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[/] [async_sdm_noc/] [trunk/] [sdm/] [src/] [sdm_sch.v] - Blame information for rev 63

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1 19 wsong0210
/*
2
 Asynchronous SDM NoC
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 (C)2011 Wei Song
4
 Advanced Processor Technologies Group
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 Computer Science, the Univ. of Manchester, UK
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7
 Authors:
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 Wei Song     wsong83@gmail.com
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10
 License: LGPL 3.0 or later
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12
 Crossbar based SDM switch allocator
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 *** SystemVerilog is used ***
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15
 References
16
 For the detail structure, please refer to Section 6.3.1 of the thesis:
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   Wei Song, Spatial parallelism in the routers of asynchronous on-chip networks, PhD thesis, the University of Manchester, 2011.
18
 
19
 History:
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 28/09/2009  Initial version. <wsong83@gmail.com>
21 28 wsong0210
 27/05/2011  Clean up for opensource. <wsong83@gmail.com>
22 19 wsong0210
 
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*/
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// the router structure definitions
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`include "define.v"
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module sdm_sch (/*AUTOARG*/
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   // Outputs
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   sack, wack, nack, eack, lack, scfg, ncfg, wcfg, ecfg, lcfg,
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   // Inputs
32 28 wsong0210
   sreq, nreq, lreq, wreq, ereq, rst_n
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   );
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   parameter VCN = 2;           // the number of virtual circuits per port
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   // income requests
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   input [VCN-1:0][3:0]            sreq, nreq, lreq;
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   input [VCN-1:0][1:0]      wreq, ereq;
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   // ack to input buffers
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   output [VCN-1:0]                 sack, wack, nack, eack, lack;
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   // configuration to the crossbar
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   output [VCN-1:0][1:0][VCN-1:0]  scfg, ncfg;
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   output [VCN-1:0][3:0][VCN-1:0]  wcfg, ecfg, lcfg;
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48
   input                           rst_n; // active low global reset
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   // requests to arbiters
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`ifndef ENABLE_MRMA
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   wire [1:0][VCN-1:0][VCN-1:0]    r2s, r2n; // shuffle the incoming request signals
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   wire [3:0][VCN-1:0][VCN-1:0]    r2w, r2e, r2l;
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`else
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   wire [1:0][VCN-1:0]               r2s, r2n; // shuffle the incoming request signals
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   wire [3:0][VCN-1:0]               r2w, r2e, r2l;
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`endif
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   // ack from arbiters
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   wire [VCN-1:0][3:0]               a2s, a2n, a2l;
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   wire [VCN-1:0][1:0]               a2w, a2e;
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   // ack of the arbiters
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   wire [1:0][VCN-1:0]               r2sa, r2na;
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   wire [3:0][VCN-1:0]               r2wa, r2ea, r2la;
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67
`ifdef ENABLE_MRMA
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   wire [VCN:0]             OPrst_n; // the buffered resets to avoid metastability
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   wire [VCN-1:0]                   SOPrdy, SOPblk; // OP ready and blocked status
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   wire [VCN-1:0]                   WOPrdy, WOPblk; // OP ready and blocked status
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   wire [VCN-1:0]                   NOPrdy, NOPblk; // OP ready and blocked status
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   wire [VCN-1:0]                   EOPrdy, EOPblk; // OP ready and blocked status
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   wire [VCN-1:0]                   LOPrdy, LOPblk; // OP ready and blocked status
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`endif
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76
   genvar                          i,j;
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   // wire shuffle
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   generate for(i=0; i<VCN; i++) begin: SHUF
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`ifndef ENABLE_MRMA
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      for(j=0; j<VCN; j++) begin: CO
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         assign r2s[0][i][j] = nreq[i][0];
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         assign r2s[1][i][j] = lreq[i][0];
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         assign r2w[0][i][j] = sreq[i][0];
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         assign r2w[1][i][j] = nreq[i][1];
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         assign r2w[2][i][j] = ereq[i][0];
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         assign r2w[3][i][j] = lreq[i][1];
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         assign r2n[0][i][j] = sreq[i][1];
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         assign r2n[1][i][j] = lreq[i][2];
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         assign r2e[0][i][j] = sreq[i][2];
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         assign r2e[1][i][j] = wreq[i][0];
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         assign r2e[2][i][j] = nreq[i][2];
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         assign r2e[3][i][j] = lreq[i][3];
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         assign r2l[0][i][j] = sreq[i][3];
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         assign r2l[1][i][j] = wreq[i][1];
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         assign r2l[2][i][j] = nreq[i][3];
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         assign r2l[3][i][j] = ereq[i][1];
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      end // block: CO
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`else // !`ifndef ENABLE_MRMA
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      assign r2s[0][i] = nreq[i][0];
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      assign r2s[1][i] = lreq[i][0];
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      assign r2w[0][i] = sreq[i][0];
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      assign r2w[1][i] = nreq[i][1];
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      assign r2w[2][i] = ereq[i][0];
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      assign r2w[3][i] = lreq[i][1];
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      assign r2n[0][i] = sreq[i][1];
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      assign r2n[1][i] = lreq[i][2];
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      assign r2e[0][i] = sreq[i][2];
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      assign r2e[1][i] = wreq[i][0];
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      assign r2e[2][i] = nreq[i][2];
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      assign r2e[3][i] = lreq[i][3];
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      assign r2l[0][i] = sreq[i][3];
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      assign r2l[1][i] = wreq[i][1];
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      assign r2l[2][i] = nreq[i][3];
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      assign r2l[3][i] = ereq[i][1];
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`endif // !`ifndef ENABLE_MRMA
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      assign a2s[i][0] = r2wa[0][i];
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      assign a2s[i][1] = r2na[0][i];
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      assign a2s[i][2] = r2ea[0][i];
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      assign a2s[i][3] = r2la[0][i];
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      assign a2w[i][0] = r2ea[1][i];
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      assign a2w[i][1] = r2la[1][i];
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      assign a2n[i][0] = r2sa[0][i];
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      assign a2n[i][1] = r2wa[1][i];
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      assign a2n[i][2] = r2ea[2][i];
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      assign a2n[i][3] = r2la[2][i];
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      assign a2e[i][0] = r2wa[2][i];
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      assign a2e[i][1] = r2la[3][i];
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      assign a2l[i][0] = r2sa[1][i];
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      assign a2l[i][1] = r2wa[3][i];
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      assign a2l[i][2] = r2na[1][i];
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      assign a2l[i][3] = r2ea[3][i];
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      assign sack[i] = |a2s[i];
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      assign wack[i] = |a2w[i];
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      assign nack[i] = |a2n[i];
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      assign eack[i] = |a2e[i];
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      assign lack[i] = |a2l[i];
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139
   end // block: SHUF
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   endgenerate
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   // output port arbiter/allocators
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`ifndef ENABLE_MRMA
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   mnma #(.N(2*VCN), .M(VCN))
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   SCBA (
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         .r     ( r2s    ),
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         .ra    ( r2sa   ),
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         .cfg   ( scfg   )
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         );
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   mnma #(.N(4*VCN), .M(VCN))
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   WCBA (
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         .r     ( r2w    ),
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         .ra    ( r2wa   ),
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         .cfg   ( wcfg   )
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         );
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158
   mnma #(.N(2*VCN), .M(VCN))
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   NCBA (
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         .r     ( r2n    ),
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         .ra    ( r2na   ),
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         .cfg   ( ncfg   )
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         );
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   mnma #(.N(4*VCN), .M(VCN))
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   ECBA (
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         .r     ( r2e    ),
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         .ra    ( r2ea   ),
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         .cfg   ( ecfg   )
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         );
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   mnma #(.N(4*VCN), .M(VCN))
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   LCBA (
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         .r     ( r2l    ),
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         .ra    ( r2la   ),
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         .cfg   ( lcfg   )
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         );
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`else // !`ifndef ENABLE_MRMA
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   mrma #(.N(2*VCN), .M(VCN))
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   SCBA (
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         .ca    ( r2sa   ),
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         .ra    ( SOPblk ),
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         .cfg   ( scfg   ),
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         .c     ( r2s    ),
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         .r     ( SOPrdy ),
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         .rst_n ( rst_n  )
187
         );
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   mrma #(.N(4*VCN), .M(VCN))
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   WCBA (
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         .ca    ( r2wa   ),
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         .ra    ( WOPblk ),
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         .cfg   ( wcfg   ),
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         .c     ( r2w    ),
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         .r     ( WOPrdy ),
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         .rst_n ( rst_n  )
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         );
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   mrma #(.N(2*VCN), .M(VCN))
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   NCBA (
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         .ca    ( r2na   ),
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         .ra    ( NOPblk ),
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         .cfg   ( ncfg   ),
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         .c     ( r2n    ),
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         .r     ( NOPrdy ),
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         .rst_n ( rst_n  )
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         );
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209
   mrma #(.N(4*VCN), .M(VCN))
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   ECBA (
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         .ca    ( r2ea   ),
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         .ra    ( EOPblk ),
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         .cfg   ( ecfg   ),
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         .c     ( r2e    ),
215
         .r     ( EOPrdy ),
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         .rst_n ( rst_n  )
217
         );
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219
   mrma #(.N(4*VCN), .M(VCN))
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   LCBA (
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         .ca    ( r2la   ),
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         .ra    ( LOPblk ),
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         .cfg   ( lcfg   ),
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         .c     ( r2l    ),
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         .r     ( LOPrdy ),
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         .rst_n ( rst_n  )
227
         );
228
 
229
   generate
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      for(i=0; i<VCN; i++) begin: OPC
231
         delay DLY ( .q(OPrst_n[i+1]), .a(OPrst_n[i])); // dont touch
232 28 wsong0210
         assign SOPrdy[i] = (~SOPblk[i])&OPrst_n[i+1];
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         assign WOPrdy[i] = (~WOPblk[i])&OPrst_n[i+1];
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         assign NOPrdy[i] = (~NOPblk[i])&OPrst_n[i+1];
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         assign EOPrdy[i] = (~EOPblk[i])&OPrst_n[i+1];
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         assign LOPrdy[i] = (~LOPblk[i])&OPrst_n[i+1];
237 19 wsong0210
      end
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   endgenerate
239 28 wsong0210
 
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   assign OPrst_n[0] = rst_n;
241 19 wsong0210
 
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`endif // !`ifndef ENABLE_MRMA
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endmodule // sdm_sch

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