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[/] [sparc64soc/] [trunk/] [T1-CPU/] [exu/] [sparc_exu_eclccr.v] - Blame information for rev 2

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// ========== Copyright Header Begin ==========================================
// 
// OpenSPARC T1 Processor File: sparc_exu_eclccr.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 ============================================
////////////////////////////////////////////////////////////////////////
/*
//  Module Name: sparc_exu_eclccr
//      Description: 4 bit condition code registers with forwarding.  Takes
//      the e_stage result and writes on the w stage.
*/
 
module sparc_exu_eclccr (/*AUTOARG*/
   // Outputs
   exu_ifu_cc_d, exu_tlu_ccr0_w, exu_tlu_ccr1_w, exu_tlu_ccr2_w,
   exu_tlu_ccr3_w,
   // Inputs
   clk, se, alu_xcc_e, alu_icc_e, tid_d, thrdec_d, thr_match_dm,
   thr_match_de, tid_w, thr_w, ifu_exu_kill_e, ifu_exu_setcc_d,
   byp_ecl_wrccr_data_w, wb_ccr_wrccr_w, wb_ccr_setcc_g,
   divcntl_ccr_cc_w2, wb_ccr_thr_g, tlu_exu_cwpccr_update_m,
   tlu_exu_ccr_m, ifu_exu_inst_vld_w, ifu_tlu_flush_w, early_flush_w
   ) ;
   input clk;
   input se;
   input [3:0] alu_xcc_e;    // condition codes from the alu
   input [3:0] alu_icc_e;
   input [1:0] tid_d;   // thread for each stage
   input [3:0] thrdec_d;   // decoded tid_d for mux select
   input       thr_match_dm;
   input       thr_match_de;
   input [1:0] tid_w;
   input [3:0] thr_w;        // decoded tid_w
   input       ifu_exu_kill_e;
   input       ifu_exu_setcc_d;
   input [7:0] byp_ecl_wrccr_data_w;// for the WRCCR operation (LSBs of
   input       wb_ccr_wrccr_w; // ALU result) + wen signal
   input       wb_ccr_setcc_g;
   input [7:0] divcntl_ccr_cc_w2;
   input [1:0] wb_ccr_thr_g;
   input       tlu_exu_cwpccr_update_m;
   input [7:0] tlu_exu_ccr_m;
   input       ifu_exu_inst_vld_w;
   input       ifu_tlu_flush_w;
   input       early_flush_w;
 
   output [7:0] exu_ifu_cc_d;   // condition codes for current thread
   output [7:0] exu_tlu_ccr0_w;
   output [7:0] exu_tlu_ccr1_w;
   output [7:0] exu_tlu_ccr2_w;
   output [7:0] exu_tlu_ccr3_w;
 
   wire [7:0]   partial_cc_d;   // partial bypassed ccr
   wire [7:0]   alu_cc_e;   // alu combined condition codes
   wire [7:0]   alu_cc_m;   // m stage alu ccs
   wire [7:0]   alu_cc_w;
   wire [7:0]   exu_ifu_cc_w;   // writeback data
   wire         setcc_e;        // from previous stage
   wire         setcc_m;
   wire         setcc_w;
   wire         valid_setcc_e;  // after comparing with kill
   wire         valid_setcc_m;
   wire         valid_setcc_w;
   wire         setcc_w2;
   wire [7:0]   ccrin_thr0;
   wire [7:0]   ccrin_thr1;
   wire [7:0]   ccrin_thr2;
   wire [7:0]   ccrin_thr3;
   wire [7:0]   ccr_d;
   wire [7:0]   ccr_thr0;
   wire [7:0]   ccr_thr1;
   wire [7:0]   ccr_thr2;
   wire [7:0]   ccr_thr3;
   wire         use_alu_cc;
   wire         use_ccr;
   wire         use_cc_e;
   wire         use_cc_m;
   wire         use_cc_w;
   wire  [1:0]   tid_dxorw;
   wire         thr_match_de;
   wire         thrmatch_w;
   wire [1:0]   thr_w2;
   wire          thr0_w2;
   wire          thr1_w2;
   wire          thr2_w2;
   wire          thr3_w2;
   wire          wen_thr0_w;    // write enable for each input/thread
   wire          wen_thr0_w2;
   wire          wen_thr1_w;
   wire          wen_thr1_w2;
   wire          wen_thr2_w;
   wire          wen_thr2_w2;
   wire          wen_thr3_w;
   wire          wen_thr3_w2;
   wire          wen_thr0_l;      // overall write enable for each thread
   wire          wen_thr1_l;
   wire          wen_thr2_l;
   wire          wen_thr3_l;
   wire          bypass_cc_w;
 
   wire [7:0]    ccr_m;
 
 
   // D2E flops
   dff_s dff_setcc_d2e(.din(ifu_exu_setcc_d), .clk(clk), .q(setcc_e),
                     .se(se), .si(), .so());
 
   // E stage
   assign       alu_cc_e = {alu_xcc_e, alu_icc_e};
   assign       valid_setcc_e = setcc_e & ~ifu_exu_kill_e;
 
   dff_s #(8) dff_cc_e2m(.din(alu_cc_e[7:0]), .clk(clk), .q(alu_cc_m[7:0]),
                  .se(se), .si(), .so());
   dff_s dff_setcc_e2m(.din(valid_setcc_e), .clk(clk), .q(setcc_m),
                     .se(se), .si(), .so());
 
   // M stage
   assign       valid_setcc_m = setcc_m | tlu_exu_cwpccr_update_m;
   mux2ds #(8) mux_ccr_m(.dout(ccr_m[7:0]),
                            .in0(alu_cc_m[7:0]),
                            .in1(tlu_exu_ccr_m[7:0]),
                            .sel0(~tlu_exu_cwpccr_update_m),
                            .sel1(tlu_exu_cwpccr_update_m));
 
   dff_s #(8) dff_cc_m2w(.din(ccr_m[7:0]), .clk(clk), .q(alu_cc_w[7:0]),
                  .se(se), .si(), .so());
   dff_s dff_setcc_m2w(.din(valid_setcc_m), .clk(clk), .q(setcc_w),
                     .se(se), .si(), .so());
 
   // W stage
   assign bypass_cc_w = ifu_exu_inst_vld_w & setcc_w;
   assign valid_setcc_w = ~ifu_tlu_flush_w & ~early_flush_w & ifu_exu_inst_vld_w & (setcc_w | wb_ccr_wrccr_w);
 
   // mux with wrccr
   assign        use_alu_cc = ~(wb_ccr_wrccr_w);
   mux2ds #(8) mux_ccrin_cc(.dout(exu_ifu_cc_w[7:0]), .sel0(wb_ccr_wrccr_w),
                          .sel1(use_alu_cc),
                          .in0(byp_ecl_wrccr_data_w[7:0]),
                          .in1(alu_cc_w[7:0]));
 
   dff_s #(3) setcc_g2w2 (.din({wb_ccr_setcc_g, wb_ccr_thr_g[1:0]}), .clk(clk),
                        .q({setcc_w2, thr_w2[1:0]}),
                        .se(se), .si(), .so());
 
 
   /////////////////////////
   // Storage of ccr
   /////////////////////////
`ifdef FPGA_SYN_1THREAD
 
   assign          thr0_w2 = ~thr_w2[1] & ~thr_w2[0];
   assign          wen_thr0_w = (thr_w[0] & valid_setcc_w & ~wen_thr0_w2);
   assign          wen_thr0_w2 = thr0_w2 & setcc_w2;
   assign          wen_thr0_l = ~(wen_thr0_w | wen_thr0_w2);
   // mux between cc_w, cc_w2, old value, tlu value
   mux3ds #(8) mux_ccrin0(.dout(ccrin_thr0[7:0]), .sel0(wen_thr0_w),
                          .sel1(wen_thr0_w2), .sel2(wen_thr0_l),
                          .in0(exu_ifu_cc_w[7:0]),
                          .in1(divcntl_ccr_cc_w2[7:0]), .in2(ccr_thr0[7:0]));
   // store new value
   dff_s #(8) dff_ccr_thr0(.din(ccrin_thr0[7:0]), .clk(clk), .q(ccr_thr0[7:0]),
                       .se(se), .si(), .so());
   assign          ccr_d[7:0] = ccr_thr0[7:0];
 
`else // !`ifdef FPGA_SYN_1THREAD
 
   // decode thr_w2 for mux select
   assign        thr0_w2 = ~thr_w2[1] & ~thr_w2[0];
   assign        thr1_w2 = ~thr_w2[1] & thr_w2[0];
   assign        thr2_w2 = thr_w2[1] & ~thr_w2[0];
   assign        thr3_w2 = thr_w2[1] & thr_w2[0];
   // enable input for each thread
   assign        wen_thr0_w = (thr_w[0] & valid_setcc_w & ~wen_thr0_w2);
   assign        wen_thr0_w2 = thr0_w2 & setcc_w2;
   assign        wen_thr0_l = ~(wen_thr0_w | wen_thr0_w2);
   assign        wen_thr1_w = (thr_w[1] & valid_setcc_w & ~wen_thr1_w2);
   assign        wen_thr1_w2 = (thr1_w2 & setcc_w2);
   assign        wen_thr1_l = ~(wen_thr1_w | wen_thr1_w2);
   assign        wen_thr2_w = (thr_w[2] & valid_setcc_w & ~wen_thr2_w2);
   assign        wen_thr2_w2 = (thr2_w2 & setcc_w2);
   assign        wen_thr2_l = ~(wen_thr2_w | wen_thr2_w2);
   assign        wen_thr3_w = (thr_w[3] & valid_setcc_w & ~wen_thr3_w2);
   assign        wen_thr3_w2 = (thr3_w2 & setcc_w2);
   assign        wen_thr3_l = ~(wen_thr3_w | wen_thr3_w2);
 
   // mux between cc_w, cc_w2, old value, tlu value
   mux3ds #(8) mux_ccrin0(.dout(ccrin_thr0[7:0]), .sel0(wen_thr0_w),
                          .sel1(wen_thr0_w2), .sel2(wen_thr0_l),
                          .in0(exu_ifu_cc_w[7:0]),
                          .in1(divcntl_ccr_cc_w2[7:0]), .in2(ccr_thr0[7:0]));
   mux3ds #(8) mux_ccrin1(.dout(ccrin_thr1[7:0]), .sel0(wen_thr1_w),
                          .sel1(wen_thr1_w2), .sel2(wen_thr1_l),
                          .in0(exu_ifu_cc_w[7:0]),
                          .in1(divcntl_ccr_cc_w2[7:0]), .in2(ccr_thr1[7:0]));
   mux3ds #(8) mux_ccrin2(.dout(ccrin_thr2[7:0]), .sel0(wen_thr2_w),
                          .sel1(wen_thr2_w2), .sel2(wen_thr2_l),
                          .in0(exu_ifu_cc_w[7:0]),
                          .in1(divcntl_ccr_cc_w2[7:0]), .in2(ccr_thr2[7:0]));
   mux3ds #(8) mux_ccrin3(.dout(ccrin_thr3[7:0]), .sel0(wen_thr3_w),
                          .sel1(wen_thr3_w2), .sel2(wen_thr3_l),
                          .in0(exu_ifu_cc_w[7:0]),
                          .in1(divcntl_ccr_cc_w2[7:0]), .in2(ccr_thr3[7:0]));
 
   // store new value
   dff_s #(8) dff_ccr_thr0(.din(ccrin_thr0[7:0]), .clk(clk), .q(ccr_thr0[7:0]),
                       .se(se), .si(), .so());
   dff_s #(8) dff_ccr_thr1(.din(ccrin_thr1[7:0]), .clk(clk), .q(ccr_thr1[7:0]),
                       .se(se), .si(), .so());
   dff_s #(8) dff_ccr_thr2(.din(ccrin_thr2[7:0]), .clk(clk), .q(ccr_thr2[7:0]),
                       .se(se), .si(), .so());
   dff_s #(8) dff_ccr_thr3(.din(ccrin_thr3[7:0]), .clk(clk), .q(ccr_thr3[7:0]),
                       .se(se), .si(), .so());
 
 
   // mux between the 4 sets of ccrs
   mux4ds #(8) mux_ccr_out(.dout(ccr_d[7:0]), .sel0(thrdec_d[0]),
                         .sel1(thrdec_d[1]), .sel2(thrdec_d[2]),
                         .sel3(thrdec_d[3]), .in0(ccr_thr0[7:0]),
                         .in1(ccr_thr1[7:0]), .in2(ccr_thr2[7:0]),
                         .in3(ccr_thr3[7:0]));
`endif // !`ifdef FPGA_SYN_1THREAD
 
   // bypass the ccs to the output.  Only alu result needs to be bypassed
   assign        exu_ifu_cc_d[7:0] = (use_cc_e)? alu_cc_e[7:0]: partial_cc_d[7:0];
   mux3ds #(8) mux_ccr_bypass1(.dout(partial_cc_d[7:0]),
                               .sel0(use_ccr),
                               .sel1(use_cc_m),
                               .sel2(use_cc_w),
                               .in0(ccr_d[7:0]),
                               .in1(alu_cc_m[7:0]),
                               .in2(alu_cc_w[7:0]));
 
   assign        use_cc_e = valid_setcc_e & thr_match_de;
   assign        use_cc_m = setcc_m & thr_match_dm;
   assign        use_cc_w = bypass_cc_w & thrmatch_w & ~use_cc_m;
   assign        use_ccr = ~(use_cc_m | use_cc_w);
 
   assign        tid_dxorw = tid_w ^ tid_d;
 
   assign        thrmatch_w = ~(tid_dxorw[1] | tid_dxorw[0]);
 
   // generate ccr_w for the tlu
   assign        exu_tlu_ccr0_w[7:0] = ccr_thr0[7:0];
   assign        exu_tlu_ccr1_w[7:0] = ccr_thr1[7:0];
   assign        exu_tlu_ccr2_w[7:0] = ccr_thr2[7:0];
   assign        exu_tlu_ccr3_w[7:0] = ccr_thr3[7:0];
 
 
endmodule // sparc_exu_eclccr

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[/] [sparc64soc/] [trunk/] [T1-CPU/] [exu/] [sparc_exu_eclccr.v] - Blame information for rev 2

Line No.	Rev	Author	Line
1	2	dmitryr	`// ========== Copyright Header Begin ==========================================`
2			`//`
3			`// OpenSPARC T1 Processor File: sparc_exu_eclccr.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			`////////////////////////////////////////////////////////////////////////`
22			`/*`
23			`// Module Name: sparc_exu_eclccr`
24			`// Description: 4 bit condition code registers with forwarding. Takes`
25			`// the e_stage result and writes on the w stage.`
26			`*/`
27
28			`module sparc_exu_eclccr (/AUTOARG/`
29			`// Outputs`
30			`exu_ifu_cc_d, exu_tlu_ccr0_w, exu_tlu_ccr1_w, exu_tlu_ccr2_w,`
31			`exu_tlu_ccr3_w,`
32			`// Inputs`
33			`clk, se, alu_xcc_e, alu_icc_e, tid_d, thrdec_d, thr_match_dm,`
34			`thr_match_de, tid_w, thr_w, ifu_exu_kill_e, ifu_exu_setcc_d,`
35			`byp_ecl_wrccr_data_w, wb_ccr_wrccr_w, wb_ccr_setcc_g,`
36			`divcntl_ccr_cc_w2, wb_ccr_thr_g, tlu_exu_cwpccr_update_m,`
37			`tlu_exu_ccr_m, ifu_exu_inst_vld_w, ifu_tlu_flush_w, early_flush_w`
38			`) ;`
39			`input clk;`
40			`input se;`
41			`input [3:0] alu_xcc_e; // condition codes from the alu`
42			`input [3:0] alu_icc_e;`
43			`input [1:0] tid_d; // thread for each stage`
44			`input [3:0] thrdec_d; // decoded tid_d for mux select`
45			`input thr_match_dm;`
46			`input thr_match_de;`
47			`input [1:0] tid_w;`
48			`input [3:0] thr_w; // decoded tid_w`
49			`input ifu_exu_kill_e;`
50			`input ifu_exu_setcc_d;`
51			`input [7:0] byp_ecl_wrccr_data_w;// for the WRCCR operation (LSBs of`
52			`input wb_ccr_wrccr_w; // ALU result) + wen signal`
53			`input wb_ccr_setcc_g;`
54			`input [7:0] divcntl_ccr_cc_w2;`
55			`input [1:0] wb_ccr_thr_g;`
56			`input tlu_exu_cwpccr_update_m;`
57			`input [7:0] tlu_exu_ccr_m;`
58			`input ifu_exu_inst_vld_w;`
59			`input ifu_tlu_flush_w;`
60			`input early_flush_w;`
61
62			`output [7:0] exu_ifu_cc_d; // condition codes for current thread`
63			`output [7:0] exu_tlu_ccr0_w;`
64			`output [7:0] exu_tlu_ccr1_w;`
65			`output [7:0] exu_tlu_ccr2_w;`
66			`output [7:0] exu_tlu_ccr3_w;`
67
68			`wire [7:0] partial_cc_d; // partial bypassed ccr`
69			`wire [7:0] alu_cc_e; // alu combined condition codes`
70			`wire [7:0] alu_cc_m; // m stage alu ccs`
71			`wire [7:0] alu_cc_w;`
72			`wire [7:0] exu_ifu_cc_w; // writeback data`
73			`wire setcc_e; // from previous stage`
74			`wire setcc_m;`
75			`wire setcc_w;`
76			`wire valid_setcc_e; // after comparing with kill`
77			`wire valid_setcc_m;`
78			`wire valid_setcc_w;`
79			`wire setcc_w2;`
80			`wire [7:0] ccrin_thr0;`
81			`wire [7:0] ccrin_thr1;`
82			`wire [7:0] ccrin_thr2;`
83			`wire [7:0] ccrin_thr3;`
84			`wire [7:0] ccr_d;`
85			`wire [7:0] ccr_thr0;`
86			`wire [7:0] ccr_thr1;`
87			`wire [7:0] ccr_thr2;`
88			`wire [7:0] ccr_thr3;`
89			`wire use_alu_cc;`
90			`wire use_ccr;`
91			`wire use_cc_e;`
92			`wire use_cc_m;`
93			`wire use_cc_w;`
94			`wire [1:0] tid_dxorw;`
95			`wire thr_match_de;`
96			`wire thrmatch_w;`
97			`wire [1:0] thr_w2;`
98			`wire thr0_w2;`
99			`wire thr1_w2;`
100			`wire thr2_w2;`
101			`wire thr3_w2;`
102			`wire wen_thr0_w; // write enable for each input/thread`
103			`wire wen_thr0_w2;`
104			`wire wen_thr1_w;`
105			`wire wen_thr1_w2;`
106			`wire wen_thr2_w;`
107			`wire wen_thr2_w2;`
108			`wire wen_thr3_w;`
109			`wire wen_thr3_w2;`
110			`wire wen_thr0_l; // overall write enable for each thread`
111			`wire wen_thr1_l;`
112			`wire wen_thr2_l;`
113			`wire wen_thr3_l;`
114			`wire bypass_cc_w;`
115
116			`wire [7:0] ccr_m;`
117
118
119			`// D2E flops`
120			`dff_s dff_setcc_d2e(.din(ifu_exu_setcc_d), .clk(clk), .q(setcc_e),`
121			`.se(se), .si(), .so());`
122
123			`// E stage`
124			`assign alu_cc_e = {alu_xcc_e, alu_icc_e};`
125			`assign valid_setcc_e = setcc_e & ~ifu_exu_kill_e;`
126
127			`dff_s #(8) dff_cc_e2m(.din(alu_cc_e[7:0]), .clk(clk), .q(alu_cc_m[7:0]),`
128			`.se(se), .si(), .so());`
129			`dff_s dff_setcc_e2m(.din(valid_setcc_e), .clk(clk), .q(setcc_m),`
130			`.se(se), .si(), .so());`
131
132			`// M stage`
133			`assign valid_setcc_m = setcc_m \| tlu_exu_cwpccr_update_m;`
134			`mux2ds #(8) mux_ccr_m(.dout(ccr_m[7:0]),`
135			`.in0(alu_cc_m[7:0]),`
136			`.in1(tlu_exu_ccr_m[7:0]),`
137			`.sel0(~tlu_exu_cwpccr_update_m),`
138			`.sel1(tlu_exu_cwpccr_update_m));`
139
140			`dff_s #(8) dff_cc_m2w(.din(ccr_m[7:0]), .clk(clk), .q(alu_cc_w[7:0]),`
141			`.se(se), .si(), .so());`
142			`dff_s dff_setcc_m2w(.din(valid_setcc_m), .clk(clk), .q(setcc_w),`
143			`.se(se), .si(), .so());`
144
145			`// W stage`
146			`assign bypass_cc_w = ifu_exu_inst_vld_w & setcc_w;`
147			`assign valid_setcc_w = ~ifu_tlu_flush_w & ~early_flush_w & ifu_exu_inst_vld_w & (setcc_w \| wb_ccr_wrccr_w);`
148
149			`// mux with wrccr`
150			`assign use_alu_cc = ~(wb_ccr_wrccr_w);`
151			`mux2ds #(8) mux_ccrin_cc(.dout(exu_ifu_cc_w[7:0]), .sel0(wb_ccr_wrccr_w),`
152			`.sel1(use_alu_cc),`
153			`.in0(byp_ecl_wrccr_data_w[7:0]),`
154			`.in1(alu_cc_w[7:0]));`
155
156			`dff_s #(3) setcc_g2w2 (.din({wb_ccr_setcc_g, wb_ccr_thr_g[1:0]}), .clk(clk),`
157			`.q({setcc_w2, thr_w2[1:0]}),`
158			`.se(se), .si(), .so());`
159
160
161			`/////////////////////////`
162			`// Storage of ccr`
163			`/////////////////////////`
164			`ifdef FPGA_SYN_1THREAD
165
166			`assign thr0_w2 = ~thr_w2[1] & ~thr_w2[0];`
167			`assign wen_thr0_w = (thr_w[0] & valid_setcc_w & ~wen_thr0_w2);`
168			`assign wen_thr0_w2 = thr0_w2 & setcc_w2;`
169			`assign wen_thr0_l = ~(wen_thr0_w \| wen_thr0_w2);`
170			`// mux between cc_w, cc_w2, old value, tlu value`
171			`mux3ds #(8) mux_ccrin0(.dout(ccrin_thr0[7:0]), .sel0(wen_thr0_w),`
172			`.sel1(wen_thr0_w2), .sel2(wen_thr0_l),`
173			`.in0(exu_ifu_cc_w[7:0]),`
174			`.in1(divcntl_ccr_cc_w2[7:0]), .in2(ccr_thr0[7:0]));`
175			`// store new value`
176			`dff_s #(8) dff_ccr_thr0(.din(ccrin_thr0[7:0]), .clk(clk), .q(ccr_thr0[7:0]),`
177			`.se(se), .si(), .so());`
178			`assign ccr_d[7:0] = ccr_thr0[7:0];`
179
180			`else // !`ifdef FPGA_SYN_1THREAD
181
182			`// decode thr_w2 for mux select`
183			`assign thr0_w2 = ~thr_w2[1] & ~thr_w2[0];`
184			`assign thr1_w2 = ~thr_w2[1] & thr_w2[0];`
185			`assign thr2_w2 = thr_w2[1] & ~thr_w2[0];`
186			`assign thr3_w2 = thr_w2[1] & thr_w2[0];`
187			`// enable input for each thread`
188			`assign wen_thr0_w = (thr_w[0] & valid_setcc_w & ~wen_thr0_w2);`
189			`assign wen_thr0_w2 = thr0_w2 & setcc_w2;`
190			`assign wen_thr0_l = ~(wen_thr0_w \| wen_thr0_w2);`
191			`assign wen_thr1_w = (thr_w[1] & valid_setcc_w & ~wen_thr1_w2);`
192			`assign wen_thr1_w2 = (thr1_w2 & setcc_w2);`
193			`assign wen_thr1_l = ~(wen_thr1_w \| wen_thr1_w2);`
194			`assign wen_thr2_w = (thr_w[2] & valid_setcc_w & ~wen_thr2_w2);`
195			`assign wen_thr2_w2 = (thr2_w2 & setcc_w2);`
196			`assign wen_thr2_l = ~(wen_thr2_w \| wen_thr2_w2);`
197			`assign wen_thr3_w = (thr_w[3] & valid_setcc_w & ~wen_thr3_w2);`
198			`assign wen_thr3_w2 = (thr3_w2 & setcc_w2);`
199			`assign wen_thr3_l = ~(wen_thr3_w \| wen_thr3_w2);`
200
201			`// mux between cc_w, cc_w2, old value, tlu value`
202			`mux3ds #(8) mux_ccrin0(.dout(ccrin_thr0[7:0]), .sel0(wen_thr0_w),`
203			`.sel1(wen_thr0_w2), .sel2(wen_thr0_l),`
204			`.in0(exu_ifu_cc_w[7:0]),`
205			`.in1(divcntl_ccr_cc_w2[7:0]), .in2(ccr_thr0[7:0]));`
206			`mux3ds #(8) mux_ccrin1(.dout(ccrin_thr1[7:0]), .sel0(wen_thr1_w),`
207			`.sel1(wen_thr1_w2), .sel2(wen_thr1_l),`
208			`.in0(exu_ifu_cc_w[7:0]),`
209			`.in1(divcntl_ccr_cc_w2[7:0]), .in2(ccr_thr1[7:0]));`
210			`mux3ds #(8) mux_ccrin2(.dout(ccrin_thr2[7:0]), .sel0(wen_thr2_w),`
211			`.sel1(wen_thr2_w2), .sel2(wen_thr2_l),`
212			`.in0(exu_ifu_cc_w[7:0]),`
213			`.in1(divcntl_ccr_cc_w2[7:0]), .in2(ccr_thr2[7:0]));`
214			`mux3ds #(8) mux_ccrin3(.dout(ccrin_thr3[7:0]), .sel0(wen_thr3_w),`
215			`.sel1(wen_thr3_w2), .sel2(wen_thr3_l),`
216			`.in0(exu_ifu_cc_w[7:0]),`
217			`.in1(divcntl_ccr_cc_w2[7:0]), .in2(ccr_thr3[7:0]));`
218
219			`// store new value`
220			`dff_s #(8) dff_ccr_thr0(.din(ccrin_thr0[7:0]), .clk(clk), .q(ccr_thr0[7:0]),`
221			`.se(se), .si(), .so());`
222			`dff_s #(8) dff_ccr_thr1(.din(ccrin_thr1[7:0]), .clk(clk), .q(ccr_thr1[7:0]),`
223			`.se(se), .si(), .so());`
224			`dff_s #(8) dff_ccr_thr2(.din(ccrin_thr2[7:0]), .clk(clk), .q(ccr_thr2[7:0]),`
225			`.se(se), .si(), .so());`
226			`dff_s #(8) dff_ccr_thr3(.din(ccrin_thr3[7:0]), .clk(clk), .q(ccr_thr3[7:0]),`
227			`.se(se), .si(), .so());`
228
229
230			`// mux between the 4 sets of ccrs`
231			`mux4ds #(8) mux_ccr_out(.dout(ccr_d[7:0]), .sel0(thrdec_d[0]),`
232			`.sel1(thrdec_d[1]), .sel2(thrdec_d[2]),`
233			`.sel3(thrdec_d[3]), .in0(ccr_thr0[7:0]),`
234			`.in1(ccr_thr1[7:0]), .in2(ccr_thr2[7:0]),`
235			`.in3(ccr_thr3[7:0]));`
236			`endif // !`ifdef FPGA_SYN_1THREAD
237
238			`// bypass the ccs to the output. Only alu result needs to be bypassed`
239			`assign exu_ifu_cc_d[7:0] = (use_cc_e)? alu_cc_e[7:0]: partial_cc_d[7:0];`
240			`mux3ds #(8) mux_ccr_bypass1(.dout(partial_cc_d[7:0]),`
241			`.sel0(use_ccr),`
242			`.sel1(use_cc_m),`
243			`.sel2(use_cc_w),`
244			`.in0(ccr_d[7:0]),`
245			`.in1(alu_cc_m[7:0]),`
246			`.in2(alu_cc_w[7:0]));`
247
248			`assign use_cc_e = valid_setcc_e & thr_match_de;`
249			`assign use_cc_m = setcc_m & thr_match_dm;`
250			`assign use_cc_w = bypass_cc_w & thrmatch_w & ~use_cc_m;`
251			`assign use_ccr = ~(use_cc_m \| use_cc_w);`
252
253			`assign tid_dxorw = tid_w ^ tid_d;`
254
255			`assign thrmatch_w = ~(tid_dxorw[1] \| tid_dxorw[0]);`
256
257			`// generate ccr_w for the tlu`
258			`assign exu_tlu_ccr0_w[7:0] = ccr_thr0[7:0];`
259			`assign exu_tlu_ccr1_w[7:0] = ccr_thr1[7:0];`
260			`assign exu_tlu_ccr2_w[7:0] = ccr_thr2[7:0];`
261			`assign exu_tlu_ccr3_w[7:0] = ccr_thr3[7:0];`
262
263
264			`endmodule // sparc_exu_eclccr`