// See LICENSE for license details. package rocket import Chisel._ import Instructions._ import Util._ import FPConstants._ import uncore.constants.MemoryOpConstants._ import uncore.util._ import cde.{Parameters, Field} case class FPUConfig( divSqrt: Boolean = true, sfmaLatency: Int = 2, dfmaLatency: Int = 3 ) object FPConstants { val FCMD_ADD = BitPat("b0??00") val FCMD_SUB = BitPat("b0??01") val FCMD_MUL = BitPat("b0??10") val FCMD_MADD = BitPat("b1??00") val FCMD_MSUB = BitPat("b1??01") val FCMD_NMSUB = BitPat("b1??10") val FCMD_NMADD = BitPat("b1??11") val FCMD_DIV = BitPat("b?0011") val FCMD_SQRT = BitPat("b?1011") val FCMD_SGNJ = BitPat("b??1?0") val FCMD_MINMAX = BitPat("b?01?1") val FCMD_CVT_FF = BitPat("b??0??") val FCMD_CVT_IF = BitPat("b?10??") val FCMD_CMP = BitPat("b?01??") val FCMD_MV_XF = BitPat("b?11??") val FCMD_CVT_FI = BitPat("b??0??") val FCMD_MV_FX = BitPat("b??1??") val FCMD_X = BitPat("b?????") val FCMD_WIDTH = 5 val RM_SZ = 3 val FLAGS_SZ = 5 } trait HasFPUCtrlSigs { val cmd = Bits(width = FCMD_WIDTH) val ldst = Bool() val wen = Bool() val ren1 = Bool() val ren2 = Bool() val ren3 = Bool() val swap12 = Bool() val swap23 = Bool() val single = Bool() val fromint = Bool() val toint = Bool() val fastpipe = Bool() val fma = Bool() val div = Bool() val sqrt = Bool() val round = Bool() val wflags = Bool() } class FPUCtrlSigs extends Bundle with HasFPUCtrlSigs class FPUDecoder(implicit p: Parameters) extends FPUModule()(p) { val io = new Bundle { val inst = Bits(INPUT, 32) val sigs = new FPUCtrlSigs().asOutput } val default = List(FCMD_X, X,X,X,X,X,X,X,X,X,X,X,X,X,X,X,X) val f = Array(FLW -> List(FCMD_X, Y,Y,N,N,N,X,X,Y,N,N,N,N,N,N,N,N), FSW -> List(FCMD_MV_XF, Y,N,N,Y,N,Y,X,Y,N,Y,N,N,N,N,N,N), FMV_S_X -> List(FCMD_MV_FX, N,Y,N,N,N,X,X,Y,Y,N,N,N,N,N,Y,N), FCVT_S_W -> List(FCMD_CVT_FI, N,Y,N,N,N,X,X,Y,Y,N,N,N,N,N,Y,Y), FCVT_S_WU-> List(FCMD_CVT_FI, N,Y,N,N,N,X,X,Y,Y,N,N,N,N,N,Y,Y), FCVT_S_L -> List(FCMD_CVT_FI, N,Y,N,N,N,X,X,Y,Y,N,N,N,N,N,Y,Y), FCVT_S_LU-> List(FCMD_CVT_FI, N,Y,N,N,N,X,X,Y,Y,N,N,N,N,N,Y,Y), FMV_X_S -> List(FCMD_MV_XF, N,N,Y,N,N,N,X,Y,N,Y,N,N,N,N,Y,N), FCLASS_S -> List(FCMD_MV_XF, N,N,Y,N,N,N,X,Y,N,Y,N,N,N,N,Y,N), FCVT_W_S -> List(FCMD_CVT_IF, N,N,Y,N,N,N,X,Y,N,Y,N,N,N,N,Y,Y), FCVT_WU_S-> List(FCMD_CVT_IF, N,N,Y,N,N,N,X,Y,N,Y,N,N,N,N,Y,Y), FCVT_L_S -> List(FCMD_CVT_IF, N,N,Y,N,N,N,X,Y,N,Y,N,N,N,N,Y,Y), FCVT_LU_S-> List(FCMD_CVT_IF, N,N,Y,N,N,N,X,Y,N,Y,N,N,N,N,Y,Y), FEQ_S -> List(FCMD_CMP, N,N,Y,Y,N,N,N,Y,N,Y,N,N,N,N,N,Y), FLT_S -> List(FCMD_CMP, N,N,Y,Y,N,N,N,Y,N,Y,N,N,N,N,N,Y), FLE_S -> List(FCMD_CMP, N,N,Y,Y,N,N,N,Y,N,Y,N,N,N,N,N,Y), FSGNJ_S -> List(FCMD_SGNJ, N,Y,Y,Y,N,N,N,Y,N,N,Y,N,N,N,N,N), FSGNJN_S -> List(FCMD_SGNJ, N,Y,Y,Y,N,N,N,Y,N,N,Y,N,N,N,N,N), FSGNJX_S -> List(FCMD_SGNJ, N,Y,Y,Y,N,N,N,Y,N,N,Y,N,N,N,N,N), FMIN_S -> List(FCMD_MINMAX, N,Y,Y,Y,N,N,N,Y,N,N,Y,N,N,N,N,Y), FMAX_S -> List(FCMD_MINMAX, N,Y,Y,Y,N,N,N,Y,N,N,Y,N,N,N,N,Y), FADD_S -> List(FCMD_ADD, N,Y,Y,Y,N,N,Y,Y,N,N,N,Y,N,N,Y,Y), FSUB_S -> List(FCMD_SUB, N,Y,Y,Y,N,N,Y,Y,N,N,N,Y,N,N,Y,Y), FMUL_S -> List(FCMD_MUL, N,Y,Y,Y,N,N,N,Y,N,N,N,Y,N,N,Y,Y), FMADD_S -> List(FCMD_MADD, N,Y,Y,Y,Y,N,N,Y,N,N,N,Y,N,N,Y,Y), FMSUB_S -> List(FCMD_MSUB, N,Y,Y,Y,Y,N,N,Y,N,N,N,Y,N,N,Y,Y), FNMADD_S -> List(FCMD_NMADD, N,Y,Y,Y,Y,N,N,Y,N,N,N,Y,N,N,Y,Y), FNMSUB_S -> List(FCMD_NMSUB, N,Y,Y,Y,Y,N,N,Y,N,N,N,Y,N,N,Y,Y), FDIV_S -> List(FCMD_DIV, N,Y,Y,Y,N,N,N,Y,N,N,N,N,Y,N,Y,Y), FSQRT_S -> List(FCMD_SQRT, N,Y,Y,N,N,Y,X,Y,N,N,N,N,N,Y,Y,Y)) val d = Array(FLD -> List(FCMD_X, Y,Y,N,N,N,X,X,N,N,N,N,N,N,N,N,N), FSD -> List(FCMD_MV_XF, Y,N,N,Y,N,Y,X,N,N,Y,N,N,N,N,N,N), FMV_D_X -> List(FCMD_MV_FX, N,Y,N,N,N,X,X,N,Y,N,N,N,N,N,Y,N), FCVT_D_W -> List(FCMD_CVT_FI, N,Y,N,N,N,X,X,N,Y,N,N,N,N,N,Y,Y), FCVT_D_WU-> List(FCMD_CVT_FI, N,Y,N,N,N,X,X,N,Y,N,N,N,N,N,Y,Y), FCVT_D_L -> List(FCMD_CVT_FI, N,Y,N,N,N,X,X,N,Y,N,N,N,N,N,Y,Y), FCVT_D_LU-> List(FCMD_CVT_FI, N,Y,N,N,N,X,X,N,Y,N,N,N,N,N,Y,Y), FMV_X_D -> List(FCMD_MV_XF, N,N,Y,N,N,N,X,N,N,Y,N,N,N,N,Y,N), FCLASS_D -> List(FCMD_MV_XF, N,N,Y,N,N,N,X,N,N,Y,N,N,N,N,Y,N), FCVT_W_D -> List(FCMD_CVT_IF, N,N,Y,N,N,N,X,N,N,Y,N,N,N,N,Y,Y), FCVT_WU_D-> List(FCMD_CVT_IF, N,N,Y,N,N,N,X,N,N,Y,N,N,N,N,Y,Y), FCVT_L_D -> List(FCMD_CVT_IF, N,N,Y,N,N,N,X,N,N,Y,N,N,N,N,Y,Y), FCVT_LU_D-> List(FCMD_CVT_IF, N,N,Y,N,N,N,X,N,N,Y,N,N,N,N,Y,Y), FCVT_S_D -> List(FCMD_CVT_FF, N,Y,Y,N,N,N,X,Y,N,N,Y,N,N,N,Y,Y), FCVT_D_S -> List(FCMD_CVT_FF, N,Y,Y,N,N,N,X,N,N,N,Y,N,N,N,Y,Y), FEQ_D -> List(FCMD_CMP, N,N,Y,Y,N,N,N,N,N,Y,N,N,N,N,N,Y), FLT_D -> List(FCMD_CMP, N,N,Y,Y,N,N,N,N,N,Y,N,N,N,N,N,Y), FLE_D -> List(FCMD_CMP, N,N,Y,Y,N,N,N,N,N,Y,N,N,N,N,N,Y), FSGNJ_D -> List(FCMD_SGNJ, N,Y,Y,Y,N,N,N,N,N,N,Y,N,N,N,N,N), FSGNJN_D -> List(FCMD_SGNJ, N,Y,Y,Y,N,N,N,N,N,N,Y,N,N,N,N,N), FSGNJX_D -> List(FCMD_SGNJ, N,Y,Y,Y,N,N,N,N,N,N,Y,N,N,N,N,N), FMIN_D -> List(FCMD_MINMAX, N,Y,Y,Y,N,N,N,N,N,N,Y,N,N,N,N,Y), FMAX_D -> List(FCMD_MINMAX, N,Y,Y,Y,N,N,N,N,N,N,Y,N,N,N,N,Y), FADD_D -> List(FCMD_ADD, N,Y,Y,Y,N,N,Y,N,N,N,N,Y,N,N,Y,Y), FSUB_D -> List(FCMD_SUB, N,Y,Y,Y,N,N,Y,N,N,N,N,Y,N,N,Y,Y), FMUL_D -> List(FCMD_MUL, N,Y,Y,Y,N,N,N,N,N,N,N,Y,N,N,Y,Y), FMADD_D -> List(FCMD_MADD, N,Y,Y,Y,Y,N,N,N,N,N,N,Y,N,N,Y,Y), FMSUB_D -> List(FCMD_MSUB, N,Y,Y,Y,Y,N,N,N,N,N,N,Y,N,N,Y,Y), FNMADD_D -> List(FCMD_NMADD, N,Y,Y,Y,Y,N,N,N,N,N,N,Y,N,N,Y,Y), FNMSUB_D -> List(FCMD_NMSUB, N,Y,Y,Y,Y,N,N,N,N,N,N,Y,N,N,Y,Y), FDIV_D -> List(FCMD_DIV, N,Y,Y,Y,N,N,N,N,N,N,N,N,Y,N,Y,Y), FSQRT_D -> List(FCMD_SQRT, N,Y,Y,N,N,Y,X,N,N,N,N,N,N,Y,Y,Y)) val insns = fLen match { case 32 => f case 64 => f ++ d } val decoder = DecodeLogic(io.inst, default, insns) val s = io.sigs val sigs = Seq(s.cmd, s.ldst, s.wen, s.ren1, s.ren2, s.ren3, s.swap12, s.swap23, s.single, s.fromint, s.toint, s.fastpipe, s.fma, s.div, s.sqrt, s.round, s.wflags) sigs zip decoder map {case(s,d) => s := d} } class FPUIO(implicit p: Parameters) extends CoreBundle { val inst = Bits(INPUT, 32) val fromint_data = Bits(INPUT, xLen) val fcsr_rm = Bits(INPUT, FPConstants.RM_SZ) val fcsr_flags = Valid(Bits(width = FPConstants.FLAGS_SZ)) val store_data = Bits(OUTPUT, fLen) val toint_data = Bits(OUTPUT, xLen) val dmem_resp_val = Bool(INPUT) val dmem_resp_type = Bits(INPUT, 3) val dmem_resp_tag = UInt(INPUT, 5) val dmem_resp_data = Bits(INPUT, fLen) val valid = Bool(INPUT) val fcsr_rdy = Bool(OUTPUT) val nack_mem = Bool(OUTPUT) val illegal_rm = Bool(OUTPUT) val killx = Bool(INPUT) val killm = Bool(INPUT) val dec = new FPUCtrlSigs().asOutput val sboard_set = Bool(OUTPUT) val sboard_clr = Bool(OUTPUT) val sboard_clra = UInt(OUTPUT, 5) val cp_req = Decoupled(new FPInput()).flip //cp doesn't pay attn to kill sigs val cp_resp = Decoupled(new FPResult()) } class FPResult(implicit p: Parameters) extends CoreBundle()(p) { val data = Bits(width = fLen+1) val exc = Bits(width = 5) } class FPInput(implicit p: Parameters) extends CoreBundle()(p) with HasFPUCtrlSigs { val rm = Bits(width = 3) val typ = Bits(width = 2) val in1 = Bits(width = fLen+1) val in2 = Bits(width = fLen+1) val in3 = Bits(width = fLen+1) override def cloneType = new FPInput().asInstanceOf[this.type] } object ClassifyRecFN { def apply(expWidth: Int, sigWidth: Int, in: UInt) = { val sign = in(sigWidth + expWidth) val exp = in(sigWidth + expWidth - 1, sigWidth - 1) val sig = in(sigWidth - 2, 0) val code = exp(expWidth,expWidth-2) val codeHi = code(2, 1) val isSpecial = codeHi === UInt(3) val isHighSubnormalIn = exp(expWidth-2, 0) < UInt(2) val isSubnormal = code === UInt(1) || codeHi === UInt(1) && isHighSubnormalIn val isNormal = codeHi === UInt(1) && !isHighSubnormalIn || codeHi === UInt(2) val isZero = code === UInt(0) val isInf = isSpecial && !exp(expWidth-2) val isNaN = code.andR val isSNaN = isNaN && !sig(sigWidth-2) val isQNaN = isNaN && sig(sigWidth-2) Cat(isQNaN, isSNaN, isInf && !sign, isNormal && !sign, isSubnormal && !sign, isZero && !sign, isZero && sign, isSubnormal && sign, isNormal && sign, isInf && sign) } } object IsNaNRecFN { def apply(expWidth: Int, sigWidth: Int, in: UInt) = in(sigWidth + expWidth - 1, sigWidth + expWidth - 3).andR } object IsSNaNRecFN { def apply(expWidth: Int, sigWidth: Int, in: UInt) = IsNaNRecFN(expWidth, sigWidth, in) && !in(sigWidth - 2) } /** Format conversion without rounding or NaN handling */ object RecFNToRecFN_noncompliant { def apply(in: UInt, inExpWidth: Int, inSigWidth: Int, outExpWidth: Int, outSigWidth: Int) = { val sign = in(inSigWidth + inExpWidth) val fractIn = in(inSigWidth - 2, 0) val expIn = in(inSigWidth + inExpWidth - 1, inSigWidth - 1) val fractOut = fractIn << outSigWidth >> inSigWidth val expOut = { val expCode = expIn(inExpWidth, inExpWidth - 2) val commonCase = (expIn + (1 << outExpWidth)) - (1 << inExpWidth) Mux(expCode === 0 || expCode >= 6, Cat(expCode, commonCase(outExpWidth - 3, 0)), commonCase(outExpWidth, 0)) } Cat(sign, expOut, fractOut) } } trait HasFPUParameters { val fLen: Int val (sExpWidth, sSigWidth) = (8, 24) val (dExpWidth, dSigWidth) = (11, 53) val (maxExpWidth, maxSigWidth) = fLen match { case 32 => (sExpWidth, sSigWidth) case 64 => (dExpWidth, dSigWidth) } } abstract class FPUModule(implicit p: Parameters) extends CoreModule()(p) with HasFPUParameters class FPToInt(implicit p: Parameters) extends FPUModule()(p) { class Output extends Bundle { val lt = Bool() val store = Bits(width = fLen) val toint = Bits(width = xLen) val exc = Bits(width = 5) override def cloneType = new Output().asInstanceOf[this.type] } val io = new Bundle { val in = Valid(new FPInput).flip val as_double = new FPInput().asOutput val out = Valid(new Output) } val in = Reg(new FPInput) val valid = Reg(next=io.in.valid) def upconvert(x: UInt) = RecFNToRecFN_noncompliant(x, sExpWidth, sSigWidth, maxExpWidth, maxSigWidth) when (io.in.valid) { in := io.in.bits if (fLen > 32) when (io.in.bits.single && !io.in.bits.ldst && io.in.bits.cmd =/= FCMD_MV_XF) { in.in1 := upconvert(io.in.bits.in1) in.in2 := upconvert(io.in.bits.in2) } } val unrec_s = hardfloat.fNFromRecFN(sExpWidth, sSigWidth, in.in1).sextTo(xLen) val unrec_mem = fLen match { case 32 => unrec_s case 64 => val unrec_d = hardfloat.fNFromRecFN(dExpWidth, dSigWidth, in.in1).sextTo(xLen) Mux(in.single, unrec_s, unrec_d) } val unrec_int = xLen match { case 32 => unrec_s case fLen => unrec_mem } val classify_s = ClassifyRecFN(sExpWidth, sSigWidth, in.in1) val classify_out = fLen match { case 32 => classify_s case 64 => val classify_d = ClassifyRecFN(dExpWidth, dSigWidth, in.in1) Mux(in.single, classify_s, classify_d) } val dcmp = Module(new hardfloat.CompareRecFN(maxExpWidth, maxSigWidth)) dcmp.io.a := in.in1 dcmp.io.b := in.in2 dcmp.io.signaling := Bool(true) val dcmp_out = (~in.rm & Cat(dcmp.io.lt, dcmp.io.eq)).orR val dcmp_exc = dcmp.io.exceptionFlags io.out.bits.toint := Mux(in.rm(0), classify_out, unrec_int) io.out.bits.store := unrec_mem io.out.bits.exc := Bits(0) when (in.cmd === FCMD_CMP) { io.out.bits.toint := dcmp_out io.out.bits.exc := dcmp_exc } when (in.cmd === FCMD_CVT_IF) { val minXLen = 32 val n = log2Ceil(xLen/minXLen) + 1 for (i <- 0 until n) { val conv = Module(new hardfloat.RecFNToIN(maxExpWidth, maxSigWidth, minXLen << i)) conv.io.in := in.in1 conv.io.roundingMode := in.rm conv.io.signedOut := ~in.typ(0) when (in.typ.extract(log2Ceil(n), 1) === i) { io.out.bits.toint := conv.io.out.sextTo(xLen) io.out.bits.exc := Cat(conv.io.intExceptionFlags(2, 1).orR, UInt(0, 3), conv.io.intExceptionFlags(0)) } } } io.out.valid := valid io.out.bits.lt := dcmp.io.lt io.as_double := in } class IntToFP(val latency: Int)(implicit p: Parameters) extends FPUModule()(p) { val io = new Bundle { val in = Valid(new FPInput).flip val out = Valid(new FPResult) } val in = Pipe(io.in) val mux = Wire(new FPResult) mux.exc := Bits(0) mux.data := hardfloat.recFNFromFN(sExpWidth, sSigWidth, in.bits.in1) if (fLen > 32) when (!in.bits.single) { mux.data := hardfloat.recFNFromFN(dExpWidth, dSigWidth, in.bits.in1) } val intValue = { val minXLen = 32 val n = log2Ceil(xLen/minXLen) + 1 val res = Wire(init = in.bits.in1.asSInt) for (i <- 0 until n-1) { val smallInt = in.bits.in1((minXLen << i) - 1, 0) when (in.bits.typ.extract(log2Ceil(n), 1) === i) { res := Mux(in.bits.typ(0), smallInt.zext, smallInt.asSInt) } } res.asUInt } when (in.bits.cmd === FCMD_CVT_FI) { val l2s = Module(new hardfloat.INToRecFN(xLen, sExpWidth, sSigWidth)) l2s.io.signedIn := ~in.bits.typ(0) l2s.io.in := intValue l2s.io.roundingMode := in.bits.rm mux.data := Cat(UInt((BigInt(1) << (fLen - 32)) - 1), l2s.io.out) mux.exc := l2s.io.exceptionFlags fLen match { case 32 => case 64 => val l2d = Module(new hardfloat.INToRecFN(xLen, dExpWidth, dSigWidth)) l2d.io.signedIn := ~in.bits.typ(0) l2d.io.in := intValue l2d.io.roundingMode := in.bits.rm when (!in.bits.single) { mux.data := Cat(UInt((BigInt(1) << (fLen - 64)) - 1), l2d.io.out) mux.exc := l2d.io.exceptionFlags } } } io.out <> Pipe(in.valid, mux, latency-1) } class FPToFP(val latency: Int)(implicit p: Parameters) extends FPUModule()(p) { val io = new Bundle { val in = Valid(new FPInput).flip val out = Valid(new FPResult) val lt = Bool(INPUT) // from FPToInt } val in = Pipe(io.in) val signNum = Mux(in.bits.rm(1), in.bits.in1 ^ in.bits.in2, Mux(in.bits.rm(0), ~in.bits.in2, in.bits.in2)) val fsgnj_s = Cat(signNum(32), in.bits.in1(31, 0)) val fsgnj = fLen match { case 32 => fsgnj_s case 64 => Mux(in.bits.single, Cat(in.bits.in1 >> 33, fsgnj_s), Cat(signNum(64), in.bits.in1(63, 0))) } val mux = Wire(new FPResult) mux.exc := UInt(0) mux.data := fsgnj when (in.bits.cmd === FCMD_MINMAX) { def doMinMax(expWidth: Int, sigWidth: Int) = { val isnan1 = IsNaNRecFN(expWidth, sigWidth, in.bits.in1) val isnan2 = IsNaNRecFN(expWidth, sigWidth, in.bits.in2) val issnan1 = IsSNaNRecFN(expWidth, sigWidth, in.bits.in1) val issnan2 = IsSNaNRecFN(expWidth, sigWidth, in.bits.in2) (isnan2 || in.bits.rm(0) =/= io.lt && !isnan1, issnan1 || issnan2) } val (isLHS, isInvalid) = fLen match { case 32 => doMinMax(sExpWidth, sSigWidth) case 64 => MuxT(in.bits.single, doMinMax(sExpWidth, sSigWidth), doMinMax(dExpWidth, dSigWidth)) } mux.exc := isInvalid << 4 mux.data := in.bits.in1 when (!isLHS) { mux.data := in.bits.in2 } } fLen match { case 32 => case 64 => when (in.bits.cmd === FCMD_CVT_FF) { when (in.bits.single) { val d2s = Module(new hardfloat.RecFNToRecFN(dExpWidth, dSigWidth, sExpWidth, sSigWidth)) d2s.io.in := in.bits.in1 d2s.io.roundingMode := in.bits.rm mux.data := Cat(UInt((BigInt(1) << (fLen - 32)) - 1), d2s.io.out) mux.exc := d2s.io.exceptionFlags }.otherwise { val s2d = Module(new hardfloat.RecFNToRecFN(sExpWidth, sSigWidth, dExpWidth, dSigWidth)) s2d.io.in := in.bits.in1 s2d.io.roundingMode := in.bits.rm mux.data := s2d.io.out mux.exc := s2d.io.exceptionFlags } } } io.out <> Pipe(in.valid, mux, latency-1) } class FPUFMAPipe(val latency: Int, expWidth: Int, sigWidth: Int)(implicit p: Parameters) extends FPUModule()(p) { val io = new Bundle { val in = Valid(new FPInput).flip val out = Valid(new FPResult) } val width = sigWidth + expWidth val one = UInt(1) << (width-1) val zero = (io.in.bits.in1(width) ^ io.in.bits.in2(width)) << width val valid = Reg(next=io.in.valid) val in = Reg(new FPInput) when (io.in.valid) { in := io.in.bits val cmd_fma = io.in.bits.ren3 val cmd_addsub = io.in.bits.swap23 in.cmd := Cat(io.in.bits.cmd(1) & (cmd_fma || cmd_addsub), io.in.bits.cmd(0)) when (cmd_addsub) { in.in2 := one } unless (cmd_fma || cmd_addsub) { in.in3 := zero } } val fma = Module(new hardfloat.MulAddRecFN(expWidth, sigWidth)) fma.io.op := in.cmd fma.io.roundingMode := in.rm fma.io.a := in.in1 fma.io.b := in.in2 fma.io.c := in.in3 val res = Wire(new FPResult) res.data := Cat(UInt((BigInt(1) << (fLen - (expWidth + sigWidth))) - 1), fma.io.out) res.exc := fma.io.exceptionFlags io.out := Pipe(valid, res, latency-1) } class FPU(cfg: FPUConfig)(implicit p: Parameters) extends FPUModule()(p) { val io = new FPUIO val ex_reg_valid = Reg(next=io.valid, init=Bool(false)) val req_valid = ex_reg_valid || io.cp_req.valid val ex_reg_inst = RegEnable(io.inst, io.valid) val ex_cp_valid = io.cp_req.fire() val mem_reg_valid = Reg(next=ex_reg_valid && !io.killx || ex_cp_valid, init=Bool(false)) val mem_reg_inst = RegEnable(ex_reg_inst, ex_reg_valid) val mem_cp_valid = Reg(next=ex_cp_valid, init=Bool(false)) val killm = (io.killm || io.nack_mem) && !mem_cp_valid val wb_reg_valid = Reg(next=mem_reg_valid && (!killm || mem_cp_valid), init=Bool(false)) val wb_cp_valid = Reg(next=mem_cp_valid, init=Bool(false)) val fp_decoder = Module(new FPUDecoder) fp_decoder.io.inst := io.inst val cp_ctrl = Wire(new FPUCtrlSigs) cp_ctrl <> io.cp_req.bits io.cp_resp.valid := Bool(false) io.cp_resp.bits.data := UInt(0) val id_ctrl = fp_decoder.io.sigs val ex_ctrl = Mux(ex_cp_valid, cp_ctrl, RegEnable(id_ctrl, io.valid)) val mem_ctrl = RegEnable(ex_ctrl, req_valid) val wb_ctrl = RegEnable(mem_ctrl, mem_reg_valid) // load response val load_wb = Reg(next=io.dmem_resp_val) val load_wb_single = RegEnable(!io.dmem_resp_type(0), io.dmem_resp_val) val load_wb_data = RegEnable(io.dmem_resp_data, io.dmem_resp_val) val load_wb_tag = RegEnable(io.dmem_resp_tag, io.dmem_resp_val) val rec_s = hardfloat.recFNFromFN(sExpWidth, sSigWidth, load_wb_data) val load_wb_data_recoded = fLen match { case 32 => rec_s case 64 => val rec_d = hardfloat.recFNFromFN(dExpWidth, dSigWidth, load_wb_data) Mux(load_wb_single, Cat(UInt((BigInt(1) << (fLen - 32)) - 1), rec_s), rec_d) } // regfile val regfile = Mem(32, Bits(width = fLen+1)) when (load_wb) { regfile(load_wb_tag) := load_wb_data_recoded if (enableCommitLog) printf("f%d p%d 0x%x\n", load_wb_tag, load_wb_tag + 32, Mux(load_wb_single, load_wb_data(31,0), load_wb_data)) } val ex_ra1::ex_ra2::ex_ra3::Nil = List.fill(3)(Reg(UInt())) when (io.valid) { when (id_ctrl.ren1) { when (!id_ctrl.swap12) { ex_ra1 := io.inst(19,15) } when (id_ctrl.swap12) { ex_ra2 := io.inst(19,15) } } when (id_ctrl.ren2) { when (id_ctrl.swap12) { ex_ra1 := io.inst(24,20) } when (id_ctrl.swap23) { ex_ra3 := io.inst(24,20) } when (!id_ctrl.swap12 && !id_ctrl.swap23) { ex_ra2 := io.inst(24,20) } } when (id_ctrl.ren3) { ex_ra3 := io.inst(31,27) } } val ex_rm = Mux(ex_reg_inst(14,12) === Bits(7), io.fcsr_rm, ex_reg_inst(14,12)) val req = Wire(new FPInput) req := ex_ctrl req.rm := ex_rm req.in1 := regfile(ex_ra1) req.in2 := regfile(ex_ra2) req.in3 := regfile(ex_ra3) req.typ := ex_reg_inst(21,20) when (ex_cp_valid) { req := io.cp_req.bits when (io.cp_req.bits.swap23) { req.in2 := io.cp_req.bits.in3 req.in3 := io.cp_req.bits.in2 } } val sfma = Module(new FPUFMAPipe(cfg.sfmaLatency, sExpWidth, sSigWidth)) sfma.io.in.valid := req_valid && ex_ctrl.fma && ex_ctrl.single sfma.io.in.bits := req val fpiu = Module(new FPToInt) fpiu.io.in.valid := req_valid && (ex_ctrl.toint || ex_ctrl.div || ex_ctrl.sqrt || ex_ctrl.cmd === FCMD_MINMAX) fpiu.io.in.bits := req io.store_data := fpiu.io.out.bits.store io.toint_data := fpiu.io.out.bits.toint when(fpiu.io.out.valid && mem_cp_valid && mem_ctrl.toint){ io.cp_resp.bits.data := fpiu.io.out.bits.toint io.cp_resp.valid := Bool(true) } val ifpu = Module(new IntToFP(2)) ifpu.io.in.valid := req_valid && ex_ctrl.fromint ifpu.io.in.bits := req ifpu.io.in.bits.in1 := Mux(ex_cp_valid, io.cp_req.bits.in1, io.fromint_data) val fpmu = Module(new FPToFP(2)) fpmu.io.in.valid := req_valid && ex_ctrl.fastpipe fpmu.io.in.bits := req fpmu.io.lt := fpiu.io.out.bits.lt val divSqrt_wen = Reg(next=Bool(false)) val divSqrt_inReady = Wire(init=Bool(false)) val divSqrt_waddr = Reg(UInt(width = 5)) val divSqrt_wdata = Wire(UInt(width = fLen+1)) val divSqrt_flags = Wire(UInt(width = 5)) val divSqrt_in_flight = Reg(init=Bool(false)) val divSqrt_killed = Reg(Bool()) // writeback arbitration case class Pipe(p: Module, lat: Int, cond: (FPUCtrlSigs) => Bool, res: FPResult) val pipes = List( Pipe(fpmu, fpmu.latency, (c: FPUCtrlSigs) => c.fastpipe, fpmu.io.out.bits), Pipe(ifpu, ifpu.latency, (c: FPUCtrlSigs) => c.fromint, ifpu.io.out.bits), Pipe(sfma, sfma.latency, (c: FPUCtrlSigs) => c.fma && c.single, sfma.io.out.bits)) ++ (fLen > 32).option({ val dfma = Module(new FPUFMAPipe(cfg.dfmaLatency, dExpWidth, dSigWidth)) dfma.io.in.valid := req_valid && ex_ctrl.fma && !ex_ctrl.single dfma.io.in.bits := req Pipe(dfma, dfma.latency, (c: FPUCtrlSigs) => c.fma && !c.single, dfma.io.out.bits) }) def latencyMask(c: FPUCtrlSigs, offset: Int) = { require(pipes.forall(_.lat >= offset)) pipes.map(p => Mux(p.cond(c), UInt(1 << p.lat-offset), UInt(0))).reduce(_|_) } def pipeid(c: FPUCtrlSigs) = pipes.zipWithIndex.map(p => Mux(p._1.cond(c), UInt(p._2), UInt(0))).reduce(_|_) val maxLatency = pipes.map(_.lat).max val memLatencyMask = latencyMask(mem_ctrl, 2) class WBInfo extends Bundle { val rd = UInt(width = 5) val single = Bool() val cp = Bool() val pipeid = UInt(width = log2Ceil(pipes.size)) override def cloneType: this.type = new WBInfo().asInstanceOf[this.type] } val wen = Reg(init=Bits(0, maxLatency-1)) val wbInfo = Reg(Vec(maxLatency-1, new WBInfo)) val mem_wen = mem_reg_valid && (mem_ctrl.fma || mem_ctrl.fastpipe || mem_ctrl.fromint) val write_port_busy = RegEnable(mem_wen && (memLatencyMask & latencyMask(ex_ctrl, 1)).orR || (wen & latencyMask(ex_ctrl, 0)).orR, req_valid) for (i <- 0 until maxLatency-2) { when (wen(i+1)) { wbInfo(i) := wbInfo(i+1) } } wen := wen >> 1 when (mem_wen) { when (!killm) { wen := wen >> 1 | memLatencyMask } for (i <- 0 until maxLatency-1) { when (!write_port_busy && memLatencyMask(i)) { wbInfo(i).cp := mem_cp_valid wbInfo(i).single := mem_ctrl.single wbInfo(i).pipeid := pipeid(mem_ctrl) wbInfo(i).rd := mem_reg_inst(11,7) } } } val waddr = Mux(divSqrt_wen, divSqrt_waddr, wbInfo(0).rd) val wdata = Mux(divSqrt_wen, divSqrt_wdata, (pipes.map(_.res.data): Seq[UInt])(wbInfo(0).pipeid)) val wexc = (pipes.map(_.res.exc): Seq[UInt])(wbInfo(0).pipeid) when ((!wbInfo(0).cp && wen(0)) || divSqrt_wen) { regfile(waddr) := wdata if (enableCommitLog) { val wdata_unrec_s = hardfloat.fNFromRecFN(sExpWidth, sSigWidth, wdata) val unrec = fLen match { case 32 => wdata_unrec_s case 64 => val wdata_unrec_d = hardfloat.fNFromRecFN(dExpWidth, dSigWidth, wdata) Mux(wbInfo(0).single, wdata_unrec_s, wdata_unrec_d) } printf("f%d p%d 0x%x\n", waddr, waddr + 32, unrec) } } when (wbInfo(0).cp && wen(0)) { io.cp_resp.bits.data := wdata io.cp_resp.valid := Bool(true) } io.cp_req.ready := !ex_reg_valid val wb_toint_valid = wb_reg_valid && wb_ctrl.toint val wb_toint_exc = RegEnable(fpiu.io.out.bits.exc, mem_ctrl.toint) io.fcsr_flags.valid := wb_toint_valid || divSqrt_wen || wen(0) io.fcsr_flags.bits := Mux(wb_toint_valid, wb_toint_exc, UInt(0)) | Mux(divSqrt_wen, divSqrt_flags, UInt(0)) | Mux(wen(0), wexc, UInt(0)) val units_busy = mem_reg_valid && (mem_ctrl.div || mem_ctrl.sqrt) && (!divSqrt_inReady || wen.orR) io.fcsr_rdy := !(ex_reg_valid && ex_ctrl.wflags || mem_reg_valid && mem_ctrl.wflags || wb_reg_valid && wb_ctrl.toint || wen.orR || divSqrt_in_flight) io.nack_mem := units_busy || write_port_busy || divSqrt_in_flight io.dec <> fp_decoder.io.sigs def useScoreboard(f: ((Pipe, Int)) => Bool) = pipes.zipWithIndex.filter(_._1.lat > 3).map(x => f(x)).fold(Bool(false))(_||_) io.sboard_set := wb_reg_valid && !wb_cp_valid && Reg(next=useScoreboard(_._1.cond(mem_ctrl)) || mem_ctrl.div || mem_ctrl.sqrt) io.sboard_clr := !wb_cp_valid && (divSqrt_wen || (wen(0) && useScoreboard(x => wbInfo(0).pipeid === UInt(x._2)))) io.sboard_clra := waddr // we don't currently support round-max-magnitude (rm=4) io.illegal_rm := ex_rm(2) && ex_ctrl.round divSqrt_wdata := 0 divSqrt_flags := 0 if (cfg.divSqrt) { require(fLen == 64) val divSqrt_single = Reg(Bool()) val divSqrt_rm = Reg(Bits()) val divSqrt_flags_double = Reg(Bits()) val divSqrt_wdata_double = Reg(Bits()) val divSqrt = Module(new hardfloat.DivSqrtRecF64) divSqrt_inReady := Mux(divSqrt.io.sqrtOp, divSqrt.io.inReady_sqrt, divSqrt.io.inReady_div) val divSqrt_outValid = divSqrt.io.outValid_div || divSqrt.io.outValid_sqrt divSqrt.io.inValid := mem_reg_valid && (mem_ctrl.div || mem_ctrl.sqrt) && !divSqrt_in_flight divSqrt.io.sqrtOp := mem_ctrl.sqrt divSqrt.io.a := fpiu.io.as_double.in1 divSqrt.io.b := fpiu.io.as_double.in2 divSqrt.io.roundingMode := fpiu.io.as_double.rm when (divSqrt.io.inValid && divSqrt_inReady) { divSqrt_in_flight := true divSqrt_killed := killm divSqrt_single := mem_ctrl.single divSqrt_waddr := mem_reg_inst(11,7) divSqrt_rm := divSqrt.io.roundingMode } when (divSqrt_outValid) { divSqrt_wen := !divSqrt_killed divSqrt_wdata_double := divSqrt.io.out divSqrt_in_flight := false divSqrt_flags_double := divSqrt.io.exceptionFlags } val divSqrt_toSingle = Module(new hardfloat.RecFNToRecFN(11, 53, 8, 24)) divSqrt_toSingle.io.in := divSqrt_wdata_double divSqrt_toSingle.io.roundingMode := divSqrt_rm divSqrt_wdata := Mux(divSqrt_single, divSqrt_toSingle.io.out, divSqrt_wdata_double) divSqrt_flags := divSqrt_flags_double | Mux(divSqrt_single, divSqrt_toSingle.io.exceptionFlags, Bits(0)) } else { when (ex_ctrl.div || ex_ctrl.sqrt) { io.illegal_rm := true } } }