1/*************************************************************************************** 2* Copyright (c) 2020-2021 Institute of Computing Technology, Chinese Academy of Sciences 3* Copyright (c) 2020-2021 Peng Cheng Laboratory 4* 5* XiangShan is licensed under Mulan PSL v2. 6* You can use this software according to the terms and conditions of the Mulan PSL v2. 7* You may obtain a copy of Mulan PSL v2 at: 8* http://license.coscl.org.cn/MulanPSL2 9* 10* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND, 11* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT, 12* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE. 13* 14* See the Mulan PSL v2 for more details. 15***************************************************************************************/ 16 17package xiangshan.backend.exu 18 19import org.chipsalliance.cde.config.Parameters 20import chisel3._ 21import chisel3.experimental.hierarchy.{Definition, instantiable} 22import chisel3.util._ 23import freechips.rocketchip.diplomacy.{LazyModule, LazyModuleImp} 24import utility.DelayN 25import utils._ 26import xiangshan.backend.fu.{CSRFileIO, FenceIO, FuncUnitInput} 27import xiangshan.backend.Bundles.{ExuInput, ExuOutput, MemExuInput, MemExuOutput} 28import xiangshan.{FPUCtrlSignals, HasXSParameter, Redirect, XSBundle, XSModule} 29import xiangshan.backend.datapath.WbConfig.{PregWB, _} 30import xiangshan.backend.fu.FuType 31import xiangshan.backend.fu.vector.Bundles.{VType, Vxrm} 32import xiangshan.backend.fu.fpu.Bundles.Frm 33 34class ExeUnitIO(params: ExeUnitParams)(implicit p: Parameters) extends XSBundle { 35 val flush = Flipped(ValidIO(new Redirect())) 36 val in = Flipped(DecoupledIO(new ExuInput(params))) 37 val out = DecoupledIO(new ExuOutput(params)) 38 val csrio = OptionWrapper(params.hasCSR, new CSRFileIO) 39 val fenceio = OptionWrapper(params.hasFence, new FenceIO) 40 val frm = OptionWrapper(params.needSrcFrm, Input(Frm())) 41 val vxrm = OptionWrapper(params.needSrcVxrm, Input(Vxrm())) 42 val vtype = OptionWrapper(params.writeVType, new VType) 43} 44 45class ExeUnit(val exuParams: ExeUnitParams)(implicit p: Parameters) extends LazyModule { 46 override def shouldBeInlined: Boolean = false 47 48 lazy val module = new ExeUnitImp(this)(p, exuParams) 49} 50 51class ExeUnitImp( 52 override val wrapper: ExeUnit 53)(implicit 54 p: Parameters, exuParams: ExeUnitParams 55) extends LazyModuleImp(wrapper) with HasXSParameter{ 56 private val fuCfgs = exuParams.fuConfigs 57 58 val io = IO(new ExeUnitIO(exuParams)) 59 60 val funcUnits = fuCfgs.map(cfg => { 61 assert(cfg.fuGen != null, cfg.name + "Cfg'fuGen is null !!!") 62 val module = cfg.fuGen(p, cfg) 63 module 64 }) 65 66 if (EnableClockGate) { 67 fuCfgs.zip(funcUnits).foreach { case (cfg, fu) => 68 val clk_en = WireInit(false.B) 69 val fuVld_en = WireInit(false.B) 70 val fuVld_en_reg = RegInit(false.B) 71 val uncer_en_reg = RegInit(false.B) 72 73 def latReal: Int = cfg.latency.latencyVal.getOrElse(0) 74 def extralat: Int = cfg.latency.extraLatencyVal.getOrElse(0) 75 76 val uncerLat = cfg.latency.uncertainLatencyVal.nonEmpty 77 val lat0 = (latReal == 0 && !uncerLat).asBool 78 val latN = (latReal > 0&& !uncerLat).asBool 79 80 81 82 val fuVldVec = (io.in.valid && latN) +: Seq.fill(latReal)(RegInit(false.B)) 83 val fuRdyVec = Seq.fill(latReal)(Wire(Bool())) :+ io.out.ready 84 85 for (i <- 0 until latReal) { 86 fuRdyVec(i) := !fuVldVec(i + 1) || fuRdyVec(i + 1) 87 } 88 89 for (i <- 1 to latReal) { 90 when(fuRdyVec(i - 1) && fuVldVec(i - 1)) { 91 fuVldVec(i) := fuVldVec(i - 1) 92 }.elsewhen(fuRdyVec(i)) { 93 fuVldVec(i) := false.B 94 } 95 } 96 fuVld_en := fuVldVec.map(v => v).reduce(_ || _) 97 fuVld_en_reg := fuVld_en 98 99 when(uncerLat.asBool && io.in.fire) { 100 uncer_en_reg := true.B 101 }.elsewhen(uncerLat.asBool && io.out.fire) { 102 uncer_en_reg := false.B 103 } 104 105 when(lat0 && io.in.fire) { 106 clk_en := true.B 107 }.elsewhen(latN && fuVld_en || fuVld_en_reg) { 108 clk_en := true.B 109 }.elsewhen(uncerLat.asBool && io.in.fire || uncer_en_reg) { 110 clk_en := true.B 111 } 112 113 if (cfg.ckAlwaysEn) { 114 clk_en := true.B 115 } 116 117 val clk_gate = Module(new ClockGate) 118 clk_gate.io.TE := false.B 119 clk_gate.io.E := clk_en 120 clk_gate.io.CK := clock 121 fu.clock := clk_gate.io.Q 122 XSPerfAccumulate(s"clock_gate_en_${fu.cfg.name}", clk_en) 123 } 124 } 125 126 val busy = RegInit(false.B) 127 if (exuParams.latencyCertain){ 128 busy := false.B 129 } 130 else { 131 val robIdx = RegEnable(io.in.bits.robIdx, io.in.fire) 132 when(io.in.fire && io.in.bits.robIdx.needFlush(io.flush)) { 133 busy := false.B 134 }.elsewhen(busy && robIdx.needFlush(io.flush)) { 135 busy := false.B 136 }.elsewhen(io.out.fire) { 137 busy := false.B 138 }.elsewhen(io.in.fire) { 139 busy := true.B 140 } 141 } 142 143 exuParams.wbPortConfigs.map{ 144 x => x match { 145 case IntWB(port, priority) => assert(priority >= 0 && priority <= 2, 146 s"${exuParams.name}: WbPort must priority=0 or priority=1") 147 case VfWB (port, priority) => assert(priority >= 0 && priority <= 2, 148 s"${exuParams.name}: WbPort must priority=0 or priority=1") 149 case _ => 150 } 151 } 152 val intWbPort = exuParams.getIntWBPort 153 if (intWbPort.isDefined){ 154 val sameIntPortExuParam = backendParams.allExuParams.filter(_.getIntWBPort.isDefined) 155 .filter(_.getIntWBPort.get.port == intWbPort.get.port) 156 val samePortOneCertainOneUncertain = sameIntPortExuParam.map(_.latencyCertain).contains(true) && sameIntPortExuParam.map(_.latencyCertain).contains(false) 157 if (samePortOneCertainOneUncertain) sameIntPortExuParam.map(samePort => 158 samePort.wbPortConfigs.map( 159 x => x match { 160 case IntWB(port, priority) => { 161 if (!samePort.latencyCertain) assert(priority == sameIntPortExuParam.size - 1, 162 s"${samePort.name}: IntWbPort $port must latencyCertain priority=0 or latencyUnCertain priority=max(${sameIntPortExuParam.size - 1})") 163 // Certain latency can be handled by WbBusyTable, so there is no need to limit the exu's WB priority 164 } 165 case _ => 166 } 167 ) 168 ) 169 } 170 val vfWbPort = exuParams.getVfWBPort 171 if (vfWbPort.isDefined) { 172 val sameVfPortExuParam = backendParams.allExuParams.filter(_.getVfWBPort.isDefined) 173 .filter(_.getVfWBPort.get.port == vfWbPort.get.port) 174 val samePortOneCertainOneUncertain = sameVfPortExuParam.map(_.latencyCertain).contains(true) && sameVfPortExuParam.map(_.latencyCertain).contains(false) 175 if (samePortOneCertainOneUncertain) sameVfPortExuParam.map(samePort => 176 samePort.wbPortConfigs.map( 177 x => x match { 178 case VfWB(port, priority) => { 179 if (!samePort.latencyCertain) assert(priority == sameVfPortExuParam.size - 1, 180 s"${samePort.name}: VfWbPort $port must latencyCertain priority=0 or latencyUnCertain priority=max(${sameVfPortExuParam.size - 1})") 181 // Certain latency can be handled by WbBusyTable, so there is no need to limit the exu's WB priority 182 } 183 case _ => 184 } 185 ) 186 ) 187 } 188 if(backendParams.debugEn) { 189 dontTouch(io.out.ready) 190 } 191 // rob flush --> funcUnits 192 funcUnits.zipWithIndex.foreach { case (fu, i) => 193 fu.io.flush <> io.flush 194 } 195 196 def acceptCond(input: ExuInput): Seq[Bool] = { 197 input.params.fuConfigs.map(_.fuSel(input)) 198 } 199 200 val in1ToN = Module(new Dispatcher(new ExuInput(exuParams), funcUnits.length, acceptCond)) 201 202 // ExeUnit.in <---> Dispatcher.in 203 in1ToN.io.in.valid := io.in.valid && !busy 204 in1ToN.io.in.bits := io.in.bits 205 io.in.ready := !busy && in1ToN.io.in.ready 206 207 // Dispatcher.out <---> FunctionUnits 208 in1ToN.io.out.zip(funcUnits.map(_.io.in)).foreach { 209 case (source: DecoupledIO[ExuInput], sink: DecoupledIO[FuncUnitInput]) => 210 sink.valid := source.valid 211 source.ready := sink.ready 212 213 sink.bits.data.src.zip(source.bits.src).foreach { case(fuSrc, exuSrc) => fuSrc := exuSrc } 214 sink.bits.data.pc .foreach(x => x := source.bits.pc.get) 215 sink.bits.data.imm := source.bits.imm 216 sink.bits.ctrl.fuOpType := source.bits.fuOpType 217 sink.bits.ctrl.robIdx := source.bits.robIdx 218 sink.bits.ctrl.pdest := source.bits.pdest 219 sink.bits.ctrl.rfWen .foreach(x => x := source.bits.rfWen.get) 220 sink.bits.ctrl.fpWen .foreach(x => x := source.bits.fpWen.get) 221 sink.bits.ctrl.vecWen .foreach(x => x := source.bits.vecWen.get) 222 sink.bits.ctrl.flushPipe .foreach(x => x := source.bits.flushPipe.get) 223 sink.bits.ctrl.preDecode .foreach(x => x := source.bits.preDecode.get) 224 sink.bits.ctrl.ftqIdx .foreach(x => x := source.bits.ftqIdx.get) 225 sink.bits.ctrl.ftqOffset .foreach(x => x := source.bits.ftqOffset.get) 226 sink.bits.ctrl.predictInfo .foreach(x => x := source.bits.predictInfo.get) 227 sink.bits.ctrl.fpu .foreach(x => x := source.bits.fpu.get) 228 sink.bits.ctrl.vpu .foreach(x => x := source.bits.vpu.get) 229 sink.bits.perfDebugInfo := source.bits.perfDebugInfo 230 } 231 232 private val OutresVecs = funcUnits.map { fu => 233 def latDiff :Int = fu.cfg.latency.extraLatencyVal.getOrElse(0) 234 val OutresVec = fu.io.out.bits.res +: Seq.fill(latDiff)(Reg(chiselTypeOf(fu.io.out.bits.res))) 235 for (i <- 1 to latDiff) { 236 OutresVec(i) := OutresVec(i - 1) 237 } 238 OutresVec 239 } 240 OutresVecs.foreach(vec => vec.foreach(res =>dontTouch(res))) 241 242 private val fuOutValidOH = funcUnits.map(_.io.out.valid) 243 XSError(PopCount(fuOutValidOH) > 1.U, p"fuOutValidOH ${Binary(VecInit(fuOutValidOH).asUInt)} should be one-hot)\n") 244 private val fuOutBitsVec = funcUnits.map(_.io.out.bits) 245 private val fuOutresVec = OutresVecs.map(_.last) 246 private val fuRedirectVec: Seq[Option[ValidIO[Redirect]]] = fuOutresVec.map(_.redirect) 247 248 // Assume that one fu can only write int or fp or vec, 249 // otherwise, wenVec should be assigned to wen in fu. 250 private val fuIntWenVec = funcUnits.map(x => x.cfg.needIntWen.B && x.io.out.bits.ctrl.rfWen.getOrElse(false.B)) 251 private val fuFpWenVec = funcUnits.map(x => x.cfg.needFpWen.B && x.io.out.bits.ctrl.fpWen.getOrElse(false.B)) 252 private val fuVecWenVec = funcUnits.map(x => x.cfg.needVecWen.B && x.io.out.bits.ctrl.vecWen.getOrElse(false.B)) 253 // FunctionUnits <---> ExeUnit.out 254 io.out.valid := Cat(fuOutValidOH).orR 255 funcUnits.foreach(fu => fu.io.out.ready := io.out.ready) 256 257 // select one fu's result 258 io.out.bits.data := Mux1H(fuOutValidOH, fuOutresVec.map(_.data)) 259 io.out.bits.robIdx := Mux1H(fuOutValidOH, fuOutBitsVec.map(_.ctrl.robIdx)) 260 io.out.bits.pdest := Mux1H(fuOutValidOH, fuOutBitsVec.map(_.ctrl.pdest)) 261 io.out.bits.intWen.foreach(x => x := Mux1H(fuOutValidOH, fuIntWenVec)) 262 io.out.bits.fpWen.foreach(x => x := Mux1H(fuOutValidOH, fuFpWenVec)) 263 io.out.bits.vecWen.foreach(x => x := Mux1H(fuOutValidOH, fuVecWenVec)) 264 io.out.bits.redirect.foreach(x => x := Mux1H((fuOutValidOH zip fuRedirectVec).filter(_._2.isDefined).map(x => (x._1, x._2.get)))) 265 io.out.bits.fflags.foreach(x => x := Mux1H(fuOutValidOH, fuOutresVec.map(_.fflags.getOrElse(0.U.asTypeOf(io.out.bits.fflags.get))))) 266 io.out.bits.wflags.foreach(x => x := Mux1H(fuOutValidOH, fuOutBitsVec.map(_.ctrl.fpu.getOrElse(0.U.asTypeOf(new FPUCtrlSignals)).wflags))) 267 io.out.bits.vxsat.foreach(x => x := Mux1H(fuOutValidOH, fuOutresVec.map(_.vxsat.getOrElse(0.U.asTypeOf(io.out.bits.vxsat.get))))) 268 io.out.bits.exceptionVec.foreach(x => x := Mux1H(fuOutValidOH, fuOutBitsVec.map(_.ctrl.exceptionVec.getOrElse(0.U.asTypeOf(io.out.bits.exceptionVec.get))))) 269 io.out.bits.flushPipe.foreach(x => x := Mux1H(fuOutValidOH, fuOutBitsVec.map(_.ctrl.flushPipe.getOrElse(0.U.asTypeOf(io.out.bits.flushPipe.get))))) 270 io.out.bits.replay.foreach(x => x := Mux1H(fuOutValidOH, fuOutBitsVec.map(_.ctrl.replay.getOrElse(0.U.asTypeOf(io.out.bits.replay.get))))) 271 io.out.bits.predecodeInfo.foreach(x => x := Mux1H(fuOutValidOH, fuOutBitsVec.map(_.ctrl.preDecode.getOrElse(0.U.asTypeOf(io.out.bits.predecodeInfo.get))))) 272 273 io.csrio.foreach(exuio => funcUnits.foreach(fu => fu.io.csrio.foreach{ 274 fuio => 275 exuio <> fuio 276 fuio.exception := DelayN(exuio.exception, 2) 277 })) 278 279 io.vtype.foreach(exuio => funcUnits.foreach(fu => fu.io.vtype.foreach(fuio => exuio := fuio))) 280 io.fenceio.foreach(exuio => funcUnits.foreach(fu => fu.io.fenceio.foreach(fuio => fuio <> exuio))) 281 io.frm.foreach(exuio => funcUnits.foreach(fu => fu.io.frm.foreach(fuio => fuio <> exuio))) 282 io.vxrm.foreach(exuio => funcUnits.foreach(fu => fu.io.vxrm.foreach(fuio => fuio <> exuio))) 283 284 // debug info 285 io.out.bits.debug := 0.U.asTypeOf(io.out.bits.debug) 286 io.out.bits.debug.isPerfCnt := funcUnits.map(_.io.csrio.map(_.isPerfCnt)).map(_.getOrElse(false.B)).reduce(_ || _) 287 io.out.bits.debugInfo := Mux1H(fuOutValidOH, fuOutBitsVec.map(_.perfDebugInfo)) 288} 289 290class DispatcherIO[T <: Data](private val gen: T, n: Int) extends Bundle { 291 val in = Flipped(DecoupledIO(gen)) 292 293 val out = Vec(n, DecoupledIO(gen)) 294} 295 296class Dispatcher[T <: Data](private val gen: T, n: Int, acceptCond: T => Seq[Bool]) 297 (implicit p: Parameters) 298 extends Module { 299 300 val io = IO(new DispatcherIO(gen, n)) 301 302 private val acceptVec: Vec[Bool] = VecInit(acceptCond(io.in.bits)) 303 304 XSError(io.in.valid && PopCount(acceptVec) > 1.U, s"s[ExeUnit] accept vec should no more than 1, ${Binary(acceptVec.asUInt)} ") 305 XSError(io.in.valid && PopCount(acceptVec) === 0.U, "[ExeUnit] there is a inst not dispatched to any fu") 306 307 io.out.zipWithIndex.foreach { case (out, i) => 308 out.valid := acceptVec(i) && io.in.valid 309 out.bits := io.in.bits 310 } 311 312 io.in.ready := Mux1H(acceptVec,io.out.map(_.ready)) 313} 314 315class MemExeUnitIO (implicit p: Parameters) extends XSBundle { 316 val flush = Flipped(ValidIO(new Redirect())) 317 val in = Flipped(DecoupledIO(new MemExuInput())) 318 val out = DecoupledIO(new MemExuOutput()) 319} 320 321class MemExeUnit(exuParams: ExeUnitParams)(implicit p: Parameters) extends XSModule { 322 val io = IO(new MemExeUnitIO) 323 val fu = exuParams.fuConfigs.head.fuGen(p, exuParams.fuConfigs.head) 324 fu.io.flush := io.flush 325 fu.io.in.valid := io.in.valid 326 io.in.ready := fu.io.in.ready 327 328 fu.io.in.bits.ctrl.robIdx := io.in.bits.uop.robIdx 329 fu.io.in.bits.ctrl.pdest := io.in.bits.uop.pdest 330 fu.io.in.bits.ctrl.fuOpType := io.in.bits.uop.fuOpType 331 fu.io.in.bits.data.imm := io.in.bits.uop.imm 332 fu.io.in.bits.data.src.zip(io.in.bits.src).foreach(x => x._1 := x._2) 333 fu.io.in.bits.perfDebugInfo := io.in.bits.uop.debugInfo 334 335 io.out.valid := fu.io.out.valid 336 fu.io.out.ready := io.out.ready 337 338 io.out.bits := 0.U.asTypeOf(io.out.bits) // dontCare other fields 339 io.out.bits.data := fu.io.out.bits.res.data 340 io.out.bits.uop.robIdx := fu.io.out.bits.ctrl.robIdx 341 io.out.bits.uop.pdest := fu.io.out.bits.ctrl.pdest 342 io.out.bits.uop.fuType := io.in.bits.uop.fuType 343 io.out.bits.uop.fuOpType:= io.in.bits.uop.fuOpType 344 io.out.bits.uop.sqIdx := io.in.bits.uop.sqIdx 345 io.out.bits.uop.debugInfo := fu.io.out.bits.perfDebugInfo 346 347 io.out.bits.debug := 0.U.asTypeOf(io.out.bits.debug) 348}