a2o/dev/verilog/work/fu_eov.v

// © IBM Corp. 2020
// Licensed under the Apache License, Version 2.0 (the "License"), as modified by
// the terms below; you may not use the files in this repository except in
// compliance with the License as modified.
// You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0
//
// Modified Terms:
//
//    1) For the purpose of the patent license granted to you in Section 3 of the
//    License, the "Work" hereby includes implementations of the work of authorship
//    in physical form.
//
//    2) Notwithstanding any terms to the contrary in the License, any licenses
//    necessary for implementation of the Work that are available from OpenPOWER
//    via the Power ISA End User License Agreement (EULA) are explicitly excluded
//    hereunder, and may be obtained from OpenPOWER under the terms and conditions
//    of the EULA.  
//
// Unless required by applicable law or agreed to in writing, the reference design
// distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
// WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License
// for the specific language governing permissions and limitations under the License.
// 
// Additional rights, including the ability to physically implement a softcore that
// is compliant with the required sections of the Power ISA Specification, are
// available at no cost under the terms of the OpenPOWER Power ISA EULA, which can be
// obtained (along with the Power ISA) here: https://openpowerfoundation.org. 

`timescale 1 ns / 1 ns

`include "tri_a2o.vh"

module fu_eov(
   vdd,
   gnd,
   clkoff_b,
   act_dis,
   flush,
   delay_lclkr,
   mpw1_b,
   mpw2_b,
   sg_1,
   thold_1,
   fpu_enable,
   nclk,
   f_eov_si,
   f_eov_so,
   ex3_act_b,
   f_tbl_ex5_unf_expo,
   f_tbe_ex4_may_ov,
   f_tbe_ex4_expo,
   f_pic_ex4_sel_est,
   f_eie_ex4_iexp,
   f_pic_ex4_sp_b,
   f_pic_ex5_oe,
   f_pic_ex5_ue,
   f_pic_ex5_ov_en,
   f_pic_ex5_uf_en,
   f_pic_ex5_spec_sel_k_e,
   f_pic_ex5_spec_sel_k_f,
   f_pic_ex5_sel_ov_spec,
   f_pic_ex5_to_int_ov_all,
   f_lza_ex5_sh_rgt_en_eov,
   f_lza_ex5_lza_amt_eov,
   f_lza_ex5_no_lza_edge,
   f_nrm_ex5_extra_shift,
   f_eov_ex5_may_ovf,
   f_eov_ex6_sel_k_f,
   f_eov_ex6_sel_k_e,
   f_eov_ex6_sel_kif_f,
   f_eov_ex6_sel_kif_e,
   f_eov_ex6_unf_expo,
   f_eov_ex6_ovf_expo,
   f_eov_ex6_ovf_if_expo,
   f_eov_ex6_expo_p0,
   f_eov_ex6_expo_p1,
   f_eov_ex6_expo_p0_ue1oe1,
   f_eov_ex6_expo_p1_ue1oe1
);
   parameter     expand_type = 2;		// 0 - ibm tech, 1 - other );

   inout         vdd;
   inout         gnd;
   input         clkoff_b;		// tiup
   input         act_dis;		// ??tidn??
   input         flush;		// ??tidn??
   input [4:5]   delay_lclkr;		// tidn,
   input [4:5]   mpw1_b;		// tidn,
   input [0:1]   mpw2_b;		// tidn,
   input         sg_1;
   input         thold_1;
   input         fpu_enable;		//dc_act
   input [0:`NCLK_WIDTH-1]         nclk;

   input         f_eov_si;		// perv
   output        f_eov_so;		// perv
   input         ex3_act_b;		// act

   input         f_tbl_ex5_unf_expo;
   input         f_tbe_ex4_may_ov;
   input [1:13]  f_tbe_ex4_expo;
   input         f_pic_ex4_sel_est;
   input [1:13]  f_eie_ex4_iexp;

   input         f_pic_ex4_sp_b;
   input         f_pic_ex5_oe;
   input         f_pic_ex5_ue;
   input         f_pic_ex5_ov_en;
   input         f_pic_ex5_uf_en;
   input         f_pic_ex5_spec_sel_k_e;
   input         f_pic_ex5_spec_sel_k_f;
   input         f_pic_ex5_sel_ov_spec;
   input         f_pic_ex5_to_int_ov_all;

   input         f_lza_ex5_sh_rgt_en_eov;
   input [0:7]   f_lza_ex5_lza_amt_eov;
   input         f_lza_ex5_no_lza_edge;
   input         f_nrm_ex5_extra_shift;
   output        f_eov_ex5_may_ovf;		////#pic generate constant

   output        f_eov_ex6_sel_k_f;		////#rnd
   output        f_eov_ex6_sel_k_e;		////#rnd
   output        f_eov_ex6_sel_kif_f;		////#rnd
   output        f_eov_ex6_sel_kif_e;		////#rnd
   output        f_eov_ex6_unf_expo;		////#rnd for ux
   output        f_eov_ex6_ovf_expo;		////#rnd for INF,ox
   output        f_eov_ex6_ovf_if_expo;		////#rnd for INF,ox
   output [1:13] f_eov_ex6_expo_p0;		////#rnd result exponent
   output [1:13] f_eov_ex6_expo_p1;		////#rnd result exponent if rnd_up_all1
   output [3:7]  f_eov_ex6_expo_p0_ue1oe1;		////#rnd
   output [3:7]  f_eov_ex6_expo_p1_ue1oe1;		////#rnd

   // end ports

   // ENTITY


   parameter     tiup = 1'b1;
   parameter     tidn = 1'b0;

   wire          sg_0;
   wire          thold_0_b;
   wire          thold_0;
   wire          force_t;
   wire          ex4_act;
   wire          ex3_act;
   wire          ex5_act;
   (* analysis_not_referenced="TRUE" *) // unused
   wire [0:2]    act_spare_unused;
   //-----------------
   wire [0:4]    act_so;		//SCAN
   wire [0:4]    act_si;		//SCAN
   wire [0:15]   ex5_iexp_so;		//SCAN
   wire [0:15]   ex5_iexp_si;		//SCAN
   wire [0:2]    ex6_ovctl_so;		//SCAN
   wire [0:2]    ex6_ovctl_si;		//SCAN
   wire [0:12]   ex6_misc_so;		//SCAN
   wire [0:12]   ex6_misc_si;		//SCAN
   wire [0:12]   ex6_urnd0_so;		//SCAN
   wire [0:12]   ex6_urnd0_si;		//SCAN
   wire [0:12]   ex6_urnd1_so;		//SCAN
   wire [0:12]   ex6_urnd1_si;		//SCAN
   //-----------------
   wire          ex5_sp;
   wire          ex5_unf_m1_co12;
   wire          ex5_unf_p0_co12;
   wire          ex5_ovf_m1_co12;
   wire          ex5_ovf_p0_co12;
   wire          ex5_ovf_p1_co12;
   wire          ex5_ovf_m1;
   wire          ex5_ovf_p0;
   wire          ex5_ovf_p1;
   wire          ex5_unf_m1;
   wire          ex5_unf_p0;
   wire [1:13]   ex5_i_exp;
   wire [3:7]    ex5_ue1oe1_k;
   wire [1:13]   ex5_lzasub_sum;
   wire [1:12]   ex5_lzasub_car;
   wire [1:12]   ex5_lzasub_p;
   wire [2:12]   ex5_lzasub_t;
   wire [2:12]   ex5_lzasub_g;
   wire [1:13]   ex5_lzasub_m1;
   wire [1:13]   ex5_lzasub_p0;
   wire [1:13]   ex5_lzasub_p1;
   wire [2:11]   ex5_lzasub_c0;
   wire [2:11]   ex5_lzasub_c1;
   wire [1:11]   ex5_lzasub_s0;
   wire [1:11]   ex5_lzasub_s1;
   wire [1:13]   ex5_ovf_sum;
   wire [1:12]   ex5_ovf_car;
   wire [2:12]   ex5_ovf_g;
   wire [2:12]   ex5_ovf_t;
   wire [1:1]    ex5_ovf_p;
   wire [1:13]   ex5_unf_sum;
   wire [1:12]   ex5_unf_car;
   wire [2:12]   ex5_unf_g;
   wire [2:12]   ex5_unf_t;
   wire [1:1]    ex5_unf_p;
   wire          ex5_unf_ci0_02t11;
   wire          ex5_unf_ci1_02t11;
   wire [1:13]   ex5_expo_p0;
   wire [1:13]   ex5_expo_p1;
   wire [1:13]   ex6_expo_p0;
   wire [1:13]   ex6_expo_p1;
   wire [3:7]    ex6_ue1oe1_k;
   wire [3:7]    ex6_ue1oe1_p0_p;
   wire [4:6]    ex6_ue1oe1_p0_t;
   wire [4:7]    ex6_ue1oe1_p0_g;
   wire [4:7]    ex6_ue1oe1_p0_c;
   wire [3:7]    ex6_ue1oe1_p1_p;
   wire [4:6]    ex6_ue1oe1_p1_t;
   wire [4:7]    ex6_ue1oe1_p1_g;
   wire [4:7]    ex6_ue1oe1_p1_c;
   wire          ex5_lzasub_m1_c12;
   wire          ex5_lzasub_p0_c12;
   wire          ex5_lzasub_p1_c12;
   wire          ex5_may_ovf;
   wire [0:7]    ex5_lza_amt_b;
   wire [0:7]    ex5_lza_amt;
   wire [1:13]   ex4_iexp;
   wire          ex4_sp;
   wire          ex4_may_ovf;
   wire          ex5_unf_c2_m1;
   wire          ex5_unf_c2_p0;
   wire          ex5_c2_m1;
   wire          ex5_c2_p0;
   wire          ex5_c2_p1;
   wire [4:7]    ex6_ue1oe1_p0_g2_b;
   wire [4:5]    ex6_ue1oe1_p0_t2_b;
   wire [4:7]    ex6_ue1oe1_p1_g2_b;
   wire [4:5]    ex6_ue1oe1_p1_t2_b;
   wire          ex5_unf_g2_02t03;
   wire          ex5_unf_g2_04t05;
   wire          ex5_unf_g2_06t07;
   wire          ex5_unf_g2_08t09;
   wire          ex5_unf_g2_10t11;
   wire          ex5_unf_ci0_g2;
   wire          ex5_unf_ci1_g2;
   wire          ex5_unf_t2_02t03;
   wire          ex5_unf_t2_04t05;
   wire          ex5_unf_t2_06t07;
   wire          ex5_unf_t2_08t09;
   wire          ex5_unf_t2_10t11;
   wire          ex5_unf_g4_02t05;
   wire          ex5_unf_g4_06t09;
   wire          ex5_unf_ci0_g4;
   wire          ex5_unf_ci1_g4;
   wire          ex5_unf_t4_02t05;
   wire          ex5_unf_t4_06t09;
   wire          ex5_unf_g8_02t09;
   wire          ex5_unf_ci0_g8;
   wire          ex5_unf_ci1_g8;
   wire          ex5_unf_t8_02t09;

   wire          ex5_ovf_ci0_02t11;
   wire          ex5_ovf_ci1_02t11;

   wire          ex5_ovf_g2_02t03;
   wire          ex5_ovf_g2_04t05;
   wire          ex5_ovf_g2_06t07;
   wire          ex5_ovf_g2_08t09;
   wire          ex5_ovf_g2_ci0;
   wire          ex5_ovf_g2_ci1;
   wire          ex5_ovf_t2_02t03;
   wire          ex5_ovf_t2_04t05;
   wire          ex5_ovf_t2_06t07;
   wire          ex5_ovf_t2_08t09;
   wire          ex5_ovf_g4_02t05;
   wire          ex5_ovf_g4_06t09;
   wire          ex5_ovf_g4_ci0;
   wire          ex5_ovf_g4_ci1;
   wire          ex5_ovf_t4_02t05;
   wire          ex5_ovf_t4_06t09;
   wire          ex5_ovf_g8_02t09;
   wire          ex5_ovf_g8_ci0;
   wire          ex5_ovf_g8_ci1;
   wire          ex5_ovf_t8_02t09;

   wire [2:11]   ex5_lzasub_gg02;
   wire [2:11]   ex5_lzasub_gt02;
   wire [2:11]   ex5_lzasub_gg04;
   wire [2:11]   ex5_lzasub_gt04;
   wire [2:11]   ex5_lzasub_gg08;
   wire [2:11]   ex5_lzasub_gt08;
   wire          ex5_sh_rgt_en_b;

   wire          ex4_may_ov_usual;

   wire          ex5_ovf_calc;
   wire          ex5_ovf_if_calc;
   wire          ex5_unf_calc;
   wire          ex5_unf_tbl;
   wire          ex5_unf_tbl_spec_e;
   wire          ex5_ov_en;
   wire          ex5_ov_en_oe0;
   wire          ex5_sel_ov_spec;
   wire          ex5_unf_en_nedge;
   wire          ex5_unf_ue0_nestsp;
   wire          ex5_sel_k_part_f;
   wire          ex5_sel_k_part_e;
   wire          ex6_ovf_calc;
   wire          ex6_ovf_if_calc;
   wire          ex6_unf_calc;
   wire          ex6_unf_tbl;
   wire          ex6_unf_tbl_b;
   wire          ex6_unf_tbl_spec_e;
   wire          ex6_ov_en;
   wire          ex6_ov_en_oe0;
   wire          ex6_sel_ov_spec;
   wire          ex6_unf_en_nedge;
   wire          ex6_unf_ue0_nestsp;
   wire          ex6_sel_k_part_f;
   wire          ex6_sel_ov_spec_b;
   wire          ex6_ovf_b;
   wire          ex6_ovf_if_b;
   wire          ex6_ovf_oe0_b;
   wire          ex6_ovf_if_oe0_b;
   wire          ex6_unf_b;
   wire          ex6_unf_ue0_b;
   wire          ex6_sel_k_part_f_b;
   wire          ex6_unf_tbl_spec_e_b;
   wire          ex5_sel_est;
   wire          ex5_est_sp;

   wire [1:13]   ex5_expo_p0_0_b;
   wire [1:13]   ex5_expo_p0_1_b;
   wire [1:13]   ex5_expo_p1_0_b;
   wire [1:13]   ex5_expo_p1_1_b;
   wire          ex5_ovf_calc_0_b;
   wire          ex5_ovf_calc_1_b;
   wire          ex5_ovf_if_calc_0_b;
   wire          ex5_ovf_if_calc_1_b;
   wire          ex5_unf_calc_0_b;
   wire          ex5_unf_calc_1_b;
   wire          ex6_d1clk;
   wire          ex6_d2clk;
   wire [0:`NCLK_WIDTH-1]          ex6_lclk;
   (* analysis_not_referenced="TRUE" *) // unused
   wire          unused;

   assign unused = |(ex5_expo_p0[1:13]) | |(ex5_expo_p1[1:13]) | ex5_ovf_calc | ex5_ovf_if_calc | ex5_unf_calc;

   ////############################################
   ////# pervasive
   ////############################################


   tri_plat  thold_reg_0(
      .vd(vdd),
      .gd(gnd),
      .nclk(nclk),
      .flush(flush),
      .din(thold_1),
      .q(thold_0)
   );


   tri_plat  sg_reg_0(
      .vd(vdd),
      .gd(gnd),
      .nclk(nclk),
      .flush(flush),
      .din(sg_1),
      .q(sg_0)
   );


   tri_lcbor  lcbor_0(
      .clkoff_b(clkoff_b),
      .thold(thold_0),
      .sg(sg_0),
      .act_dis(act_dis),
      .force_t(force_t),
      .thold_b(thold_0_b)
   );

   tri_lcbnd  ex6_lcb(
      .delay_lclkr(delay_lclkr[5]),		// tidn
      .mpw1_b(mpw1_b[5]),		// tidn
      .mpw2_b(mpw2_b[1]),		// tidn
      .force_t(force_t),		// tidn
      .nclk(nclk),		//in
      .vd(vdd),		//inout
      .gd(gnd),		//inout
      .act(ex5_act),		//in
      .sg(sg_0),		//in
      .thold_b(thold_0_b),		//in
      .d1clk(ex6_d1clk),		//out
      .d2clk(ex6_d2clk),		//out
      .lclk(ex6_lclk)		//out
   );

   ////############################################
   ////# ACT LATCHES
   ////############################################

   assign ex3_act = (~ex3_act_b);


   tri_rlmreg_p #(.WIDTH(5),  .NEEDS_SRESET(0)) act_lat(
      .force_t(force_t),		// tidn,
      .d_mode(tiup),
      .delay_lclkr(delay_lclkr[4]),		// tidn,
      .mpw1_b(mpw1_b[4]),		// tidn,
      .mpw2_b(mpw2_b[0]),		// tidn,
      .vd(vdd),
      .gd(gnd),
      .nclk(nclk),
      .thold_b(thold_0_b),
      .sg(sg_0),
      .act(fpu_enable),
      .scout(act_so),
      .scin(act_si),
      //-----------------
      .din({  act_spare_unused[0],
              act_spare_unused[1],
              ex3_act,
              ex4_act,
              act_spare_unused[2]}),
      //-----------------
      .dout({  act_spare_unused[0],
               act_spare_unused[1],
               ex4_act,
               ex5_act,
               act_spare_unused[2]})
   );

   ////##############################################
   ////# EX4 logic
   ////##############################################

   assign ex4_iexp[1:13] = ({13{(~f_pic_ex4_sel_est)}} & f_eie_ex4_iexp[1:13]) |
                            ({13{f_pic_ex4_sel_est}}   & f_tbe_ex4_expo[1:13]);

   assign ex4_sp = (~f_pic_ex4_sp_b);

   // for bias 1023 ... dp underflow =    0,    1        <1+163> =  164
   // for bias 2047 ... dp underflow = 1024, 1025     <1025+163> = 1188
   //
   // for bias 1023 ... sp underflow =  896,  897      <897+163> = 1060
   // for bias 2047 ... sp underflow = 1920, 1921     <1921+163> = 2084
   //
   // lza can subtract at most 163, if expo is > 163, then it will not underflow.
   // (round up a little to make it easier ... sp is the problem )
   //
   //      0_0100_0010_0100 1060  1024 + 36
   //      0_1000_0010_0100 2084
   //      0_1000_0011_0000 <= round up a little to look at less bits
   //      0_0100_0011_0000 <= round up a little to look at less bits
   //----------------------
   //                  1111
   //      1 2345 6789 0123

   assign ex4_may_ovf = (ex4_may_ov_usual & (~f_pic_ex4_sel_est)) | (f_tbe_ex4_may_ov & f_pic_ex4_sel_est);

   assign ex4_may_ov_usual = ((~f_eie_ex4_iexp[1]) & f_eie_ex4_iexp[2]) | ((~f_eie_ex4_iexp[1]) & f_eie_ex4_iexp[3] & f_eie_ex4_iexp[4]) | ((~f_eie_ex4_iexp[1]) & f_eie_ex4_iexp[3] & f_eie_ex4_iexp[5]) | ((~f_eie_ex4_iexp[1]) & f_eie_ex4_iexp[3] & f_eie_ex4_iexp[6]) | ((~f_eie_ex4_iexp[1]) & f_eie_ex4_iexp[3] & f_eie_ex4_iexp[7]) | ((~f_eie_ex4_iexp[1]) & f_eie_ex4_iexp[3] & f_eie_ex4_iexp[8] & f_eie_ex4_iexp[9]);

   ////##############################################
   ////# EX5 latch inputs from ex4
   ////##############################################


   tri_rlmreg_p #(.WIDTH(16),  .NEEDS_SRESET(0)) ex5_iexp_lat(
      .force_t(force_t),		// tidn,
      .d_mode(tiup),
      .delay_lclkr(delay_lclkr[4]),		// tidn,
      .mpw1_b(mpw1_b[4]),		// tidn,
      .mpw2_b(mpw2_b[0]),		// tidn,
      .vd(vdd),
      .gd(gnd),
      .nclk(nclk),
      .thold_b(thold_0_b),
      .sg(sg_0),
      .act(ex4_act),
      .scout(ex5_iexp_so),
      .scin(ex5_iexp_si),
      //-----------------
      .din({ ex4_sp,
             ex4_iexp[1:13],
             ex4_may_ovf,
             f_pic_ex4_sel_est}),
      //-----------------
      .dout({ ex5_sp,		//LAT--
              ex5_i_exp[1:13],		//LAT--
              ex5_may_ovf,		//LAT--
              ex5_sel_est})		//LAT--
   );

   assign f_eov_ex5_may_ovf = ex5_may_ovf;

   ////##############################################
   ////# EX5 logic
   ////##############################################

   ////#-------------------------------------------
   ////# ue1oe1 constant
   ////#-------------------------------------------
   // need to know constant (sp/dp +/-192 +/-1536 )
   // +1536 11000  UNF
   // -1536 01000  OVF
   //  +192 00011  UNF
   //  -192 11101  OVF

   assign ex5_ue1oe1_k[3] = ((~ex5_may_ovf) & (~ex5_sp)) | (ex5_may_ovf & ex5_sp);

   assign ex5_ue1oe1_k[4] = ((~ex5_sp)) | (ex5_may_ovf & ex5_sp);

   assign ex5_ue1oe1_k[5] = (ex5_may_ovf & ex5_sp);

   assign ex5_ue1oe1_k[6] = ((~ex5_may_ovf) & ex5_sp);
   assign ex5_ue1oe1_k[7] = (ex5_sp);

   ////#-------------------------------------------
   ////# subtract the lza (lza is an early signal)
   ////#-------------------------------------------
   // rnd_up=0 extra=1    +0-1  = -1
   // rnd_up=0 extra=0    +0-0  = -0
   // rnd_up=1 extra=1    +1-1  = -0
   // rnd_up=1 extra=0    +1-0  = +1
   //
   // (a - b)    = a + !b + 1
   // (a - b) -1 = a + !b
   //
   // need to calculate (A+!B), (A+!B+1), (A+!B+2)
   // calculate lower 2 bits (A+!B) then determine the co for the 3 seperate cases
   // compound add the upper bits (ci=0) (ci+1), then use the lower cases to select the combinations
   //

   // sort of 3:2 compresor to make room for extra carry for +1 +2;

   assign ex5_lza_amt_b[0:7] = (~f_lza_ex5_lza_amt_eov[0:7]);
   assign ex5_lza_amt[0:7] = f_lza_ex5_lza_amt_eov[0:7];
   assign ex5_sh_rgt_en_b = (~f_lza_ex5_sh_rgt_en_eov);

   //  ex5_lzasub_sum( 0) <=      ex5_sh_rgt_en_b  xor ex5_i_exp( 1);
   assign ex5_lzasub_sum[1] = ex5_sh_rgt_en_b ^ ex5_i_exp[1];
   assign ex5_lzasub_sum[2] = ex5_sh_rgt_en_b ^ ex5_i_exp[2];
   assign ex5_lzasub_sum[3] = ex5_sh_rgt_en_b ^ ex5_i_exp[3];
   assign ex5_lzasub_sum[4] = ex5_sh_rgt_en_b ^ ex5_i_exp[4];
   assign ex5_lzasub_sum[5] = ex5_sh_rgt_en_b ^ ex5_i_exp[5];
   assign ex5_lzasub_sum[6] = ex5_lza_amt_b[0] ^ ex5_i_exp[6];
   assign ex5_lzasub_sum[7] = ex5_lza_amt_b[1] ^ ex5_i_exp[7];
   assign ex5_lzasub_sum[8] = ex5_lza_amt_b[2] ^ ex5_i_exp[8];
   assign ex5_lzasub_sum[9] = ex5_lza_amt_b[3] ^ ex5_i_exp[9];
   assign ex5_lzasub_sum[10] = ex5_lza_amt_b[4] ^ ex5_i_exp[10];
   assign ex5_lzasub_sum[11] = ex5_lza_amt_b[5] ^ ex5_i_exp[11];
   assign ex5_lzasub_sum[12] = ex5_lza_amt_b[6] ^ ex5_i_exp[12];
   assign ex5_lzasub_sum[13] = (~(ex5_lza_amt_b[7] ^ ex5_i_exp[13]));		//!!!!!!!! +1 for negation

   //  ex5_lzasub_car( 0) <= ex5_sh_rgt_en_b  and ex5_i_exp( 1);
   assign ex5_lzasub_car[1] = ex5_sh_rgt_en_b & ex5_i_exp[2];
   assign ex5_lzasub_car[2] = ex5_sh_rgt_en_b & ex5_i_exp[3];
   assign ex5_lzasub_car[3] = ex5_sh_rgt_en_b & ex5_i_exp[4];
   assign ex5_lzasub_car[4] = ex5_sh_rgt_en_b & ex5_i_exp[5];
   assign ex5_lzasub_car[5] = ex5_lza_amt_b[0] & ex5_i_exp[6];
   assign ex5_lzasub_car[6] = ex5_lza_amt_b[1] & ex5_i_exp[7];
   assign ex5_lzasub_car[7] = ex5_lza_amt_b[2] & ex5_i_exp[8];
   assign ex5_lzasub_car[8] = ex5_lza_amt_b[3] & ex5_i_exp[9];
   assign ex5_lzasub_car[9] = ex5_lza_amt_b[4] & ex5_i_exp[10];
   assign ex5_lzasub_car[10] = ex5_lza_amt_b[5] & ex5_i_exp[11];
   assign ex5_lzasub_car[11] = ex5_lza_amt_b[6] & ex5_i_exp[12];
   assign ex5_lzasub_car[12] = ex5_lza_amt_b[7] | ex5_i_exp[13];		//!!!!!! +1 for negation

   assign ex5_lzasub_p[1:12] = ex5_lzasub_car[1:12] ^ ex5_lzasub_sum[1:12];
   assign ex5_lzasub_t[2:12] = ex5_lzasub_car[2:12] | ex5_lzasub_sum[2:12];
   assign ex5_lzasub_g[2:12] = ex5_lzasub_car[2:12] & ex5_lzasub_sum[2:12];

   ////##------------------------------
   ////##-- add the 2 lower bits for the different conditions (+0,+1.+2)
   ////##------------------------------

   assign ex5_lzasub_m1_c12 = ex5_lzasub_g[12];
   assign ex5_lzasub_p0_c12 = ex5_lzasub_g[12] | (ex5_lzasub_t[12] & ex5_lzasub_sum[13]);
   assign ex5_lzasub_p1_c12 = ex5_lzasub_t[12];

   assign ex5_lzasub_m1[13] = ex5_lzasub_sum[13];		//LSB is done  +0
   assign ex5_lzasub_p0[13] = (~ex5_lzasub_sum[13]);		//LSB is done  +1
   assign ex5_lzasub_p1[13] = ex5_lzasub_sum[13];		//LSB is done  +2

   assign ex5_lzasub_m1[12] = ex5_lzasub_p[12];		// +0
   assign ex5_lzasub_p0[12] = ex5_lzasub_p[12] ^ ex5_lzasub_sum[13];		// +1
   assign ex5_lzasub_p1[12] = (~ex5_lzasub_p[12]);		// +2

   ////##-----------------------------------
   ////## the conditional carry chain (+ci,-ci)
   ////##-----------------------------------

   assign ex5_lzasub_gg02[11] = ex5_lzasub_g[11];
   assign ex5_lzasub_gg02[10] = ex5_lzasub_g[10] | (ex5_lzasub_t[10] & ex5_lzasub_g[11]);		//final
   assign ex5_lzasub_gg02[9] = ex5_lzasub_g[9] | (ex5_lzasub_t[9] & ex5_lzasub_g[10]);
   assign ex5_lzasub_gg02[8] = ex5_lzasub_g[8] | (ex5_lzasub_t[8] & ex5_lzasub_g[9]);
   assign ex5_lzasub_gg02[7] = ex5_lzasub_g[7] | (ex5_lzasub_t[7] & ex5_lzasub_g[8]);
   assign ex5_lzasub_gg02[6] = ex5_lzasub_g[6] | (ex5_lzasub_t[6] & ex5_lzasub_g[7]);
   assign ex5_lzasub_gg02[5] = ex5_lzasub_g[5] | (ex5_lzasub_t[5] & ex5_lzasub_g[6]);
   assign ex5_lzasub_gg02[4] = ex5_lzasub_g[4] | (ex5_lzasub_t[4] & ex5_lzasub_g[5]);
   assign ex5_lzasub_gg02[3] = ex5_lzasub_g[3] | (ex5_lzasub_t[3] & ex5_lzasub_g[4]);
   assign ex5_lzasub_gg02[2] = ex5_lzasub_g[2] | (ex5_lzasub_t[2] & ex5_lzasub_g[3]);

   assign ex5_lzasub_gt02[11] = ex5_lzasub_t[11];
   assign ex5_lzasub_gt02[10] = ex5_lzasub_g[10] | (ex5_lzasub_t[10] & ex5_lzasub_t[11]);		//final
   assign ex5_lzasub_gt02[9] = (ex5_lzasub_t[9] & ex5_lzasub_t[10]);
   assign ex5_lzasub_gt02[8] = (ex5_lzasub_t[8] & ex5_lzasub_t[9]);
   assign ex5_lzasub_gt02[7] = (ex5_lzasub_t[7] & ex5_lzasub_t[8]);
   assign ex5_lzasub_gt02[6] = (ex5_lzasub_t[6] & ex5_lzasub_t[7]);
   assign ex5_lzasub_gt02[5] = (ex5_lzasub_t[5] & ex5_lzasub_t[6]);
   assign ex5_lzasub_gt02[4] = (ex5_lzasub_t[4] & ex5_lzasub_t[5]);
   assign ex5_lzasub_gt02[3] = (ex5_lzasub_t[3] & ex5_lzasub_t[4]);
   assign ex5_lzasub_gt02[2] = (ex5_lzasub_t[2] & ex5_lzasub_t[3]);

   assign ex5_lzasub_gg04[11] = ex5_lzasub_gg02[11];
   assign ex5_lzasub_gg04[10] = ex5_lzasub_gg02[10];
   assign ex5_lzasub_gg04[9] = ex5_lzasub_gg02[9] | (ex5_lzasub_gt02[9] & ex5_lzasub_gg02[11]);		//final
   assign ex5_lzasub_gg04[8] = ex5_lzasub_gg02[8] | (ex5_lzasub_gt02[8] & ex5_lzasub_gg02[10]);		//final
   assign ex5_lzasub_gg04[7] = ex5_lzasub_gg02[7] | (ex5_lzasub_gt02[7] & ex5_lzasub_gg02[9]);
   assign ex5_lzasub_gg04[6] = ex5_lzasub_gg02[6] | (ex5_lzasub_gt02[6] & ex5_lzasub_gg02[8]);
   assign ex5_lzasub_gg04[5] = ex5_lzasub_gg02[5] | (ex5_lzasub_gt02[5] & ex5_lzasub_gg02[7]);
   assign ex5_lzasub_gg04[4] = ex5_lzasub_gg02[4] | (ex5_lzasub_gt02[4] & ex5_lzasub_gg02[6]);
   assign ex5_lzasub_gg04[3] = ex5_lzasub_gg02[3] | (ex5_lzasub_gt02[3] & ex5_lzasub_gg02[5]);
   assign ex5_lzasub_gg04[2] = ex5_lzasub_gg02[2] | (ex5_lzasub_gt02[2] & ex5_lzasub_gg02[4]);

   assign ex5_lzasub_gt04[11] = ex5_lzasub_gt02[11];
   assign ex5_lzasub_gt04[10] = ex5_lzasub_gt02[10];
   assign ex5_lzasub_gt04[9] = ex5_lzasub_gg02[9] | (ex5_lzasub_gt02[9] & ex5_lzasub_gt02[11]);		//final
   assign ex5_lzasub_gt04[8] = ex5_lzasub_gg02[8] | (ex5_lzasub_gt02[8] & ex5_lzasub_gt02[10]);		//final
   assign ex5_lzasub_gt04[7] = (ex5_lzasub_gt02[7] & ex5_lzasub_gt02[9]);
   assign ex5_lzasub_gt04[6] = (ex5_lzasub_gt02[6] & ex5_lzasub_gt02[8]);
   assign ex5_lzasub_gt04[5] = (ex5_lzasub_gt02[5] & ex5_lzasub_gt02[7]);
   assign ex5_lzasub_gt04[4] = (ex5_lzasub_gt02[4] & ex5_lzasub_gt02[6]);
   assign ex5_lzasub_gt04[3] = (ex5_lzasub_gt02[3] & ex5_lzasub_gt02[5]);
   assign ex5_lzasub_gt04[2] = (ex5_lzasub_gt02[2] & ex5_lzasub_gt02[4]);

   assign ex5_lzasub_gg08[11] = ex5_lzasub_gg04[11];
   assign ex5_lzasub_gg08[10] = ex5_lzasub_gg04[10];
   assign ex5_lzasub_gg08[9] = ex5_lzasub_gg04[9];
   assign ex5_lzasub_gg08[8] = ex5_lzasub_gg04[8];
   assign ex5_lzasub_gg08[7] = ex5_lzasub_gg04[7] | (ex5_lzasub_gt04[7] & ex5_lzasub_gg04[11]);		//final
   assign ex5_lzasub_gg08[6] = ex5_lzasub_gg04[6] | (ex5_lzasub_gt04[6] & ex5_lzasub_gg04[10]);		//final
   assign ex5_lzasub_gg08[5] = ex5_lzasub_gg04[5] | (ex5_lzasub_gt04[5] & ex5_lzasub_gg04[9]);		//final
   assign ex5_lzasub_gg08[4] = ex5_lzasub_gg04[4] | (ex5_lzasub_gt04[4] & ex5_lzasub_gg04[8]);		//final
   assign ex5_lzasub_gg08[3] = ex5_lzasub_gg04[3] | (ex5_lzasub_gt04[3] & ex5_lzasub_gg04[7]);
   assign ex5_lzasub_gg08[2] = ex5_lzasub_gg04[2] | (ex5_lzasub_gt04[2] & ex5_lzasub_gg04[6]);

   assign ex5_lzasub_gt08[11] = ex5_lzasub_gt04[11];
   assign ex5_lzasub_gt08[10] = ex5_lzasub_gt04[10];
   assign ex5_lzasub_gt08[9] = ex5_lzasub_gt04[9];
   assign ex5_lzasub_gt08[8] = ex5_lzasub_gt04[8];
   assign ex5_lzasub_gt08[7] = ex5_lzasub_gg04[7] | (ex5_lzasub_gt04[7] & ex5_lzasub_gt04[11]);		//final
   assign ex5_lzasub_gt08[6] = ex5_lzasub_gg04[6] | (ex5_lzasub_gt04[6] & ex5_lzasub_gt04[10]);		//final
   assign ex5_lzasub_gt08[5] = ex5_lzasub_gg04[5] | (ex5_lzasub_gt04[5] & ex5_lzasub_gt04[9]);		//final
   assign ex5_lzasub_gt08[4] = ex5_lzasub_gg04[4] | (ex5_lzasub_gt04[4] & ex5_lzasub_gt04[8]);		//final
   assign ex5_lzasub_gt08[3] = (ex5_lzasub_gt04[3] & ex5_lzasub_gt04[7]);
   assign ex5_lzasub_gt08[2] = (ex5_lzasub_gt04[2] & ex5_lzasub_gt04[6]);

   assign ex5_lzasub_c0[11] = ex5_lzasub_gg08[11];
   assign ex5_lzasub_c0[10] = ex5_lzasub_gg08[10];
   assign ex5_lzasub_c0[9] = ex5_lzasub_gg08[9];
   assign ex5_lzasub_c0[8] = ex5_lzasub_gg08[8];
   assign ex5_lzasub_c0[7] = ex5_lzasub_gg08[7];
   assign ex5_lzasub_c0[6] = ex5_lzasub_gg08[6];
   assign ex5_lzasub_c0[5] = ex5_lzasub_gg08[5];
   assign ex5_lzasub_c0[4] = ex5_lzasub_gg08[4];
   assign ex5_lzasub_c0[3] = ex5_lzasub_gg08[3] | (ex5_lzasub_gt08[3] & ex5_lzasub_gg08[11]);		//final
   assign ex5_lzasub_c0[2] = ex5_lzasub_gg08[2] | (ex5_lzasub_gt08[2] & ex5_lzasub_gg08[10]);		//final

   assign ex5_lzasub_c1[11] = ex5_lzasub_gt08[11];
   assign ex5_lzasub_c1[10] = ex5_lzasub_gt08[10];
   assign ex5_lzasub_c1[9] = ex5_lzasub_gt08[9];
   assign ex5_lzasub_c1[8] = ex5_lzasub_gt08[8];
   assign ex5_lzasub_c1[7] = ex5_lzasub_gt08[7];
   assign ex5_lzasub_c1[6] = ex5_lzasub_gt08[6];
   assign ex5_lzasub_c1[5] = ex5_lzasub_gt08[5];
   assign ex5_lzasub_c1[4] = ex5_lzasub_gt08[4];
   assign ex5_lzasub_c1[3] = ex5_lzasub_gg08[3] | (ex5_lzasub_gt08[3] & ex5_lzasub_gt08[11]);		//final
   assign ex5_lzasub_c1[2] = ex5_lzasub_gg08[2] | (ex5_lzasub_gt08[2] & ex5_lzasub_gt08[10]);		//final

   assign ex5_lzasub_s0[1:11] = ex5_lzasub_p[1:11] ^ ({ex5_lzasub_c0[2:11], tidn});
   assign ex5_lzasub_s1[1:11] = ex5_lzasub_p[1:11] ^ ({ex5_lzasub_c1[2:11], tiup});

   assign ex5_lzasub_m1[1:11] = (ex5_lzasub_s0[1:11] & {11{(~ex5_lzasub_m1_c12)}}) |
                                (ex5_lzasub_s1[1:11] & {11{ex5_lzasub_m1_c12}});

   assign ex5_lzasub_p0[1:11] = (ex5_lzasub_s0[1:11] & {11{(~ex5_lzasub_p0_c12)}}) |
                                (ex5_lzasub_s1[1:11] & {11{ex5_lzasub_p0_c12}});

   assign ex5_lzasub_p1[1:11] = (ex5_lzasub_s0[1:11] & {11{(~ex5_lzasub_p1_c12)}}) |
                                (ex5_lzasub_s1[1:11] & {11{ex5_lzasub_p1_c12}});

   ////#-------------------------------------------
   ////# determine overflow (expo bias = 1023, with signed bit)
   ////#-------------------------------------------
   //
   // dp  overflow: ge 2047      = 2047     ge 2047
   // sp  overflow: ge 255 + 896 = 1151     ge 1151
   //
   // using expo_m1 as the base:
   //              m1      p0      p1
   // dp ovf:  ge 2047  ge 2046  ge 2045
   // sp ovf:  ge 1151  ge 1150  ge 1149
   //
   // could just do the subtract, then decode the result. (triple compound add becomes critical).
   // doingg compare before the add (faster)
   //
   // 2047     0_0111_1111_1111
   // 1151     0_0100_0111_1111
   //
   //          0 0000 0000 1111
   //          1 2345 6789 0123
   //
   //-------------------------------
   //          0_01dd_d111_1111  (minimum)
   //          1_10ss_s000_0000 !(minimum)
   //          1_10ss_s000_0001 -(minimum)
   //          1_10ss_s000_0010  BOUNDRY   +1 for -lza = !lza+1
   //          1_11                        add the lza sign xtd
   //--------------------------------
   //-         1_01ss_s000_0100
   //--------------------------------
   // overflow if (iexp-lza)        >= 2047
   // overflow if (iexp-lza) - 2047 >=    0
   // POSITIVE result means    overflow.
   // NEGATIVE result means no overflow.

   assign ex5_ovf_sum[1] = ex5_sh_rgt_en_b ^ (~ex5_i_exp[1]);		// 1    !R  [1]
   assign ex5_ovf_sum[2] = ex5_sh_rgt_en_b ^ (~ex5_i_exp[2]);		// 1    !R  [2]
   assign ex5_ovf_sum[3] = ex5_sh_rgt_en_b ^ ex5_i_exp[3];		// 0    !R  [3]
   assign ex5_ovf_sum[4] = ex5_sh_rgt_en_b ^ ex5_i_exp[4] ^ ex5_sp;		// s    !R  [4]
   assign ex5_ovf_sum[5] = ex5_sh_rgt_en_b ^ ex5_i_exp[5] ^ ex5_sp;		// s    !R  [5]
   assign ex5_ovf_sum[6] = (~ex5_lza_amt[0]) ^ ex5_i_exp[6] ^ ex5_sp;		// s  ![0]  [6]
   assign ex5_ovf_sum[7] = (~ex5_lza_amt[1]) ^ ex5_i_exp[7];		// 0  ![1]  [7]
   assign ex5_ovf_sum[8] = (~ex5_lza_amt[2]) ^ ex5_i_exp[8];		// 0  ![2]  [8]
   assign ex5_ovf_sum[9] = (~ex5_lza_amt[3]) ^ ex5_i_exp[9];		// 0  ![3]  [9]
   assign ex5_ovf_sum[10] = (~ex5_lza_amt[4]) ^ ex5_i_exp[10];		// 0  ![4] [10]
   assign ex5_ovf_sum[11] = (~ex5_lza_amt[5]) ^ ex5_i_exp[11];		// 0  ![5] [11]
   assign ex5_ovf_sum[12] = (~ex5_lza_amt[6]) ^ (~ex5_i_exp[12]);		// 1  ![6] [12]
   assign ex5_ovf_sum[13] = (~ex5_lza_amt[7]) ^ ex5_i_exp[13];		// 0  ![7] [13]

   assign ex5_ovf_car[1] = ex5_sh_rgt_en_b | ex5_i_exp[2];		// 1    !R  [2]
   assign ex5_ovf_car[2] = ex5_sh_rgt_en_b & ex5_i_exp[3];		// 0    !R  [3]

   assign ex5_ovf_car[3] = (ex5_sp & ex5_i_exp[4]) | (ex5_sh_rgt_en_b & ex5_i_exp[4]) | (ex5_sh_rgt_en_b & ex5_sp);		// s    !R  [4]

   assign ex5_ovf_car[4] = (ex5_sp & ex5_i_exp[5]) | (ex5_sh_rgt_en_b & ex5_i_exp[5]) | (ex5_sh_rgt_en_b & ex5_sp);		// s    !R  [5]

   assign ex5_ovf_car[5] = ((~ex5_lza_amt[0]) & ex5_i_exp[6]) | ((~ex5_lza_amt[0]) & ex5_sp) | (ex5_sp & ex5_i_exp[6]);		// s  ![0]  [6]
   assign ex5_ovf_car[6] = (~ex5_lza_amt[1]) & ex5_i_exp[7];		// 0  ![1]  [7]
   assign ex5_ovf_car[7] = (~ex5_lza_amt[2]) & ex5_i_exp[8];		// 0  ![2]  [8]
   assign ex5_ovf_car[8] = (~ex5_lza_amt[3]) & ex5_i_exp[9];		// 0  ![3]  [9]
   assign ex5_ovf_car[9] = (~ex5_lza_amt[4]) & ex5_i_exp[10];		// 0  ![4] [10]
   assign ex5_ovf_car[10] = (~ex5_lza_amt[5]) & ex5_i_exp[11];		// 0  ![5] [11]
   assign ex5_ovf_car[11] = (~ex5_lza_amt[6]) | ex5_i_exp[12];		// 1  ![6] [12]
   assign ex5_ovf_car[12] = (~ex5_lza_amt[7]) & ex5_i_exp[13];		// 0  ![7] [13]

   assign ex5_ovf_g[2:12] = ex5_ovf_car[2:12] & ex5_ovf_sum[2:12];
   assign ex5_ovf_t[2:12] = ex5_ovf_car[2:12] | ex5_ovf_sum[2:12];
   assign ex5_ovf_p[1] = ex5_ovf_car[1] ^ ex5_ovf_sum[1];

   // lower bits (compute 3 possible combinations)

   assign ex5_ovf_m1_co12 = ex5_ovf_g[12];
   assign ex5_ovf_p0_co12 = ex5_ovf_g[12] | (ex5_ovf_t[12] & ex5_ovf_sum[13]);
   assign ex5_ovf_p1_co12 = ex5_ovf_t[12];

   // upper bits (compute 2 possible combinations)

   assign ex5_ovf_g2_02t03 = ex5_ovf_g[2] | (ex5_ovf_t[2] & ex5_ovf_g[3]);
   assign ex5_ovf_g2_04t05 = ex5_ovf_g[4] | (ex5_ovf_t[4] & ex5_ovf_g[5]);
   assign ex5_ovf_g2_06t07 = ex5_ovf_g[6] | (ex5_ovf_t[6] & ex5_ovf_g[7]);
   assign ex5_ovf_g2_08t09 = ex5_ovf_g[8] | (ex5_ovf_t[8] & ex5_ovf_g[9]);
   assign ex5_ovf_g2_ci0 = ex5_ovf_g[10] | (ex5_ovf_t[10] & ex5_ovf_g[11]);
   assign ex5_ovf_g2_ci1 = ex5_ovf_g[10] | (ex5_ovf_t[10] & ex5_ovf_t[11]);

   assign ex5_ovf_t2_02t03 = (ex5_ovf_t[2] & ex5_ovf_t[3]);
   assign ex5_ovf_t2_04t05 = (ex5_ovf_t[4] & ex5_ovf_t[5]);
   assign ex5_ovf_t2_06t07 = (ex5_ovf_t[6] & ex5_ovf_t[7]);
   assign ex5_ovf_t2_08t09 = (ex5_ovf_t[8] & ex5_ovf_t[9]);

   assign ex5_ovf_g4_02t05 = ex5_ovf_g2_02t03 | (ex5_ovf_t2_02t03 & ex5_ovf_g2_04t05);
   assign ex5_ovf_g4_06t09 = ex5_ovf_g2_06t07 | (ex5_ovf_t2_06t07 & ex5_ovf_g2_08t09);
   assign ex5_ovf_g4_ci0 = ex5_ovf_g2_ci0;
   assign ex5_ovf_g4_ci1 = ex5_ovf_g2_ci1;

   assign ex5_ovf_t4_02t05 = (ex5_ovf_t2_02t03 & ex5_ovf_t2_04t05);
   assign ex5_ovf_t4_06t09 = (ex5_ovf_t2_06t07 & ex5_ovf_t2_08t09);

   assign ex5_ovf_g8_02t09 = ex5_ovf_g4_02t05 | (ex5_ovf_t4_02t05 & ex5_ovf_g4_06t09);
   assign ex5_ovf_g8_ci0 = ex5_ovf_g4_ci0;
   assign ex5_ovf_g8_ci1 = ex5_ovf_g4_ci1;

   assign ex5_ovf_t8_02t09 = (ex5_ovf_t4_02t05 & ex5_ovf_t4_06t09);

   assign ex5_ovf_ci0_02t11 = ex5_ovf_g8_02t09 | (ex5_ovf_t8_02t09 & ex5_ovf_g8_ci0);
   assign ex5_ovf_ci1_02t11 = ex5_ovf_g8_02t09 | (ex5_ovf_t8_02t09 & ex5_ovf_g8_ci1);

   //  13 BITS HOLDS EVERYTHING  -- positive result means overflow
   assign ex5_c2_m1 = (ex5_ovf_ci0_02t11 | (ex5_ovf_ci1_02t11 & ex5_ovf_m1_co12));
   assign ex5_c2_p0 = (ex5_ovf_ci0_02t11 | (ex5_ovf_ci1_02t11 & ex5_ovf_p0_co12));
   assign ex5_c2_p1 = (ex5_ovf_ci0_02t11 | (ex5_ovf_ci1_02t11 & ex5_ovf_p1_co12));

   assign ex5_ovf_m1 = (~ex5_ovf_p[1]) ^ ex5_c2_m1;
   assign ex5_ovf_p0 = (~ex5_ovf_p[1]) ^ ex5_c2_p0;
   assign ex5_ovf_p1 = (~ex5_ovf_p[1]) ^ ex5_c2_p1;

   ////#-------------------------------------------
   ////# determine underflow (expo bias = 1023, with signed bit)
   ////#-------------------------------------------
   // dp underflow: le 0          =  le   0  =>  !ge    1
   // sp underflow: le 0    + 896 =  le 896  =>  !ge  897
   //
   // if the exponent will be incremented (then there are less overflows).
   // just need for m1, p0 because underflow is determined before rounding.
   // if there is an underflow exception it cannot round up the exponent.
   //              m1          p0
   // dp unf: !ge   1     !ge   0
   // sp unf: !ge 897     !ge 896
   //
   //    1     0_0000_0000_0001         dp: 0_0000_0000_0001   sp: 0_0011_1000_0001   emin
   //    0     0_0000_0000_0000             1_1111_1111_1110       1_1100_0111_1110  !emin
   //                                       1_1111_1111_1111       1_1100_0111_1111  -emin
   //          0 0000 0000 1111             0_0000_0000_0000       1_1100_1000_0000  <= +1 -lza=!lza+1
   //          1 2345 6789 0123
   //
   //  897     0_0011_1000_0001
   //  896     0_0011_1000_0000
   //-------------------------------
   // if (exp-lza)        >= emin  NO_UNDERFLOW
   // if (exp-lza) - emin >= 0    UNDERFLOW {sign bit = "1"}

   assign ex5_unf_sum[1] = ex5_sh_rgt_en_b ^ ex5_i_exp[1] ^ ex5_sp;		// s  !R    [1]
   assign ex5_unf_sum[2] = ex5_sh_rgt_en_b ^ ex5_i_exp[2] ^ ex5_sp;		// s  !R    [2]
   assign ex5_unf_sum[3] = ex5_sh_rgt_en_b ^ ex5_i_exp[3] ^ ex5_sp;		// s  !R    [3]
   assign ex5_unf_sum[4] = ex5_sh_rgt_en_b ^ ex5_i_exp[4];		// 0  !R    [4]
   assign ex5_unf_sum[5] = ex5_sh_rgt_en_b ^ ex5_i_exp[5];		// 0  !R    [5]
   assign ex5_unf_sum[6] = (~ex5_lza_amt[0]) ^ ex5_i_exp[6] ^ ex5_sp;		// s  ![0]  [6]
   assign ex5_unf_sum[7] = (~ex5_lza_amt[1]) ^ ex5_i_exp[7];		// 0  ![1]  [7]
   assign ex5_unf_sum[8] = (~ex5_lza_amt[2]) ^ ex5_i_exp[8];		// 0  ![2]  [8]
   assign ex5_unf_sum[9] = (~ex5_lza_amt[3]) ^ ex5_i_exp[9];		// 0  ![3]  [9]
   assign ex5_unf_sum[10] = (~ex5_lza_amt[4]) ^ ex5_i_exp[10];		// 0  ![4] [10]
   assign ex5_unf_sum[11] = (~ex5_lza_amt[5]) ^ ex5_i_exp[11];		// 0  ![5] [11]
   assign ex5_unf_sum[12] = (~ex5_lza_amt[6]) ^ ex5_i_exp[12];		// 0  ![6] [12]
   assign ex5_unf_sum[13] = (~ex5_lza_amt[7]) ^ ex5_i_exp[13];		// 0  ![7] [13]

   assign ex5_unf_car[1] = (ex5_sp & ex5_i_exp[2]) | (ex5_sh_rgt_en_b & ex5_i_exp[2]) | (ex5_sh_rgt_en_b & ex5_sp);		// s  !R   [2]
   assign ex5_unf_car[2] = (ex5_sp & ex5_i_exp[3]) | (ex5_sh_rgt_en_b & ex5_i_exp[3]) | (ex5_sh_rgt_en_b & ex5_sp);		// s  !R   [3]
   assign ex5_unf_car[3] = ex5_sh_rgt_en_b & ex5_i_exp[4];		// 0  !R   [4]
   assign ex5_unf_car[4] = ex5_sh_rgt_en_b & ex5_i_exp[5];		// 0  !R   [5]
   assign ex5_unf_car[5] = ((~ex5_lza_amt[0]) & ex5_i_exp[6]) | ((~ex5_lza_amt[0]) & ex5_sp) | (ex5_sp & ex5_i_exp[6]);		// s ![0]  [6]
   assign ex5_unf_car[6] = (~ex5_lza_amt[1]) & ex5_i_exp[7];		// 0  ![1]  [7]
   assign ex5_unf_car[7] = (~ex5_lza_amt[2]) & ex5_i_exp[8];		// 0  ![2]  [8]
   assign ex5_unf_car[8] = (~ex5_lza_amt[3]) & ex5_i_exp[9];		// 0  ![3]  [9]
   assign ex5_unf_car[9] = (~ex5_lza_amt[4]) & ex5_i_exp[10];		// 0  ![4] [10]
   assign ex5_unf_car[10] = (~ex5_lza_amt[5]) & ex5_i_exp[11];		// 0  ![5] [11]
   assign ex5_unf_car[11] = (~ex5_lza_amt[6]) & ex5_i_exp[12];		// 0  ![6] [12]
   assign ex5_unf_car[12] = (~ex5_lza_amt[7]) & ex5_i_exp[13];		// 0  ![7] [13]

   assign ex5_unf_g[2:12] = ex5_unf_car[2:12] & ex5_unf_sum[2:12];
   assign ex5_unf_t[2:12] = ex5_unf_car[2:12] | ex5_unf_sum[2:12];
   assign ex5_unf_p[1] = ex5_unf_car[1] ^ ex5_unf_sum[1];

   assign ex5_unf_m1_co12 = ex5_unf_g[12];
   assign ex5_unf_p0_co12 = ex5_unf_g[12] | (ex5_unf_t[12] & ex5_unf_sum[13]);

   assign ex5_unf_g2_02t03 = ex5_unf_g[2] | (ex5_unf_t[2] & ex5_unf_g[3]);
   assign ex5_unf_g2_04t05 = ex5_unf_g[4] | (ex5_unf_t[4] & ex5_unf_g[5]);
   assign ex5_unf_g2_06t07 = ex5_unf_g[6] | (ex5_unf_t[6] & ex5_unf_g[7]);
   assign ex5_unf_g2_08t09 = ex5_unf_g[8] | (ex5_unf_t[8] & ex5_unf_g[9]);
   assign ex5_unf_g2_10t11 = ex5_unf_g[10] | (ex5_unf_t[10] & ex5_unf_g[11]);
   assign ex5_unf_ci0_g2 = ex5_unf_g[12];
   assign ex5_unf_ci1_g2 = ex5_unf_t[12];

   assign ex5_unf_t2_02t03 = (ex5_unf_t[2] & ex5_unf_t[3]);
   assign ex5_unf_t2_04t05 = (ex5_unf_t[4] & ex5_unf_t[5]);
   assign ex5_unf_t2_06t07 = (ex5_unf_t[6] & ex5_unf_t[7]);
   assign ex5_unf_t2_08t09 = (ex5_unf_t[8] & ex5_unf_t[9]);
   assign ex5_unf_t2_10t11 = (ex5_unf_t[10] & ex5_unf_t[11]);
   assign ex5_unf_g4_02t05 = ex5_unf_g2_02t03 | (ex5_unf_t2_02t03 & ex5_unf_g2_04t05);
   assign ex5_unf_g4_06t09 = ex5_unf_g2_06t07 | (ex5_unf_t2_06t07 & ex5_unf_g2_08t09);
   assign ex5_unf_ci0_g4 = ex5_unf_g2_10t11 | (ex5_unf_t2_10t11 & ex5_unf_ci0_g2);
   assign ex5_unf_ci1_g4 = ex5_unf_g2_10t11 | (ex5_unf_t2_10t11 & ex5_unf_ci1_g2);

   assign ex5_unf_t4_02t05 = (ex5_unf_t2_02t03 & ex5_unf_t2_04t05);
   assign ex5_unf_t4_06t09 = (ex5_unf_t2_06t07 & ex5_unf_t2_08t09);

   assign ex5_unf_g8_02t09 = ex5_unf_g4_02t05 | (ex5_unf_t4_02t05 & ex5_unf_g4_06t09);
   assign ex5_unf_ci0_g8 = ex5_unf_ci0_g4;
   assign ex5_unf_ci1_g8 = ex5_unf_ci1_g4;

   assign ex5_unf_t8_02t09 = (ex5_unf_t4_02t05 & ex5_unf_t4_06t09);

   assign ex5_unf_ci0_02t11 = ex5_unf_g8_02t09 | (ex5_unf_t8_02t09 & ex5_unf_ci0_g8);
   assign ex5_unf_ci1_02t11 = ex5_unf_g8_02t09 | (ex5_unf_t8_02t09 & ex5_unf_ci1_g8);

   assign ex5_unf_c2_m1 = (ex5_unf_ci0_02t11 | (ex5_unf_ci1_02t11 & ex5_unf_m1_co12));
   assign ex5_unf_c2_p0 = (ex5_unf_ci0_02t11 | (ex5_unf_ci1_02t11 & ex5_unf_p0_co12));

   // 13 BITS HOLDS EVERYTHING (sign==1 {neg} means underflow)
   assign ex5_unf_m1 = ex5_unf_p[1] ^ ex5_unf_c2_m1;
   assign ex5_unf_p0 = ex5_unf_p[1] ^ ex5_unf_c2_p0;

   ////#-----------------------------------
   ////# adjust for the lza extra shift (late signal)
   ////#-----------------------------------

   //    ex5_expo_p0(1 to 13) <=
   //            (ex5_lzasub_m1(1 to 13) and (1 to 13 =>     f_nrm_ex5_extra_shift) ) or --sim-only
   //            (ex5_lzasub_p0(1 to 13) and (1 to 13 => not f_nrm_ex5_extra_shift) ) ; --sim-only
   //   ex5_expo_p1(1 to 13) <=  --sim-only
   //            (ex5_lzasub_p0(1 to 13) and (1 to 13 =>     f_nrm_ex5_extra_shift) ) or  --sim-only
   //            (ex5_lzasub_p1(1 to 13) and (1 to 13 => not f_nrm_ex5_extra_shift) ) ; --sim-only
   //    ex5_ovf_calc         <= --sim-only
   //            (ex5_ovf_m1             and                 f_nrm_ex5_extra_shift  ) or  --sim-only
   //            (ex5_ovf_p0             and             not f_nrm_ex5_extra_shift  ) ; --sim-only
   //    ex5_ovf_if_calc      <=  --sim-only
   //            (ex5_ovf_p0             and                 f_nrm_ex5_extra_shift  ) or  --sim-only
   //            (ex5_ovf_p1             and             not f_nrm_ex5_extra_shift  ) ; --sim-only
   //    ex5_unf_calc         <= -- for recip sp : do not zero out exponent ... let it go neg_sp (norm in dp range) --sim-only
   //            (ex5_unf_m1             and                 f_nrm_ex5_extra_shift  ) or  --sim-only
   //            (ex5_unf_p0             and             not f_nrm_ex5_extra_shift  ); --sim-only
   //

   assign ex5_expo_p0_0_b[1:13] = (~(ex5_lzasub_m1[1:13] & {13{f_nrm_ex5_extra_shift}}));
   assign ex5_expo_p0_1_b[1:13] = (~(ex5_lzasub_p0[1:13] & {13{(~f_nrm_ex5_extra_shift)}}));
   assign ex5_expo_p0[1:13] = (~(ex5_expo_p0_0_b[1:13] & ex5_expo_p0_1_b[1:13]));

   assign ex5_expo_p1_0_b[1:13] = (~(ex5_lzasub_p0[1:13] & {13{f_nrm_ex5_extra_shift}}));
   assign ex5_expo_p1_1_b[1:13] = (~(ex5_lzasub_p1[1:13] & {13{(~f_nrm_ex5_extra_shift)}}));
   assign ex5_expo_p1[1:13] = (~(ex5_expo_p1_0_b[1:13] & ex5_expo_p1_1_b[1:13]));

   assign ex5_ovf_calc_0_b = (~(ex5_ovf_m1 & f_nrm_ex5_extra_shift));
   assign ex5_ovf_calc_1_b = (~(ex5_ovf_p0 & (~f_nrm_ex5_extra_shift)));
   assign ex5_ovf_calc = (~(ex5_ovf_calc_0_b & ex5_ovf_calc_1_b));

   assign ex5_ovf_if_calc_0_b = (~(ex5_ovf_p0 & f_nrm_ex5_extra_shift));
   assign ex5_ovf_if_calc_1_b = (~(ex5_ovf_p1 & (~f_nrm_ex5_extra_shift)));
   assign ex5_ovf_if_calc = (~(ex5_ovf_if_calc_0_b & ex5_ovf_if_calc_1_b));

   // for recip sp : do not zero out exponent ... let it go neg_sp (norm in dp range)
   assign ex5_unf_calc_0_b = (~(ex5_unf_m1 & f_nrm_ex5_extra_shift));
   assign ex5_unf_calc_1_b = (~(ex5_unf_p0 & (~f_nrm_ex5_extra_shift)));
   assign ex5_unf_calc = (~(ex5_unf_calc_0_b & ex5_unf_calc_1_b));

   assign ex5_est_sp = ex5_sel_est & ex5_sp;

   assign ex5_unf_tbl = f_pic_ex5_uf_en & f_tbl_ex5_unf_expo;
   assign ex5_unf_tbl_spec_e = (ex5_unf_tbl & (~ex5_est_sp) & (~f_pic_ex5_ue)) | ex5_sel_k_part_e;
   assign ex5_ov_en = f_pic_ex5_ov_en;
   assign ex5_ov_en_oe0 = f_pic_ex5_ov_en & (~f_pic_ex5_oe);
   assign ex5_sel_ov_spec = f_pic_ex5_sel_ov_spec;
   assign ex5_unf_en_nedge = f_pic_ex5_uf_en & (~f_lza_ex5_no_lza_edge);
   assign ex5_unf_ue0_nestsp = f_pic_ex5_uf_en & (~f_lza_ex5_no_lza_edge) & (~f_pic_ex5_ue) & (~(ex5_est_sp));
   assign ex5_sel_k_part_e = f_pic_ex5_spec_sel_k_e | f_pic_ex5_to_int_ov_all;
   assign ex5_sel_k_part_f = f_pic_ex5_spec_sel_k_f | f_pic_ex5_to_int_ov_all;

   ////##############################################
   ////# EX6 latches <outputs>
   ////##############################################

   tri_nand2_nlats #(.WIDTH(13), .NEEDS_SRESET(0)) ex6_urnd0_lat(
      .vd(vdd),
      .gd(gnd),
      .lclk(ex6_lclk),		// lclk.clk
      .d1clk(ex6_d1clk),
      .d2clk(ex6_d2clk),
      .scanin(ex6_urnd0_si),
      .scanout(ex6_urnd0_so),
      .a1(ex5_expo_p0_0_b[1:13]),
      .a2(ex5_expo_p0_1_b[1:13]),
      .qb(ex6_expo_p0[1:13])		//LAT--
   );

   tri_nand2_nlats #(.WIDTH(13),  .NEEDS_SRESET(0)) ex6_urnd1_lat(
      .vd(vdd),
      .gd(gnd),
      .lclk(ex6_lclk),		//lclk.clk
      .d1clk(ex6_d1clk),
      .d2clk(ex6_d2clk),
      .scanin(ex6_urnd1_si),
      .scanout(ex6_urnd1_so),
      .a1(ex5_expo_p1_0_b[1:13]),
      .a2(ex5_expo_p1_1_b[1:13]),
      .qb(ex6_expo_p1[1:13])		//LAT--
   );

   tri_nand2_nlats #(.WIDTH(3),   .NEEDS_SRESET(0)) ex6_ovctl_lat(
      .vd(vdd),
      .gd(gnd),
      .lclk(ex6_lclk),		//lclk.clk
      .d1clk(ex6_d1clk),
      .d2clk(ex6_d2clk),
      .scanin(ex6_ovctl_si),
      .scanout(ex6_ovctl_so),
      //-----------------
      .a1({ex5_ovf_calc_0_b,
           ex5_ovf_if_calc_0_b,
           ex5_unf_calc_0_b}),
      //-----------------
      .a2({ex5_ovf_calc_1_b,
           ex5_ovf_if_calc_1_b,
           ex5_unf_calc_1_b}),
      //-----------------
      .qb({ex6_ovf_calc,		//LAT--
           ex6_ovf_if_calc,		//LAT--
           ex6_unf_calc})		//LAT--
   );


   tri_rlmreg_p #(.WIDTH(13),  .NEEDS_SRESET(0)) ex6_misc_lat(
      .force_t(force_t),		// tidn,
      .d_mode(tiup),
      .delay_lclkr(delay_lclkr[5]),		// tidn,
      .mpw1_b(mpw1_b[5]),		// tidn,
      .mpw2_b(mpw2_b[1]),		// tidn,
      .vd(vdd),
      .gd(gnd),
      .nclk(nclk),
      .thold_b(thold_0_b),
      .sg(sg_0),
      .act(ex5_act),
      .scout(ex6_misc_so),
      .scin(ex6_misc_si),
      //-----------------
      .din({ ex5_unf_tbl,
             ex5_unf_tbl_spec_e,
             ex5_ov_en,
             ex5_ov_en_oe0,
             ex5_sel_ov_spec,
             ex5_unf_en_nedge,
             ex5_unf_ue0_nestsp,
             ex5_sel_k_part_f,
             ex5_ue1oe1_k[3:7]}),
      //-----------------
      .dout({ ex6_unf_tbl,		//LAT--
              ex6_unf_tbl_spec_e,		//LAT--
              ex6_ov_en,		//LAT--
              ex6_ov_en_oe0,		//LAT--
              ex6_sel_ov_spec,		//LAT--
              ex6_unf_en_nedge,		//LAT--
              ex6_unf_ue0_nestsp,		//LAT--
              ex6_sel_k_part_f,		//LAT--
              ex6_ue1oe1_k[3:7]})		//LAT--
   );

   ////##############################################
   ////# EX6 logic
   ////##############################################

   assign f_eov_ex6_expo_p0[1:13] = ex6_expo_p0[1:13];		////#rnd result exponent
   assign f_eov_ex6_expo_p1[1:13] = ex6_expo_p1[1:13];		////#rnd result exponent if rnd_up_all1

   ////#-----------------------------------------
   ////# moved from ex5 to ex6 for timing
   ////#-----------------------------------------

   //------- LEVEL 1 -----------------------------------

   assign ex6_sel_ov_spec_b = (~(ex6_sel_ov_spec));
   assign ex6_ovf_b = (~(ex6_ovf_calc & ex6_ov_en));
   assign ex6_ovf_if_b = (~(ex6_ovf_if_calc & ex6_ov_en));
   assign ex6_ovf_oe0_b = (~(ex6_ovf_calc & ex6_ov_en_oe0));
   assign ex6_ovf_if_oe0_b = (~(ex6_ovf_if_calc & ex6_ov_en_oe0));
   assign ex6_unf_b = (~(ex6_unf_calc & ex6_unf_en_nedge));
   assign ex6_unf_ue0_b = (~(ex6_unf_calc & ex6_unf_ue0_nestsp));
   assign ex6_sel_k_part_f_b = (~(ex6_sel_k_part_f));
   assign ex6_unf_tbl_spec_e_b = (~(ex6_unf_tbl_spec_e));
   assign ex6_unf_tbl_b = (~(ex6_unf_tbl));

   //------- LEVEL 2 -----------------------------------

   assign f_eov_ex6_ovf_expo = (~(ex6_ovf_b & ex6_sel_ov_spec_b));
   assign f_eov_ex6_ovf_if_expo = (~(ex6_ovf_if_b & ex6_sel_ov_spec_b));
   assign f_eov_ex6_sel_k_f = (~(ex6_ovf_oe0_b & ex6_sel_k_part_f_b));
   assign f_eov_ex6_sel_kif_f = (~(ex6_ovf_if_oe0_b & ex6_sel_k_part_f_b));
   assign f_eov_ex6_unf_expo = (~(ex6_unf_b & ex6_unf_tbl_b));
   assign f_eov_ex6_sel_k_e = (~(ex6_unf_ue0_b & ex6_unf_tbl_spec_e_b & ex6_ovf_oe0_b));
   assign f_eov_ex6_sel_kif_e = (~(ex6_unf_ue0_b & ex6_unf_tbl_spec_e_b & ex6_ovf_if_oe0_b));

   ////#-----------------------------
   ////# ue1 oe1 adders (does not need to be real fast)
   ////#-----------------------------

   assign f_eov_ex6_expo_p0_ue1oe1[3:6] = ex6_ue1oe1_p0_p[3:6] ^ ex6_ue1oe1_p0_c[4:7];		//output-
   assign f_eov_ex6_expo_p0_ue1oe1[7] = ex6_ue1oe1_p0_p[7];

   assign ex6_ue1oe1_p0_p[3:7] = ex6_expo_p0[3:7] ^ ex6_ue1oe1_k[3:7];
   assign ex6_ue1oe1_p0_g[4:7] = ex6_expo_p0[4:7] & ex6_ue1oe1_k[4:7];
   assign ex6_ue1oe1_p0_t[4:6] = ex6_expo_p0[4:6] | ex6_ue1oe1_k[4:6];

   assign ex6_ue1oe1_p0_g2_b[7] = (~(ex6_ue1oe1_p0_g[7]));
   assign ex6_ue1oe1_p0_g2_b[6] = (~(ex6_ue1oe1_p0_g[6] | (ex6_ue1oe1_p0_t[6] & ex6_ue1oe1_p0_g[7])));
   assign ex6_ue1oe1_p0_g2_b[5] = (~(ex6_ue1oe1_p0_g[5]));
   assign ex6_ue1oe1_p0_g2_b[4] = (~(ex6_ue1oe1_p0_g[4] | (ex6_ue1oe1_p0_t[4] & ex6_ue1oe1_p0_g[5])));

   assign ex6_ue1oe1_p0_t2_b[5] = (~(ex6_ue1oe1_p0_t[5]));
   assign ex6_ue1oe1_p0_t2_b[4] = (~((ex6_ue1oe1_p0_t[4] & ex6_ue1oe1_p0_t[5])));

   assign ex6_ue1oe1_p0_c[7] = (~(ex6_ue1oe1_p0_g2_b[7]));
   assign ex6_ue1oe1_p0_c[6] = (~(ex6_ue1oe1_p0_g2_b[6]));
   assign ex6_ue1oe1_p0_c[5] = (~(ex6_ue1oe1_p0_g2_b[5] & (ex6_ue1oe1_p0_t2_b[5] | ex6_ue1oe1_p0_g2_b[6])));
   assign ex6_ue1oe1_p0_c[4] = (~(ex6_ue1oe1_p0_g2_b[4] & (ex6_ue1oe1_p0_t2_b[4] | ex6_ue1oe1_p0_g2_b[6])));

   //-------------------

   assign f_eov_ex6_expo_p1_ue1oe1[3:6] = ex6_ue1oe1_p1_p[3:6] ^ ex6_ue1oe1_p1_c[4:7];		//output-
   assign f_eov_ex6_expo_p1_ue1oe1[7] = ex6_ue1oe1_p1_p[7];

   assign ex6_ue1oe1_p1_p[3:7] = ex6_expo_p1[3:7] ^ ex6_ue1oe1_k[3:7];
   assign ex6_ue1oe1_p1_g[4:7] = ex6_expo_p1[4:7] & ex6_ue1oe1_k[4:7];
   assign ex6_ue1oe1_p1_t[4:6] = ex6_expo_p1[4:6] | ex6_ue1oe1_k[4:6];

   assign ex6_ue1oe1_p1_g2_b[7] = (~(ex6_ue1oe1_p1_g[7]));
   assign ex6_ue1oe1_p1_g2_b[6] = (~(ex6_ue1oe1_p1_g[6] | (ex6_ue1oe1_p1_t[6] & ex6_ue1oe1_p1_g[7])));
   assign ex6_ue1oe1_p1_g2_b[5] = (~(ex6_ue1oe1_p1_g[5]));
   assign ex6_ue1oe1_p1_g2_b[4] = (~(ex6_ue1oe1_p1_g[4] | (ex6_ue1oe1_p1_t[4] & ex6_ue1oe1_p1_g[5])));

   assign ex6_ue1oe1_p1_t2_b[5] = (~(ex6_ue1oe1_p1_t[5]));
   assign ex6_ue1oe1_p1_t2_b[4] = (~((ex6_ue1oe1_p1_t[4] & ex6_ue1oe1_p1_t[5])));

   assign ex6_ue1oe1_p1_c[7] = (~(ex6_ue1oe1_p1_g2_b[7]));
   assign ex6_ue1oe1_p1_c[6] = (~(ex6_ue1oe1_p1_g2_b[6]));
   assign ex6_ue1oe1_p1_c[5] = (~(ex6_ue1oe1_p1_g2_b[5] & (ex6_ue1oe1_p1_t2_b[5] | ex6_ue1oe1_p1_g2_b[6])));
   assign ex6_ue1oe1_p1_c[4] = (~(ex6_ue1oe1_p1_g2_b[4] & (ex6_ue1oe1_p1_t2_b[4] | ex6_ue1oe1_p1_g2_b[6])));

   ////############################################
   ////# scan
   ////############################################

   assign act_si[0:4] = {act_so[1:4], f_eov_si};
   assign ex5_iexp_si[0:15] = {ex5_iexp_so[1:15], act_so[0]};
   assign ex6_ovctl_si[0:2] = {ex6_ovctl_so[1:2], ex5_iexp_so[0]};
   assign ex6_misc_si[0:12] = {ex6_misc_so[1:12], ex6_ovctl_so[0]};
   assign ex6_urnd0_si[0:12] = {ex6_urnd0_so[1:12], ex6_misc_so[0]};
   assign ex6_urnd1_si[0:12] = {ex6_urnd1_so[1:12], ex6_urnd0_so[0]};
   assign f_eov_so = ex6_urnd1_so[0];

endmodule