Verilog/DECODE-GateArray/DGA/circuit/DECODE_DGA_COMM.v

/**************************************************************************
** ND120 DGA (Decode Gate Array)                                         **
** DGA (Decode Gate Array)                                               **
**                                                                       **
** Decode Internal Databus Commands                                      **
**                                                                       **
** Page 16 DECODE - DECODE_DGA_COMM - Sheet 1 of 4                       **
** Page 17 DECODE - DECODE_DGA_COMM - Sheet 2 of 4                       **
** Page 18 DECODE - DECODE_DGA_COMM - Sheet 3 of 4                       **
** Page 19 DECODE - DECODE_DGA_COMM - Sheet 4 of 4                       **
**                                                                       **
** Last reviewed: 2-FEB-2025                                             **
** Ronny Hansen                                                          **
***************************************************************************/

module DECODE_DGA_COMM (
    input       BRKN,         //! Break signal
    input       CLEAR,        //! Clear signal
    input       CLK1,         //! Clock input 1
    input       CLK2,         //! Clock input 2
    input       CLK3,         //! Clock input 3
    input [4:0] CSCOMM_4_0,   //! Microcode Command 4:0
    input [1:0] CSMIS_1_0,    //! Microcode Misc signal 1:0
    input       DAPN,         //! Data Address
    input       EORFN,        //! Enable Output Register
    input       HITN,         //! Cache Hit
    input       IDBI2,        //! Internal data bus input bit 2
    input       IDBI5,        //! Internal data bus input bit 5
    input       IDBI7,        //! Internal data bus input bit 7
    input       LCSN,         //! Load Control Store
    input       LSHADOW,      //! Load shadow
    input       PONI,         //! Memory Protection ON, PONI=1
    input       UCLK,         //! U clock

    output CA10,         //! Control Store address bit 10
    output CCLRN,        //! Cache Clear
    output CEUARTN,      //! Enable UART
    output CLRTIN,       //! Clear Real Time Clock
    output DTN,          //! Data Transfer
    output DVACCN,       //! Data Valid
    output ECREQ,        //! Enable CPU Request
    output EMCLN,        //! Enable Master Clear
    output EMPIDN,       //! Enable MPID - Set bits in the micro—PID (Priority Interrupt Detect) register in the PIC. Command #012. "set mask reg: inh all ints"
    output ESTOFN,       //! Enable Store Overflow
    output FETCH,        //! Fetch cycle active
    output FMISS,        //! Cache miss during fetch
    output FORMN,        //! Form number
    output IORQN,        //! I/O Request
    output LDPANCN,      //! Load Panel Control
    output LHIT,         //! Load Hit
    output MREQ,         //! Memory Request
    output RESET,        //! Reset signal
    output RTN,          //! Return
    output RWCSN,        //! Read Write Control Store
    output SHORTN,       //! Short cycle active
    output SIOCN,        //! Serial I/O Control
    output SLOWN,        //! Slow cycle active
    output SSEMAN,       //! Serial Semaphore
    output SSTOPN,       //! Set Stop Flip-Flop
    output STARTN,       //! Start signal
    output STOCN,        //! Stop signal
    output WCHIMN,       //! Write Cache Miss
    output WRITE         //! Write Cycle Active
);

  /*******************************************************************************
   ** The wires are defined here                                                 **
   *******************************************************************************/
  wire [1:0] s_csmis_1_0;
  wire [4:0] s_cscomm_4_0;

  wire       a_a237_nand_out;
  wire       s_208_y;
  wire       s_rt;
  wire       s_a141_nand_out;
  wire       s_a142_nand_out;
  wire       s_a143_nand_out;
  wire       s_a144_nand_out;
  wire       s_a145_nand_out;
  wire       s_a147_nand_out;
  wire       s_a148_nand_out;
  wire       s_irt;
  wire       s_a150_nand_out;
  wire       s_a152_nand_out;
  wire       s_a153_nand_out;
  wire       s_a155_nand_out;
  wire       s_a156_nand_out;
  wire       s_dt;
  wire       s_a162_nand_out;
  wire       s_a166_nand_out;
  wire       s_a167_nand_out;
  wire       s_a171_nand_out;
  wire       s_a172_nand_out;
  wire       s_a177_nand_out;
  wire       s_a185_nand_out;
  wire       s_a189_nand_out;
  wire       s_isstop_n;
  wire       s_a192_nand_out;
  wire       s_a193_nand_out;
  wire       s_a196_nand_out;
  wire       s_a199_nand_out;
  wire       s_a201_y;
  wire       s_a204_q;
  wire       s_a206_nand_out;
  wire       s_a211_nand_out;
  wire       s_a212_nand_out;
  wire       s_a213_nand_out;
  wire       s_a214_q0;
  wire       s_a215_nand_out;
  wire       s_a216_nand_out;
  wire       s_a216_nand_out5;
  wire       s_a217_nand_out;
  wire       s_a218_nand_out;
  wire       s_a219_nand_out;
  wire       s_a220_nand_out;
  wire       s_a221_y;
  wire       s_a222_nand_out;
  wire       s_a223_nand_out;
  wire       s_a224_nand_out;
  wire       s_a226_q_n;
  wire       s_a226_q;
  wire       s_a228_nand_out;
  wire       s_a229_nand_out;
  wire       s_a233_nand_out;
  wire       s_a235_nand_out;
  wire       s_a236_y;
  wire       s_a238_nand_out;
  wire       s_a242_and_out;
  wire       s_a243_nand_out;
  wire       s_a245_nand_out;
  wire       s_brk_n;
  wire       s_ca10;
  wire       s_cclr_n;
  wire       s_ceuart_n;
  wire       s_clear;
  wire       s_clk1;
  wire       s_clk2;
  wire       s_clk3_n;
  wire       s_clk3;
  wire       s_clrti_n;
  wire       s_cscomm_0_n;
  wire       s_cscomm_1_n;
  wire       s_cscomm_2_n;
  wire       s_cscomm_3_n;
  wire       s_cscomm_4_n;
  wire       s_csmis_0_n;
  wire       s_csmis_1_n;
  wire       s_dap_n;
  wire       s_dap;
  wire       s_dt_n;
  wire       s_dvacc_n;
  wire       s_ecrq;
  wire       s_emcl_n;
  wire       s_empid_n;
  wire       s_erof_n;
  wire       s_erof;
  wire       s_estof_n;
  wire       s_fetch;
  wire       s_fmiss;
  wire       s_form_n;
  wire       s_gnd;
  wire       s_hit_n;
  wire       s_iclrti_n;
  wire       s_idbi2;
  wire       s_idbi5;
  wire       s_idbi7;
  wire       s_iempid_latched;
  wire       s_iempid_n;
  wire       s_ildpanc_n;
  wire       s_iorq_n;
  wire       s_iorq;
  wire       s_isioc_n;
  wire       s_islow_n;
  wire       s_istart_n;
  wire       s_iwchim_n;
  wire       s_lcs_n;
  wire       s_ldpanc_latched;
  wire       s_ldpanc_n;
  wire       s_lhit_n;
  wire       s_lhit;
  wire       s_lshadow_n;
  wire       s_lshadow;
  wire       s_mreq;
  wire       s_poni_n;
  wire       s_poni;
  wire       s_reset;
  wire       s_rt_n;
  wire       s_rwcs_n;
  wire       s_short_n;
  wire       s_sioc_n;
  wire       s_slow_n;
  wire       s_ssema_n;
  wire       s_ssema;
  wire       s_sstop_n;
  wire       s_start_n;
  wire       s_stoc_n;
  wire       s_uclk;
  wire       s_vcc;
  wire       s_wchim_n;
  wire       s_write;
  wire       s_zz1;

  /*******************************************************************************
   ** Here all input connections are defined                                     **
   *******************************************************************************/
  assign s_csmis_1_0[1:0]  = CSMIS_1_0;
  assign s_cscomm_4_0[4:0] = CSCOMM_4_0;
  assign s_erof_n          = EORFN;
  assign s_dap_n           = DAPN;
  assign s_clk1            = CLK1;
  assign s_lcs_n           = LCSN;
  assign s_brk_n           = BRKN;
  assign s_clk3            = CLK3;
  assign s_clk2            = CLK2;
  assign s_lshadow         = LSHADOW;
  assign s_poni            = PONI;
  assign s_uclk            = UCLK;
  assign s_idbi7           = IDBI7;
  assign s_clear           = CLEAR;
  assign s_idbi2           = IDBI2;
  assign s_hit_n           = HITN;
  assign s_idbi5           = IDBI5;

  /*******************************************************************************
   ** Here all output connections are defined                                    **
   *******************************************************************************/
  assign CA10              = s_ca10;
  assign CCLRN             = s_cclr_n;
  assign CEUARTN           = s_ceuart_n;
  assign CLRTIN            = s_clrti_n;
  assign DTN               = s_dt_n;
  assign DVACCN            = s_dvacc_n;
  assign ECREQ             = s_ecrq;
  assign EMCLN             = s_emcl_n;
  assign EMPIDN            = s_empid_n;
  assign ESTOFN            = s_estof_n;
  assign FETCH             = s_fetch;
  assign FMISS             = s_fmiss;
  assign FORMN             = s_form_n;
  assign IORQN             = s_iorq_n;
  assign LDPANCN           = s_ldpanc_n;
  assign LHIT              = s_lhit;
  assign MREQ              = s_mreq;
  assign RESET             = s_reset;
  assign RTN               = s_rt_n;
  assign RWCSN             = s_rwcs_n;
  assign SHORTN            = s_short_n;
  assign SIOCN             = s_sioc_n;
  assign SLOWN             = s_slow_n;
  assign SSEMAN            = s_ssema_n;
  assign SSTOPN            = s_sstop_n;
  assign STARTN            = s_start_n;
  assign STOCN             = s_stoc_n;
  assign WCHIMN            = s_wchim_n;
  assign WRITE             = s_write;

  /*******************************************************************************
   ** Here all in-lined components are defined                                   **
   *******************************************************************************/

  // Power and Ground
  assign s_vcc             = 1'b1;
  assign s_gnd             = 1'b0;


  // NOT Gate: A241
  assign s_lshadow_n       = ~s_lshadow;

  // NOT Gate: A240
  assign s_dap             = ~s_dap_n;

  // NOT Gate
  assign s_erof            = ~s_erof_n;

  // Negated CSCOMM
  assign s_cscomm_0_n      = ~s_cscomm_4_0[0];
  assign s_cscomm_1_n      = ~s_cscomm_4_0[1];
  assign s_cscomm_2_n      = ~s_cscomm_4_0[2];
  assign s_cscomm_3_n      = ~s_cscomm_4_0[3];
  assign s_cscomm_4_n      = ~s_cscomm_4_0[4];

  // Negated CSMIS
  assign s_csmis_0_n       = ~s_csmis_1_0[0];
  assign s_csmis_1_n       = ~s_csmis_1_0[1];

  // NOT Gate: A230
  assign s_poni_n          = ~s_poni;

  // NOT Gate: A197
  assign s_clk3_n          = ~s_clk3;

  /*******************************************************************************
   ** Here all normal components are defined                                     **
   *******************************************************************************/
  NAND_GATE #(
      .BubblesMask(2'b00)
  ) A206 (
      .input1(s_a192_nand_out),
      .input2(s_a193_nand_out),
      .result(s_a206_nand_out)
  );

  NAND_GATE_8_INPUTS #(
      .BubblesMask(8'h00)
  ) A212 (
      .input1(s_zz1),
      .input2(s_csmis_1_0[1]),
      .input3(s_cscomm_4_0[4]),
      .input4(s_cscomm_4_0[3]),
      .input5(s_cscomm_4_0[2]),
      .input6(s_cscomm_4_0[1]),
      .input7(s_cscomm_4_0[0]),
      .input8(s_lcs_n),
      .result(s_a212_nand_out)
  );

  NAND_GATE_8_INPUTS #(
      .BubblesMask(8'h00)
  ) A193 (
      .input1(s_csmis_1_n),
      .input2(s_csmis_1_0[0]),
      .input3(s_cscomm_4_0[4]),
      .input4(s_cscomm_3_n),
      .input5(s_cscomm_2_n),
      .input6(s_cscomm_1_n),
      .input7(s_cscomm_4_0[0]),
      .input8(s_lcs_n),
      .result(s_a193_nand_out)
  );

  NAND_GATE_4_INPUTS #(
      .BubblesMask(4'h0)
  ) A156 (
      .input1(s_cscomm_4_0[4]),
      .input2(s_cscomm_3_n),
      .input3(s_cscomm_4_0[2]),
      .input4(s_lcs_n),
      .result(s_a156_nand_out)
  );

  NAND_GATE_6_INPUTS #(
      .BubblesMask({2'b00, 4'h0})
  ) A149 (
      .input1(s_a156_nand_out),
      .input2(s_a142_nand_out),
      .input3(s_a145_nand_out),
      .input4(s_a152_nand_out),
      .input5(s_a150_nand_out),
      .input6(s_a155_nand_out),
      .result(s_irt)
  );

  NAND_GATE_5_INPUTS #(
      .BubblesMask({1'b0, 4'h0})
  ) A150 (
      .input1(s_cscomm_4_0[4]),
      .input2(s_cscomm_3_n),
      .input3(s_cscomm_4_0[1]),
      .input4(s_cscomm_4_0[0]),
      .input5(s_lcs_n),
      .result(s_a150_nand_out)
  );

  NAND_GATE_8_INPUTS #(
      .BubblesMask(8'h00)
  ) A211 (
      .input1(s_csmis_1_n),
      .input2(s_csmis_1_0[0]),
      .input3(s_cscomm_4_0[4]),
      .input4(s_cscomm_4_0[3]),
      .input5(s_cscomm_4_0[2]),
      .input6(s_cscomm_4_0[1]),
      .input7(s_cscomm_0_n),
      .input8(s_lcs_n),
      .result(s_a211_nand_out)
  );

  NAND_GATE_6_INPUTS #(
      .BubblesMask({2'b00, 4'h0})
  ) A199 (
      .input1(s_cscomm_4_n),
      .input2(s_cscomm_3_n),
      .input3(s_cscomm_4_0[2]),
      .input4(s_cscomm_1_n),
      .input5(s_cscomm_4_0[0]),
      .input6(s_lcs_n),
      .result(s_a199_nand_out)
  );

  NAND_GATE_5_INPUTS #(
      .BubblesMask({1'b0, 4'h0})
  ) A155 (
      .input1(s_cscomm_4_0[4]),
      .input2(s_cscomm_4_0[3]),
      .input3(s_cscomm_2_n),
      .input4(s_cscomm_1_n),
      .input5(s_lcs_n),
      .result(s_a155_nand_out)
  );

  NAND_GATE_6_INPUTS #(
      .BubblesMask({2'b00, 4'h0})
  ) A191 (
      .input1(s_cscomm_4_n),
      .input2(s_cscomm_4_0[3]),
      .input3(s_cscomm_4_0[2]),
      .input4(s_cscomm_1_n),
      .input5(s_cscomm_0_n),
      .input6(s_lcs_n),
      .result(s_isstop_n)
  );

  NAND_GATE_5_INPUTS #(
      .BubblesMask({1'b0, 4'h0})
  ) A152 (
      .input1(s_cscomm_4_0[4]),
      .input2(s_cscomm_4_0[3]),
      .input3(s_cscomm_1_n),
      .input4(s_cscomm_0_n),
      .input5(s_lcs_n),
      .result(s_a152_nand_out)
  );

  NAND_GATE_5_INPUTS #(
      .BubblesMask({1'b0, 4'h0})
  ) A222 (
      .input1(s_csmis_1_0[0]),
      .input2(s_cscomm_4_n),
      .input3(s_cscomm_4_0[2]),
      .input4(s_cscomm_4_0[1]),
      .input5(s_lcs_n),
      .result(s_a222_nand_out)
  );

  NAND_GATE_3_INPUTS #(
      .BubblesMask(3'b000)
  ) A158 (
      .input1(s_a147_nand_out),
      .input2(s_a141_nand_out),
      .input3(s_a145_nand_out),
      .result(s_dt)
  );

  NAND_GATE_6_INPUTS #(
      .BubblesMask({2'b00, 4'h0})
  ) A185 (
      .input1(s_cscomm_4_0[4]),
      .input2(s_cscomm_4_0[3]),
      .input3(s_cscomm_4_0[2]),
      .input4(s_cscomm_4_0[1]),
      .input5(s_cscomm_0_n),
      .input6(s_csmis_1_0[0]),
      .result(s_a185_nand_out)
  );

  AND_GATE_3_INPUTS #(
      .BubblesMask(3'b000)
  ) A242 (
      .input1(s_brk_n),
      .input2(s_lshadow_n),
      .input3(s_erof),
      .result(s_a242_and_out)
  );

  NAND_GATE_5_INPUTS #(
      .BubblesMask({1'b0, 4'h0})
  ) A147 (
      .input1(s_cscomm_4_0[4]),
      .input2(s_cscomm_4_0[3]),
      .input3(s_cscomm_2_n),
      .input4(s_cscomm_4_0[1]),
      .input5(s_lcs_n),
      .result(s_a147_nand_out)
  );

  NAND_GATE_5_INPUTS #(
      .BubblesMask({1'b0, 4'h0})
  ) A223 (
      .input1(s_csmis_1_0[0]),
      .input2(s_cscomm_3_n),
      .input3(s_cscomm_2_n),
      .input4(s_cscomm_1_n),
      .input5(s_lcs_n),
      .result(s_a223_nand_out)
  );

  NAND_GATE #(
      .BubblesMask(2'b00)
  ) A237 (
      .input1(s_write),
      .input2(s_uclk),
      .result(a_a237_nand_out)
  );

  NAND_GATE_5_INPUTS #(
      .BubblesMask({1'b0, 4'h0})
  ) A198 (
      .input1(s_cscomm_4_n),
      .input2(s_cscomm_3_n),
      .input3(s_cscomm_4_0[2]),
      .input4(s_cscomm_1_n),
      .input5(s_cscomm_4_0[0]),
      .result(s_a216_nand_out5)
  );

  NAND_GATE_3_INPUTS #(
      .BubblesMask(3'b000)
  ) A200 (
      .input1(s_a185_nand_out),
      .input2(s_a216_nand_out5),
      .input3(s_lcs_n),
      .result(s_islow_n)
  );

  NAND_GATE_4_INPUTS #(
      .BubblesMask(4'h0)
  ) A141 (
      .input1(s_cscomm_4_0[4]),
      .input2(s_cscomm_4_0[3]),
      .input3(s_cscomm_1_n),
      .input4(s_lcs_n),
      .result(s_a141_nand_out)
  );

  NAND_GATE_5_INPUTS #(
      .BubblesMask({1'b0, 4'h0})
  ) A228 (
      .input1(s_csmis_1_0[1]),
      .input2(s_cscomm_3_n),
      .input3(s_cscomm_2_n),
      .input4(s_cscomm_1_n),
      .input5(s_lcs_n),
      .result(s_a228_nand_out)
  );

  AND_GATE #(
      .BubblesMask(2'b00)
  ) A246 (
      .input1(s_lshadow),
      .input2(s_rt),
      .result(s_estof_n)
  );

  NAND_GATE_3_INPUTS #(
      .BubblesMask(3'b000)
  ) A233 (
      .input1(s_rt),
      .input2(s_hit_n),
      .input3(s_a242_and_out),
      .result(s_a233_nand_out)
  );

  NAND_GATE #(
      .BubblesMask(2'b00)
  ) A238 (
      .input1(s_write),
      .input2(s_a242_and_out),
      .result(s_a238_nand_out)
  );

  NAND_GATE #(
      .BubblesMask(2'b00)
  ) A235 (
      .input1(s_erof),
      .input2(s_iorq),
      .result(s_a235_nand_out)
  );

  NAND_GATE #(
      .BubblesMask(2'b00)
  ) A245 (
      .input1(s_rt),
      .input2(s_lshadow_n),
      .result(s_a245_nand_out)
  );

  NAND_GATE #(
      .BubblesMask(2'b00)
  ) A243 (
      .input1(s_iorq),
      .input2(s_dap),
      .result(s_a243_nand_out)
  );

  NAND_GATE #(
      .BubblesMask(2'b00)
  ) A209 (
      .input1(s_erof),
      .input2(s_iempid_latched),
      .result(s_empid_n)
  );

  NAND_GATE_3_INPUTS #(
      .BubblesMask(3'b000)
  ) A162 (
      .input1(s_a156_nand_out),
      .input2(s_a150_nand_out),
      .input3(s_a142_nand_out),
      .result(s_a162_nand_out)
  );

  NAND_GATE_3_INPUTS #(
      .BubblesMask(3'b000)
  ) A239 (
      .input1(s_a233_nand_out),
      .input2(s_a238_nand_out),
      .input3(s_a235_nand_out),
      .result(s_ecrq)
  );

  NAND_GATE #(
      .BubblesMask(2'b00)
  ) A244 (
      .input1(s_a245_nand_out),
      .input2(s_a243_nand_out),
      .result(s_stoc_n)
  );

  NAND_GATE_6_INPUTS #(
      .BubblesMask({2'b00, 4'h0})
  ) A183 (
      .input1(s_cscomm_4_n),       // 0
      .input2(s_cscomm_4_0[3]),    // 1
      .input3(s_cscomm_2_n),       // 0
      .input4(s_cscomm_4_0[1]),    // 1
      .input5(s_cscomm_0_n),       // 0  = 01010 = 0xA = 10d = EPIC.LDMPIE (set mask reg: inh all ints)
      .input6(s_lcs_n),
      .result(s_iempid_n)
  );

  NAND_GATE_8_INPUTS #(
      .BubblesMask(8'h00)
  ) A145 (
      .input1(s_zz1),
      .input2(s_csmis_1_n),
      .input3(s_cscomm_4_0[4]),
      .input4(s_cscomm_3_n),
      .input5(s_cscomm_2_n),
      .input6(s_cscomm_4_0[1]),
      .input7(s_cscomm_0_n),
      .input8(s_lcs_n),
      .result(s_a145_nand_out)
  );

  NAND_GATE_8_INPUTS #(
      .BubblesMask(8'h00)
  ) A216 (
      .input1(s_zz1),
      .input2(s_a222_nand_out),
      .input3(s_a223_nand_out),
      .input4(s_a228_nand_out),
      .input5(s_a229_nand_out),
      .input6(s_a217_nand_out),
      .input7(s_a218_nand_out),
      .input8(s_a219_nand_out),
      .result(s_a216_nand_out)
  );

  NAND_GATE_5_INPUTS #(
      .BubblesMask({1'b0, 4'h0})
  ) A229 (
      .input1(s_cscomm_4_n),
      .input2(s_cscomm_4_0[2]),
      .input3(s_cscomm_1_n),
      .input4(s_cscomm_0_n),
      .input5(s_lcs_n),
      .result(s_a229_nand_out)
  );

  NAND_GATE_6_INPUTS #(
      .BubblesMask({2'b00, 4'h0})
  ) A182 (
      .input1(s_cscomm_4_n),
      .input2(s_cscomm_3_n),
      .input3(s_cscomm_4_0[2]),
      .input4(s_cscomm_4_0[1]),
      .input5(s_cscomm_4_0[0]),
      .input6(s_lcs_n),
      .result(s_isioc_n)
  );

  NAND_GATE #(
      .BubblesMask(2'b00)
  ) A167 (
      .input1(s_a147_nand_out),
      .input2(s_a144_nand_out),
      .result(s_a167_nand_out)
  );

  NAND_GATE_5_INPUTS #(
      .BubblesMask({1'b0, 4'h0})
  ) A217 (
      .input1(s_cscomm_3_n),
      .input2(s_cscomm_2_n),
      .input3(s_cscomm_1_n),
      .input4(s_cscomm_0_n),
      .input5(s_lcs_n),
      .result(s_a217_nand_out)
  );

  NAND_GATE_8_INPUTS #(
      .BubblesMask(8'h00)
  ) A142 (
      .input1(s_csmis_1_0[0]),
      .input2(s_csmis_1_0[1]),
      .input3(s_cscomm_4_0[4]),
      .input4(s_cscomm_3_n),
      .input5(s_cscomm_2_n),
      .input6(s_cscomm_4_0[1]),
      .input7(s_cscomm_0_n),
      .input8(s_lcs_n),
      .result(s_a142_nand_out)
  );

  NAND_GATE_6_INPUTS #(
      .BubblesMask({2'b00, 4'h0})
  ) A184 (
      .input1(s_cscomm_4_n),
      .input2(s_cscomm_4_0[3]),
      .input3(s_cscomm_4_0[2]),
      .input4(s_cscomm_1_n),
      .input5(s_cscomm_4_0[0]),
      .input6(s_lcs_n),
      .result(s_iclrti_n)
  );

  NAND_GATE_6_INPUTS #(
      .BubblesMask({2'b00, 4'h0})
  ) A148 (
      .input1(s_a145_nand_out),
      .input2(s_a142_nand_out),
      .input3(s_a156_nand_out),
      .input4(s_a150_nand_out),
      .input5(s_a141_nand_out),
      .input6(s_a147_nand_out),
      .result(s_a148_nand_out)
  );

  NAND_GATE_4_INPUTS #(
      .BubblesMask(4'h0)
  ) A218 (
      .input1(s_cscomm_4_n),
      .input2(s_cscomm_3_n),
      .input3(s_cscomm_2_n),
      .input4(s_lcs_n),
      .result(s_a218_nand_out)
  );

  NAND_GATE_8_INPUTS #(
      .BubblesMask(8'h00)
  ) A143 (
      .input1(s_zz1),
      .input2(s_csmis_1_0[1]),
      .input3(s_cscomm_4_0[4]),
      .input4(s_cscomm_3_n),
      .input5(s_cscomm_2_n),
      .input6(s_cscomm_4_0[1]),
      .input7(s_cscomm_0_n),
      .input8(s_lcs_n),
      .result(s_a143_nand_out)
  );

  NAND_GATE_8_INPUTS #(
      .BubblesMask(8'h00)
  ) A180 (
      .input1(s_csmis_0_n),
      .input2(s_csmis_1_n),
      .input3(s_cscomm_4_0[4]),
      .input4(s_cscomm_3_n),
      .input5(s_cscomm_2_n),
      .input6(s_cscomm_1_n),
      .input7(s_cscomm_4_0[0]),
      .input8(s_lcs_n),
      .result(s_iwchim_n)
  );

  NAND_GATE_4_INPUTS #(
      .BubblesMask(4'h0)
  ) A219 (
      .input1(s_cscomm_4_n),
      .input2(s_cscomm_4_0[3]),
      .input3(s_cscomm_4_0[2]),
      .input4(s_lcs_n),
      .result(s_a219_nand_out)
  );

  NAND_GATE_3_INPUTS #(
      .BubblesMask(3'b000)
  ) A166 (
      .input1(s_a143_nand_out),
      .input2(s_a156_nand_out),
      .input3(s_a150_nand_out),
      .result(s_a166_nand_out)
  );

  NAND_GATE_6_INPUTS #(
      .BubblesMask({2'b00, 4'h0})
  ) A144 (
      .input1(s_cscomm_4_0[4]),
      .input2(s_cscomm_4_0[3]),
      .input3(s_cscomm_4_0[2]),
      .input4(s_cscomm_1_n),
      .input5(s_cscomm_4_0[0]),
      .input6(s_lcs_n),
      .result(s_a144_nand_out)
  );

  NAND_GATE #(
      .BubblesMask(2'b00)
  ) A195 (
      .input1(s_erof),
      .input2(s_ldpanc_latched),
      .result(s_ldpanc_n)
  );

  NAND_GATE_8_INPUTS #(
      .BubblesMask(8'h00)
  ) A186 (
      .input1(s_csmis_0_n),
      .input2(s_csmis_1_0[1]),
      .input3(s_cscomm_4_n),
      .input4(s_cscomm_3_n),
      .input5(s_cscomm_4_0[2]),
      .input6(s_cscomm_4_0[1]),
      .input7(s_cscomm_0_n),
      .input8(s_lcs_n),
      .result(s_ildpanc_n)
  );

  NAND_GATE_8_INPUTS #(
      .BubblesMask(8'h00)
  ) A213 (
      .input1(s_csmis_1_0[1]),
      .input2(s_csmis_1_0[0]),
      .input3(s_cscomm_4_0[4]),
      .input4(s_cscomm_3_n),
      .input5(s_cscomm_2_n),
      .input6(s_cscomm_1_n),
      .input7(s_cscomm_4_0[0]),
      .input8(s_lcs_n),
      .result(s_a213_nand_out)
  );

  NAND_GATE_5_INPUTS #(
      .BubblesMask({1'b0, 4'h0})
  ) A153 (
      .input1(s_a142_nand_out),
      .input2(s_a150_nand_out),
      .input3(s_a144_nand_out),
      .input4(s_a156_nand_out),
      .input5(s_a147_nand_out),
      .result(s_a153_nand_out)
  );

  NAND_GATE_6_INPUTS #(
      .BubblesMask({2'b00, 4'h0})
  ) A190 (
      .input1(s_cscomm_4_n),
      .input2(s_cscomm_4_0[3]),
      .input3(s_cscomm_2_n),
      .input4(s_cscomm_4_0[1]),
      .input5(s_cscomm_4_0[0]),
      .input6(s_lcs_n),
      .result(s_istart_n)
  );

  NAND_GATE_3_INPUTS #(
      .BubblesMask(3'b000)
  ) A177 (
      .input1(s_lcs_n),
      .input2(s_mreq),
      .input3(s_fmiss),
      .result(s_a177_nand_out)
  );

  NAND_GATE_8_INPUTS #(
      .BubblesMask(8'h00)
  ) A215 (
      .input1(s_a226_q_n),
      .input2(s_csmis_1_0[1]),
      .input3(s_csmis_1_0[0]),
      .input4(s_cscomm_4_0[4]),
      .input5(s_cscomm_4_0[3]),
      .input6(s_cscomm_4_0[2]),
      .input7(s_cscomm_1_n),
      .input8(s_lcs_n),
      .result(s_a215_nand_out)
  );

  NAND_GATE_3_INPUTS #(
      .BubblesMask(3'b000)
  ) A220 (
      .input1(s_a212_nand_out),
      .input2(s_a215_nand_out),
      .input3(s_a224_nand_out),
      .result(s_a220_nand_out)
  );

  NAND_GATE #(
      .BubblesMask(2'b00)
  ) A171 (
      .input1(s_a177_nand_out),
      .input2(s_a172_nand_out),
      .result(s_a171_nand_out)
  );

  NAND_GATE #(
      .BubblesMask(2'b00)
  ) A172 (
      .input1(s_lcs_n),
      .input2(s_ssema),
      .result(s_a172_nand_out)
  );

  NAND_GATE #(
      .BubblesMask(2'b00)
  ) A224 (
      .input1(s_poni_n),
      .input2(s_lcs_n),
      .result(s_a224_nand_out)
  );

  NAND_GATE_8_INPUTS #(
      .BubblesMask(8'h00)
  ) A189 (
      .input1(s_csmis_0_n),
      .input2(s_csmis_1_0[1]),
      .input3(s_cscomm_4_0[4]),
      .input4(s_cscomm_3_n),
      .input5(s_cscomm_2_n),
      .input6(s_cscomm_1_n),
      .input7(s_cscomm_4_0[0]),
      .input8(s_lcs_n),
      .result(s_a189_nand_out)
  );

  NOR_GATE #(
      .BubblesMask(2'b00)
  ) A196 (
      .input1(s_a204_q),
      .input2(s_clk3_n),
      .result(s_a196_nand_out)
  );

  NAND_GATE_3_INPUTS #(
      .BubblesMask(3'b000)
  ) A192 (
      .input1(s_ssema),
      .input2(s_mreq),
      .input3(s_lcs_n),
      .result(s_a192_nand_out)
  );

  D_FLIPFLOP #(
      .InvertClockEnable(0)
  ) MEMORY_63 (
      .clock(s_clk1),
      .d(s_a153_nand_out),
      .preset(s_gnd),
      .q(s_ca10),
      .qBar(),
      .reset(!a_a237_nand_out),  // Reset signal is negated, as this flip-flop has RESET active high
      .tick(1'b1)
  );

  D_FLIPFLOP #(
      .InvertClockEnable(0)
  ) A226 (
      .clock(s_clk2),
      .d(s_a221_y),
      .preset(1'b0),
      .q(s_a226_q),
      .qBar(s_a226_q_n),
      .reset(1'b0),
      .tick(1'b1)
  );

  D_FLIPFLOP #(
      .InvertClockEnable(0)
  ) A232 (
      .clock(s_clk1),
      .d(s_a236_y),
      .preset(1'b0),
      .q(s_lhit_n),
      .qBar(s_lhit),
      .reset(1'b0),
      .tick(1'b1)
  );


  D_FLIPFLOP #(
      .InvertClockEnable(0)
  ) A227 (
      .clock(s_clk2),
      .d(s_a220_nand_out),
      .preset(1'b0),
      .q(),
      .qBar(s_dvacc_n),
      .reset(1'b0),
      .tick(1'b1)
  );

  D_FLIPFLOP #(
      .InvertClockEnable(0)
  ) MEMORY_68 (
      .clock(s_clk3),
      .d(s_a201_y),
      .preset(1'b0),
      .q(s_reset),
      .qBar(),
      .reset(s_clear),
      .tick(1'b1)
  );

  D_FLIPFLOP #(
      .InvertClockEnable(0)
  ) A204 (
      .clock(s_clk3_n),
      .d(s_a189_nand_out),
      .preset(1'b0),
      .q(s_a204_q),
      .qBar(),
      .reset(1'b0),
      .tick(1'b1)
  );


  /*******************************************************************************
   ** Here all sub-circuits are defined                                          **
   *******************************************************************************/

  F924 A181 (
      .C_H05  (s_clk3),
      .D0_H01 (s_vcc),
      .D1_H02 (s_isstop_n),
      .D2_H03 (s_a199_nand_out),
      .D3_H04 (s_a206_nand_out),
      .N01_Q0 (),
      .N02_Q1 (s_sstop_n),
      .N03_Q2 (s_ceuart_n),
      .N04_Q3 (s_ssema),
      .N05_Q0B(),
      .N06_Q1B(),
      .N07_Q2B(),
      .N08_Q3B(s_ssema_n)
  );

  F924 A214 (
      .C_H05  (s_clk2),
      .D0_H01 (s_a213_nand_out),
      .D1_H02 (s_a216_nand_out),
      .D2_H03 (s_a211_nand_out),
      .D3_H04 (s_a212_nand_out),
      .N01_Q0 (s_a214_q0),
      .N02_Q1 (),
      .N03_Q2 (s_rwcs_n),
      .N04_Q3 (s_iorq_n),
      .N05_Q0B(),
      .N06_Q1B(s_short_n),
      .N07_Q2B(),
      .N08_Q3B(s_iorq)
  );

  F924 A140 (
      .C_H05  (s_clk2),
      .D0_H01 (s_a162_nand_out),
      .D1_H02 (s_vcc),
      .D2_H03 (s_dt),
      .D3_H04 (s_irt),
      .N01_Q0 (s_fetch),
      .N02_Q1 (),
      .N03_Q2 (),
      .N04_Q3 (s_rt),
      .N05_Q0B(),
      .N06_Q1B(),
      .N07_Q2B(s_dt_n),
      .N08_Q3B(s_rt_n)
  );

  F091 A178 (
      .N01(s_zz1),
      .N02()
  );

  F571 A221 (
      .A(s_a214_q0),
      .D0(s_idbi2),
      .D1(s_a226_q),
      .ENB_N(s_gnd),
      .Y(s_a221_y)
  );

  F571 A236 (
      .A(s_rt),
      .D0(s_lhit_n),
      .D1(s_hit_n),
      .ENB_N(s_gnd),
      .Y(s_a236_y)
  );

  F924 A187 (
      .C_H05  (s_clk3),
      .D0_H01 (s_iclrti_n),
      .D1_H02 (s_isioc_n),
      .D2_H03 (s_iempid_n),
      .D3_H04 (s_islow_n),
      .N01_Q0 (s_clrti_n),
      .N02_Q1 (s_sioc_n),
      .N03_Q2 (),
      .N04_Q3 (s_slow_n),
      .N05_Q0B(),
      .N06_Q1B(),
      .N07_Q2B(s_iempid_latched),
      .N08_Q3B()
  );

  F924 A160 (
      .C_H05  (s_clk2),
      .D0_H01 (s_a171_nand_out),
      .D1_H02 (s_a166_nand_out),
      .D2_H03 (s_a148_nand_out),
      .D3_H04 (s_a167_nand_out),
      .N01_Q0 (s_fmiss),
      .N02_Q1 (),
      .N03_Q2 (),
      .N04_Q3 (s_write),
      .N05_Q0B(),
      .N06_Q1B(s_form_n),
      .N07_Q2B(s_mreq),
      .N08_Q3B()
  );

  F571 A208 (
      .A(s_sioc_n),
      .D0(s_idbi5),
      .D1(s_emcl_n),
      .ENB_N(s_gnd),
      .Y(s_208_y)
  );

  D_FLIPFLOP #(
      .InvertClockEnable(0)
  ) MEMORY_66 (
      .clock(s_clk3),
      .d(s_208_y),
      .preset(1'b0),
      .q(s_emcl_n),
      .qBar(),
      .reset(s_clear),
      .tick(1'b1)
  );

/* REFACTOR EMCL_n logic to avoid race condition */
/* refactor removed as original code worked...

  reg regEMCL_n;
  assign s_emcl_n = regEMCL_n;

  // Normally POSEDGE CLK3, but to avoid race we latch on the negative edge. EMCL_n is not time sensitve inside the opcode
  always@(negedge s_clk3, posedge s_clear)
  begin
    if (s_clear) begin
        regEMCL_n <= 0;
    end else begin
        if (s_sioc_n == 1'b0) begin
            regEMCL_n <= s_idbi5;
        end
    end
  end
*/

  F924 A188 (
      .C_H05  (s_clk3),
      .D0_H01 (s_vcc),
      .D1_H02 (s_istart_n),
      .D2_H03 (s_ildpanc_n),
      .D3_H04 (s_iwchim_n),
      .N01_Q0 (),
      .N02_Q1 (s_start_n),
      .N03_Q2 (),
      .N04_Q3 (s_wchim_n),
      .N05_Q0B(),
      .N06_Q1B(),
      .N07_Q2B(s_ldpanc_latched),
      .N08_Q3B()
  );

  F571 A201 (
      .D0(s_idbi7),
      .D1(s_reset),
      .A(s_sioc_n),
      .ENB_N(s_gnd),
      .Y(s_a201_y)
  );

  F595 A207 (
      .H01_S (s_a196_nand_out),
      .H02_R (s_clk3_n),
      .H03_G (s_zz1),
      .N01_Q (),
      .N02_QB(s_cclr_n)
  );

endmodule