xref: /XiangShan/src/main/scala/xiangshan/backend/fu/FuncUnit.scala (revision c37914a4bb81e2f217181b5d62b4dfcc06090ace) 
1package xiangshan.backend.fu
2
3import org.chipsalliance.cde.config.Parameters
4import chisel3._
5import chisel3.util._
6import utility._
7import utils.OptionWrapper
8import xiangshan._
9import xiangshan.backend.Bundles.VPUCtrlSignals
10import xiangshan.backend.rob.RobPtr
11import xiangshan.frontend.{FtqPtr, PreDecodeInfo}
12import xiangshan.backend.datapath.DataConfig._
13import xiangshan.backend.fu.vector.Bundles.Vxsat
14import xiangshan.ExceptionNO.illegalInstr
15import xiangshan.backend.fu.vector.Bundles.VType
16import xiangshan.backend.fu.wrapper.{CSRInput, CSRToDecode}
17
18class FuncUnitCtrlInput(cfg: FuConfig)(implicit p: Parameters) extends XSBundle {
19  val fuOpType    = FuOpType()
20  val robIdx      = new RobPtr
21  val pdest       = UInt(PhyRegIdxWidth.W)
22  val rfWen       = OptionWrapper(cfg.needIntWen, Bool())
23  val fpWen       = OptionWrapper(cfg.needFpWen,  Bool())
24  val vecWen      = OptionWrapper(cfg.needVecWen, Bool())
25  val v0Wen       = OptionWrapper(cfg.needV0Wen, Bool())
26  val vlWen       = OptionWrapper(cfg.needVlWen, Bool())
27  val flushPipe   = OptionWrapper(cfg.flushPipe,  Bool())
28  val preDecode   = OptionWrapper(cfg.hasPredecode, new PreDecodeInfo)
29  val ftqIdx      = OptionWrapper(cfg.needPc || cfg.replayInst || cfg.isSta || cfg.isCsr, new FtqPtr)
30  val ftqOffset   = OptionWrapper(cfg.needPc || cfg.replayInst || cfg.isSta || cfg.isCsr, UInt(log2Up(PredictWidth).W))
31  val predictInfo = OptionWrapper(cfg.needPdInfo, new Bundle {
32    val target    = UInt(VAddrData().dataWidth.W)
33    val taken     = Bool()
34  })
35  val fpu         = OptionWrapper(cfg.writeFflags, new FPUCtrlSignals)
36  val vpu         = OptionWrapper(cfg.needVecCtrl, new VPUCtrlSignals)
37}
38
39class FuncUnitCtrlOutput(cfg: FuConfig)(implicit p: Parameters) extends XSBundle {
40  val robIdx        = new RobPtr
41  val pdest         = UInt(PhyRegIdxWidth.W) // Todo: use maximum of pregIdxWidth of different pregs
42  val rfWen         = OptionWrapper(cfg.needIntWen, Bool())
43  val fpWen         = OptionWrapper(cfg.needFpWen,  Bool())
44  val vecWen        = OptionWrapper(cfg.needVecWen, Bool())
45  val v0Wen         = OptionWrapper(cfg.needV0Wen, Bool())
46  val vlWen         = OptionWrapper(cfg.needVlWen, Bool())
47  val exceptionVec  = OptionWrapper(cfg.exceptionOut.nonEmpty, ExceptionVec())
48  val flushPipe     = OptionWrapper(cfg.flushPipe,  Bool())
49  val replay        = OptionWrapper(cfg.replayInst, Bool())
50  val preDecode     = OptionWrapper(cfg.hasPredecode, new PreDecodeInfo)
51  val fpu           = OptionWrapper(cfg.writeFflags, new FPUCtrlSignals)
52  val vpu           = OptionWrapper(cfg.needVecCtrl, new VPUCtrlSignals)
53}
54
55class FuncUnitDataInput(cfg: FuConfig)(implicit p: Parameters) extends XSBundle {
56  val src       = MixedVec(cfg.genSrcDataVec)
57  val imm       = UInt(cfg.destDataBits.W)
58  val pc        = OptionWrapper(cfg.needPc, UInt(VAddrData().dataWidth.W))
59
60  def getSrcVConfig : UInt = src(cfg.vconfigIdx)
61  def getSrcMask    : UInt = src(cfg.maskSrcIdx)
62}
63
64class FuncUnitDataOutput(cfg: FuConfig)(implicit p: Parameters) extends XSBundle {
65  val data      = UInt(cfg.destDataBits.W)
66  val fflags    = OptionWrapper(cfg.writeFflags, UInt(5.W))
67  val vxsat     = OptionWrapper(cfg.writeVxsat, Vxsat())
68  val redirect  = OptionWrapper(cfg.hasRedirect, ValidIO(new Redirect))
69}
70
71class FuncUnitInput(cfg: FuConfig)(implicit p: Parameters) extends XSBundle {
72  val ctrl = new FuncUnitCtrlInput(cfg)
73  val data = new FuncUnitDataInput(cfg)
74  val perfDebugInfo = new PerfDebugInfo()
75}
76
77class FuncUnitOutput(cfg: FuConfig)(implicit p: Parameters) extends XSBundle {
78  val ctrl = new FuncUnitCtrlOutput(cfg)
79  val res = new FuncUnitDataOutput(cfg)
80  val perfDebugInfo = new PerfDebugInfo()
81}
82
83class FuncUnitIO(cfg: FuConfig)(implicit p: Parameters) extends XSBundle {
84  val flush = Flipped(ValidIO(new Redirect))
85  val in = Flipped(DecoupledIO(new FuncUnitInput(cfg)))
86  val out = DecoupledIO(new FuncUnitOutput(cfg))
87  val csrin = OptionWrapper(cfg.isCsr, new CSRInput)
88  val csrio = OptionWrapper(cfg.isCsr, new CSRFileIO)
89  val csrToDecode = OptionWrapper(cfg.isCsr, Output(new CSRToDecode))
90  val fenceio = OptionWrapper(cfg.isFence, new FenceIO)
91  val frm = OptionWrapper(cfg.needSrcFrm, Input(UInt(3.W)))
92  val vxrm = OptionWrapper(cfg.needSrcVxrm, Input(UInt(2.W)))
93  val vtype = OptionWrapper(cfg.writeVlRf, (Valid(new VType)))
94  val vlIsZero = OptionWrapper(cfg.writeVlRf, Output(Bool()))
95  val vlIsVlmax = OptionWrapper(cfg.writeVlRf, Output(Bool()))
96  val instrAddrTransType = Option.when(cfg.isJmp || cfg.isBrh)(Input(new AddrTransType))
97}
98
99abstract class FuncUnit(val cfg: FuConfig)(implicit p: Parameters) extends XSModule with HasCriticalErrors {
100  val io = IO(new FuncUnitIO(cfg))
101  val criticalErrors = Seq(("none", false.B))
102
103  // should only be used in non-piped fu
104  def connectNonPipedCtrlSingal: Unit = {
105    io.out.bits.ctrl.robIdx := RegEnable(io.in.bits.ctrl.robIdx, io.in.fire)
106    io.out.bits.ctrl.pdest  := RegEnable(io.in.bits.ctrl.pdest, io.in.fire)
107    io.out.bits.ctrl.rfWen  .foreach(_ := RegEnable(io.in.bits.ctrl.rfWen.get, io.in.fire))
108    io.out.bits.ctrl.fpWen  .foreach(_ := RegEnable(io.in.bits.ctrl.fpWen.get, io.in.fire))
109    io.out.bits.ctrl.vecWen .foreach(_ := RegEnable(io.in.bits.ctrl.vecWen.get, io.in.fire))
110    io.out.bits.ctrl.v0Wen .foreach(_ := RegEnable(io.in.bits.ctrl.v0Wen.get, io.in.fire))
111    io.out.bits.ctrl.vlWen .foreach(_ := RegEnable(io.in.bits.ctrl.vlWen.get, io.in.fire))
112    // io.out.bits.ctrl.flushPipe should be connected in fu
113    io.out.bits.ctrl.preDecode.foreach(_ := RegEnable(io.in.bits.ctrl.preDecode.get, io.in.fire))
114    io.out.bits.ctrl.fpu      .foreach(_ := RegEnable(io.in.bits.ctrl.fpu.get, io.in.fire))
115    io.out.bits.ctrl.vpu      .foreach(_ := RegEnable(io.in.bits.ctrl.vpu.get, io.in.fire))
116    io.out.bits.perfDebugInfo := RegEnable(io.in.bits.perfDebugInfo, io.in.fire)
117  }
118
119  def connectNonPipedCtrlSingalForCSR: Unit = {
120    io.out.bits.ctrl.robIdx := DataHoldBypass(io.in.bits.ctrl.robIdx, io.in.fire)
121    io.out.bits.ctrl.pdest := DataHoldBypass(io.in.bits.ctrl.pdest, io.in.fire)
122    io.out.bits.ctrl.rfWen.foreach(_ := DataHoldBypass(io.in.bits.ctrl.rfWen.get, io.in.fire))
123    io.out.bits.ctrl.fpWen.foreach(_ := DataHoldBypass(io.in.bits.ctrl.fpWen.get, io.in.fire))
124    io.out.bits.ctrl.vecWen.foreach(_ := DataHoldBypass(io.in.bits.ctrl.vecWen.get, io.in.fire))
125    io.out.bits.ctrl.v0Wen.foreach(_ := DataHoldBypass(io.in.bits.ctrl.v0Wen.get, io.in.fire))
126    io.out.bits.ctrl.vlWen.foreach(_ := DataHoldBypass(io.in.bits.ctrl.vlWen.get, io.in.fire))
127    // io.out.bits.ctrl.flushPipe should be connected in fu
128    io.out.bits.ctrl.preDecode.foreach(_ := DataHoldBypass(io.in.bits.ctrl.preDecode.get, io.in.fire))
129    io.out.bits.ctrl.fpu.foreach(_ := DataHoldBypass(io.in.bits.ctrl.fpu.get, io.in.fire))
130    io.out.bits.ctrl.vpu.foreach(_ := DataHoldBypass(io.in.bits.ctrl.vpu.get, io.in.fire))
131    io.out.bits.perfDebugInfo := DataHoldBypass(io.in.bits.perfDebugInfo, io.in.fire)
132  }
133
134  def connect0LatencyCtrlSingal: Unit = {
135    io.out.bits.ctrl.robIdx := io.in.bits.ctrl.robIdx
136    io.out.bits.ctrl.pdest := io.in.bits.ctrl.pdest
137    io.out.bits.ctrl.rfWen.foreach(_ := io.in.bits.ctrl.rfWen.get)
138    io.out.bits.ctrl.fpWen.foreach(_ := io.in.bits.ctrl.fpWen.get)
139    io.out.bits.ctrl.vecWen.foreach(_ := io.in.bits.ctrl.vecWen.get)
140    io.out.bits.ctrl.v0Wen.foreach(_ := io.in.bits.ctrl.v0Wen.get)
141    io.out.bits.ctrl.vlWen.foreach(_ := io.in.bits.ctrl.vlWen.get)
142    // io.out.bits.ctrl.flushPipe should be connected in fu
143    io.out.bits.ctrl.preDecode.foreach(_ := io.in.bits.ctrl.preDecode.get)
144    io.out.bits.ctrl.fpu.foreach(_ := io.in.bits.ctrl.fpu.get)
145    io.out.bits.ctrl.vpu.foreach(_ := io.in.bits.ctrl.vpu.get)
146    io.out.bits.perfDebugInfo := io.in.bits.perfDebugInfo
147  }
148}
149
150/**
151  * @author LinJiaWei, Yinan Xu
152  */
153trait HasPipelineReg { this: FuncUnit =>
154  def latency: Int
155
156  val latdiff :Int = cfg.latency.extraLatencyVal.getOrElse(0)
157  val preLat :Int = latency - latdiff
158  require(latency >= 0 && latdiff >=0)
159
160  def pipelineReg(init: FuncUnitInput , valid:Bool, ready: Bool,latency: Int, flush:ValidIO[Redirect]): (Seq[FuncUnitInput],Seq[Bool],Seq[Bool])={
161    val rdyVec = Seq.fill(latency)(Wire(Bool())) :+ ready
162    val validVec = valid +: Seq.fill(latency)(RegInit(false.B))
163    val ctrlVec = init.ctrl +: Seq.fill(latency)(Reg(chiselTypeOf(io.in.bits.ctrl)))
164    val dataVec = init.data +: Seq.fill(latency)(Reg(chiselTypeOf(io.in.bits.data)))
165    val perfVec = init.perfDebugInfo +: Seq.fill(latency)(Reg(chiselTypeOf(io.in.bits.perfDebugInfo)))
166
167
168
169    val robIdxVec = ctrlVec.map(_.robIdx)
170
171    // if flush(0), valid 0 will not given, so set flushVec(0) to false.B
172    val flushVec = validVec.zip(robIdxVec).map(x => x._1 && x._2.needFlush(flush))
173
174    for (i <- 0 until latency) {
175      rdyVec(i) := !validVec(i + 1) || rdyVec(i + 1).asTypeOf(Bool())
176    }
177    for (i <- 1 to latency) {
178      when(rdyVec(i - 1) && validVec(i - 1) && !flushVec(i - 1)) {
179        validVec(i) := validVec(i - 1)
180        ctrlVec(i) := ctrlVec(i - 1)
181        dataVec(i) := dataVec(i - 1)
182        perfVec(i) := perfVec(i - 1)
183      }.elsewhen(flushVec(i) || rdyVec(i)) {
184        validVec(i) := false.B
185      }
186    }
187
188    (ctrlVec.zip(dataVec).zip(perfVec).map{
189      case(( ctrl,data), perf) => {
190        val out = Wire(new FuncUnitInput(cfg))
191        out.ctrl := ctrl
192        out.data := data
193        out.perfDebugInfo := perf
194        out
195      }
196    },validVec, rdyVec)
197  }
198  val (pipeReg : Seq[FuncUnitInput],validVec ,rdyVec ) = pipelineReg(io.in.bits, io.in.valid,io.out.ready,preLat, io.flush)
199  val ctrlVec = pipeReg.map(_.ctrl)
200  val dataVec = pipeReg.map(_.data)
201  val perfVec = pipeReg.map(_.perfDebugInfo)
202  val robIdxVec = ctrlVec.map(_.robIdx)
203  val pipeflushVec = validVec.zip(robIdxVec).map(x => x._1 && x._2.needFlush(io.flush))
204
205
206  val fixtiminginit = Wire(new FuncUnitInput(cfg))
207  fixtiminginit.ctrl := ctrlVec.last
208  fixtiminginit.data := dataVec.last
209  fixtiminginit.perfDebugInfo := perfVec.last
210
211  // fixtiming pipelinereg
212  val (fixpipeReg : Seq[FuncUnitInput], fixValidVec, fixRdyVec) = pipelineReg(fixtiminginit, validVec.last,rdyVec.head ,latdiff, io.flush)
213  val fixCtrlVec = fixpipeReg.map(_.ctrl)
214  val fixDataVec = fixpipeReg.map(_.data)
215  val fixPerfVec = fixpipeReg.map(_.perfDebugInfo)
216  val fixrobIdxVec = ctrlVec.map(_.robIdx)
217  val fixflushVec = fixValidVec.zip(fixrobIdxVec).map(x => x._1 && x._2.needFlush(io.flush))
218  val flushVec = pipeflushVec ++ fixflushVec
219  val pcVec = fixDataVec.map(_.pc)
220
221  io.in.ready := fixRdyVec.head
222  io.out.valid := fixValidVec.last
223
224  io.out.bits.ctrl.robIdx := fixCtrlVec.last.robIdx
225  io.out.bits.ctrl.pdest := fixCtrlVec.last.pdest
226  io.out.bits.ctrl.rfWen.foreach(_ := fixCtrlVec.last.rfWen.get)
227  io.out.bits.ctrl.fpWen.foreach(_ := fixCtrlVec.last.fpWen.get)
228  io.out.bits.ctrl.vecWen.foreach(_ := fixCtrlVec.last.vecWen.get)
229  io.out.bits.ctrl.v0Wen.foreach(_ := fixCtrlVec.last.v0Wen.get)
230  io.out.bits.ctrl.vlWen.foreach(_ := fixCtrlVec.last.vlWen.get)
231  io.out.bits.ctrl.fpu.foreach(_ := fixCtrlVec.last.fpu.get)
232  io.out.bits.ctrl.vpu.foreach(_ := fixCtrlVec.last.vpu.get)
233  io.out.bits.perfDebugInfo := fixPerfVec.last
234
235  // vstart illegal
236  if (cfg.exceptionOut.nonEmpty) {
237    val outVstart = fixCtrlVec.last.vpu.get.vstart
238    val vstartIllegal = outVstart =/= 0.U
239    io.out.bits.ctrl.exceptionVec.get := 0.U.asTypeOf(io.out.bits.ctrl.exceptionVec.get)
240    io.out.bits.ctrl.exceptionVec.get(illegalInstr) := vstartIllegal
241  }
242
243  def regEnable(i: Int): Bool = validVec(i - 1) && rdyVec(i - 1) && !flushVec(i - 1)
244
245  def PipelineReg[TT <: Data](i: Int)(next: TT) = {
246    val lat = preLat min i
247    RegEnable(
248      next,
249      regEnable(lat)
250    )
251  }
252
253  def SNReg[TT <: Data](in: TT, n: Int): TT ={
254    val lat = preLat min n
255    var next = in
256    for (i <- 1 to lat) {
257      next = PipelineReg[TT](i)(next)
258    }
259    next
260  }
261
262  def S1Reg[TT <: Data](next: TT): TT = PipelineReg[TT](1)(next)
263
264  def S2Reg[TT <: Data](next: TT): TT = PipelineReg[TT](2)(next)
265
266  def S3Reg[TT <: Data](next: TT): TT = PipelineReg[TT](3)(next)
267
268  def S4Reg[TT <: Data](next: TT): TT = PipelineReg[TT](4)(next)
269
270  def S5Reg[TT <: Data](next: TT): TT = PipelineReg[TT](5)(next)
271
272}
273
274abstract class PipedFuncUnit(override val cfg: FuConfig)(implicit p: Parameters) extends FuncUnit(cfg)
275  with HasPipelineReg {
276  override def latency: Int = cfg.latency.latencyVal.get
277}
278