OpenFPGA/openfpga_flow/benchmarks/iwls2005/fpu/rtl/post_norm.v

676 lines
24 KiB
Verilog

/////////////////////////////////////////////////////////////////////
//// ////
//// Post Norm ////
//// Floating Point Post Normalisation Unit ////
//// ////
//// Author: Rudolf Usselmann ////
//// rudi@asics.ws ////
//// ////
/////////////////////////////////////////////////////////////////////
//// ////
//// Copyright (C) 2000 Rudolf Usselmann ////
//// rudi@asics.ws ////
//// ////
//// This source file may be used and distributed without ////
//// restriction provided that this copyright statement is not ////
//// removed from the file and that any derivative work contains ////
//// the original copyright notice and the associated disclaimer.////
//// ////
//// THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY ////
//// EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED ////
//// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS ////
//// FOR A PARTICULAR PURPOSE. IN NO EVENT SHALL THE AUTHOR ////
//// OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, ////
//// INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES ////
//// (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE ////
//// GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR ////
//// BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF ////
//// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT ////
//// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT ////
//// OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE ////
//// POSSIBILITY OF SUCH DAMAGE. ////
//// ////
/////////////////////////////////////////////////////////////////////
`timescale 1ns / 100ps
module post_norm( clk, fpu_op, opas, sign, rmode, fract_in, exp_in, exp_ovf,
opa_dn, opb_dn, rem_00, div_opa_ldz, output_zero, out,
ine, overflow, underflow, f2i_out_sign);
input clk;
input [2:0] fpu_op;
input opas;
input sign;
input [1:0] rmode;
input [47:0] fract_in;
input [1:0] exp_ovf;
input [7:0] exp_in;
input opa_dn, opb_dn;
input rem_00;
input [4:0] div_opa_ldz;
input output_zero;
output [30:0] out;
output ine;
output overflow, underflow;
output f2i_out_sign;
////////////////////////////////////////////////////////////////////////
//
// Local Wires and registers
//
wire [22:0] fract_out;
wire [7:0] exp_out;
wire [30:0] out;
wire exp_out1_co, overflow, underflow;
wire [22:0] fract_out_final;
reg [22:0] fract_out_rnd;
wire [8:0] exp_next_mi;
wire dn;
wire exp_rnd_adj;
wire [7:0] exp_out_final;
reg [7:0] exp_out_rnd;
wire op_dn = opa_dn | opb_dn;
wire op_mul = fpu_op[2:0]==3'b010;
wire op_div = fpu_op[2:0]==3'b011;
wire op_i2f = fpu_op[2:0]==3'b100;
wire op_f2i = fpu_op[2:0]==3'b101;
reg [5:0] fi_ldz;
wire g, r, s;
wire round, round2, round2a, round2_fasu, round2_fmul;
wire [7:0] exp_out_rnd0, exp_out_rnd1, exp_out_rnd2, exp_out_rnd2a;
wire [22:0] fract_out_rnd0, fract_out_rnd1, fract_out_rnd2, fract_out_rnd2a;
wire exp_rnd_adj0, exp_rnd_adj2a;
wire r_sign;
wire ovf0, ovf1;
wire [23:0] fract_out_pl1;
wire [7:0] exp_out_pl1, exp_out_mi1;
wire exp_out_00, exp_out_fe, exp_out_ff, exp_in_00, exp_in_ff;
wire exp_out_final_ff, fract_out_7fffff;
wire [24:0] fract_trunc;
wire [7:0] exp_out1;
wire grs_sel;
wire fract_out_00, fract_in_00;
wire shft_co;
wire [8:0] exp_in_pl1, exp_in_mi1;
wire [47:0] fract_in_shftr;
wire [47:0] fract_in_shftl;
wire [7:0] exp_div;
wire [7:0] shft2;
wire [7:0] exp_out1_mi1;
wire div_dn;
wire div_nr;
wire grs_sel_div;
wire div_inf;
wire [6:0] fi_ldz_2a;
wire [7:0] fi_ldz_2;
wire [7:0] div_shft1, div_shft2, div_shft3, div_shft4;
wire div_shft1_co;
wire [8:0] div_exp1;
wire [7:0] div_exp2, div_exp3;
wire left_right, lr_mul, lr_div;
wire [7:0] shift_right, shftr_mul, shftr_div;
wire [7:0] shift_left, shftl_mul, shftl_div;
wire [7:0] fasu_shift;
wire [7:0] exp_fix_div;
wire [7:0] exp_fix_diva, exp_fix_divb;
wire [5:0] fi_ldz_mi1;
wire [5:0] fi_ldz_mi22;
wire exp_zero;
wire [6:0] ldz_all;
wire [7:0] ldz_dif;
wire [8:0] div_scht1a;
wire [7:0] f2i_shft;
wire [55:0] exp_f2i_1;
wire f2i_zero, f2i_max;
wire [7:0] f2i_emin;
wire [7:0] conv_shft;
wire [7:0] exp_i2f, exp_f2i, conv_exp;
wire round2_f2i;
////////////////////////////////////////////////////////////////////////
//
// Normalize and Round Logic
//
// ---------------------------------------------------------------------
// Count Leading zeros in fraction
always @(fract_in)
casex(fract_in) // synopsys full_case parallel_case
48'b1???????????????????????????????????????????????: fi_ldz = 1;
48'b01??????????????????????????????????????????????: fi_ldz = 2;
48'b001?????????????????????????????????????????????: fi_ldz = 3;
48'b0001????????????????????????????????????????????: fi_ldz = 4;
48'b00001???????????????????????????????????????????: fi_ldz = 5;
48'b000001??????????????????????????????????????????: fi_ldz = 6;
48'b0000001?????????????????????????????????????????: fi_ldz = 7;
48'b00000001????????????????????????????????????????: fi_ldz = 8;
48'b000000001???????????????????????????????????????: fi_ldz = 9;
48'b0000000001??????????????????????????????????????: fi_ldz = 10;
48'b00000000001?????????????????????????????????????: fi_ldz = 11;
48'b000000000001????????????????????????????????????: fi_ldz = 12;
48'b0000000000001???????????????????????????????????: fi_ldz = 13;
48'b00000000000001??????????????????????????????????: fi_ldz = 14;
48'b000000000000001?????????????????????????????????: fi_ldz = 15;
48'b0000000000000001????????????????????????????????: fi_ldz = 16;
48'b00000000000000001???????????????????????????????: fi_ldz = 17;
48'b000000000000000001??????????????????????????????: fi_ldz = 18;
48'b0000000000000000001?????????????????????????????: fi_ldz = 19;
48'b00000000000000000001????????????????????????????: fi_ldz = 20;
48'b000000000000000000001???????????????????????????: fi_ldz = 21;
48'b0000000000000000000001??????????????????????????: fi_ldz = 22;
48'b00000000000000000000001?????????????????????????: fi_ldz = 23;
48'b000000000000000000000001????????????????????????: fi_ldz = 24;
48'b0000000000000000000000001???????????????????????: fi_ldz = 25;
48'b00000000000000000000000001??????????????????????: fi_ldz = 26;
48'b000000000000000000000000001?????????????????????: fi_ldz = 27;
48'b0000000000000000000000000001????????????????????: fi_ldz = 28;
48'b00000000000000000000000000001???????????????????: fi_ldz = 29;
48'b000000000000000000000000000001??????????????????: fi_ldz = 30;
48'b0000000000000000000000000000001?????????????????: fi_ldz = 31;
48'b00000000000000000000000000000001????????????????: fi_ldz = 32;
48'b000000000000000000000000000000001???????????????: fi_ldz = 33;
48'b0000000000000000000000000000000001??????????????: fi_ldz = 34;
48'b00000000000000000000000000000000001?????????????: fi_ldz = 35;
48'b000000000000000000000000000000000001????????????: fi_ldz = 36;
48'b0000000000000000000000000000000000001???????????: fi_ldz = 37;
48'b00000000000000000000000000000000000001??????????: fi_ldz = 38;
48'b000000000000000000000000000000000000001?????????: fi_ldz = 39;
48'b0000000000000000000000000000000000000001????????: fi_ldz = 40;
48'b00000000000000000000000000000000000000001???????: fi_ldz = 41;
48'b000000000000000000000000000000000000000001??????: fi_ldz = 42;
48'b0000000000000000000000000000000000000000001?????: fi_ldz = 43;
48'b00000000000000000000000000000000000000000001????: fi_ldz = 44;
48'b000000000000000000000000000000000000000000001???: fi_ldz = 45;
48'b0000000000000000000000000000000000000000000001??: fi_ldz = 46;
48'b00000000000000000000000000000000000000000000001?: fi_ldz = 47;
48'b00000000000000000000000000000000000000000000000?: fi_ldz = 48;
endcase
// ---------------------------------------------------------------------
// Normalize
wire exp_in_80;
wire rmode_00, rmode_01, rmode_10, rmode_11;
// Misc common signals
assign exp_in_ff = &exp_in;
assign exp_in_00 = !(|exp_in);
assign exp_in_80 = exp_in[7] & !(|exp_in[6:0]);
assign exp_out_ff = &exp_out;
assign exp_out_00 = !(|exp_out);
assign exp_out_fe = &exp_out[7:1] & !exp_out[0];
assign exp_out_final_ff = &exp_out_final;
assign fract_out_7fffff = &fract_out;
assign fract_out_00 = !(|fract_out);
assign fract_in_00 = !(|fract_in);
assign rmode_00 = (rmode==2'b00);
assign rmode_01 = (rmode==2'b01);
assign rmode_10 = (rmode==2'b10);
assign rmode_11 = (rmode==2'b11);
// Fasu Output will be denormalized ...
assign dn = !op_mul & !op_div & (exp_in_00 | (exp_next_mi[8] & !fract_in[47]) );
// ---------------------------------------------------------------------
// Fraction Normalization
parameter f2i_emax = 8'h9d;
// Incremented fraction for rounding
assign fract_out_pl1 = fract_out + 1;
// Special Signals for f2i
assign f2i_emin = rmode_00 ? 8'h7e : 8'h7f;
assign f2i_zero = (!opas & (exp_in<f2i_emin)) | (opas & (exp_in>f2i_emax)) | (opas & (exp_in<f2i_emin) & (fract_in_00 | !rmode_11));
assign f2i_max = (!opas & (exp_in>f2i_emax)) | (opas & (exp_in<f2i_emin) & !fract_in_00 & rmode_11);
// Claculate various shifting options
assign {shft_co,shftr_mul} = (!exp_ovf[1] & exp_in_00) ? {1'b0, exp_out} : exp_in_mi1 ;
assign {div_shft1_co, div_shft1} = exp_in_00 ? {1'b0, div_opa_ldz} : div_scht1a;
assign div_scht1a = exp_in-div_opa_ldz; // 9 bits - includes carry out
assign div_shft2 = exp_in+2;
assign div_shft3 = div_opa_ldz+exp_in;
assign div_shft4 = div_opa_ldz-exp_in;
assign div_dn = op_dn & div_shft1_co;
assign div_nr = op_dn & exp_ovf[1] & !(|fract_in[46:23]) & (div_shft3>8'h16);
assign f2i_shft = exp_in-8'h7d;
// Select shifting direction
assign left_right = op_div ? lr_div : op_mul ? lr_mul : 1;
assign lr_div = (op_dn & !exp_ovf[1] & exp_ovf[0]) ? 1 :
(op_dn & exp_ovf[1]) ? 0 :
(op_dn & div_shft1_co) ? 0 :
(op_dn & exp_out_00) ? 1 :
(!op_dn & exp_out_00 & !exp_ovf[1]) ? 1 :
exp_ovf[1] ? 0 :
1;
assign lr_mul = (shft_co | (!exp_ovf[1] & exp_in_00) |
(!exp_ovf[1] & !exp_in_00 & (exp_out1_co | exp_out_00) )) ? 1 :
( exp_ovf[1] | exp_in_00 ) ? 0 :
1;
// Select Left and Right shift value
assign fasu_shift = (dn | exp_out_00) ? (exp_in_00 ? 8'h2 : exp_in_pl1[7:0]) : {2'h0, fi_ldz};
assign shift_right = op_div ? shftr_div : shftr_mul;
assign conv_shft = op_f2i ? f2i_shft : {2'h0, fi_ldz};
assign shift_left = op_div ? shftl_div : op_mul ? shftl_mul : (op_f2i | op_i2f) ? conv_shft : fasu_shift;
assign shftl_mul = (shft_co |
(!exp_ovf[1] & exp_in_00) |
(!exp_ovf[1] & !exp_in_00 & (exp_out1_co | exp_out_00))) ? exp_in_pl1[7:0] : {2'h0, fi_ldz};
assign shftl_div = ( op_dn & exp_out_00 & !(!exp_ovf[1] & exp_ovf[0])) ? div_shft1[7:0] :
(!op_dn & exp_out_00 & !exp_ovf[1]) ? exp_in[7:0] :
{2'h0, fi_ldz};
assign shftr_div = (op_dn & exp_ovf[1]) ? div_shft3 :
(op_dn & div_shft1_co) ? div_shft4 :
div_shft2;
// Do the actual shifting
assign fract_in_shftr = (|shift_right[7:6]) ? 0 : fract_in>>shift_right[5:0];
assign fract_in_shftl = (|shift_left[7:6] | (f2i_zero & op_f2i)) ? 0 : fract_in<<shift_left[5:0];
// Chose final fraction output
assign {fract_out,fract_trunc} = left_right ? fract_in_shftl : fract_in_shftr;
// ---------------------------------------------------------------------
// Exponent Normalization
assign fi_ldz_mi1 = fi_ldz - 1;
assign fi_ldz_mi22 = fi_ldz - 22;
assign exp_out_pl1 = exp_out + 1;
assign exp_out_mi1 = exp_out - 1;
assign exp_in_pl1 = exp_in + 1; // 9 bits - includes carry out
assign exp_in_mi1 = exp_in - 1; // 9 bits - includes carry out
assign exp_out1_mi1 = exp_out1 - 1;
assign exp_next_mi = exp_in_pl1 - fi_ldz_mi1; // 9 bits - includes carry out
assign exp_fix_diva = exp_in - fi_ldz_mi22;
assign exp_fix_divb = exp_in - fi_ldz_mi1;
assign exp_zero = (exp_ovf[1] & !exp_ovf[0] & op_mul & (!exp_rnd_adj2a | !rmode[1])) | (op_mul & exp_out1_co);
assign {exp_out1_co, exp_out1} = fract_in[47] ? exp_in_pl1 : exp_next_mi;
assign f2i_out_sign = !opas ? ((exp_in<f2i_emin) ? 0 : (exp_in>f2i_emax) ? 0 : opas) :
((exp_in<f2i_emin) ? 0 : (exp_in>f2i_emax) ? 1 : opas);
assign exp_i2f = fract_in_00 ? (opas ? 8'h9e : 0) : (8'h9e-fi_ldz);
assign exp_f2i_1 = {{8{fract_in[47]}}, fract_in }<<f2i_shft;
assign exp_f2i = f2i_zero ? 0 : f2i_max ? 8'hff : exp_f2i_1[55:48];
assign conv_exp = op_f2i ? exp_f2i : exp_i2f;
assign exp_out = op_div ? exp_div : (op_f2i | op_i2f) ? conv_exp : exp_zero ? 8'h0 : dn ? {6'h0, fract_in[47:46]} : exp_out1;
assign ldz_all = div_opa_ldz + fi_ldz;
assign ldz_dif = fi_ldz_2 - div_opa_ldz;
assign fi_ldz_2a = 6'd23 - fi_ldz;
assign fi_ldz_2 = {fi_ldz_2a[6], fi_ldz_2a[6:0]};
assign div_exp1 = exp_in_mi1 + fi_ldz_2; // 9 bits - includes carry out
assign div_exp2 = exp_in_pl1 - ldz_all;
assign div_exp3 = exp_in + ldz_dif;
assign exp_div =(opa_dn & opb_dn) ? div_exp3 :
opb_dn ? div_exp1[7:0] :
(opa_dn & !( (exp_in<div_opa_ldz) | (div_exp2>9'hfe) )) ? div_exp2 :
(opa_dn | (exp_in_00 & !exp_ovf[1]) ) ? 0 :
exp_out1_mi1;
assign div_inf = opb_dn & !opa_dn & (div_exp1[7:0] < 8'h7f);
// ---------------------------------------------------------------------
// Round
// Extract rounding (GRS) bits
assign grs_sel_div = op_div & (exp_ovf[1] | div_dn | exp_out1_co | exp_out_00);
assign g = grs_sel_div ? fract_out[0] : fract_out[0];
assign r = grs_sel_div ? (fract_trunc[24] & !div_nr) : fract_trunc[24];
assign s = grs_sel_div ? |fract_trunc[24:0] : (|fract_trunc[23:0] | (fract_trunc[24] & op_div));
// Round to nearest even
assign round = (g & r) | (r & s) ;
assign {exp_rnd_adj0, fract_out_rnd0} = round ? fract_out_pl1 : {1'b0, fract_out};
assign exp_out_rnd0 = exp_rnd_adj0 ? exp_out_pl1 : exp_out;
assign ovf0 = exp_out_final_ff & !rmode_01 & !op_f2i;
// round to zero
assign fract_out_rnd1 = (exp_out_ff & !op_div & !dn & !op_f2i) ? 23'h7fffff : fract_out;
assign exp_fix_div = (fi_ldz>22) ? exp_fix_diva : exp_fix_divb;
assign exp_out_rnd1 = (g & r & s & exp_in_ff) ? (op_div ? exp_fix_div : exp_next_mi[7:0]) :
(exp_out_ff & !op_f2i) ? exp_in : exp_out;
assign ovf1 = exp_out_ff & !dn;
// round to +inf (UP) and -inf (DOWN)
assign r_sign = sign;
assign round2a = !exp_out_fe | !fract_out_7fffff | (exp_out_fe & fract_out_7fffff);
assign round2_fasu = ((r | s) & !r_sign) & (!exp_out[7] | (exp_out[7] & round2a));
assign round2_fmul = !r_sign &
(
(exp_ovf[1] & !fract_in_00 &
( ((!exp_out1_co | op_dn) & (r | s | (!rem_00 & op_div) )) | fract_out_00 | (!op_dn & !op_div))
) |
(
(r | s | (!rem_00 & op_div)) & (
(!exp_ovf[1] & (exp_in_80 | !exp_ovf[0])) | op_div |
( exp_ovf[1] & !exp_ovf[0] & exp_out1_co)
)
)
);
assign round2_f2i = rmode_10 & (( |fract_in[23:0] & !opas & (exp_in<8'h80 )) | (|fract_trunc));
assign round2 = (op_mul | op_div) ? round2_fmul : op_f2i ? round2_f2i : round2_fasu;
assign {exp_rnd_adj2a, fract_out_rnd2a} = round2 ? fract_out_pl1 : {1'b0, fract_out};
assign exp_out_rnd2a = exp_rnd_adj2a ? ((exp_ovf[1] & op_mul) ? exp_out_mi1 : exp_out_pl1) : exp_out;
assign fract_out_rnd2 = (r_sign & exp_out_ff & !op_div & !dn & !op_f2i) ? 23'h7fffff : fract_out_rnd2a;
assign exp_out_rnd2 = (r_sign & exp_out_ff & !op_f2i) ? 8'hfe : exp_out_rnd2a;
// Choose rounding mode
always @(rmode or exp_out_rnd0 or exp_out_rnd1 or exp_out_rnd2)
case(rmode) // synopsys full_case parallel_case
0: exp_out_rnd = exp_out_rnd0;
1: exp_out_rnd = exp_out_rnd1;
2,3: exp_out_rnd = exp_out_rnd2;
endcase
always @(rmode or fract_out_rnd0 or fract_out_rnd1 or fract_out_rnd2)
case(rmode) // synopsys full_case parallel_case
0: fract_out_rnd = fract_out_rnd0;
1: fract_out_rnd = fract_out_rnd1;
2,3: fract_out_rnd = fract_out_rnd2;
endcase
// ---------------------------------------------------------------------
// Final Output Mux
// Fix Output for denormalized and special numbers
wire max_num, inf_out;
assign max_num = ( !rmode_00 & (op_mul | op_div ) & (
( exp_ovf[1] & exp_ovf[0]) |
(!exp_ovf[1] & !exp_ovf[0] & exp_in_ff & (fi_ldz_2<24) & (exp_out!=8'hfe) )
)
) |
( op_div & (
( rmode_01 & ( div_inf |
(exp_out_ff & !exp_ovf[1] ) |
(exp_ovf[1] & exp_ovf[0] )
)
) |
( rmode[1] & !exp_ovf[1] & (
( exp_ovf[0] & exp_in_ff & r_sign & fract_in[47]
) |
( r_sign & (
(fract_in[47] & div_inf) |
(exp_in[7] & !exp_out_rnd[7] & !exp_in_80 & exp_out!=8'h7f ) |
(exp_in[7] & exp_out_rnd[7] & r_sign & exp_out_ff & op_dn &
div_exp1>9'h0fe )
)
) |
( exp_in_00 & r_sign & (
div_inf |
(r_sign & exp_out_ff & fi_ldz_2<24)
)
)
)
)
)
);
assign inf_out = (rmode[1] & (op_mul | op_div) & !r_sign & ( (exp_in_ff & !op_div) |
(exp_ovf[1] & exp_ovf[0] & (exp_in_00 | exp_in[7]) )
)
) | (div_inf & op_div & (
rmode_00 |
(rmode[1] & !exp_in_ff & !exp_ovf[1] & !exp_ovf[0] & !r_sign ) |
(rmode[1] & !exp_ovf[1] & exp_ovf[0] & exp_in_00 & !r_sign)
)
) | (op_div & rmode[1] & exp_in_ff & op_dn & !r_sign & (fi_ldz_2 < 24) & (exp_out_rnd!=8'hfe) );
assign fract_out_final = (inf_out | ovf0 | output_zero ) ? 23'h0 :
(max_num | (f2i_max & op_f2i) ) ? 23'h7fffff :
fract_out_rnd;
assign exp_out_final = ((op_div & exp_ovf[1] & !exp_ovf[0]) | output_zero ) ? 8'h00 :
((op_div & exp_ovf[1] & exp_ovf[0] & rmode_00) | inf_out | (f2i_max & op_f2i) ) ? 8'hff :
max_num ? 8'hfe :
exp_out_rnd;
// ---------------------------------------------------------------------
// Pack Result
assign out = {exp_out_final, fract_out_final};
// ---------------------------------------------------------------------
// Exceptions
wire underflow_fmul;
wire overflow_fdiv;
wire undeflow_div;
wire z = shft_co | ( exp_ovf[1] | exp_in_00) |
(!exp_ovf[1] & !exp_in_00 & (exp_out1_co | exp_out_00));
assign underflow_fmul = ( (|fract_trunc) & z & !exp_in_ff ) |
(fract_out_00 & !fract_in_00 & exp_ovf[1]);
assign undeflow_div = !(exp_ovf[1] & exp_ovf[0] & rmode_00) & !inf_out & !max_num & exp_out_final!=8'hff & (
((|fract_trunc) & !opb_dn & (
( op_dn & !exp_ovf[1] & exp_ovf[0]) |
( op_dn & exp_ovf[1]) |
( op_dn & div_shft1_co) |
exp_out_00 |
exp_ovf[1]
)
) |
( exp_ovf[1] & !exp_ovf[0] & (
( op_dn & exp_in>8'h16 & fi_ldz<23) |
( op_dn & exp_in<23 & fi_ldz<23 & !rem_00) |
( !op_dn & (exp_in[7]==exp_div[7]) & !rem_00) |
( !op_dn & exp_in_00 & (exp_div[7:1]==7'h7f) ) |
( !op_dn & exp_in<8'h7f & exp_in>8'h20 )
)
) |
(!exp_ovf[1] & !exp_ovf[0] & (
( op_dn & fi_ldz<23 & exp_out_00) |
( exp_in_00 & !rem_00) |
( !op_dn & ldz_all<23 & exp_in==1 & exp_out_00 & !rem_00)
)
)
);
assign underflow = op_div ? undeflow_div : op_mul ? underflow_fmul : (!fract_in[47] & exp_out1_co) & !dn;
assign overflow_fdiv = inf_out |
(!rmode_00 & max_num) |
(exp_in[7] & op_dn & exp_out_ff) |
(exp_ovf[0] & (exp_ovf[1] | exp_out_ff) );
assign overflow = op_div ? overflow_fdiv : (ovf0 | ovf1);
wire f2i_ine;
assign f2i_ine = (f2i_zero & !fract_in_00 & !opas) |
(|fract_trunc) |
(f2i_zero & (exp_in<8'h80) & opas & !fract_in_00) |
(f2i_max & rmode_11 & (exp_in<8'h80));
assign ine = op_f2i ? f2i_ine :
op_i2f ? (|fract_trunc) :
((r & !dn) | (s & !dn) | max_num | (op_div & !rem_00));
// ---------------------------------------------------------------------
// Debugging Stuff
// synopsys translate_off
wire [26:0] fracta_del, fractb_del;
wire [2:0] grs_del;
wire dn_del;
wire [7:0] exp_in_del;
wire [7:0] exp_out_del;
wire [22:0] fract_out_del;
wire [47:0] fract_in_del;
wire overflow_del;
wire [1:0] exp_ovf_del;
wire [22:0] fract_out_x_del, fract_out_rnd2a_del;
wire [24:0] trunc_xx_del;
wire exp_rnd_adj2a_del;
wire [22:0] fract_dn_del;
wire [4:0] div_opa_ldz_del;
wire [23:0] fracta_div_del;
wire [23:0] fractb_div_del;
wire div_inf_del;
wire [7:0] fi_ldz_2_del;
wire inf_out_del, max_out_del;
wire [5:0] fi_ldz_del;
wire rx_del;
wire ez_del;
wire lr;
wire [7:0] shr, shl, exp_div_del;
delay2 #26 ud000(clk, test.u0.fracta, fracta_del);
delay2 #26 ud001(clk, test.u0.fractb, fractb_del);
delay1 #2 ud002(clk, {g,r,s}, grs_del);
delay1 #0 ud004(clk, dn, dn_del);
delay1 #7 ud005(clk, exp_in, exp_in_del);
delay1 #7 ud007(clk, exp_out_rnd, exp_out_del);
delay1 #47 ud009(clk, fract_in, fract_in_del);
delay1 #0 ud010(clk, overflow, overflow_del);
delay1 #1 ud011(clk, exp_ovf, exp_ovf_del);
delay1 #22 ud014(clk, fract_out, fract_out_x_del);
delay1 #24 ud015(clk, fract_trunc, trunc_xx_del);
delay1 #0 ud017(clk, exp_rnd_adj2a, exp_rnd_adj2a_del);
delay1 #4 ud019(clk, div_opa_ldz, div_opa_ldz_del);
delay3 #23 ud020(clk, test.u0.fdiv_opa[49:26], fracta_div_del);
delay3 #23 ud021(clk, test.u0.fractb_mul, fractb_div_del);
delay1 #0 ud023(clk, div_inf, div_inf_del);
delay1 #7 ud024(clk, fi_ldz_2, fi_ldz_2_del);
delay1 #0 ud025(clk, inf_out, inf_out_del);
delay1 #0 ud026(clk, max_num, max_num_del);
delay1 #5 ud027(clk, fi_ldz, fi_ldz_del);
delay1 #0 ud028(clk, rem_00, rx_del);
delay1 #0 ud029(clk, left_right, lr);
delay1 #7 ud030(clk, shift_right, shr);
delay1 #7 ud031(clk, shift_left, shl);
delay1 #22 ud032(clk, fract_out_rnd2a, fract_out_rnd2a_del);
delay1 #7 ud033(clk, exp_div, exp_div_del);
always @(test.error_event)
begin
$display("\n----------------------------------------------");
$display("ERROR: GRS: %b exp_ovf: %b dn: %h exp_in: %h exp_out: %h, exp_rnd_adj2a: %b",
grs_del, exp_ovf_del, dn_del, exp_in_del, exp_out_del, exp_rnd_adj2a_del);
$display(" div_opa: %b, div_opb: %b, rem_00: %b, exp_div: %h",
fracta_div_del, fractb_div_del, rx_del, exp_div_del);
$display(" lr: %b, shl: %h, shr: %h",
lr, shl, shr);
$display(" overflow: %b, fract_in=%b fa:%h fb:%h",
overflow_del, fract_in_del, fracta_del, fractb_del);
$display(" div_opa_ldz: %h, div_inf: %b, inf_out: %b, max_num: %b, fi_ldz: %h, fi_ldz_2: %h",
div_opa_ldz_del, div_inf_del, inf_out_del, max_num_del, fi_ldz_del, fi_ldz_2_del);
$display(" fract_out_x: %b, fract_out_rnd2a_del: %h, fract_trunc: %b\n",
fract_out_x_del, fract_out_rnd2a_del, trunc_xx_del);
end
// synopsys translate_on
endmodule
// synopsys translate_off
module delay1(clk, in, out);
parameter N = 1;
input [N:0] in;
output [N:0] out;
input clk;
reg [N:0] out;
always @(posedge clk)
out <= #1 in;
endmodule
module delay2(clk, in, out);
parameter N = 1;
input [N:0] in;
output [N:0] out;
input clk;
reg [N:0] out, r1;
always @(posedge clk)
r1 <= #1 in;
always @(posedge clk)
out <= #1 r1;
endmodule
module delay3(clk, in, out);
parameter N = 1;
input [N:0] in;
output [N:0] out;
input clk;
reg [N:0] out, r1, r2;
always @(posedge clk)
r1 <= #1 in;
always @(posedge clk)
r2 <= #1 r1;
always @(posedge clk)
out <= #1 r2;
endmodule
// synopsys translate_on