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[/] [sparc64soc/] [trunk/] [T1-common/] [srams/] [bw_r_l2d_32k.v] - Blame information for rev 2

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// ========== Copyright Header Begin ==========================================
// 
// OpenSPARC T1 Processor File: bw_r_l2d_32k.v
// Copyright (c) 2006 Sun Microsystems, Inc.  All Rights Reserved.
// DO NOT ALTER OR REMOVE COPYRIGHT NOTICES.
// 
// The above named program is free software; you can redistribute it and/or
// modify it under the terms of the GNU General Public
// License version 2 as published by the Free Software Foundation.
// 
// The above named program is distributed in the hope that it will be 
// useful, but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
// General Public License for more details.
// 
// You should have received a copy of the GNU General Public
// License along with this work; if not, write to the Free Software
// Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA.
// 
// ========== Copyright Header End ============================================
//FPGA_SYN enables all FPGA related modifications
`ifdef FPGA_SYN
`define FPGA_SYN_RED
`endif
 
module bw_r_l2d_32k (/*AUTOARG*/
   // Outputs
   decc_out, so, l2d_fuse_data_out,
   // Inputs
   decc_in_l, decc_read_in, word_en_l, way_sel_l, set_l,
   col_offset_l, wr_en_l, rclk, arst_l, mem_write_disable,
   sehold, se, si, fuse_l2d_wren, fuse_l2d_rden,
   fuse_l2d_rid, fuse_clk1, fuse_clk2,
   fuse_l2d_data_in, fuse_read_data_in
   );
 
   input [155:0] decc_in_l;
   input [155:0]         decc_read_in;
   input [3:0]           word_en_l;
   input [1:0]           way_sel_l;
   input [9:0]           set_l;
   input                col_offset_l;
   input                wr_en_l;
   input                rclk;
   input                arst_l;
 
   // Test signals
   input                mem_write_disable;
   input                sehold;
   input                se;
   input                si;
 
 
   // Efuse inputs
   input                fuse_l2d_wren;
   input                fuse_l2d_rden;
   input [2:0]           fuse_l2d_rid;
   input                fuse_clk1;
   input                fuse_clk2;
   input                fuse_l2d_data_in;
   input                fuse_read_data_in;
 
 
   output [155:0]        decc_out ;
   output               so;
 
   // Efuse outputs
   output               l2d_fuse_data_out;
 
   reg [155:0]           tmp_decc_out;
   reg [155:0]           decc_out_tmp;
   reg [155:0]           reg_decc_in;
 
`ifdef DEFINE_0IN
`else
   reg [155:0]           way0_decc[1023:0] ;
   reg [155:0]           way1_decc[1023:0] ;
`endif
 
   wire                 acc_en_d1;
   reg [1:0]             way_sel_d1;
   reg [9:0]             set_d1;
   reg [3:0]             word_en_d1;
   reg                  wr_en_d1;
   reg [155:0]           decc_in_d1;
   reg [155:0]           decc_out_d1;
   reg                  col_offset_d1;
 
   wire [1:0]            way_sel_sehold;
   wire [9:0]            set_sehold;
   wire [3:0]            word_en_sehold;
   wire                 wr_en_sehold;
   wire [155:0]  decc_in_sehold;
   wire                 col_offset;
 
   wire [155:0]  decc_out ;
 
// JC begin
// Because of this 2 cycle block,
// The following codes are just helping me for Innologic verification 
// stop_1_cyc: when col_offset = 1, the next cycle will be ignore
// keep_rd_out: The output data will be kept for another cycle
   reg                  keep_rd_out;
   reg                  stop_1_cyc;
   always @(posedge rclk) begin
      if (col_offset && (|way_sel_sehold)) begin
         stop_1_cyc <= 1'b1;
      end
      else stop_1_cyc <= 1'b0;
      if (acc_en_d1 & ~wr_en_d1) begin
         keep_rd_out <= 1'b1;
      end
      else keep_rd_out <= 1'b0;
   end
// JC end  
 
 
   assign               wr_en_sehold = (sehold) ? wr_en_d1 : ~wr_en_l;
   assign               set_sehold = (sehold) ? set_d1 : ~set_l;
   assign               way_sel_sehold = (sehold) ? way_sel_d1 : ~way_sel_l;
   assign               word_en_sehold = (sehold) ? word_en_d1 : ~word_en_l;
// In Circuits, we use se to disable write, however, I modified testbench as following 
// to verify write disable:
//     force inno_tb_top.xtor.xcnt.se_l = ~mem_write_disable ;
 
   assign               col_offset = (stop_1_cyc || mem_write_disable ) ? (1'b0) : ~col_offset_l ;
 
   assign acc_en_d1 = col_offset_d1 & (|way_sel_d1);
 
   always @(posedge rclk) begin
      col_offset_d1 <= col_offset;
      way_sel_d1  <= way_sel_sehold;
      set_d1  <= set_sehold;
      word_en_d1 <= word_en_sehold;
      wr_en_d1  <= wr_en_sehold;
// JC 
// EVEN THOUGH We don't have any write data latch,
// Our write-data drivers act like latch which gating by 
// Worden signals.
      decc_in_d1 <= ~decc_in_l;
// JC 
//This is NOT output flops, but we can keep read outs for
// 2 cycles.      
      decc_out_d1 <= decc_out_tmp;
   end
 
 
`ifdef DEFINE_0IN
   wire [155:0] decc_out0, decc_out1;
 
   wire [155:0] wm  = { {39{word_en_d1[3]}}, {39{word_en_d1[2]}}, {39{word_en_d1[1]}}, {39{word_en_d1[0]}} };
   wire         we0 = acc_en_d1 & wr_en_d1 & way_sel_d1[0];
   wire         we1 = acc_en_d1 & wr_en_d1 & way_sel_d1[1];
 
l2data_axis     data_array0 (.data_out  (decc_out0[155:0]),
                             .rclk      (rclk),
                             .adr       (set_d1[9:0]),
                             .data_in   (decc_in_d1[155:0]),
                             .we        (we0),
                             .wm        (wm[155:0]) );
l2data_axis     data_array1 (.data_out  (decc_out1[155:0]),
                             .rclk      (rclk),
                             .adr       (set_d1[9:0]),
                             .data_in   (decc_in_d1[155:0]),
                             .we        (we1),
                             .wm        (wm[155:0]) );
 
   always @(/*AUTOSENSE*/acc_en_d1 or decc_in_d1 or decc_out0
            or decc_out1 or way_sel_d1 or word_en_d1 or wr_en_d1) begin
        if (acc_en_d1 & ~wr_en_d1) begin
           //////////////////////////
           // 16 or 64B byte read
           //////////////////////////
           decc_out_tmp = way_sel_d1[0] ? decc_out0[155:0] : decc_out1[155:0];
        end
 
        if (acc_en_d1 & wr_en_d1) begin
           //////////////////////////
           // Store word/dword OR 64B store
           //////////////////////////
           tmp_decc_out = way_sel_d1[0] ? decc_out0[155:0] : decc_out1[155:0];
 
           //////////////////////////////////////
           // Write data based on Word enables.
           //////////////////////////////////////
 
           reg_decc_in[155:117] = (decc_in_d1[155:117] & {39{word_en_d1[3]}} |
                                   tmp_decc_out[155:117] & {39{~word_en_d1[3]}});
           reg_decc_in[116:78] = (decc_in_d1[116:78] & {39{word_en_d1[2]}} |
                                  tmp_decc_out[116:78] & {39{~word_en_d1[2]}});
           reg_decc_in[77:39] = (decc_in_d1[77:39] & {39{word_en_d1[1]}} |
                                 tmp_decc_out[77:39] & {39{~word_en_d1[1]}});
           reg_decc_in[38:0] = (decc_in_d1[38:0] & {39{word_en_d1[0]}} |
                                tmp_decc_out[38:0] & {39{~word_en_d1[0]}});
 
           //////////////////////////////////////////////////////////
           // the store data gets reflected onto the read output bus
           //////////////////////////////////////////////////////////
 
//           decc_out_tmp[155:0] = reg_decc_in[155:0];
// Store data is *not* reflected onto the read output bus in the physical implementation
             decc_out_tmp[155:0] = 156'b0;
 
        end // of write operation
 
      if (~acc_en_d1) begin
        // no access
         decc_out_tmp[155:0] = 156'b0;
      end
 
   end // of always block
 
`else
 
   always @(/*AUTOSENSE*/acc_en_d1 or decc_in_d1 or set_d1
            or way_sel_d1 or word_en_d1 or wr_en_d1) begin
 
`ifdef  INNO_MUXEX
`else
//----- PURELY FOR VERIFICATION -----------------------
      if(wr_en_d1==1'bx) begin
        `ifdef MODELSIM
         $display("L2_DATA_ERR"," wr en error %b ", wr_en_d1);
        `else
         $error("L2_DATA_ERR"," wr en error %b ", wr_en_d1);
        `endif
      end
//----- PURELY FOR VERIFICATION -----------------------
`endif
 
 
//////////////////
// MEMORY ACCESS
//////////////////
 
      if (acc_en_d1) begin
 
`ifdef  INNO_MUXEX
`else
//----- PURELY FOR VERIFICATION -----------------------
         if(set_d1==10'bx) begin
        `ifdef MODELSIM
            $error("L2_DATA_ERR"," index error %h ", set_d1[9:0]);
        `else
            $display("L2_DATA_ERR"," index error %h ", set_d1[9:0]);
        `endif
         end
//----- PURELY FOR VERIFICATION -----------------------
`endif
 
 
        if (~wr_en_d1) begin
           //////////////////////////
           // 16 or 64B byte read 
           //////////////////////////
           decc_out_tmp = way_sel_d1[0] ? way0_decc[set_d1] : way1_decc[set_d1];
//JC: For keeping data for 2 cycle
//         keep_rd_out = 2'b01;    
        end
 
        else begin
           //////////////////////////
           // Store word/dword OR 64B store
           //////////////////////////
           tmp_decc_out = way_sel_d1[0] ? way0_decc[set_d1] : way1_decc[set_d1];
 
//         keep_rd_out = 2'b00;    
           //////////////////////////////////////
           // Write data based on Word enables.
           //////////////////////////////////////
 
           reg_decc_in[155:117] = (decc_in_d1[155:117] & {39{word_en_d1[3]}} |
                                   tmp_decc_out[155:117] & {39{~word_en_d1[3]}});
           reg_decc_in[116:78] = (decc_in_d1[116:78] & {39{word_en_d1[2]}} |
                                  tmp_decc_out[116:78] & {39{~word_en_d1[2]}});
           reg_decc_in[77:39] = (decc_in_d1[77:39] & {39{word_en_d1[1]}} |
                                 tmp_decc_out[77:39] & {39{~word_en_d1[1]}});
           reg_decc_in[38:0] = (decc_in_d1[38:0] & {39{word_en_d1[0]}} |
                                tmp_decc_out[38:0] & {39{~word_en_d1[0]}});
 
           if (way_sel_d1[0]) way0_decc[set_d1] =  reg_decc_in;
           if (way_sel_d1[1]) way1_decc[set_d1] =  reg_decc_in;
 
           //////////////////////////////////////////////////////////
           // the store data gets reflected onto the read output bus
           //////////////////////////////////////////////////////////
 
//           decc_out_tmp[155:0] = reg_decc_in[155:0];
// Store data is *not* reflected onto the read output bus in the physical implementation
 
             decc_out_tmp[155:0] = 156'b0;
 
        end // of write operation
 
      end
 
      else begin
        // no access
         decc_out_tmp[155:0] = 156'b0;
      end
 
   end // of always block
`endif
   // Modeling wired-OR
 
// JC we don't have any flop in this level
//   assign decc_out[155:0] = decc_out_d1[155:0] | decc_read_in[155:0];   
 
   assign decc_out[155:0] = (acc_en_d1 & ~wr_en_d1) ? 156'bX : (keep_rd_out) ?
                            (decc_out_d1[155:0] | decc_read_in[155:0]) :
                            (decc_out_tmp[155:0] | decc_read_in[155:0]);
 
/////////////////////////////////////////////////////////////////////
// Redundancy Registers
/////////////////////////////////////////////////////////////////////
 
   reg [8:0]     s_red_reg0;
   reg [8:0]     s_red_reg1;
   reg [8:0]     s_red_reg2;
   reg [8:0]     s_red_reg3;
   reg [8:0]     s_red_reg4;
   reg [8:0]     s_red_reg5;
 
   reg [8:0]     m_red_reg0;
   reg [8:0]     m_red_reg1;
   reg [8:0]     m_red_reg2;
   reg [8:0]     m_red_reg3;
   reg [8:0]     m_red_reg4;
   reg [8:0]     m_red_reg5;
 
   wire      l2d_fuse_data_out;
 
assign l2d_fuse_data_out = s_red_reg5[8];
 
   always @(arst_l or fuse_clk1 or fuse_l2d_rid or fuse_l2d_wren or fuse_l2d_rden
            or fuse_l2d_data_in or fuse_read_data_in
            or s_red_reg0 or s_red_reg1 or s_red_reg2
            or s_red_reg3 or s_red_reg4 or s_red_reg5) begin
 
      if (!arst_l) begin
         m_red_reg0[8:0] = 9'b0;
         m_red_reg1[8:0] = 9'b0;
         m_red_reg2[8:0] = 9'b0;
         m_red_reg3[8:0] = 9'b0;
         m_red_reg4[8:0] = 9'b0;
         m_red_reg5[8:0] = 9'b0;
      end
 
      if (arst_l && fuse_clk1) begin
 
      /////////////////////////////////
      // Write operation
      /////////////////////////////////
 
         if (fuse_l2d_wren) begin
            case (fuse_l2d_rid) //selecting among the six registers
              3'b101: m_red_reg0[8:0] = {s_red_reg0[7:0], fuse_l2d_data_in};// bottom odd row
              3'b011: m_red_reg1[8:0] = {s_red_reg1[7:0], fuse_l2d_data_in};// bottom even row
              3'b010: m_red_reg2[8:0] = {s_red_reg2[7:0], fuse_l2d_data_in};// bottom column
              3'b100: m_red_reg3[8:0] = {s_red_reg3[7:0], fuse_l2d_data_in};// top odd row
              3'b001: m_red_reg4[8:0] = {s_red_reg4[7:0], fuse_l2d_data_in};// top even row
              3'b000: m_red_reg5[8:0] = {s_red_reg5[7:0], fuse_l2d_data_in};// top column
              default: ;
            endcase // case(fuse_l2d_rid)
         end // if (fuse_l2d_wren)
 
      /////////////////////////////////
      // Read operation
      /////////////////////////////////
 
//JC This is just temporary fix for read operation, rid = 3'b111 will turn on everything
         else if (fuse_l2d_rden) begin
                      m_red_reg0[8:0] = {s_red_reg0[7:0], fuse_read_data_in};
                      m_red_reg1[8:0] = {s_red_reg1[7:0], s_red_reg0[8]};
                      m_red_reg2[8:0] = {s_red_reg2[7:0], s_red_reg1[8]};
                      m_red_reg3[8:0] = {s_red_reg3[7:0], s_red_reg2[8]};
                      m_red_reg4[8:0] = {s_red_reg4[7:0], s_red_reg3[8]};
                      m_red_reg5[8:0] = {s_red_reg5[7:0], s_red_reg4[8]};
              end // if (fuse_l2d_rden)
 
      end // if (fuse_clk1)
 
   end // always @ (fuse_clk1 or...
 
//   always @(posedge efc_scdata_fuse_clk1) begin
 
   always @(arst_l or fuse_clk2 or fuse_l2d_rid or fuse_l2d_wren or fuse_l2d_rden
            or m_red_reg0 or m_red_reg1 or m_red_reg2
            or m_red_reg3 or m_red_reg4 or m_red_reg5) begin
 
`ifdef DEFINE_0IN
`else
  `ifdef FPGA_SYN_RED
  `else
      if (!arst_l) begin
         m_red_reg0[8:0] = 9'b0;
         m_red_reg1[8:0] = 9'b0;
         m_red_reg2[8:0] = 9'b0;
         m_red_reg3[8:0] = 9'b0;
         m_red_reg4[8:0] = 9'b0;
         m_red_reg5[8:0] = 9'b0;
      end
  `endif
`endif
 
      if (fuse_clk2) begin
 
         if (fuse_l2d_wren) begin
            case (fuse_l2d_rid) //selecting among the six registers
              3'b101: s_red_reg0[8:0] = m_red_reg0[8:0];// bottom odd row
              3'b011: s_red_reg1[8:0] = m_red_reg1[8:0];// bottom even row
              3'b010: s_red_reg2[8:0] = m_red_reg2[8:0];// bottom column
              3'b100: s_red_reg3[8:0] = m_red_reg3[8:0];// top odd row
              3'b001: s_red_reg4[8:0] = m_red_reg4[8:0];// top even row
              3'b000: s_red_reg5[8:0] = m_red_reg5[8:0];// top column
             default: ;
            endcase // case(fuse_l2d_rid)
         end // if (fuse_l2d_wren)
         else if (fuse_l2d_rden) begin
                s_red_reg0[8:0] = m_red_reg0[8:0];// bottom odd row
                s_red_reg1[8:0] = m_red_reg1[8:0];// bottom even row
                s_red_reg2[8:0] = m_red_reg2[8:0];// bottom column
                s_red_reg3[8:0] = m_red_reg3[8:0];// top odd row
                s_red_reg4[8:0] = m_red_reg4[8:0];// top even row
                s_red_reg5[8:0] = m_red_reg5[8:0];// top column
              end // if (fuse_l2d_rden)
 
      end // if (fuse_clk2)
 
   end // always @ (fuse_clk2 or...
 
endmodule // bw_r_l2d_32k
 

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[/] [sparc64soc/] [trunk/] [T1-common/] [srams/] [bw_r_l2d_32k.v] - Blame information for rev 2

Line No.	Rev	Author	Line
1	2	dmitryr	`// ========== Copyright Header Begin ==========================================`
2			`//`
3			`// OpenSPARC T1 Processor File: bw_r_l2d_32k.v`
4			`// Copyright (c) 2006 Sun Microsystems, Inc. All Rights Reserved.`
5			`// DO NOT ALTER OR REMOVE COPYRIGHT NOTICES.`
6			`//`
7			`// The above named program is free software; you can redistribute it and/or`
8			`// modify it under the terms of the GNU General Public`
9			`// License version 2 as published by the Free Software Foundation.`
10			`//`
11			`// The above named program is distributed in the hope that it will be`
12			`// useful, but WITHOUT ANY WARRANTY; without even the implied warranty of`
13			`// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU`
14			`// General Public License for more details.`
15			`//`
16			`// You should have received a copy of the GNU General Public`
17			`// License along with this work; if not, write to the Free Software`
18			`// Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA.`
19			`//`
20			`// ========== Copyright Header End ============================================`
21			`//FPGA_SYN enables all FPGA related modifications`
22			`ifdef FPGA_SYN
23			`define FPGA_SYN_RED
24			`endif
25
26			`module bw_r_l2d_32k (/AUTOARG/`
27			`// Outputs`
28			`decc_out, so, l2d_fuse_data_out,`
29			`// Inputs`
30			`decc_in_l, decc_read_in, word_en_l, way_sel_l, set_l,`
31			`col_offset_l, wr_en_l, rclk, arst_l, mem_write_disable,`
32			`sehold, se, si, fuse_l2d_wren, fuse_l2d_rden,`
33			`fuse_l2d_rid, fuse_clk1, fuse_clk2,`
34			`fuse_l2d_data_in, fuse_read_data_in`
35			`);`
36
37			`input [155:0] decc_in_l;`
38			`input [155:0] decc_read_in;`
39			`input [3:0] word_en_l;`
40			`input [1:0] way_sel_l;`
41			`input [9:0] set_l;`
42			`input col_offset_l;`
43			`input wr_en_l;`
44			`input rclk;`
45			`input arst_l;`
46
47			`// Test signals`
48			`input mem_write_disable;`
49			`input sehold;`
50			`input se;`
51			`input si;`
52
53
54			`// Efuse inputs`
55			`input fuse_l2d_wren;`
56			`input fuse_l2d_rden;`
57			`input [2:0] fuse_l2d_rid;`
58			`input fuse_clk1;`
59			`input fuse_clk2;`
60			`input fuse_l2d_data_in;`
61			`input fuse_read_data_in;`
62
63
64			`output [155:0] decc_out ;`
65			`output so;`
66
67			`// Efuse outputs`
68			`output l2d_fuse_data_out;`
69
70			`reg [155:0] tmp_decc_out;`
71			`reg [155:0] decc_out_tmp;`
72			`reg [155:0] reg_decc_in;`
73
74			`ifdef DEFINE_0IN
75			`else
76			`reg [155:0] way0_decc[1023:0] ;`
77			`reg [155:0] way1_decc[1023:0] ;`
78			`endif
79
80			`wire acc_en_d1;`
81			`reg [1:0] way_sel_d1;`
82			`reg [9:0] set_d1;`
83			`reg [3:0] word_en_d1;`
84			`reg wr_en_d1;`
85			`reg [155:0] decc_in_d1;`
86			`reg [155:0] decc_out_d1;`
87			`reg col_offset_d1;`
88
89			`wire [1:0] way_sel_sehold;`
90			`wire [9:0] set_sehold;`
91			`wire [3:0] word_en_sehold;`
92			`wire wr_en_sehold;`
93			`wire [155:0] decc_in_sehold;`
94			`wire col_offset;`
95
96			`wire [155:0] decc_out ;`
97
98			`// JC begin`
99			`// Because of this 2 cycle block,`
100			`// The following codes are just helping me for Innologic verification`
101			`// stop_1_cyc: when col_offset = 1, the next cycle will be ignore`
102			`// keep_rd_out: The output data will be kept for another cycle`
103			`reg keep_rd_out;`
104			`reg stop_1_cyc;`
105			`always @(posedge rclk) begin`
106			`if (col_offset && (\|way_sel_sehold)) begin`
107			`stop_1_cyc <= 1'b1;`
108			`end`
109			`else stop_1_cyc <= 1'b0;`
110			`if (acc_en_d1 & ~wr_en_d1) begin`
111			`keep_rd_out <= 1'b1;`
112			`end`
113			`else keep_rd_out <= 1'b0;`
114			`end`
115			`// JC end`
116
117
118			`assign wr_en_sehold = (sehold) ? wr_en_d1 : ~wr_en_l;`
119			`assign set_sehold = (sehold) ? set_d1 : ~set_l;`
120			`assign way_sel_sehold = (sehold) ? way_sel_d1 : ~way_sel_l;`
121			`assign word_en_sehold = (sehold) ? word_en_d1 : ~word_en_l;`
122			`// In Circuits, we use se to disable write, however, I modified testbench as following`
123			`// to verify write disable:`
124			`// force inno_tb_top.xtor.xcnt.se_l = ~mem_write_disable ;`
125
126			`assign col_offset = (stop_1_cyc \|\| mem_write_disable ) ? (1'b0) : ~col_offset_l ;`
127
128			`assign acc_en_d1 = col_offset_d1 & (\|way_sel_d1);`
129
130			`always @(posedge rclk) begin`
131			`col_offset_d1 <= col_offset;`
132			`way_sel_d1 <= way_sel_sehold;`
133			`set_d1 <= set_sehold;`
134			`word_en_d1 <= word_en_sehold;`
135			`wr_en_d1 <= wr_en_sehold;`
136			`// JC`
137			`// EVEN THOUGH We don't have any write data latch,`
138			`// Our write-data drivers act like latch which gating by`
139			`// Worden signals.`
140			`decc_in_d1 <= ~decc_in_l;`
141			`// JC`
142			`//This is NOT output flops, but we can keep read outs for`
143			`// 2 cycles.`
144			`decc_out_d1 <= decc_out_tmp;`
145			`end`
146
147
148			`ifdef DEFINE_0IN
149			`wire [155:0] decc_out0, decc_out1;`
150
151			`wire [155:0] wm = { {39{word_en_d1[3]}}, {39{word_en_d1[2]}}, {39{word_en_d1[1]}}, {39{word_en_d1[0]}} };`
152			`wire we0 = acc_en_d1 & wr_en_d1 & way_sel_d1[0];`
153			`wire we1 = acc_en_d1 & wr_en_d1 & way_sel_d1[1];`
154
155			`l2data_axis data_array0 (.data_out (decc_out0[155:0]),`
156			`.rclk (rclk),`
157			`.adr (set_d1[9:0]),`
158			`.data_in (decc_in_d1[155:0]),`
159			`.we (we0),`
160			`.wm (wm[155:0]) );`
161			`l2data_axis data_array1 (.data_out (decc_out1[155:0]),`
162			`.rclk (rclk),`
163			`.adr (set_d1[9:0]),`
164			`.data_in (decc_in_d1[155:0]),`
165			`.we (we1),`
166			`.wm (wm[155:0]) );`
167
168			`always @(/AUTOSENSE/acc_en_d1 or decc_in_d1 or decc_out0`
169			`or decc_out1 or way_sel_d1 or word_en_d1 or wr_en_d1) begin`
170			`if (acc_en_d1 & ~wr_en_d1) begin`
171			`//////////////////////////`
172			`// 16 or 64B byte read`
173			`//////////////////////////`
174			`decc_out_tmp = way_sel_d1[0] ? decc_out0[155:0] : decc_out1[155:0];`
175			`end`
176
177			`if (acc_en_d1 & wr_en_d1) begin`
178			`//////////////////////////`
179			`// Store word/dword OR 64B store`
180			`//////////////////////////`
181			`tmp_decc_out = way_sel_d1[0] ? decc_out0[155:0] : decc_out1[155:0];`
182
183			`//////////////////////////////////////`
184			`// Write data based on Word enables.`
185			`//////////////////////////////////////`
186
187			`reg_decc_in[155:117] = (decc_in_d1[155:117] & {39{word_en_d1[3]}} \|`
188			`tmp_decc_out[155:117] & {39{~word_en_d1[3]}});`
189			`reg_decc_in[116:78] = (decc_in_d1[116:78] & {39{word_en_d1[2]}} \|`
190			`tmp_decc_out[116:78] & {39{~word_en_d1[2]}});`
191			`reg_decc_in[77:39] = (decc_in_d1[77:39] & {39{word_en_d1[1]}} \|`
192			`tmp_decc_out[77:39] & {39{~word_en_d1[1]}});`
193			`reg_decc_in[38:0] = (decc_in_d1[38:0] & {39{word_en_d1[0]}} \|`
194			`tmp_decc_out[38:0] & {39{~word_en_d1[0]}});`
195
196			`//////////////////////////////////////////////////////////`
197			`// the store data gets reflected onto the read output bus`
198			`//////////////////////////////////////////////////////////`
199
200			`// decc_out_tmp[155:0] = reg_decc_in[155:0];`
201			`// Store data is not reflected onto the read output bus in the physical implementation`
202			`decc_out_tmp[155:0] = 156'b0;`
203
204			`end // of write operation`
205
206			`if (~acc_en_d1) begin`
207			`// no access`
208			`decc_out_tmp[155:0] = 156'b0;`
209			`end`
210
211			`end // of always block`
212
213			`else
214
215			`always @(/AUTOSENSE/acc_en_d1 or decc_in_d1 or set_d1`
216			`or way_sel_d1 or word_en_d1 or wr_en_d1) begin`
217
218			`ifdef INNO_MUXEX
219			`else
220			`//----- PURELY FOR VERIFICATION -----------------------`
221			`if(wr_en_d1==1'bx) begin`
222			`ifdef MODELSIM
223			`$display("L2_DATA_ERR"," wr en error %b ", wr_en_d1);`
224			`else
225			`$error("L2_DATA_ERR"," wr en error %b ", wr_en_d1);`
226			`endif
227			`end`
228			`//----- PURELY FOR VERIFICATION -----------------------`
229			`endif
230
231
232			`//////////////////`
233			`// MEMORY ACCESS`
234			`//////////////////`
235
236			`if (acc_en_d1) begin`
237
238			`ifdef INNO_MUXEX
239			`else
240			`//----- PURELY FOR VERIFICATION -----------------------`
241			`if(set_d1==10'bx) begin`
242			`ifdef MODELSIM
243			`$error("L2_DATA_ERR"," index error %h ", set_d1[9:0]);`
244			`else
245			`$display("L2_DATA_ERR"," index error %h ", set_d1[9:0]);`
246			`endif
247			`end`
248			`//----- PURELY FOR VERIFICATION -----------------------`
249			`endif
250
251
252			`if (~wr_en_d1) begin`
253			`//////////////////////////`
254			`// 16 or 64B byte read`
255			`//////////////////////////`
256			`decc_out_tmp = way_sel_d1[0] ? way0_decc[set_d1] : way1_decc[set_d1];`
257			`//JC: For keeping data for 2 cycle`
258			`// keep_rd_out = 2'b01;`
259			`end`
260
261			`else begin`
262			`//////////////////////////`
263			`// Store word/dword OR 64B store`
264			`//////////////////////////`
265			`tmp_decc_out = way_sel_d1[0] ? way0_decc[set_d1] : way1_decc[set_d1];`
266
267			`// keep_rd_out = 2'b00;`
268			`//////////////////////////////////////`
269			`// Write data based on Word enables.`
270			`//////////////////////////////////////`
271
272			`reg_decc_in[155:117] = (decc_in_d1[155:117] & {39{word_en_d1[3]}} \|`
273			`tmp_decc_out[155:117] & {39{~word_en_d1[3]}});`
274			`reg_decc_in[116:78] = (decc_in_d1[116:78] & {39{word_en_d1[2]}} \|`
275			`tmp_decc_out[116:78] & {39{~word_en_d1[2]}});`
276			`reg_decc_in[77:39] = (decc_in_d1[77:39] & {39{word_en_d1[1]}} \|`
277			`tmp_decc_out[77:39] & {39{~word_en_d1[1]}});`
278			`reg_decc_in[38:0] = (decc_in_d1[38:0] & {39{word_en_d1[0]}} \|`
279			`tmp_decc_out[38:0] & {39{~word_en_d1[0]}});`
280
281			`if (way_sel_d1[0]) way0_decc[set_d1] = reg_decc_in;`
282			`if (way_sel_d1[1]) way1_decc[set_d1] = reg_decc_in;`
283
284			`//////////////////////////////////////////////////////////`
285			`// the store data gets reflected onto the read output bus`
286			`//////////////////////////////////////////////////////////`
287
288			`// decc_out_tmp[155:0] = reg_decc_in[155:0];`
289			`// Store data is not reflected onto the read output bus in the physical implementation`
290
291			`decc_out_tmp[155:0] = 156'b0;`
292
293			`end // of write operation`
294
295			`end`
296
297			`else begin`
298			`// no access`
299			`decc_out_tmp[155:0] = 156'b0;`
300			`end`
301
302			`end // of always block`
303			`endif
304			`// Modeling wired-OR`
305
306			`// JC we don't have any flop in this level`
307			`// assign decc_out[155:0] = decc_out_d1[155:0] \| decc_read_in[155:0];`
308
309			`assign decc_out[155:0] = (acc_en_d1 & ~wr_en_d1) ? 156'bX : (keep_rd_out) ?`
310			`(decc_out_d1[155:0] \| decc_read_in[155:0]) :`
311			`(decc_out_tmp[155:0] \| decc_read_in[155:0]);`
312
313			`/////////////////////////////////////////////////////////////////////`
314			`// Redundancy Registers`
315			`/////////////////////////////////////////////////////////////////////`
316
317			`reg [8:0] s_red_reg0;`
318			`reg [8:0] s_red_reg1;`
319			`reg [8:0] s_red_reg2;`
320			`reg [8:0] s_red_reg3;`
321			`reg [8:0] s_red_reg4;`
322			`reg [8:0] s_red_reg5;`
323
324			`reg [8:0] m_red_reg0;`
325			`reg [8:0] m_red_reg1;`
326			`reg [8:0] m_red_reg2;`
327			`reg [8:0] m_red_reg3;`
328			`reg [8:0] m_red_reg4;`
329			`reg [8:0] m_red_reg5;`
330
331			`wire l2d_fuse_data_out;`
332
333			`assign l2d_fuse_data_out = s_red_reg5[8];`
334
335			`always @(arst_l or fuse_clk1 or fuse_l2d_rid or fuse_l2d_wren or fuse_l2d_rden`
336			`or fuse_l2d_data_in or fuse_read_data_in`
337			`or s_red_reg0 or s_red_reg1 or s_red_reg2`
338			`or s_red_reg3 or s_red_reg4 or s_red_reg5) begin`
339
340			`if (!arst_l) begin`
341			`m_red_reg0[8:0] = 9'b0;`
342			`m_red_reg1[8:0] = 9'b0;`
343			`m_red_reg2[8:0] = 9'b0;`
344			`m_red_reg3[8:0] = 9'b0;`
345			`m_red_reg4[8:0] = 9'b0;`
346			`m_red_reg5[8:0] = 9'b0;`
347			`end`
348
349			`if (arst_l && fuse_clk1) begin`
350
351			`/////////////////////////////////`
352			`// Write operation`
353			`/////////////////////////////////`
354
355			`if (fuse_l2d_wren) begin`
356			`case (fuse_l2d_rid) //selecting among the six registers`
357			`3'b101: m_red_reg0[8:0] = {s_red_reg0[7:0], fuse_l2d_data_in};// bottom odd row`
358			`3'b011: m_red_reg1[8:0] = {s_red_reg1[7:0], fuse_l2d_data_in};// bottom even row`
359			`3'b010: m_red_reg2[8:0] = {s_red_reg2[7:0], fuse_l2d_data_in};// bottom column`
360			`3'b100: m_red_reg3[8:0] = {s_red_reg3[7:0], fuse_l2d_data_in};// top odd row`
361			`3'b001: m_red_reg4[8:0] = {s_red_reg4[7:0], fuse_l2d_data_in};// top even row`
362			`3'b000: m_red_reg5[8:0] = {s_red_reg5[7:0], fuse_l2d_data_in};// top column`
363			`default: ;`
364			`endcase // case(fuse_l2d_rid)`
365			`end // if (fuse_l2d_wren)`
366
367			`/////////////////////////////////`
368			`// Read operation`
369			`/////////////////////////////////`
370
371			`//JC This is just temporary fix for read operation, rid = 3'b111 will turn on everything`
372			`else if (fuse_l2d_rden) begin`
373			`m_red_reg0[8:0] = {s_red_reg0[7:0], fuse_read_data_in};`
374			`m_red_reg1[8:0] = {s_red_reg1[7:0], s_red_reg0[8]};`
375			`m_red_reg2[8:0] = {s_red_reg2[7:0], s_red_reg1[8]};`
376			`m_red_reg3[8:0] = {s_red_reg3[7:0], s_red_reg2[8]};`
377			`m_red_reg4[8:0] = {s_red_reg4[7:0], s_red_reg3[8]};`
378			`m_red_reg5[8:0] = {s_red_reg5[7:0], s_red_reg4[8]};`
379			`end // if (fuse_l2d_rden)`
380
381			`end // if (fuse_clk1)`
382
383			`end // always @ (fuse_clk1 or...`
384
385			`// always @(posedge efc_scdata_fuse_clk1) begin`
386
387			`always @(arst_l or fuse_clk2 or fuse_l2d_rid or fuse_l2d_wren or fuse_l2d_rden`
388			`or m_red_reg0 or m_red_reg1 or m_red_reg2`
389			`or m_red_reg3 or m_red_reg4 or m_red_reg5) begin`
390
391			`ifdef DEFINE_0IN
392			`else
393			`ifdef FPGA_SYN_RED
394			`else
395			`if (!arst_l) begin`
396			`m_red_reg0[8:0] = 9'b0;`
397			`m_red_reg1[8:0] = 9'b0;`
398			`m_red_reg2[8:0] = 9'b0;`
399			`m_red_reg3[8:0] = 9'b0;`
400			`m_red_reg4[8:0] = 9'b0;`
401			`m_red_reg5[8:0] = 9'b0;`
402			`end`
403			`endif
404			`endif
405
406			`if (fuse_clk2) begin`
407
408			`if (fuse_l2d_wren) begin`
409			`case (fuse_l2d_rid) //selecting among the six registers`
410			`3'b101: s_red_reg0[8:0] = m_red_reg0[8:0];// bottom odd row`
411			`3'b011: s_red_reg1[8:0] = m_red_reg1[8:0];// bottom even row`
412			`3'b010: s_red_reg2[8:0] = m_red_reg2[8:0];// bottom column`
413			`3'b100: s_red_reg3[8:0] = m_red_reg3[8:0];// top odd row`
414			`3'b001: s_red_reg4[8:0] = m_red_reg4[8:0];// top even row`
415			`3'b000: s_red_reg5[8:0] = m_red_reg5[8:0];// top column`
416			`default: ;`
417			`endcase // case(fuse_l2d_rid)`
418			`end // if (fuse_l2d_wren)`
419			`else if (fuse_l2d_rden) begin`
420			`s_red_reg0[8:0] = m_red_reg0[8:0];// bottom odd row`
421			`s_red_reg1[8:0] = m_red_reg1[8:0];// bottom even row`
422			`s_red_reg2[8:0] = m_red_reg2[8:0];// bottom column`
423			`s_red_reg3[8:0] = m_red_reg3[8:0];// top odd row`
424			`s_red_reg4[8:0] = m_red_reg4[8:0];// top even row`
425			`s_red_reg5[8:0] = m_red_reg5[8:0];// top column`
426			`end // if (fuse_l2d_rden)`
427
428			`end // if (fuse_clk2)`
429
430			`end // always @ (fuse_clk2 or...`
431
432			`endmodule // bw_r_l2d_32k`
433