//max function
`define max(a,b) (((a) > (b)) ? (a) : (b))
// constants defining different privilege modes
// defined in Table 1.1 of the privileged spec
localparam M_MODE = (2'b11);
localparam S_MODE = (2'b01);
localparam U_MODE = (2'b00);
// Virtual Memory Constants
localparam VPN_SEGMENT_BITS = (XLEN == 32 ? 32'd10 : 32'd9);
localparam VPN_BITS = (XLEN==32 ? (2*VPN_SEGMENT_BITS) : (4*VPN_SEGMENT_BITS));
localparam PPN_BITS = (XLEN==32 ? 32'd22 : 32'd44);
localparam PA_BITS = (XLEN==32 ? 32'd34 : 32'd56);
localparam SVMODE_BITS = (XLEN==32 ? 32'd1 : 32'd4);
localparam ASID_BASE = (XLEN==32 ? 32'd22 : 32'd44);
localparam ASID_BITS = (XLEN==32 ? 32'd9 : 32'd16);
// constants to check SATP_MODE against
// defined in Table 4.3 of the privileged spec
localparam NO_TRANSLATE = 4'd0;
localparam SV32 = 4'd1;
localparam SV39 = 4'd8;
localparam SV48 = 4'd9;
// macros to define supported modes
localparam logic I_SUPPORTED = (!E_SUPPORTED);
localparam logic A_SUPPORTED = (ZAAMO_SUPPORTED & ZALRSC_SUPPORTED);
localparam logic B_SUPPORTED = ((ZBA_SUPPORTED & ZBB_SUPPORTED & ZBS_SUPPORTED));
localparam logic C_SUPPORTED = ZCA_SUPPORTED & (D_SUPPORTED ? ZCD_SUPPORTED : 1) & (F_SUPPORTED ? ((XLEN == 32) ? ZCF_SUPPORTED : 1) : 1);
localparam logic ZKN_SUPPORTED = (ZBKB_SUPPORTED & ZBKC_SUPPORTED & ZBKX_SUPPORTED & ZKND_SUPPORTED & ZKNE_SUPPORTED & ZKNH_SUPPORTED);
// Configure MISA based on supported extensions
localparam MISA = {6'b0, 5'b0, U_SUPPORTED, 1'b0, S_SUPPORTED, 1'b0, Q_SUPPORTED, 3'b0, M_SUPPORTED, 3'b0, I_SUPPORTED, 2'b0,
F_SUPPORTED, E_SUPPORTED, D_SUPPORTED, C_SUPPORTED, B_SUPPORTED, A_SUPPORTED};
// logarithm of XLEN, used for number of index bits to select
localparam LOG_XLEN = (XLEN == 32 ? 32'd5 : 32'd6);
// Number of 64 bit PMP Configuration Register entries (or pairs of 32 bit entries)
localparam PMPCFG_ENTRIES = (PMP_ENTRIES/32'd8);
// Floating point constants for Quad, Double, Single, and Half precisions
// Lim: I've made some of these 64 bit to avoid width warnings.
// If errors crop up, try downsizing back to 32.
localparam Q_LEN = 32'd128;
localparam Q_NE = 32'd15;
localparam Q_NF = 32'd112;
localparam Q_BIAS = 32'd16383;
localparam Q_FMT = 2'd3;
localparam D_LEN = 32'd64;
localparam D_NE = 32'd11;
localparam D_NF = 32'd52;
localparam D_BIAS = 32'd1023;
localparam D_FMT = 2'd1;
localparam S_LEN = 32'd32;
localparam S_NE = 32'd8;
localparam S_NF = 32'd23;
localparam S_BIAS = 32'd127;
localparam S_FMT = 2'd0;
localparam H_LEN = 32'd16;
localparam H_NE = 32'd5;
localparam H_NF = 32'd10;
localparam H_BIAS = 32'd15;
localparam H_FMT = 2'd2;
// Floating point length FLEN and number of exponent (NE) and fraction (NF) bits (for longest format supported)
localparam FLEN = Q_SUPPORTED ? Q_LEN : D_SUPPORTED ? D_LEN : S_LEN;
localparam NE = Q_SUPPORTED ? Q_NE : D_SUPPORTED ? D_NE : S_NE;
localparam NF = Q_SUPPORTED ? Q_NF : D_SUPPORTED ? D_NF : S_NF;
localparam FMT = Q_SUPPORTED ? 2'd3 : D_SUPPORTED ? 2'd1 : 2'd0;
localparam BIAS = Q_SUPPORTED ? Q_BIAS : D_SUPPORTED ? D_BIAS : S_BIAS;
localparam LOGFLEN = $clog2(FLEN);
// Floating point constants needed for FPU paramerterization
// LEN1/NE1/NF1/FNT1 is the size of the second longest supported format
localparam FPSIZES = (32)'(Q_SUPPORTED)+(32)'(D_SUPPORTED)+(32)'(F_SUPPORTED)+(32)'(ZFH_SUPPORTED);
localparam FMTBITS = (32)'(FPSIZES>=3)+1;
localparam LEN1 = (FLEN > D_LEN) ? D_LEN : (FLEN > S_LEN) ? S_LEN : H_LEN;
localparam NE1 = (FLEN > D_LEN) ? D_NE : (FLEN > S_LEN) ? S_NE : H_NE;
localparam NF1 = (FLEN > D_LEN) ? D_NF : (FLEN > S_LEN) ? S_NF : H_NF;
localparam FMT1 = (FLEN > D_LEN) ? 2'd1 : (FLEN > S_LEN) ? 2'd0 : 2'd2;
localparam BIAS1 = (FLEN > D_LEN) ? D_BIAS : (FLEN > S_LEN) ? S_BIAS : H_BIAS;
// LEN2 etc is the size of the third longest supported format
localparam LEN2 = (LEN1 > S_LEN) ? S_LEN : H_LEN;
localparam NE2 = (LEN1 > S_LEN) ? S_NE : H_NE;
localparam NF2 = (LEN1 > S_LEN) ? S_NF : H_NF;
localparam FMT2 = (LEN1 > S_LEN) ? 2'd0 : 2'd2;
localparam BIAS2 = (LEN1 > S_LEN) ? S_BIAS : H_BIAS;
// divider r and rk (bits per digit, bits per cycle)
localparam LOGR = $clog2(RADIX); // r = log(R) bits per digit
localparam RK = LOGR*DIVCOPIES; // r*k bits per cycle generated
// intermediate division parameters not directly used in fdivsqrt hardware
localparam FPDIVMINb = NF + 2; // minimum length of fractional part: Nf result bits + guard and round bits + 1 extra bit to allow sqrt being shifted right
localparam DIVMINb = ((FPDIVMINb<XLEN) & IDIV_ON_FPU) ? XLEN : FPDIVMINb; // minimum fractional bits b = max(XLEN, FPDIVMINb)
localparam RESBITS = DIVMINb + LOGR; // number of bits in a result: r integer + b fractional
// division constants
localparam FPDUR = (RESBITS-1)/RK + 1 ; // ceiling((r+b)/rk)
localparam DIVb = FPDUR*RK - LOGR; // divsqrt fractional bits, so total number of bits is a multiple of rk after r integer bits
localparam DURLEN = $clog2(FPDUR); // enough bits to count the duration
localparam DIVBLEN = $clog2(DIVb+1); // enough bits to count number of fractional bits + 1 integer bit
// integer division/remainder constants
localparam INTRESBITS = XLEN + LOGR; // number of bits in a result: r integer + XLEN fractional
localparam INTFPDUR = (INTRESBITS-1)/RK + 1 ;
localparam INTDIVb = INTFPDUR*RK - LOGR;
// largest length in IEU/FPU
localparam BASECVTLEN = `max(XLEN, NF); // convert length excluding Zfa fcvtmod.w.d
localparam CVTLEN = (ZFA_SUPPORTED & D_SUPPORTED) ? `max(BASECVTLEN, 32'd84) : BASECVTLEN; // fcvtmod.w.d needs at least 32+52 because a double with 52 fractional bits might be into upper bits of 32 bit word
localparam LLEN = `max($unsigned(FLEN), $unsigned(XLEN));
localparam LOGCVTLEN = $unsigned($clog2(CVTLEN+1));
// size of FMA output in U(NF+4).(3NF+2) format
localparam FMALEN = 3*NF + 6;
// NORMSHIFTSIZE is the bits out of the normalization shifter
localparam NORMSHIFTSZ = `max(`max((CVTLEN+NF+1), (DIVb + 1 + NF + 1)), (FMALEN + 2));
localparam LOGNORMSHIFTSZ = ($clog2(NORMSHIFTSZ)); // log_2(NORMSHIFTSZ)
// Disable spurious Verilator warnings
/* verilator lint_off STMTDLY */
/* verilator lint_off ASSIGNDLY */
/* verilator lint_off PINCONNECTEMPTY */