10d32f713Shappy-lxpackage xiangshan.mem.prefetch 20d32f713Shappy-lx 38891a219SYinan Xuimport org.chipsalliance.cde.config.Parameters 40d32f713Shappy-lximport chisel3._ 50d32f713Shappy-lximport chisel3.util._ 60d32f713Shappy-lximport xiangshan._ 70d32f713Shappy-lximport utils._ 80d32f713Shappy-lximport utility._ 90d32f713Shappy-lximport xiangshan.cache.HasDCacheParameters 100d32f713Shappy-lximport xiangshan.cache.mmu._ 110d32f713Shappy-lximport xiangshan.mem.{L1PrefetchReq, LdPrefetchTrainBundle} 120d32f713Shappy-lximport xiangshan.mem.trace._ 130d32f713Shappy-lximport scala.collection.SeqLike 140d32f713Shappy-lx 150d32f713Shappy-lxtrait HasStridePrefetchHelper extends HasL1PrefetchHelper { 160d32f713Shappy-lx val STRIDE_FILTER_SIZE = 6 170d32f713Shappy-lx val STRIDE_ENTRY_NUM = 10 180d32f713Shappy-lx val STRIDE_BITS = 10 + BLOCK_OFFSET 190d32f713Shappy-lx val STRIDE_VADDR_BITS = 10 + BLOCK_OFFSET 200d32f713Shappy-lx val STRIDE_CONF_BITS = 2 210d32f713Shappy-lx 220d32f713Shappy-lx // detail control 230d32f713Shappy-lx val ALWAYS_UPDATE_PRE_VADDR = 1 // 1 for true, 0 for false 240d32f713Shappy-lx val AGGRESIVE_POLICY = false // if true, prefetch degree is greater than 1, 1 otherwise 250d32f713Shappy-lx val STRIDE_LOOK_AHEAD_BLOCKS = 2 // aggressive degree 260d32f713Shappy-lx val LOOK_UP_STREAM = false // if true, avoid collision with stream 270d32f713Shappy-lx 280d32f713Shappy-lx val STRIDE_WIDTH_BLOCKS = if(AGGRESIVE_POLICY) STRIDE_LOOK_AHEAD_BLOCKS else 1 290d32f713Shappy-lx 300d32f713Shappy-lx def MAX_CONF = (1 << STRIDE_CONF_BITS) - 1 310d32f713Shappy-lx} 320d32f713Shappy-lx 330d32f713Shappy-lxclass StrideMetaBundle(implicit p: Parameters) extends XSBundle with HasStridePrefetchHelper { 340d32f713Shappy-lx val pre_vaddr = UInt(STRIDE_VADDR_BITS.W) 350d32f713Shappy-lx val stride = UInt(STRIDE_BITS.W) 360d32f713Shappy-lx val confidence = UInt(STRIDE_CONF_BITS.W) 370d32f713Shappy-lx val hash_pc = UInt(HASH_TAG_WIDTH.W) 380d32f713Shappy-lx 390d32f713Shappy-lx def reset(index: Int) = { 400d32f713Shappy-lx pre_vaddr := 0.U 410d32f713Shappy-lx stride := 0.U 420d32f713Shappy-lx confidence := 0.U 430d32f713Shappy-lx hash_pc := index.U 440d32f713Shappy-lx } 450d32f713Shappy-lx 460d32f713Shappy-lx def alloc(vaddr: UInt, alloc_hash_pc: UInt) = { 470d32f713Shappy-lx pre_vaddr := vaddr(STRIDE_VADDR_BITS - 1, 0) 480d32f713Shappy-lx stride := 0.U 490d32f713Shappy-lx confidence := 0.U 500d32f713Shappy-lx hash_pc := alloc_hash_pc 510d32f713Shappy-lx } 520d32f713Shappy-lx 530d32f713Shappy-lx def update(vaddr: UInt, always_update_pre_vaddr: Bool) = { 540d32f713Shappy-lx val new_vaddr = vaddr(STRIDE_VADDR_BITS - 1, 0) 550d32f713Shappy-lx val new_stride = new_vaddr - pre_vaddr 560d32f713Shappy-lx val new_stride_blk = block_addr(new_stride) 570d32f713Shappy-lx // NOTE: for now, disable negtive stride 580d32f713Shappy-lx val stride_valid = new_stride_blk =/= 0.U && new_stride_blk =/= 1.U && new_stride(STRIDE_VADDR_BITS - 1) === 0.U 590d32f713Shappy-lx val stride_match = new_stride === stride 600d32f713Shappy-lx val low_confidence = confidence <= 1.U 610d32f713Shappy-lx val can_send_pf = stride_valid && stride_match && confidence === MAX_CONF.U 620d32f713Shappy-lx 630d32f713Shappy-lx when(stride_valid) { 640d32f713Shappy-lx when(stride_match) { 650d32f713Shappy-lx confidence := Mux(confidence === MAX_CONF.U, confidence, confidence + 1.U) 660d32f713Shappy-lx }.otherwise { 670d32f713Shappy-lx confidence := Mux(confidence === 0.U, confidence, confidence - 1.U) 680d32f713Shappy-lx when(low_confidence) { 690d32f713Shappy-lx stride := new_stride 700d32f713Shappy-lx } 710d32f713Shappy-lx } 720d32f713Shappy-lx pre_vaddr := new_vaddr 730d32f713Shappy-lx } 740d32f713Shappy-lx when(always_update_pre_vaddr) { 750d32f713Shappy-lx pre_vaddr := new_vaddr 760d32f713Shappy-lx } 770d32f713Shappy-lx 780d32f713Shappy-lx (can_send_pf, new_stride) 790d32f713Shappy-lx } 800d32f713Shappy-lx 810d32f713Shappy-lx} 820d32f713Shappy-lx 830d32f713Shappy-lxclass StrideMetaArray(implicit p: Parameters) extends XSModule with HasStridePrefetchHelper { 840d32f713Shappy-lx val io = IO(new XSBundle { 850d32f713Shappy-lx val enable = Input(Bool()) 860d32f713Shappy-lx // TODO: flush all entry when process changing happens, or disable stream prefetch for a while 870d32f713Shappy-lx val flush = Input(Bool()) 880d32f713Shappy-lx val dynamic_depth = Input(UInt(32.W)) // TODO: enable dynamic stride depth 890d32f713Shappy-lx val train_req = Flipped(DecoupledIO(new PrefetchReqBundle)) 90*20e09ab1Shappy-lx val l1_prefetch_req = ValidIO(new StreamPrefetchReqBundle) 91*20e09ab1Shappy-lx val l2_l3_prefetch_req = ValidIO(new StreamPrefetchReqBundle) 920d32f713Shappy-lx // query Stream component to see if a stream pattern has already been detected 930d32f713Shappy-lx val stream_lookup_req = ValidIO(new PrefetchReqBundle) 940d32f713Shappy-lx val stream_lookup_resp = Input(Bool()) 950d32f713Shappy-lx }) 960d32f713Shappy-lx 970d32f713Shappy-lx val array = Reg(Vec(STRIDE_ENTRY_NUM, new StrideMetaBundle)) 980d32f713Shappy-lx val replacement = ReplacementPolicy.fromString("plru", STRIDE_ENTRY_NUM) 990d32f713Shappy-lx 1000d32f713Shappy-lx // s0: hash pc -> cam all entries 1010d32f713Shappy-lx val s0_can_accept = Wire(Bool()) 1020d32f713Shappy-lx val s0_valid = io.train_req.fire 1030d32f713Shappy-lx val s0_vaddr = io.train_req.bits.vaddr 1040d32f713Shappy-lx val s0_pc = io.train_req.bits.pc 1050d32f713Shappy-lx val s0_pc_hash = pc_hash_tag(s0_pc) 1060d32f713Shappy-lx val s0_pc_match_vec = VecInit(array.map(_.hash_pc === s0_pc_hash)).asUInt 1070d32f713Shappy-lx val s0_hit = s0_pc_match_vec.orR 1080d32f713Shappy-lx val s0_index = Mux(s0_hit, OHToUInt(s0_pc_match_vec), replacement.way) 1090d32f713Shappy-lx io.train_req.ready := s0_can_accept 1100d32f713Shappy-lx io.stream_lookup_req.valid := s0_valid 1110d32f713Shappy-lx io.stream_lookup_req.bits := io.train_req.bits 1120d32f713Shappy-lx 1130d32f713Shappy-lx when(s0_valid) { 1140d32f713Shappy-lx replacement.access(s0_index) 1150d32f713Shappy-lx } 1160d32f713Shappy-lx 1170d32f713Shappy-lx assert(PopCount(s0_pc_match_vec) <= 1.U) 1180d32f713Shappy-lx XSPerfAccumulate("s0_valid", s0_valid) 1190d32f713Shappy-lx XSPerfAccumulate("s0_hit", s0_valid && s0_hit) 1200d32f713Shappy-lx XSPerfAccumulate("s0_miss", s0_valid && !s0_hit) 1210d32f713Shappy-lx 1220d32f713Shappy-lx // s1: alloc or update 1230d32f713Shappy-lx val s1_valid = RegNext(s0_valid) 1240d32f713Shappy-lx val s1_index = RegEnable(s0_index, s0_valid) 1250d32f713Shappy-lx val s1_pc_hash = RegEnable(s0_pc_hash, s0_valid) 1260d32f713Shappy-lx val s1_vaddr = RegEnable(s0_vaddr, s0_valid) 1270d32f713Shappy-lx val s1_hit = RegEnable(s0_hit, s0_valid) 1280d32f713Shappy-lx val s1_alloc = s1_valid && !s1_hit 1290d32f713Shappy-lx val s1_update = s1_valid && s1_hit 1300d32f713Shappy-lx val s1_stride = array(s1_index).stride 1310d32f713Shappy-lx val s1_new_stride = WireInit(0.U(STRIDE_BITS.W)) 1320d32f713Shappy-lx val s1_can_send_pf = WireInit(false.B) 1330d32f713Shappy-lx s0_can_accept := !(s1_valid && s1_pc_hash === s0_pc_hash) 1340d32f713Shappy-lx 1350d32f713Shappy-lx val always_update = WireInit(Constantin.createRecord("always_update" + p(XSCoreParamsKey).HartId.toString, initValue = ALWAYS_UPDATE_PRE_VADDR.U)) === 1.U 1360d32f713Shappy-lx 1370d32f713Shappy-lx when(s1_alloc) { 1380d32f713Shappy-lx array(s1_index).alloc( 1390d32f713Shappy-lx vaddr = s1_vaddr, 1400d32f713Shappy-lx alloc_hash_pc = s1_pc_hash 1410d32f713Shappy-lx ) 1420d32f713Shappy-lx }.elsewhen(s1_update) { 1430d32f713Shappy-lx val res = array(s1_index).update(s1_vaddr, always_update) 1440d32f713Shappy-lx s1_can_send_pf := res._1 1450d32f713Shappy-lx s1_new_stride := res._2 1460d32f713Shappy-lx } 1470d32f713Shappy-lx 1480d32f713Shappy-lx val l1_stride_ratio_const = WireInit(Constantin.createRecord("l1_stride_ratio" + p(XSCoreParamsKey).HartId.toString, initValue = 2.U)) 1490d32f713Shappy-lx val l1_stride_ratio = l1_stride_ratio_const(3, 0) 1500d32f713Shappy-lx val l2_stride_ratio_const = WireInit(Constantin.createRecord("l2_stride_ratio" + p(XSCoreParamsKey).HartId.toString, initValue = 5.U)) 1510d32f713Shappy-lx val l2_stride_ratio = l2_stride_ratio_const(3, 0) 1520d32f713Shappy-lx // s2: calculate L1 & L2 pf addr 1530d32f713Shappy-lx val s2_valid = RegNext(s1_valid && s1_can_send_pf) 1540d32f713Shappy-lx val s2_vaddr = RegEnable(s1_vaddr, s1_valid && s1_can_send_pf) 1550d32f713Shappy-lx val s2_stride = RegEnable(s1_stride, s1_valid && s1_can_send_pf) 1560d32f713Shappy-lx val s2_l1_depth = s2_stride << l1_stride_ratio 1570d32f713Shappy-lx val s2_l1_pf_vaddr = (s2_vaddr + s2_l1_depth)(VAddrBits - 1, 0) 1580d32f713Shappy-lx val s2_l2_depth = s2_stride << l2_stride_ratio 1590d32f713Shappy-lx val s2_l2_pf_vaddr = (s2_vaddr + s2_l2_depth)(VAddrBits - 1, 0) 1600d32f713Shappy-lx val s2_l1_pf_req_bits = (new StreamPrefetchReqBundle).getStreamPrefetchReqBundle( 16158a9a40dSTang Haojin valid = s2_valid, 1620d32f713Shappy-lx vaddr = s2_l1_pf_vaddr, 1630d32f713Shappy-lx width = STRIDE_WIDTH_BLOCKS, 1640d32f713Shappy-lx decr_mode = false.B, 1650d32f713Shappy-lx sink = SINK_L1, 166*20e09ab1Shappy-lx source = L1_HW_PREFETCH_STRIDE, 167*20e09ab1Shappy-lx // TODO: add stride debug db, not useful for now 168*20e09ab1Shappy-lx t_pc = 0xdeadbeefL.U, 169*20e09ab1Shappy-lx t_va = 0xdeadbeefL.U 170*20e09ab1Shappy-lx ) 1710d32f713Shappy-lx val s2_l2_pf_req_bits = (new StreamPrefetchReqBundle).getStreamPrefetchReqBundle( 17258a9a40dSTang Haojin valid = s2_valid, 1730d32f713Shappy-lx vaddr = s2_l2_pf_vaddr, 1740d32f713Shappy-lx width = STRIDE_WIDTH_BLOCKS, 1750d32f713Shappy-lx decr_mode = false.B, 1760d32f713Shappy-lx sink = SINK_L2, 177*20e09ab1Shappy-lx source = L1_HW_PREFETCH_STRIDE, 178*20e09ab1Shappy-lx // TODO: add stride debug db, not useful for now 179*20e09ab1Shappy-lx t_pc = 0xdeadbeefL.U, 180*20e09ab1Shappy-lx t_va = 0xdeadbeefL.U 181*20e09ab1Shappy-lx ) 1820d32f713Shappy-lx 1830d32f713Shappy-lx // s3: send l1 pf out 1840d32f713Shappy-lx val s3_valid = if (LOOK_UP_STREAM) RegNext(s2_valid) && !io.stream_lookup_resp else RegNext(s2_valid) 1850d32f713Shappy-lx val s3_l1_pf_req_bits = RegEnable(s2_l1_pf_req_bits, s2_valid) 1860d32f713Shappy-lx val s3_l2_pf_req_bits = RegEnable(s2_l2_pf_req_bits, s2_valid) 1870d32f713Shappy-lx 1880d32f713Shappy-lx // s4: send l2 pf out 1890d32f713Shappy-lx val s4_valid = RegNext(s3_valid) 1900d32f713Shappy-lx val s4_l2_pf_req_bits = RegEnable(s3_l2_pf_req_bits, s3_valid) 1910d32f713Shappy-lx 192*20e09ab1Shappy-lx io.l1_prefetch_req.valid := s3_valid 193*20e09ab1Shappy-lx io.l1_prefetch_req.bits := s3_l1_pf_req_bits 194*20e09ab1Shappy-lx io.l2_l3_prefetch_req.valid := s4_valid 195*20e09ab1Shappy-lx io.l2_l3_prefetch_req.bits := s4_l2_pf_req_bits 1960d32f713Shappy-lx 197*20e09ab1Shappy-lx XSPerfAccumulate("pf_valid", PopCount(Seq(io.l1_prefetch_req.valid, io.l2_l3_prefetch_req.valid))) 198*20e09ab1Shappy-lx XSPerfAccumulate("l1_pf_valid", s3_valid) 1990d32f713Shappy-lx XSPerfAccumulate("l2_pf_valid", s4_valid) 2000d32f713Shappy-lx XSPerfAccumulate("detect_stream", io.stream_lookup_resp) 2010d32f713Shappy-lx XSPerfHistogram("high_conf_num", PopCount(VecInit(array.map(_.confidence === MAX_CONF.U))).asUInt, true.B, 0, STRIDE_ENTRY_NUM, 1) 2020d32f713Shappy-lx for(i <- 0 until STRIDE_ENTRY_NUM) { 2030d32f713Shappy-lx XSPerfAccumulate(s"entry_${i}_update", i.U === s1_index && s1_update) 2040d32f713Shappy-lx for(j <- 0 until 4) { 2050d32f713Shappy-lx XSPerfAccumulate(s"entry_${i}_disturb_${j}", i.U === s1_index && s1_update && 2060d32f713Shappy-lx j.U === s1_new_stride && 2070d32f713Shappy-lx array(s1_index).confidence === MAX_CONF.U && 2080d32f713Shappy-lx array(s1_index).stride =/= s1_new_stride 2090d32f713Shappy-lx ) 2100d32f713Shappy-lx } 2110d32f713Shappy-lx } 2120d32f713Shappy-lx 2130d32f713Shappy-lx for(i <- 0 until STRIDE_ENTRY_NUM) { 2140d32f713Shappy-lx when(reset.asBool || RegNext(io.flush)) { 2150d32f713Shappy-lx array(i).reset(i) 2160d32f713Shappy-lx } 2170d32f713Shappy-lx } 2180d32f713Shappy-lx}