_rep || io.lsq.ldin.ready io.feedback_slow.bits.flushState := s3_in.ptwBack io.feedback_slow.bits.robIdx := s3_in.uop.robIdx io.feedback_slow.bits.sqIdx := s3_in.uop.sqIdx io.feedback_slow.bits.lqIdx := s3_in.uop.lqIdx io.feedback_slow.bits.sourceType := RSFeedbackType.lrqFull io.feedback_slow.bits.dataInvalidSqIdx := DontCare // TODO: vector wakeup? io.ldCancel.ld2Cancel := s3_valid && !s3_safe_wakeup && !s3_isvec && (!s3_frm_mabuf || s3_in.misalignNeedWakeUp) val s3_ld_wb_meta = Mux(s3_valid, s3_out.bits, s3_mmio_req.bits) // data from load queue refill val s3_ld_raw_data_frm_mmio = RegNextN(io.lsq.ld_raw_data, 3) val s3_merged_data_frm_mmio = s3_ld_raw_data_frm_mmio.mergedData() val s3_picked_data_frm_mmio = LookupTree(s3_ld_raw_data_frm_mmio.addrOffset, List( "b000".U -> s3_merged_data_frm_mmio(63, 0), "b001".U -> s3_merged_data_frm_mmio(63, 8), "b010".U -> s3_merged_data_frm_mmio(63, 16), "b011".U -> s3_merged_data_frm_mmio(63, 24), "b100".U -> s3_merged_data_frm_mmio(63, 32), "b101".U -> s3_merged_data_frm_mmio(63, 40), "b110".U -> s3_merged_data_frm_mmio(63, 48), "b111".U -> s3_merged_data_frm_mmio(63, 56) )) val s3_ld_data_frm_mmio = rdataHelper(s3_ld_raw_data_frm_mmio.uop, s3_picked_data_frm_mmio) /* data from pipe, which forward from respectively * dcache hit: [D channel, mshr, sbuffer, sq] * nc_with_data: [sq] */ val s2_ld_data_frm_nc = shiftDataToHigh(s2_out.paddr, s2_out.data) val s2_ld_raw_data_frm_pipe = Wire(new LoadDataFromDcacheBundle) s2_ld_raw_data_frm_pipe.respDcacheData := Mux(s2_nc_with_data, s2_ld_data_frm_nc, io.dcache.resp.bits.data) s2_ld_raw_data_frm_pipe.forward_D := s2_fwd_frm_d_chan && !s2_nc_with_data s2_ld_raw_data_frm_pipe.forwardData_D := s2_fwd_data_frm_d_chan s2_ld_raw_data_frm_pipe.forward_mshr := s2_fwd_frm_mshr && !s2_nc_with_data s2_ld_raw_data_frm_pipe.forwardData_mshr := s2_fwd_data_frm_mshr s2_ld_raw_data_frm_pipe.forward_result_valid := s2_fwd_data_valid s2_ld_raw_data_frm_pipe.forwardMask := s2_fwd_mask s2_ld_raw_data_frm_pipe.forwardData := s2_fwd_data s2_ld_raw_data_frm_pipe.uop := s2_out.uop s2_ld_raw_data_frm_pipe.addrOffset := s2_out.paddr(3, 0) val s2_ld_raw_data_frm_tlD = s2_ld_raw_data_frm_pipe.mergeTLData() val s2_merged_data_frm_pipe = s2_ld_raw_data_frm_pipe.mergeLsqFwdData(s2_ld_raw_data_frm_tlD) val s3_merged_data_frm_pipe = RegEnable(s2_merged_data_frm_pipe, s2_fire) // duplicate reg for ldout and vecldout private val LdDataDup = 3 require(LdDataDup >= 2) val s3_data_frm_pipe = VecInit((0 until LdDataDup).map(i => { VecInit(Seq( s3_merged_data_frm_pipe(63, 0), s3_merged_data_frm_pipe(71, 8), s3_merged_data_frm_pipe(79, 16), s3_merged_data_frm_pipe(87, 24), s3_merged_data_frm_pipe(95, 32), s3_merged_data_frm_pipe(103, 40), s3_merged_data_frm_pipe(111, 48), s3_merged_data_frm_pipe(119, 56), s3_merged_data_frm_pipe(127, 64), s3_merged_data_frm_pipe(127, 72), s3_merged_data_frm_pipe(127, 80), s3_merged_data_frm_pipe(127, 88), s3_merged_data_frm_pipe(127, 96), s3_merged_data_frm_pipe(127, 104), s3_merged_data_frm_pipe(127, 112), s3_merged_data_frm_pipe(127, 120), )) })) val s3_picked_data_frm_pipe = VecInit((0 until LdDataDup).map(i => { Mux1H(s3_data_select_by_offset, s3_data_frm_pipe(i)) })) val s3_ld_data_frm_pipe = VecInit((0 until LdDataDup).map(i => { newRdataHelper(s3_data_select, s3_picked_data_frm_pipe(i)) })) // FIXME: add 1 cycle delay ? // io.lsq.uncache.ready := !s3_valid val s3_ldout_valid = s3_mmio_req.valid || s3_out.valid && RegNext(!s2_out.isvec && !s2_out.isFrmMisAlignBuf) val s3_outexception = ExceptionNO.selectByFu(s3_out.bits.uop.exceptionVec, LduCfg).asUInt.orR && s3_vecActive io.ldout.valid := s3_ldout_valid io.ldout.bits := s3_ld_wb_meta io.ldout.bits.data := Mux(s3_valid, s3_ld_data_frm_pipe(0), s3_ld_data_frm_mmio) io.ldout.bits.uop.rfWen := s3_rfWen io.ldout.bits.uop.fpWen := s3_fpWen io.ldout.bits.uop.pdest := s3_pdest io.ldout.bits.uop.exceptionVec := ExceptionNO.selectByFu(s3_ld_wb_meta.uop.exceptionVec, LduCfg) io.ldout.bits.isFromLoadUnit := true.B io.ldout.bits.uop.fuType := Mux( s3_valid && s3_isvec, FuType.vldu.U, FuType.ldu.U ) XSError(s3_valid && s3_in.misalignNeedWakeUp && !s3_frm_mabuf, "Only the needwakeup from the misalignbuffer may be high") XSError(s3_valid && s3_vecout.isvec && s3_in.vecActive && !s3_vecout.mask.orR, "In vecActive, mask complement should not be 0") // TODO: check this --hx // io.ldout.valid := s3_out.valid && !s3_out.bits.uop.robIdx.needFlush(io.redirect) && !s3_vecout.isvec || // io.lsq.uncache.valid && !io.lsq.uncache.bits.uop.robIdx.needFlush(io.redirect) && !s3_out.valid && !io.lsq.uncache.bits.isVls // io.ldout.bits.data := Mux(s3_out.valid, s3_ld_data_frm_pipe, s3_ld_data_frm_mmio) // io.ldout.valid := s3_out.valid && !s3_out.bits.uop.robIdx.needFlush(io.redirect) || // s3_mmio_req.valid && !s3_mmio_req.bits.uop.robIdx.needFlush(io.redirect) && !s3_out.valid // s3 load fast replay io.fast_rep_out.valid := s3_valid && s3_fast_rep io.fast_rep_out.bits := s3_in io.fast_rep_out.bits.lateKill := s3_rep_frm_fetch io.fast_rep_out.bits.delayedLoadError := s3_hw_err val vecFeedback = s3_valid && s3_fb_no_waiting && s3_lrq_rep_info.need_rep && !io.lsq.ldin.ready && s3_isvec // vector output io.vecldout.bits.alignedType := s3_vec_alignedType // vec feedback io.vecldout.bits.vecFeedback := vecFeedback // TODO: VLSU, uncache data logic val vecdata = rdataVecHelper(s3_vec_alignedType(1,0), s3_picked_data_frm_pipe(1)) io.vecldout.bits.vecdata.get := Mux( s3_in.misalignWith16Byte, s3_picked_data_frm_pipe(1), Mux( s3_in.is128bit, s3_merged_data_frm_pipe, vecdata ) ) io.vecldout.bits.isvec := s3_vecout.isvec io.vecldout.bits.elemIdx := s3_vecout.elemIdx io.vecldout.bits.elemIdxInsideVd.get := s3_vecout.elemIdxInsideVd io.vecldout.bits.mask := s3_vecout.mask io.vecldout.bits.hasException := s3_exception io.vecldout.bits.reg_offset.get := s3_vecout.reg_offset io.vecldout.bits.usSecondInv := s3_usSecondInv io.vecldout.bits.mBIndex := s3_vec_mBIndex io.vecldout.bits.hit := !s3_lrq_rep_info.need_rep || io.lsq.ldin.ready io.vecldout.bits.sourceType := RSFeedbackType.lrqFull io.vecldout.bits.trigger := s3_vecout.trigger io.vecldout.bits.flushState := DontCare io.vecldout.bits.exceptionVec := ExceptionNO.selectByFu(s3_out.bits.uop.exceptionVec, VlduCfg) io.vecldout.bits.vaddr := s3_in.fullva io.vecldout.bits.vaNeedExt := s3_in.vaNeedExt io.vecldout.bits.gpaddr := s3_in.gpaddr io.vecldout.bits.isForVSnonLeafPTE := s3_in.isForVSnonLeafPTE io.vecldout.bits.mmio := DontCare io.vecldout.bits.vstart := s3_vecout.vstart io.vecldout.bits.vecTriggerMask := s3_vecout.vecTriggerMask io.vecldout.bits.nc := DontCare io.vecldout.valid := s3_out.valid && !s3_out.bits.uop.robIdx.needFlush(io.redirect) && s3_vecout.isvec && !s3_mis_align && !s3_frm_mabuf //|| // TODO: check this, why !io.lsq.uncache.bits.isVls before? // Now vector instruction don't support mmio. // io.lsq.uncache.valid && !io.lsq.uncache.bits.uop.robIdx.needFlush(io.redirect) && !s3_out.valid && io.lsq.uncache.bits.isVls //io.lsq.uncache.valid && !io.lsq.uncache.bits.uop.robIdx.needFlush(io.redirect) && !s3_out.valid && !io.lsq.uncache.bits.isVls io.misalign_ldout.valid := s3_valid && (!s3_fast_rep || s3_fast_rep_canceled) && s3_frm_mabuf io.misalign_ldout.bits := io.lsq.ldin.bits io.misalign_ldout.bits.data := Mux(s3_in.misalignWith16Byte, s3_merged_data_frm_pipe, s3_picked_data_frm_pipe(2)) io.misalign_ldout.bits.rep_info.cause := s3_misalign_rep_cause // fast load to load forward if (EnableLoadToLoadForward) { io.l2l_fwd_out.valid := s3_valid && !s3_in.mmio && !s3_in.nc && !s3_lrq_rep_info.need_rep io.l2l_fwd_out.data := Mux(s3_in.vaddr(3), s3_merged_data_frm_pipe(127, 64), s3_merged_data_frm_pipe(63, 0)) io.l2l_fwd_out.dly_ld_err := s3_hw_err || // ecc delayed error s3_ldld_rep_inst || s3_rep_frm_fetch } else { io.l2l_fwd_out.valid := false.B io.l2l_fwd_out.data := DontCare io.l2l_fwd_out.dly_ld_err := DontCare } // s1 io.debug_ls.s1_robIdx := s1_in.uop.robIdx.value io.debug_ls.s1_isLoadToLoadForward := s1_fire && s1_try_ptr_chasing && !s1_ptr_chasing_canceled io.debug_ls.s1_isTlbFirstMiss := s1_fire && s1_tlb_miss && s1_in.isFirstIssue // s2 io.debug_ls.s2_robIdx := s2_in.uop.robIdx.value io.debug_ls.s2_isBankConflict := s2_fire && (!s2_kill && s2_bank_conflict) io.debug_ls.s2_isDcacheFirstMiss := s2_fire && io.dcache.resp.bits.miss && s2_in.isFirstIssue io.debug_ls.s2_isForwardFail := s2_fire && s2_fwd_fail // s3 io.debug_ls.s3_robIdx := s3_in.uop.robIdx.value io.debug_ls.s3_isReplayFast := s3_valid && s3_fast_rep && !s3_fast_rep_canceled io.debug_ls.s3_isReplayRS := RegNext(io.feedback_fast.valid && !io.feedback_fast.bits.hit) || (io.feedback_slow.valid && !io.feedback_slow.bits.hit) io.debug_ls.s3_isReplaySlow := io.lsq.ldin.valid && io.lsq.ldin.bits.rep_info.need_rep io.debug_ls.s3_isReplay := s3_valid && s3_lrq_rep_info.need_rep // include fast+slow+rs replay io.debug_ls.replayCause := s3_lrq_rep_info.cause io.debug_ls.replayCnt := 1.U // Topdown io.lsTopdownInfo.s1.robIdx := s1_in.uop.robIdx.value io.lsTopdownInfo.s1.vaddr_valid := s1_valid && s1_in.hasROBEntry io.lsTopdownInfo.s1.vaddr_bits := s1_vaddr io.lsTopdownInfo.s2.robIdx := s2_in.uop.robIdx.value io.lsTopdownInfo.s2.paddr_valid := s2_fire && s2_in.hasROBEntry && !s2_in.tlbMiss io.lsTopdownInfo.s2.paddr_bits := s2_in.paddr io.lsTopdownInfo.s2.first_real_miss := io.dcache.resp.bits.real_miss io.lsTopdownInfo.s2.cache_miss_en := s2_fire && s2_in.hasROBEntry && !s2_in.tlbMiss && !s2_in.missDbUpdated // perf cnt XSPerfAccumulate("s0_in_valid", io.ldin.valid) XSPerfAccumulate("s0_in_block", io.ldin.valid && !io.ldin.fire) XSPerfAccumulate("s0_vecin_valid", io.vecldin.valid) XSPerfAccumulate("s0_vecin_block", io.vecldin.valid && !io.vecldin.fire) XSPerfAccumulate("s0_in_fire_first_issue", s0_valid && s0_sel_src.isFirstIssue) XSPerfAccumulate("s0_lsq_replay_issue", io.replay.fire) XSPerfAccumulate("s0_lsq_replay_vecissue", io.replay.fire && io.replay.bits.isvec) XSPerfAccumulate("s0_ldu_fire_first_issue", io.ldin.fire && s0_sel_src.isFirstIssue) XSPerfAccumulate("s0_fast_replay_issue", io.fast_rep_in.fire) XSPerfAccumulate("s0_fast_replay_vecissue", io.fast_rep_in.fire && io.fast_rep_in.bits.isvec) XSPerfAccumulate("s0_stall_out", s0_valid && !s0_can_go) XSPerfAccumulate("s0_stall_dcache", s0_valid && !io.dcache.req.ready) XSPerfAccumulate("s0_addr_spec_success", s0_fire && s0_dcache_vaddr(VAddrBits-1, 12) === io.ldin.bits.src(0)(VAddrBits-1, 12)) XSPerfAccumulate("s0_addr_spec_failed", s0_fire && s0_dcache_vaddr(VAddrBits-1, 12) =/= io.ldin.bits.src(0)(VAddrBits-1, 12)) XSPerfAccumulate("s0_addr_spec_success_once", s0_fire && s0_dcache_vaddr(VAddrBits-1, 12) === io.ldin.bits.src(0)(VAddrBits-1, 12) && s0_sel_src.isFirstIssue) XSPerfAccumulate("s0_addr_spec_failed_once", s0_fire && s0_dcache_vaddr(VAddrBits-1, 12) =/= io.ldin.bits.src(0)(VAddrBits-1, 12) && s0_sel_src.isFirstIssue) XSPerfAccumulate("s0_vec_addr_vlen_aligned", s0_fire && s0_sel_src.isvec && s0_dcache_vaddr(3, 0) === 0.U) XSPerfAccumulate("s0_vec_addr_vlen_unaligned", s0_fire && s0_sel_src.isvec && s0_dcache_vaddr(3, 0) =/= 0.U) XSPerfAccumulate("s0_forward_tl_d_channel", s0_out.forward_tlDchannel) XSPerfAccumulate("s0_hardware_prefetch_fire", s0_fire && s0_hw_prf_select) XSPerfAccumulate("s0_software_prefetch_fire", s0_fire && s0_sel_src.prf && s0_src_select_vec(int_iss_idx)) XSPerfAccumulate("s0_hardware_prefetch_blocked", io.prefetch_req.valid && !s0_hw_prf_select) XSPerfAccumulate("s0_hardware_prefetch_total", io.prefetch_req.valid) XSPerfAccumulate("s3_rollback_total", io.rollback.valid) XSPerfAccumulate("s3_rep_frm_fetch_rollback", io.rollback.valid && s3_rep_frm_fetch) XSPerfAccumulate("s3_flushPipe_rollback", io.rollback.valid && s3_flushPipe) XSPerfAccumulate("s3_frm_mis_flush_rollback", io.rollback.valid && s3_frm_mis_flush) XSPerfAccumulate("s1_in_valid", s1_valid) XSPerfAccumulate("s1_in_fire", s1_fire) XSPerfAccumulate("s1_in_fire_first_issue", s1_fire && s1_in.isFirstIssue) XSPerfAccumulate("s1_tlb_miss", s1_fire && s1_tlb_miss) XSPerfAccumulate("s1_tlb_miss_first_issue", s1_fire && s1_tlb_miss && s1_in.isFirstIssue) XSPerfAccumulate("s1_stall_out", s1_valid && !s1_can_go) XSPerfAccumulate("s1_dly_err", s1_valid && s1_fast_rep_dly_err) XSPerfAccumulate("s2_in_valid", s2_valid) XSPerfAccumulate("s2_in_fire", s2_fire) XSPerfAccumulate("s2_in_fire_first_issue", s2_fire && s2_in.isFirstIssue) XSPerfAccumulate("s2_dcache_miss", s2_fire && io.dcache.resp.bits.miss) XSPerfAccumulate("s2_dcache_miss_first_issue", s2_fire && io.dcache.resp.bits.miss && s2_in.isFirstIssue) XSPerfAccumulate("s2_dcache_real_miss_first_issue", s2_fire && io.dcache.resp.bits.miss && s2_in.isFirstIssue) XSPerfAccumulate("s2_full_forward", s2_fire && s2_full_fwd) XSPerfAccumulate("s2_dcache_miss_full_forward", s2_fire && s2_dcache_miss) XSPerfAccumulate("s2_fwd_frm_d_can", s2_valid && s2_fwd_frm_d_chan) XSPerfAccumulate("s2_fwd_frm_d_chan_or_mshr", s2_valid && s2_fwd_frm_d_chan_or_mshr) XSPerfAccumulate("s2_stall_out", s2_fire && !s2_can_go) XSPerfAccumulate("s2_prefetch", s2_fire && s2_prf) XSPerfAccumulate("s2_prefetch_ignored", s2_fire && s2_prf && io.dcache.s2_mq_nack) // ignore prefetch for mshr full / miss req port conflict XSPerfAccumulate("s2_prefetch_miss", s2_fire && s2_prf && io.dcache.resp.bits.miss) // prefetch req miss in l1 XSPerfAccumulate("s2_prefetch_hit", s2_fire && s2_prf && !io.dcache.resp.bits.miss) // prefetch req hit in l1 XSPerfAccumulate("s2_prefetch_accept", s2_fire && s2_prf && io.dcache.resp.bits.miss && !io.dcache.s2_mq_nack) // prefetch a missed line in l1, and l1 accepted it XSPerfAccumulate("s2_forward_req", s2_fire && s2_in.forward_tlDchannel) XSPerfAccumulate("s2_successfully_forward_channel_D", s2_fire && s2_fwd_frm_d_chan && s2_fwd_data_valid) XSPerfAccumulate("s2_successfully_forward_mshr", s2_fire && s2_fwd_frm_mshr && s2_fwd_data_valid) XSPerfAccumulate("load_to_load_forward", s1_try_ptr_chasing && !s1_ptr_chasing_canceled) XSPerfAccumulate("load_to_load_forward_try", s1_try_ptr_chasing) XSPerfAccumulate("load_to_load_forward_fail", s1_cancel_ptr_chasing) XSPerfAccumulate("load_to_load_forward_fail_cancelled", s1_cancel_ptr_chasing && s1_ptr_chasing_canceled) XSPerfAccumulate("load_to_load_forward_fail_wakeup_mismatch", s1_cancel_ptr_chasing && !s1_ptr_chasing_canceled && s1_not_fast_match) XSPerfAccumulate("load_to_load_forward_fail_op_not_ld", s1_cancel_ptr_chasing && !s1_ptr_chasing_canceled && !s1_not_fast_match && s1_fu_op_type_not_ld) XSPerfAccumulate("load_to_load_forward_fail_addr_align", s1_cancel_ptr_chasing && !s1_ptr_chasing_canceled && !s1_not_fast_match && !s1_fu_op_type_not_ld && s1_addr_misaligned) XSPerfAccumulate("load_to_load_forward_fail_set_mismatch", s1_cancel_ptr_chasing && !s1_ptr_chasing_canceled && !s1_not_fast_match && !s1_fu_op_type_not_ld && !s1_addr_misaligned && s1_addr_mismatch) XSPerfAccumulate("nc_ld_writeback", io.ldout.valid && s3_nc_with_data) XSPerfAccumulate("nc_ld_exception", s3_valid && s3_nc_with_data && s3_in.uop.exceptionVec.reduce(_ || _)) XSPerfAccumulate("nc_ldld_vio", s3_valid && s3_nc_with_data && s3_ldld_rep_inst) XSPerfAccumulate("nc_stld_vio", s3_valid && s3_nc_with_data && s3_in.rep_info.nuke) XSPerfAccumulate("nc_ldld_vioNack", s3_valid && s3_nc_with_data && s3_in.rep_info.rar_nack) XSPerfAccumulate("nc_stld_vioNack", s3_valid && s3_nc_with_data && s3_in.rep_info.raw_nack) XSPerfAccumulate("nc_stld_fwd", s3_valid && s3_nc_with_data && RegNext(s2_full_fwd)) XSPerfAccumulate("nc_stld_fwdNotReady", s3_valid && s3_nc_with_data && RegNext(s2_mem_amb || s2_fwd_fail)) XSPerfAccumulate("nc_stld_fwdAddrMismatch", s3_valid && s3_nc_with_data && s3_vp_match_fail) // bug lyq: some signals in perfEvents are no longer suitable for the current MemBlock design // hardware performance counter val perfEvents = Seq( ("load_s0_in_fire ", s0_fire ), ("load_to_load_forward ", s1_fire && s1_try_ptr_chasing && !s1_ptr_chasing_canceled ), ("stall_dcache ", s0_valid && s0_can_go && !io.dcache.req.ready ), ("load_s1_in_fire ", s0_fire ), ("load_s1_tlb_miss ", s1_fire && io.tlb.resp.bits.miss ), ("load_s2_in_fire ", s1_fire ), ("load_s2_dcache_miss ", s2_fire && io.dcache.resp.bits.miss ), ) generatePerfEvent() if (backendParams.debugEn){ dontTouch(s0_src_valid_vec) dontTouch(s0_src_ready_vec) dontTouch(s0_src_select_vec) dontTouch(s3_ld_data_frm_pipe) s3_data_select_by_offset.map(x=> dontTouch(x)) s3_data_frm_pipe.map(x=> dontTouch(x)) s3_picked_data_frm_pipe.map(x=> dontTouch(x)) } XSDebug(io.ldout.fire, "ldout %x\n", io.ldout.bits.uop.pc) // end }