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1// Copyright (C) 2005 Peio Azkarate, peio@opencores.org\r
2//\r
3// This source file is free software; you can redistribute it\r
4// and/or modify it under the terms of the GNU Lesser General\r
5// Public License as published by the Free Software Foundation;\r
6// either version 2.1 of the License, or (at your option) any\r
7// later version.\r
8//\r
9\r
10(* signal_encoding = "user" *)\r
11(* safe_implementation = "yes" *)\r
12\r
13module pciwbsequ_new ( clk_i, nrst_i, cmd_i, cbe_i, frame_i, irdy_i, devsel_o, \r
14 trdy_o, adrcfg_i, adrmem_i, pciadrLD_o, pcidOE_o, parOE_o, wbdatLD_o, \r
15 wbrgdMX_o, wbd16MX_o, wrcfg_o, rdcfg_o, wb_sel_o, wb_we_o, wb_stb_o, \r
16 wb_cyc_o, wb_ack_i, wb_err_i, debug_init, debug_access );\r
17\r
18 // General \r
19 input clk_i;\r
20 input nrst_i;\r
21 // pci \r
22 // adr_i\r
23 input [3:0] cmd_i;\r
24 input [3:0] cbe_i;\r
25 input frame_i;\r
26 input irdy_i;\r
27 output devsel_o;\r
28 output trdy_o;\r
29 // control\r
30 input adrcfg_i;\r
31 input adrmem_i;\r
32 output pciadrLD_o;\r
33 output pcidOE_o;\r
34 output reg parOE_o;\r
35 output wbdatLD_o;\r
36 output wbrgdMX_o;\r
37 output wbd16MX_o;\r
38 output wrcfg_o;\r
39 output rdcfg_o;\r
40 // whisbone\r
41 output [1:0] wb_sel_o;\r
42 output wb_we_o;\r
43 inout wb_stb_o;\r
44 output wb_cyc_o;\r
45 input wb_ack_i;\r
46 input wb_err_i;\r
47 // debug signals\r
48 output reg debug_init;\r
49 output reg debug_access;\r
50\r
51 //type PciFSM is ( PCIIDLE, B_BUSY, S_DATA1, S_DATA2, TURN_AR ); \r
52 //wire pst_pci : PciFSM;\r
53 //wire nxt_pci : PciFSM;\r
54\r
55 // typedef enum reg [2:0] {\r
56 // RED, GREEN, BLUE, CYAN, MAGENTA, YELLOW\r
57 // } color_t;\r
58 //\r
59 // color_t my_color = GREEN;\r
60\r
61 // parameter PCIIDLE = 2'b00;\r
62 // parameter B_BUSY = 2'b01;\r
63 // parameter S_DATA1 = 2'b10;\r
64 // parameter S_DATA2 = 2'b11;\r
65 // parameter TURN_AR = 3'b100;\r
66\r
67 reg [2:0] pst_pci;\r
68 reg [2:0] nxt_pci;\r
69\r
70 parameter [2:0] \r
71 PCIIDLE = 3'b000,\r
72 B_BUSY = 3'b001,\r
73 S_DATA1 = 3'b010,\r
74 S_DATA2 = 3'b011,\r
75 TURN_AR = 3'b100;\r
76\r
77\r
78 initial begin\r
79 pst_pci = 3'b000;\r
80 end\r
81\r
82 initial begin\r
83 nxt_pci = 3'b000;\r
84 end\r
85 \r
86 wire sdata1;\r
87 wire sdata2;\r
88 wire idleNX;\r
89 wire sdata1NX;\r
90 wire sdata2NX;\r
91 wire turnarNX;\r
92 wire idle;\r
93 reg devselNX_n;\r
94 reg trdyNX_n;\r
95 reg devsel;\r
96 reg trdy;\r
97 wire adrpci;\r
98 wire acking;\r
99 wire rdcfg;\r
100 reg targOE;\r
101 reg pcidOE;\r
102\r
103 // always @(nrst_i or clk_i or nxt_pci)\r
104 always @(negedge nrst_i or posedge clk_i)\r
105 begin\r
106 if( nrst_i == 0 )\r
107 pst_pci <= PCIIDLE;\r
108 else \r
109 pst_pci <= nxt_pci; \r
110 end\r
111\r
112 // always @(negedge nrst_i or posedge clk_i)\r
113 always @( pst_pci or frame_i or irdy_i or adrcfg_i or adrpci or acking )\r
114 begin\r
115 devselNX_n <= 1'b1;\r
116 trdyNX_n <= 1'b1; \r
117 case (pst_pci)\r
118 PCIIDLE : \r
119 begin\r
120 if ( frame_i == 0 )\r
121 nxt_pci <= B_BUSY; \r
122 else\r
123 nxt_pci <= PCIIDLE;\r
124 end\r
125 B_BUSY:\r
126 if ( adrpci == 0 )\r
127 nxt_pci <= TURN_AR;\r
128 else\r
129 begin\r
130 nxt_pci <= S_DATA1;\r
131 devselNX_n <= 0; \r
132 end\r
133 S_DATA1:\r
134 if ( acking == 1 )\r
135 begin\r
136 nxt_pci <= S_DATA2;\r
137 devselNX_n <= 0; \r
138 trdyNX_n <= 0; \r
139 end\r
140 else\r
141 begin\r
142 nxt_pci <= S_DATA1;\r
143 devselNX_n <= 0; \r
144 end\r
145 S_DATA2:\r
146 if ( frame_i == 1 && irdy_i == 0 )\r
147 nxt_pci <= TURN_AR;\r
148 else\r
149 begin\r
150 nxt_pci <= S_DATA2;\r
151 devselNX_n <= 0;\r
152 trdyNX_n <= 0;\r
153 end\r
154 TURN_AR:\r
155 if ( frame_i == 1 )\r
156 nxt_pci <= PCIIDLE;\r
157 else\r
158 nxt_pci <= TURN_AR;\r
159 endcase\r
160 end\r
161\r
162 // FSM control signals\r
163 assign adrpci = adrmem_i;\r
164 \r
165 assign acking = (\r
166 ( wb_ack_i == 1 || wb_err_i == 1 ) || \r
167 ( adrcfg_i == 1 && irdy_i == 0)\r
168 ) ? 1'b1 : 1'b0; \r
169\r
170 // FSM derived Control signals\r
171 assign idle = ( pst_pci <= PCIIDLE ) ? 1'b1 : 1'b0;\r
172 assign sdata1 = ( pst_pci <= S_DATA1 ) ? 1'b1 : 1'b0;\r
173 assign sdata2 = ( pst_pci <= S_DATA2 ) ? 1'b1 : 1'b0;\r
174 assign idleNX = ( nxt_pci <= PCIIDLE ) ? 1'b1 : 1'b0;\r
175 assign sdata1NX = ( nxt_pci <= S_DATA1 ) ? 1'b1 : 1'b0;\r
176 assign sdata2NX = ( nxt_pci <= S_DATA2 ) ? 1'b1 : 1'b0;\r
177 assign turnarNX = ( nxt_pci <= TURN_AR ) ? 1'b1 : 1'b0;\r
178\r
179 // PCI Data Output Enable\r
180 // always @( nrst_i or clk_i or cmd_i [0] or sdata1NX or turnarNX )\r
181 always @(negedge nrst_i or posedge clk_i)\r
182 begin\r
183 if ( nrst_i == 0 )\r
184 pcidOE <= 0;\r
185 else\r
186 if ( sdata1NX == 1 && cmd_i [0] == 0 )\r
187 pcidOE <= 1;\r
188 else \r
189 if ( turnarNX == 1 )\r
190 pcidOE <= 0;\r
191 end\r
192\r
193 assign pcidOE_o = pcidOE;\r
194\r
195 // PAR Output Enable\r
196 // PCI Read data phase\r
197 // PAR is valid 1 cicle after data is valid\r
198 // always @( nrst_i or clk_i or cmd_i [0] or sdata2NX or turnarNX )\r
199 always @(negedge nrst_i or posedge clk_i)\r
200 begin\r
201 if ( nrst_i == 0 )\r
202 parOE_o <= 0;\r
203 else\r
204 if ( ( sdata2NX == 1 || turnarNX == 1 ) && cmd_i [0] == 0 )\r
205 parOE_o <= 1;\r
206 else\r
207 parOE_o <= 0;\r
208 end\r
209\r
210 // Target s/t/s signals OE control\r
211 // targOE <= '1' when ( idle = '0' and adrpci = '1' ) else '0';\r
212 // always @( nrst_i or clk_i or sdata1NX or idleNX )\r
213 always @(negedge nrst_i or posedge clk_i)\r
214 begin\r
215 if ( nrst_i == 0 )\r
216 targOE <= 0;\r
217 else\r
218 if ( sdata1NX == 1 )\r
219 targOE <= 1;\r
220 else \r
221 if ( idleNX == 1 )\r
222 targOE <= 0;\r
223 end\r
224 \r
225 // WHISBONE outs\r
226 assign wb_cyc_o = (adrmem_i == 1 && sdata1 == 1) ? 1'b1 : 1'b0;\r
227 assign wb_stb_o = (adrmem_i == 1 && sdata1 == 1 && irdy_i == 0 ) ? 1'b1 : 1'b0;\r
228\r
229 // PCI(Little endian) to WB(Big endian)\r
230 assign wb_sel_o [1] = (! cbe_i [0]) || (! cbe_i [2]);\r
231 assign wb_sel_o [0] = (! cbe_i [1]) || (! cbe_i [3]); \r
232\r
233 assign wb_we_o = cmd_i [0];\r
234\r
235 // Syncronized PCI outs\r
236 always @(negedge nrst_i or posedge clk_i)\r
237 begin\r
238 if( nrst_i == 0 )\r
239 begin\r
240 devsel <= 1;\r
241 trdy <= 1;\r
242 end\r
243 else\r
244 begin\r
245 devsel <= devselNX_n;\r
246 trdy <= trdyNX_n;\r
247 end\r
248 end\r
249\r
250 assign devsel_o = ( targOE == 1 ) ? devsel : 1'bZ;\r
251 assign trdy_o = ( targOE == 1 ) ? trdy : 1'bZ;\r
252\r
253 // rd/wr Configuration Space Registers\r
254 assign wrcfg_o = (\r
255 adrcfg_i == 1 &&\r
256 cmd_i [0] == 1 &&\r
257 sdata2 == 1\r
258 ) ? 1'b1 : 1'b0;\r
259\r
260 assign rdcfg = (\r
261 adrcfg_i == 1 &&\r
262 cmd_i [0] == 0 &&\r
263 (sdata1 == 1 || sdata2 == 1)\r
264 ) ? 1'b1 : 1'b0;\r
265\r
266 assign rdcfg_o = rdcfg;\r
267\r
268 // LoaD enable signals\r
269 assign pciadrLD_o = ! frame_i;\r
270 assign wbdatLD_o = wb_ack_i;\r
271\r
272 // Mux control signals\r
273 assign wbrgdMX_o = ! rdcfg;\r
274 assign wbd16MX_o = (cbe_i [3] == 0 || cbe_i [2] == 0) ? 1'b1 : 1'b0;\r
275 \r
276 // debug outs \r
277 always @(negedge nrst_i or posedge clk_i)\r
278 begin\r
279 if ( nrst_i == 0 )\r
280 debug_init <= 0;\r
281 else\r
282 if (devsel == 0)\r
283 debug_init <= 1;\r
284 end\r
285\r
286 always @(negedge nrst_i or posedge clk_i)\r
287 begin\r
288 if ( nrst_i == 0 )\r
289 debug_access <= 0;\r
290 else\r
291 if (wb_stb_o == 1)\r
292 debug_access <= 1;\r
293 end\r
294\r
295endmodule\r
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