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//////////////////////////////////////////////////////////////////////
///                                                               //// 
/// Wishbone arbiter, burst-compatible                            ////
///                                                               ////
/// Simple arbiter, single master, dual slave, primarily for      ////
/// processor instruction bus, providing access to one main       ////
/// memory server and one ROM                                     ////
///                                                               ////
/// Julius Baxter, julius@opencores.org                           ////
///                                                               ////
//////////////////////////////////////////////////////////////////////
////                                                              ////
//// Copyright (C) 2009, 2010 Authors and OPENCORES.ORG           ////
////                                                              ////
//// This source file may be used and distributed without         ////
//// restriction provided that this copyright statement is not    ////
//// removed from the file and that any derivative work contains  ////
//// the original copyright notice and the associated disclaimer. ////
////                                                              ////
//// This source file is free software; you can redistribute it   ////
//// and/or modify it under the terms of the GNU Lesser General   ////
//// Public License as published by the Free Software Foundation; ////
//// either version 2.1 of the License, or (at your option) any   ////
//// later version.                                               ////
////                                                              ////
//// This source 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 Lesser General Public License for more ////
//// details.                                                     ////
////                                                              ////
//// You should have received a copy of the GNU Lesser General    ////
//// Public License along with this source; if not, download it   ////
//// from http://www.opencores.org/lgpl.shtml                     ////
////                                                              ////
//////////////////////////////////////////////////////////////////////
`include "orpsoc-defines.v"
// One master, 2 slaves.
module arbiter_ibus
  (
   // instruction bus in
   // Wishbone Master interface
   wbm_adr_o,
   wbm_dat_o,
   wbm_sel_o,
   wbm_we_o,
   wbm_cyc_o,
   wbm_stb_o,
   wbm_cti_o,
   wbm_bte_o,
 
   wbm_dat_i,
   wbm_ack_i,
   wbm_err_i,
   wbm_rty_i,
 
 
   // Slave one
   // Wishbone Slave interface
   wbs0_adr_i,
   wbs0_dat_i,
   wbs0_sel_i,
   wbs0_we_i,
   wbs0_cyc_i,
   wbs0_stb_i,
   wbs0_cti_i,
   wbs0_bte_i,
 
   wbs0_dat_o,
   wbs0_ack_o,
   wbs0_err_o,
   wbs0_rty_o,
 
   // Slave two
   // Wishbone Slave interface
   wbs1_adr_i,
   wbs1_dat_i,
   wbs1_sel_i,
   wbs1_we_i,
   wbs1_cyc_i,
   wbs1_stb_i,
   wbs1_cti_i,
   wbs1_bte_i,
 
   wbs1_dat_o,
   wbs1_ack_o,
   wbs1_err_o,
   wbs1_rty_o,
 
   wb_clk,
   wb_rst
   );
 
 
   parameter wb_dat_width = 32;
   parameter wb_adr_width = 32;
 
   parameter wb_addr_match_width = 8;
 
   parameter slave0_adr = 8'hf0; // FLASH ROM
   parameter slave1_adr = 8'h00; // Main memory (SDRAM/FPGA SRAM)
 
`define WB_ARB_ADDR_MATCH_SEL wb_adr_width-1:wb_adr_width-wb_addr_match_width
 
   input wb_clk;
   input wb_rst;
 
 
   // WB Master
   input [wb_adr_width-1:0] wbm_adr_o;
   input [wb_dat_width-1:0] wbm_dat_o;
   input [3:0]               wbm_sel_o;
   input                    wbm_we_o;
   input                    wbm_cyc_o;
   input                    wbm_stb_o;
   input [2:0]               wbm_cti_o;
   input [1:0]               wbm_bte_o;
   output [wb_dat_width-1:0] wbm_dat_i;
   output                    wbm_ack_i;
   output                    wbm_err_i;
   output                    wbm_rty_i;
 
   // WB Slave 0
   output [wb_adr_width-1:0] wbs0_adr_i;
   output [wb_dat_width-1:0] wbs0_dat_i;
   output [3:0]       wbs0_sel_i;
   output                    wbs0_we_i;
   output                    wbs0_cyc_i;
   output                    wbs0_stb_i;
   output [2:0]       wbs0_cti_i;
   output [1:0]       wbs0_bte_i;
   input [wb_dat_width-1:0]  wbs0_dat_o;
   input                     wbs0_ack_o;
   input                     wbs0_err_o;
   input                     wbs0_rty_o;
 
   // WB Slave 1
   output [wb_adr_width-1:0] wbs1_adr_i;
   output [wb_dat_width-1:0] wbs1_dat_i;
   output [3:0]       wbs1_sel_i;
   output                    wbs1_we_i;
   output                    wbs1_cyc_i;
   output                    wbs1_stb_i;
   output [2:0]       wbs1_cti_i;
   output [1:0]       wbs1_bte_i;
   input [wb_dat_width-1:0]  wbs1_dat_o;
   input                     wbs1_ack_o;
   input                     wbs1_err_o;
   input                     wbs1_rty_o;
 
   wire [1:0]                 slave_sel; // One bit per slave
 
   reg                       watchdog_err;
 
`ifdef ARBITER_IBUS_WATCHDOG
   reg [`ARBITER_IBUS_WATCHDOG_TIMER_WIDTH:0]  watchdog_timer;
   reg                       wbm_stb_r; // Register strobe
   wire                      wbm_stb_edge; // Detect its edge
   reg                       wbm_stb_edge_r, wbm_ack_i_r; // Reg these, better timing
 
   always @(posedge wb_clk)
     wbm_stb_r <= wbm_stb_o;
 
   assign wbm_stb_edge = (wbm_stb_o & !wbm_stb_r);
 
   always @(posedge wb_clk)
     wbm_stb_edge_r <= wbm_stb_edge;
 
   always @(posedge wb_clk)
     wbm_ack_i_r <= wbm_ack_i;
 
 
   // Counter logic
   always @(posedge wb_clk)
     if (wb_rst) watchdog_timer <= 0;
     else if (wbm_ack_i_r) // When we see an ack, turn off timer
       watchdog_timer <= 0;
     else if (wbm_stb_edge_r) // New access means start timer again
       watchdog_timer <= 1;
     else if (|watchdog_timer) // Continue counting if counter > 0
       watchdog_timer <= watchdog_timer + 1;
 
   always @(posedge wb_clk)
     watchdog_err <= (&watchdog_timer);
 
`else // !`ifdef ARBITER_IBUS_WATCHDOG
 
   always @(posedge wb_clk)
     watchdog_err <= 0;
 
`endif // !`ifdef ARBITER_IBUS_WATCHDOG
 
 
 
`ifdef ARBITER_IBUS_REGISTERING
 
   // Master input registers
   reg [wb_adr_width-1:0]    wbm_adr_o_r;
   reg [wb_dat_width-1:0]    wbm_dat_o_r;
   reg [3:0]                  wbm_sel_o_r;
   reg                       wbm_we_o_r;
   reg                       wbm_cyc_o_r;
   reg                       wbm_stb_o_r;
   reg [2:0]                  wbm_cti_o_r;
   reg [1:0]                  wbm_bte_o_r;
   // Slave output registers
   reg [wb_dat_width-1:0]    wbs0_dat_o_r;
   reg                       wbs0_ack_o_r;
   reg                       wbs0_err_o_r;
   reg                       wbs0_rty_o_r;
   reg [wb_dat_width-1:0]    wbs1_dat_o_r;
   reg                       wbs1_ack_o_r;
   reg                       wbs1_err_o_r;
   reg                       wbs1_rty_o_r;
 
   wire                      wbm_ack_i_pre_reg;
 
 
 
   // Register master input signals
   always @(posedge wb_clk)
     begin
        wbm_adr_o_r <= wbm_adr_o;
        wbm_dat_o_r <= wbm_dat_o;
        wbm_sel_o_r <= wbm_sel_o;
        wbm_we_o_r <= wbm_we_o;
        wbm_cyc_o_r <= wbm_cyc_o;
        wbm_stb_o_r <= wbm_stb_o & !wbm_ack_i_pre_reg & !wbm_ack_i;//classic
        wbm_cti_o_r <= wbm_cti_o;
        wbm_bte_o_r <= wbm_bte_o;
 
        // Slave signals
        wbs0_dat_o_r <= wbs0_dat_o;
        wbs0_ack_o_r <= wbs0_ack_o;
        wbs0_err_o_r <= wbs0_err_o;
        wbs0_rty_o_r <= wbs0_rty_o;
        wbs1_dat_o_r <= wbs1_dat_o;
        wbs1_ack_o_r <= wbs1_ack_o;
        wbs1_err_o_r <= wbs1_err_o;
        wbs1_rty_o_r <= wbs1_rty_o;
 
     end // always @ (posedge wb_clk)
 
   // Slave select
   assign slave_sel[0] = wbm_adr_o_r[`WB_ARB_ADDR_MATCH_SEL] ==
                         slave0_adr;
 
   assign slave_sel[1] = wbm_adr_o_r[`WB_ARB_ADDR_MATCH_SEL] ==
                         slave1_adr;
 
   // Slave out assigns
   assign wbs0_adr_i = wbm_adr_o_r;
   assign wbs0_dat_i = wbm_dat_o_r;
   assign wbs0_we_i = wbm_dat_o_r;
   assign wbs0_sel_i = wbm_sel_o_r;
   assign wbs0_cti_i = wbm_cti_o_r;
   assign wbs0_bte_i = wbm_bte_o_r;
   assign wbs0_cyc_i = wbm_cyc_o_r & slave_sel[0];
   assign wbs0_stb_i = wbm_stb_o_r & slave_sel[0];
 
   assign wbs1_adr_i = wbm_adr_o_r;
   assign wbs1_dat_i = wbm_dat_o_r;
   assign wbs1_we_i = wbm_dat_o_r;
   assign wbs1_sel_i = wbm_sel_o_r;
   assign wbs1_cti_i = wbm_cti_o_r;
   assign wbs1_bte_i = wbm_bte_o_r;
   assign wbs1_cyc_i = wbm_cyc_o_r & slave_sel[1];
   assign wbs1_stb_i = wbm_stb_o_r & slave_sel[1];
 
   // Master out assigns
   // Don't care about none selected...
   assign wbm_dat_i = slave_sel[1] ? wbs1_dat_o_r :
                      wbs0_dat_o_r ;
 
   assign wbm_ack_i = (slave_sel[0] & wbs0_ack_o_r) |
                      (slave_sel[1] & wbs1_ack_o_r)
     ;
 
   assign wbm_err_i = (slave_sel[0] & wbs0_err_o_r) |
                      (slave_sel[1] & wbs1_err_o_r) |
                      watchdog_err;
 
   assign wbm_rty_i = (slave_sel[0] & wbs0_rty_o_r) |
                      (slave_sel[1] & wbs1_rty_o_r);
 
   // Non-registered ack
   assign wbm_ack_i_pre_reg = (slave_sel[0] & wbs0_ack_o) |
                              (slave_sel[1] & wbs1_ack_o);
 
`else // !`ifdef ARBITER_IBUS_REGISTERING
 
   // Slave select
   assign slave_sel[0] = wbm_adr_o[`WB_ARB_ADDR_MATCH_SEL] ==
                         slave0_adr;
 
   assign slave_sel[1] = wbm_adr_o[`WB_ARB_ADDR_MATCH_SEL] ==
                         slave1_adr;
 
   // Slave out assigns
   assign wbs0_adr_i = wbm_adr_o;
   assign wbs0_dat_i = wbm_dat_o;
   assign wbs0_we_i = wbm_dat_o;
   assign wbs0_sel_i = wbm_sel_o;
   assign wbs0_cti_i = wbm_cti_o;
   assign wbs0_bte_i = wbm_bte_o;
   assign wbs0_cyc_i = wbm_cyc_o & slave_sel[0];
   assign wbs0_stb_i = wbm_stb_o & slave_sel[0];
 
   assign wbs1_adr_i = wbm_adr_o;
   assign wbs1_dat_i = wbm_dat_o;
   assign wbs1_we_i = wbm_dat_o;
   assign wbs1_sel_i = wbm_sel_o;
   assign wbs1_cti_i = wbm_cti_o;
   assign wbs1_bte_i = wbm_bte_o;
   assign wbs1_cyc_i = wbm_cyc_o & slave_sel[1];
   assign wbs1_stb_i = wbm_stb_o & slave_sel[1];
 
   // Master out assigns
   // Don't care about none selected...
   assign wbm_dat_i = slave_sel[1] ? wbs1_dat_o :
                      wbs0_dat_o ;
 
   assign wbm_ack_i = (slave_sel[0] & wbs0_ack_o) |
                      (slave_sel[1] & wbs1_ack_o);
 
 
   assign wbm_err_i = (slave_sel[0] & wbs0_err_o) |
                      (slave_sel[1] & wbs1_err_o) |
                      watchdog_err;
 
   assign wbm_rty_i = (slave_sel[0] & wbs0_rty_o) |
                      (slave_sel[1] & wbs1_rty_o);
 
 
`endif
endmodule // arbiter_ibus
 

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[/] [openrisc/] [trunk/] [orpsocv2/] [rtl/] [verilog/] [arbiter/] [arbiter_ibus.v] - Blame information for rev 361

Line No.	Rev	Author	Line
1	361	julius	`//////////////////////////////////////////////////////////////////////`
2			`/// ////`
3			`/// Wishbone arbiter, burst-compatible ////`
4			`/// ////`
5			`/// Simple arbiter, single master, dual slave, primarily for ////`
6			`/// processor instruction bus, providing access to one main ////`
7			`/// memory server and one ROM ////`
8			`/// ////`
9			`/// Julius Baxter, julius@opencores.org ////`
10			`/// ////`
11			`//////////////////////////////////////////////////////////////////////`
12			`//// ////`
13			`//// Copyright (C) 2009, 2010 Authors and OPENCORES.ORG ////`
14			`//// ////`
15			`//// This source file may be used and distributed without ////`
16			`//// restriction provided that this copyright statement is not ////`
17			`//// removed from the file and that any derivative work contains ////`
18			`//// the original copyright notice and the associated disclaimer. ////`
19			`//// ////`
20			`//// This source file is free software; you can redistribute it ////`
21			`//// and/or modify it under the terms of the GNU Lesser General ////`
22			`//// Public License as published by the Free Software Foundation; ////`
23			`//// either version 2.1 of the License, or (at your option) any ////`
24			`//// later version. ////`
25			`//// ////`
26			`//// This source is distributed in the hope that it will be ////`
27			`//// useful, but WITHOUT ANY WARRANTY; without even the implied ////`
28			`//// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR ////`
29			`//// PURPOSE. See the GNU Lesser General Public License for more ////`
30			`//// details. ////`
31			`//// ////`
32			`//// You should have received a copy of the GNU Lesser General ////`
33			`//// Public License along with this source; if not, download it ////`
34			`//// from http://www.opencores.org/lgpl.shtml ////`
35			`//// ////`
36			`//////////////////////////////////////////////////////////////////////`
37			`include "orpsoc-defines.v"
38			`// One master, 2 slaves.`
39			`module arbiter_ibus`
40			`(`
41			`// instruction bus in`
42			`// Wishbone Master interface`
43			`wbm_adr_o,`
44			`wbm_dat_o,`
45			`wbm_sel_o,`
46			`wbm_we_o,`
47			`wbm_cyc_o,`
48			`wbm_stb_o,`
49			`wbm_cti_o,`
50			`wbm_bte_o,`
51
52			`wbm_dat_i,`
53			`wbm_ack_i,`
54			`wbm_err_i,`
55			`wbm_rty_i,`
56
57
58			`// Slave one`
59			`// Wishbone Slave interface`
60			`wbs0_adr_i,`
61			`wbs0_dat_i,`
62			`wbs0_sel_i,`
63			`wbs0_we_i,`
64			`wbs0_cyc_i,`
65			`wbs0_stb_i,`
66			`wbs0_cti_i,`
67			`wbs0_bte_i,`
68
69			`wbs0_dat_o,`
70			`wbs0_ack_o,`
71			`wbs0_err_o,`
72			`wbs0_rty_o,`
73
74			`// Slave two`
75			`// Wishbone Slave interface`
76			`wbs1_adr_i,`
77			`wbs1_dat_i,`
78			`wbs1_sel_i,`
79			`wbs1_we_i,`
80			`wbs1_cyc_i,`
81			`wbs1_stb_i,`
82			`wbs1_cti_i,`
83			`wbs1_bte_i,`
84
85			`wbs1_dat_o,`
86			`wbs1_ack_o,`
87			`wbs1_err_o,`
88			`wbs1_rty_o,`
89
90			`wb_clk,`
91			`wb_rst`
92			`);`
93
94
95			`parameter wb_dat_width = 32;`
96			`parameter wb_adr_width = 32;`
97
98			`parameter wb_addr_match_width = 8;`
99
100			`parameter slave0_adr = 8'hf0; // FLASH ROM`
101			`parameter slave1_adr = 8'h00; // Main memory (SDRAM/FPGA SRAM)`
102
103			`define WB_ARB_ADDR_MATCH_SEL wb_adr_width-1:wb_adr_width-wb_addr_match_width
104
105			`input wb_clk;`
106			`input wb_rst;`
107
108
109			`// WB Master`
110			`input [wb_adr_width-1:0] wbm_adr_o;`
111			`input [wb_dat_width-1:0] wbm_dat_o;`
112			`input [3:0] wbm_sel_o;`
113			`input wbm_we_o;`
114			`input wbm_cyc_o;`
115			`input wbm_stb_o;`
116			`input [2:0] wbm_cti_o;`
117			`input [1:0] wbm_bte_o;`
118			`output [wb_dat_width-1:0] wbm_dat_i;`
119			`output wbm_ack_i;`
120			`output wbm_err_i;`
121			`output wbm_rty_i;`
122
123			`// WB Slave 0`
124			`output [wb_adr_width-1:0] wbs0_adr_i;`
125			`output [wb_dat_width-1:0] wbs0_dat_i;`
126			`output [3:0] wbs0_sel_i;`
127			`output wbs0_we_i;`
128			`output wbs0_cyc_i;`
129			`output wbs0_stb_i;`
130			`output [2:0] wbs0_cti_i;`
131			`output [1:0] wbs0_bte_i;`
132			`input [wb_dat_width-1:0] wbs0_dat_o;`
133			`input wbs0_ack_o;`
134			`input wbs0_err_o;`
135			`input wbs0_rty_o;`
136
137			`// WB Slave 1`
138			`output [wb_adr_width-1:0] wbs1_adr_i;`
139			`output [wb_dat_width-1:0] wbs1_dat_i;`
140			`output [3:0] wbs1_sel_i;`
141			`output wbs1_we_i;`
142			`output wbs1_cyc_i;`
143			`output wbs1_stb_i;`
144			`output [2:0] wbs1_cti_i;`
145			`output [1:0] wbs1_bte_i;`
146			`input [wb_dat_width-1:0] wbs1_dat_o;`
147			`input wbs1_ack_o;`
148			`input wbs1_err_o;`
149			`input wbs1_rty_o;`
150
151			`wire [1:0] slave_sel; // One bit per slave`
152
153			`reg watchdog_err;`
154
155			`ifdef ARBITER_IBUS_WATCHDOG
156			reg [`ARBITER_IBUS_WATCHDOG_TIMER_WIDTH:0] watchdog_timer;
157			`reg wbm_stb_r; // Register strobe`
158			`wire wbm_stb_edge; // Detect its edge`
159			`reg wbm_stb_edge_r, wbm_ack_i_r; // Reg these, better timing`
160
161			`always @(posedge wb_clk)`
162			`wbm_stb_r <= wbm_stb_o;`
163
164			`assign wbm_stb_edge = (wbm_stb_o & !wbm_stb_r);`
165
166			`always @(posedge wb_clk)`
167			`wbm_stb_edge_r <= wbm_stb_edge;`
168
169			`always @(posedge wb_clk)`
170			`wbm_ack_i_r <= wbm_ack_i;`
171
172
173			`// Counter logic`
174			`always @(posedge wb_clk)`
175			`if (wb_rst) watchdog_timer <= 0;`
176			`else if (wbm_ack_i_r) // When we see an ack, turn off timer`
177			`watchdog_timer <= 0;`
178			`else if (wbm_stb_edge_r) // New access means start timer again`
179			`watchdog_timer <= 1;`
180			`else if (\|watchdog_timer) // Continue counting if counter > 0`
181			`watchdog_timer <= watchdog_timer + 1;`
182
183			`always @(posedge wb_clk)`
184			`watchdog_err <= (&watchdog_timer);`
185
186			`else // !`ifdef ARBITER_IBUS_WATCHDOG
187
188			`always @(posedge wb_clk)`
189			`watchdog_err <= 0;`
190
191			`endif // !`ifdef ARBITER_IBUS_WATCHDOG
192
193
194
195			`ifdef ARBITER_IBUS_REGISTERING
196
197			`// Master input registers`
198			`reg [wb_adr_width-1:0] wbm_adr_o_r;`
199			`reg [wb_dat_width-1:0] wbm_dat_o_r;`
200			`reg [3:0] wbm_sel_o_r;`
201			`reg wbm_we_o_r;`
202			`reg wbm_cyc_o_r;`
203			`reg wbm_stb_o_r;`
204			`reg [2:0] wbm_cti_o_r;`
205			`reg [1:0] wbm_bte_o_r;`
206			`// Slave output registers`
207			`reg [wb_dat_width-1:0] wbs0_dat_o_r;`
208			`reg wbs0_ack_o_r;`
209			`reg wbs0_err_o_r;`
210			`reg wbs0_rty_o_r;`
211			`reg [wb_dat_width-1:0] wbs1_dat_o_r;`
212			`reg wbs1_ack_o_r;`
213			`reg wbs1_err_o_r;`
214			`reg wbs1_rty_o_r;`
215
216			`wire wbm_ack_i_pre_reg;`
217
218
219
220			`// Register master input signals`
221			`always @(posedge wb_clk)`
222			`begin`
223			`wbm_adr_o_r <= wbm_adr_o;`
224			`wbm_dat_o_r <= wbm_dat_o;`
225			`wbm_sel_o_r <= wbm_sel_o;`
226			`wbm_we_o_r <= wbm_we_o;`
227			`wbm_cyc_o_r <= wbm_cyc_o;`
228			`wbm_stb_o_r <= wbm_stb_o & !wbm_ack_i_pre_reg & !wbm_ack_i;//classic`
229			`wbm_cti_o_r <= wbm_cti_o;`
230			`wbm_bte_o_r <= wbm_bte_o;`
231
232			`// Slave signals`
233			`wbs0_dat_o_r <= wbs0_dat_o;`
234			`wbs0_ack_o_r <= wbs0_ack_o;`
235			`wbs0_err_o_r <= wbs0_err_o;`
236			`wbs0_rty_o_r <= wbs0_rty_o;`
237			`wbs1_dat_o_r <= wbs1_dat_o;`
238			`wbs1_ack_o_r <= wbs1_ack_o;`
239			`wbs1_err_o_r <= wbs1_err_o;`
240			`wbs1_rty_o_r <= wbs1_rty_o;`
241
242			`end // always @ (posedge wb_clk)`
243
244			`// Slave select`
245			assign slave_sel[0] = wbm_adr_o_r[`WB_ARB_ADDR_MATCH_SEL] ==
246			`slave0_adr;`
247
248			assign slave_sel[1] = wbm_adr_o_r[`WB_ARB_ADDR_MATCH_SEL] ==
249			`slave1_adr;`
250
251			`// Slave out assigns`
252			`assign wbs0_adr_i = wbm_adr_o_r;`
253			`assign wbs0_dat_i = wbm_dat_o_r;`
254			`assign wbs0_we_i = wbm_dat_o_r;`
255			`assign wbs0_sel_i = wbm_sel_o_r;`
256			`assign wbs0_cti_i = wbm_cti_o_r;`
257			`assign wbs0_bte_i = wbm_bte_o_r;`
258			`assign wbs0_cyc_i = wbm_cyc_o_r & slave_sel[0];`
259			`assign wbs0_stb_i = wbm_stb_o_r & slave_sel[0];`
260
261			`assign wbs1_adr_i = wbm_adr_o_r;`
262			`assign wbs1_dat_i = wbm_dat_o_r;`
263			`assign wbs1_we_i = wbm_dat_o_r;`
264			`assign wbs1_sel_i = wbm_sel_o_r;`
265			`assign wbs1_cti_i = wbm_cti_o_r;`
266			`assign wbs1_bte_i = wbm_bte_o_r;`
267			`assign wbs1_cyc_i = wbm_cyc_o_r & slave_sel[1];`
268			`assign wbs1_stb_i = wbm_stb_o_r & slave_sel[1];`
269
270			`// Master out assigns`
271			`// Don't care about none selected...`
272			`assign wbm_dat_i = slave_sel[1] ? wbs1_dat_o_r :`
273			`wbs0_dat_o_r ;`
274
275			`assign wbm_ack_i = (slave_sel[0] & wbs0_ack_o_r) \|`
276			`(slave_sel[1] & wbs1_ack_o_r)`
277			`;`
278
279			`assign wbm_err_i = (slave_sel[0] & wbs0_err_o_r) \|`
280			`(slave_sel[1] & wbs1_err_o_r) \|`
281			`watchdog_err;`
282
283			`assign wbm_rty_i = (slave_sel[0] & wbs0_rty_o_r) \|`
284			`(slave_sel[1] & wbs1_rty_o_r);`
285
286			`// Non-registered ack`
287			`assign wbm_ack_i_pre_reg = (slave_sel[0] & wbs0_ack_o) \|`
288			`(slave_sel[1] & wbs1_ack_o);`
289
290			`else // !`ifdef ARBITER_IBUS_REGISTERING
291
292			`// Slave select`
293			assign slave_sel[0] = wbm_adr_o[`WB_ARB_ADDR_MATCH_SEL] ==
294			`slave0_adr;`
295
296			assign slave_sel[1] = wbm_adr_o[`WB_ARB_ADDR_MATCH_SEL] ==
297			`slave1_adr;`
298
299			`// Slave out assigns`
300			`assign wbs0_adr_i = wbm_adr_o;`
301			`assign wbs0_dat_i = wbm_dat_o;`
302			`assign wbs0_we_i = wbm_dat_o;`
303			`assign wbs0_sel_i = wbm_sel_o;`
304			`assign wbs0_cti_i = wbm_cti_o;`
305			`assign wbs0_bte_i = wbm_bte_o;`
306			`assign wbs0_cyc_i = wbm_cyc_o & slave_sel[0];`
307			`assign wbs0_stb_i = wbm_stb_o & slave_sel[0];`
308
309			`assign wbs1_adr_i = wbm_adr_o;`
310			`assign wbs1_dat_i = wbm_dat_o;`
311			`assign wbs1_we_i = wbm_dat_o;`
312			`assign wbs1_sel_i = wbm_sel_o;`
313			`assign wbs1_cti_i = wbm_cti_o;`
314			`assign wbs1_bte_i = wbm_bte_o;`
315			`assign wbs1_cyc_i = wbm_cyc_o & slave_sel[1];`
316			`assign wbs1_stb_i = wbm_stb_o & slave_sel[1];`
317
318			`// Master out assigns`
319			`// Don't care about none selected...`
320			`assign wbm_dat_i = slave_sel[1] ? wbs1_dat_o :`
321			`wbs0_dat_o ;`
322
323			`assign wbm_ack_i = (slave_sel[0] & wbs0_ack_o) \|`
324			`(slave_sel[1] & wbs1_ack_o);`
325
326
327			`assign wbm_err_i = (slave_sel[0] & wbs0_err_o) \|`
328			`(slave_sel[1] & wbs1_err_o) \|`
329			`watchdog_err;`
330
331			`assign wbm_rty_i = (slave_sel[0] & wbs0_rty_o) \|`
332			`(slave_sel[1] & wbs1_rty_o);`
333
334
335			`endif
336			`endmodule // arbiter_ibus`
337