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1 //////////////////////////////////////////////////////////////////////
2 //// ////
3 //// File name: pci_spoci_ctrl ////
4 //// ////
5 //// This file is part of the "PCI bridge" project ////
6 //// http://www.opencores.org/cores/pci/ ////
7 //// ////
8 //// Author(s): ////
9 //// - Miha Dolenc (mihad@opencores.org) ////
10 //// ////
11 //// ////
12 //////////////////////////////////////////////////////////////////////
13 //// ////
14 //// Copyright (C) 2004 Miha Dolenc, mihad@opencores.org ////
15 //// ////
16 //// This source file may be used and distributed without ////
17 //// restriction provided that this copyright statement is not ////
18 //// removed from the file and that any derivative work contains ////
19 //// the original copyright notice and the associated disclaimer. ////
20 //// ////
21 //// This source file is free; you can redistribute it ////
22 //// and/or modify it under the terms of the GNU Lesser General ////
23 //// Public License as published by the Free Software Foundation; ////
24 //// either version 2.1 of the License, or (at your option) any ////
25 //// later version. ////
26 //// ////
27 //// This source is distributed in the hope that it will be ////
28 //// useful, but WITHOUT ANY WARRANTY; without even the implied ////
29 //// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR ////
30 //// PURPOSE. See the GNU Lesser General Public License for more ////
31 //// details. ////
32 //// ////
33 //// You should have received a copy of the GNU Lesser General ////
34 //// Public License along with this source; if not, download it ////
35 //// from http://www.opencores.org/lgpl.shtml ////
36 //// ////
37 //////////////////////////////////////////////////////////////////////
38 //
39 // CVS Revision History
40 //
41 // $Log: pci_spoci_ctrl.v,v $
42 // Revision 1.1 2007-03-20 17:50:56 sithglan
43 // add shit
44 //
45 // Revision 1.1 2004/01/24 11:54:18 mihad
46 // Update! SPOCI Implemented!
47 //
48 //
49
50 `include "pci_constants.v"
51
52 // synopsys translate_off
53 `include "timescale.v"
54 // synopsys translate_on
55
56 module pci_spoci_ctrl
57 (
58 reset_i ,
59 clk_i ,
60
61 do_rnd_read_i ,
62 do_seq_read_i ,
63 do_write_i ,
64
65 write_done_o ,
66 dat_rdy_o ,
67 no_ack_o ,
68
69 adr_i ,
70 dat_i ,
71 dat_o ,
72
73 pci_spoci_sda_i ,
74 pci_spoci_sda_oe_o ,
75 pci_spoci_scl_oe_o
76 );
77
78 parameter tx_rx_state_width = 9 ;
79 parameter tx_rx_idle = 'h1 ;
80 parameter tx_rx_start = 'h2 ;
81 parameter tx_rx_restart = 'h4 ;
82 parameter tx_rx_send_bits = 'h8 ;
83 parameter tx_rx_rec_bits = 'h10 ;
84 parameter tx_rx_send_ack = 'h20 ;
85 parameter tx_rx_rec_ack = 'h40 ;
86 parameter tx_rx_send_nack = 'h80 ;
87 parameter tx_rx_stop = 'h100 ;
88
89 parameter rw_seq_state_width = 5 ;
90 parameter rw_seq_idle = 'h1 ;
91 parameter rw_seq_tx_ctrl = 'h2 ;
92 parameter rw_seq_tx_adr = 'h4 ;
93 parameter rw_seq_tx_byte = 'h8 ;
94 parameter rw_seq_rx_byte = 'h10 ;
95
96 `ifdef PCI33
97 parameter cnt_width = 9 ;
98 parameter period_cnt = 334 ;
99 `endif
100
101 `ifdef PCI66
102 parameter cnt_width = 10 ;
103 parameter period_cnt = 667 ;
104 `endif
105
106 input reset_i ,
107 clk_i ;
108
109 input do_rnd_read_i ,
110 do_seq_read_i ,
111 do_write_i ;
112
113 output write_done_o ,
114 dat_rdy_o ,
115 no_ack_o ;
116
117 input [10: 0] adr_i ;
118 input [ 7: 0] dat_i ;
119 output [ 7: 0] dat_o ;
120
121 input pci_spoci_sda_i ;
122
123 output pci_spoci_sda_oe_o ,
124 pci_spoci_scl_oe_o ;
125
126 reg write_done_o ,
127 dat_rdy_o ,
128 no_ack_o ;
129
130 reg [ 7: 0] dat_o ;
131
132 reg pci_spoci_sda_oe_o ,
133 pci_spoci_scl_oe_o ;
134
135 reg clk_gen_cnt_en ;
136 reg clk_gen_cnt_clr ;
137 reg [cnt_width - 1:0] clk_gen_cnt ;
138
139 reg [tx_rx_state_width - 1:0] tx_rx_state ;
140 reg [tx_rx_state_width - 1:0] tx_rx_next_state ;
141 reg tx_rx_sm_idle ;
142
143 reg scl_oe ;
144 reg scl_oe_en ;
145 reg sda_oe ;
146 reg sda_oe_en ;
147
148 reg sda_i_reg_en ;
149 reg sda_i_reg ;
150
151 always@(posedge clk_i or posedge reset_i)
152 begin
153 if (reset_i)
154 begin
155 clk_gen_cnt <= 'h0 ;
156
157 tx_rx_state <= tx_rx_idle ;
158
159 `ifdef ACTIVE_LOW_OE
160 pci_spoci_sda_oe_o <= 1'b1 ;
161 pci_spoci_scl_oe_o <= 1'b1 ;
162 `endif
163
164 `ifdef ACTIVE_HIGH_OE
165 pci_spoci_sda_oe_o <= 1'b0 ;
166 pci_spoci_scl_oe_o <= 1'b0 ;
167 `endif
168
169 sda_i_reg <= 1'b1 ;
170 end
171 else
172 begin
173 tx_rx_state <= tx_rx_next_state ;
174
175 if (clk_gen_cnt_clr)
176 clk_gen_cnt <= 'h0 ;
177 else if (clk_gen_cnt_en)
178 clk_gen_cnt <= clk_gen_cnt + 1'b1 ;
179
180
181 if (sda_oe_en)
182 begin
183 `ifdef ACTIVE_LOW_OE
184 pci_spoci_sda_oe_o <= ~sda_oe ;
185 `endif
186
187 `ifdef ACTIVE_HIGH_OE
188 pci_spoci_sda_oe_o <= sda_oe ;
189 `endif
190 end
191
192 if (scl_oe_en)
193 begin
194 `ifdef ACTIVE_LOW_OE
195 pci_spoci_scl_oe_o <= ~scl_oe ;
196 `endif
197
198 `ifdef ACTIVE_HIGH_OE
199 pci_spoci_scl_oe_o <= scl_oe ;
200 `endif
201 end
202
203 if (sda_i_reg_en)
204 sda_i_reg <= pci_spoci_sda_i ;
205 end
206 end
207
208 reg [ 7: 0] tx_shift_reg ;
209
210 reg send_start ;
211 reg start_sent ;
212
213 reg send_bit ;
214 reg bit_sent ;
215
216 reg rec_bit ;
217 reg bit_rec ;
218
219 reg rec_ack ;
220 reg ack_rec ;
221 reg nack_rec ;
222
223 reg send_ack ;
224 reg ack_sent ;
225 reg send_nack ;
226 reg nack_sent ;
227
228 reg send_stop ;
229 reg stop_sent ;
230
231 always@
232 (
233 tx_rx_state or
234 clk_gen_cnt or
235 send_start or
236 send_bit or
237 tx_shift_reg or
238 send_stop or
239 rec_ack or
240 sda_i_reg or
241 rec_bit or
242 send_ack or
243 send_nack
244 )
245 begin
246 clk_gen_cnt_clr = 1'b0 ;
247 clk_gen_cnt_en = 1'b0 ;
248 tx_rx_next_state = tx_rx_state ;
249 tx_rx_sm_idle = 1'b0 ;
250 scl_oe = 1'b0 ;
251 sda_oe = 1'b0 ;
252 scl_oe_en = 1'b0 ;
253 sda_oe_en = 1'b0 ;
254 start_sent = 1'b0 ;
255 bit_sent = 1'b0 ;
256 ack_rec = 1'b0 ;
257 nack_rec = 1'b0 ;
258 sda_i_reg_en = 1'b0 ;
259 stop_sent = 1'b0 ;
260 bit_rec = 1'b0 ;
261 ack_sent = 1'b0 ;
262 nack_sent = 1'b0 ;
263
264 case (tx_rx_state)
265
266 tx_rx_idle:
267 begin
268 tx_rx_sm_idle = 1'b1 ;
269
270 // from idle state, the only transition can be to the send start bit
271 if (send_start)
272 begin
273 tx_rx_next_state = tx_rx_start ;
274 clk_gen_cnt_clr = 1'b1 ;
275 end
276 end
277
278 tx_rx_start:
279 begin
280 clk_gen_cnt_en = 1'b1 ;
281 sda_oe = 1'b1 ;
282
283 // start bit is sent by transmiting 0 on the sda line
284 if (clk_gen_cnt == (period_cnt >> 1))
285 begin
286 start_sent = 1'b1 ;
287 sda_oe_en = 1'b1 ;
288 end
289
290 // after half clock period of driving the sda low, the only possible
291 // transition is to send state.
292 // if send bit is not active, stop the procedure - undrive sda
293 if (clk_gen_cnt == period_cnt)
294 begin
295 clk_gen_cnt_clr = 1'b1 ;
296 if (send_bit)
297 begin
298 tx_rx_next_state = tx_rx_send_bits ;
299 end
300 else
301 begin
302 sda_oe = 1'b0 ;
303 sda_oe_en = 1'b1 ;
304 tx_rx_next_state = tx_rx_idle ;
305 end
306 end
307 end
308
309 tx_rx_send_bits:
310 begin
311 clk_gen_cnt_en = 1'b1 ;
312
313 // generate high to low transition on the scl line immediately
314 if (clk_gen_cnt == 'h0)
315 begin
316 scl_oe = 1'b1 ;
317 scl_oe_en = 1'b1 ;
318 end
319
320 // after half of clock low time, load new value for sda oe, depending on the
321 // msb bit in the shift register
322 if (clk_gen_cnt == (period_cnt >> 2))
323 begin
324 sda_oe = ~tx_shift_reg[7] ;
325 sda_oe_en = 1'b1 ;
326 bit_sent = 1'b1 ;
327 end
328
329 // after clock low time, generate low to high transition on the scl line
330 if (clk_gen_cnt == (period_cnt >> 1))
331 begin
332 scl_oe = 1'b0 ;
333 scl_oe_en = 1'b1 ;
334 end
335
336 // after clock high time, check what to do next
337 if (clk_gen_cnt == (period_cnt))
338 begin
339 clk_gen_cnt_clr = 1'b1 ;
340
341 if (~send_bit)
342 begin
343 // after transmiting all the bits, the only possible transition is to the state
344 // that checks the eprom acknowledge
345 if (rec_ack)
346 tx_rx_next_state = tx_rx_rec_ack ;
347 else
348 begin
349 sda_oe = 1'b0 ;
350 sda_oe_en = 1'b1 ;
351 tx_rx_next_state = tx_rx_idle ;
352 end
353 end
354 end
355 end
356
357 tx_rx_rec_bits:
358 begin
359 clk_gen_cnt_en = 1'b1 ;
360 sda_i_reg_en = 1'b1 ;
361
362 // generate high to low transition on the scl line immediately
363 if (clk_gen_cnt == 'h0)
364 begin
365 scl_oe = 1'b1 ;
366 scl_oe_en = 1'b1 ;
367 end
368
369 // after half of clock low time, disable sda driver
370 if (clk_gen_cnt == (period_cnt >> 2))
371 begin
372 sda_oe = 1'b0 ;
373 sda_oe_en = 1'b1 ;
374 end
375
376 // after clock low time, generate low to high transition on the scl line
377 if (clk_gen_cnt == (period_cnt >> 1))
378 begin
379 scl_oe = 1'b0 ;
380 scl_oe_en = 1'b1 ;
381 end
382
383 // after half of clock high time, report received bit
384 if (clk_gen_cnt == ((period_cnt >> 1) + (period_cnt >> 2)) )
385 begin
386 bit_rec = 1'b1 ;
387 end
388
389 // after clock period is finished, check the next operation
390 if (clk_gen_cnt == (period_cnt))
391 begin
392 clk_gen_cnt_clr = 1'b1 ;
393
394 if (~rec_bit)
395 begin
396 // when all bits are received, only nack or ack next states are possible
397 if (send_ack)
398 tx_rx_next_state = tx_rx_send_ack ;
399 else if (send_nack)
400 tx_rx_next_state = tx_rx_send_nack ;
401 else
402 begin
403 tx_rx_next_state = tx_rx_idle ;
404 end
405 end
406 end
407 end
408
409 tx_rx_send_ack:
410 begin
411 clk_gen_cnt_en = 1'b1 ;
412
413 // generate high to low transition on the scl line
414 if (clk_gen_cnt == 'h0)
415 begin
416 scl_oe = 1'b1 ;
417 scl_oe_en = 1'b1 ;
418 end
419
420 // after half of clock low time, enable the sda driver
421 if (clk_gen_cnt == (period_cnt >> 2))
422 begin
423 sda_oe = 1'b1 ;
424 sda_oe_en = 1'b1 ;
425 ack_sent = 1'b1 ;
426 end
427
428 // after clock low time, disable the scl driver - generate low to high transition on the scl line
429 if (clk_gen_cnt == (period_cnt >> 1))
430 begin
431 scl_oe = 1'b0 ;
432 scl_oe_en = 1'b1 ;
433 end
434
435 // after clock period time expires, check what to do next
436 if (clk_gen_cnt == period_cnt)
437 begin
438 clk_gen_cnt_clr = 1'b1 ;
439
440 // after the byte is acknowledged, the only possible next state is receive bits
441 // state
442 if (rec_bit)
443 tx_rx_next_state = tx_rx_rec_bits ;
444 else
445 begin
446 // this should never happen
447 sda_oe = 1'b0 ;
448 sda_oe_en = 1'b1 ;
449
450 tx_rx_next_state = tx_rx_idle ;
451 end
452 end
453 end
454
455 tx_rx_rec_ack:
456 begin
457
458 clk_gen_cnt_en = 1'b1 ;
459 sda_i_reg_en = 1'b1 ;
460
461 // generate high to low transition on the scl line
462 if (clk_gen_cnt == 'h0)
463 begin
464 scl_oe = 1'b1 ;
465 scl_oe_en = 1'b1 ;
466 end
467
468 // after half of clock low time, disable the sda driver
469 if (clk_gen_cnt == (period_cnt >> 2))
470 begin
471 sda_oe = 1'b0 ;
472 sda_oe_en = 1'b1 ;
473 end
474
475 // after clock low time, disable the scl driver - generate low to high transition on the scl line
476 if (clk_gen_cnt == (period_cnt >> 1))
477 begin
478 scl_oe = 1'b0 ;
479 scl_oe_en = 1'b1 ;
480 end
481
482 // after 1/2 clock high time, report ack or nack condition, depending on the sda input state
483 if (clk_gen_cnt == ((period_cnt >> 1) + (period_cnt >> 2)) )
484 begin
485 ack_rec = ~sda_i_reg ;
486 nack_rec = sda_i_reg ;
487 end
488
489 // after clock period time expires, check what to do next
490 if (clk_gen_cnt == period_cnt)
491 begin
492 clk_gen_cnt_clr = 1'b1 ;
493
494 if (send_bit)
495 tx_rx_next_state = tx_rx_send_bits ;
496 else if (rec_bit)
497 tx_rx_next_state = tx_rx_rec_bits ;
498 else if (send_stop)
499 tx_rx_next_state = tx_rx_stop ;
500 else if (send_start)
501 tx_rx_next_state = tx_rx_restart ;
502 else
503 begin
504 // this should never happen
505 tx_rx_next_state = tx_rx_idle ;
506 end
507 end
508 end
509
510 tx_rx_send_nack:
511 begin
512 clk_gen_cnt_en = 1'b1 ;
513
514 // generate high to low transition on the scl line
515 if (clk_gen_cnt == 'h0)
516 begin
517 scl_oe = 1'b1 ;
518 scl_oe_en = 1'b1 ;
519 end
520
521 // after half of clock low time, disable the sda driver
522 if (clk_gen_cnt == (period_cnt >> 2))
523 begin
524 sda_oe = 1'b0 ;
525 sda_oe_en = 1'b1 ;
526 nack_sent = 1'b1 ;
527 end
528
529 // after clock low time, disable the scl driver - generate low to high transition on the scl line
530 if (clk_gen_cnt == (period_cnt >> 1))
531 begin
532 scl_oe = 1'b0 ;
533 scl_oe_en = 1'b1 ;
534 end
535
536 // after clock period time expires, check what to do next
537 if (clk_gen_cnt == period_cnt)
538 begin
539 clk_gen_cnt_clr = 1'b1 ;
540
541 // after the no acknowledge is sent, the only possible next state is stop
542 // state
543 if (send_stop)
544 tx_rx_next_state = tx_rx_stop ;
545 else
546 begin
547 // this should never happen
548 tx_rx_next_state = tx_rx_idle ;
549 end
550 end
551 end
552
553 tx_rx_restart:
554 begin
555 clk_gen_cnt_en = 1'b1 ;
556
557 // generate high to low transition
558 if (clk_gen_cnt == 'h0)
559 begin
560 scl_oe = 1'b1 ;
561 scl_oe_en = 1'b1 ;
562 end
563
564 // after half of clock low time, release sda line
565 if (clk_gen_cnt == (period_cnt >> 2))
566 begin
567 sda_oe = 1'b0 ;
568 sda_oe_en = 1'b1 ;
569 end
570
571 // generate low to high transition
572 if (clk_gen_cnt == (period_cnt >> 1))
573 begin
574 clk_gen_cnt_clr = 1'b1 ;
575
576 scl_oe = 1'b0 ;
577 scl_oe_en = 1'b1 ;
578
579 if (send_start)
580 tx_rx_next_state = tx_rx_start ;
581 else
582 tx_rx_next_state = tx_rx_idle ;
583 end
584 end
585
586 tx_rx_stop:
587 begin
588 clk_gen_cnt_en = 1'b1 ;
589
590 // generate high to low transition
591 if (clk_gen_cnt == 'h0)
592 begin
593 scl_oe = 1'b1 ;
594 scl_oe_en = 1'b1 ;
595 end
596
597 // after half of clock low time, drive sda line low
598 if (clk_gen_cnt == (period_cnt >> 2))
599 begin
600 sda_oe = 1'b1 ;
601 sda_oe_en = 1'b1 ;
602 end
603
604 // generate low to high transition
605 if (clk_gen_cnt == (period_cnt >> 1))
606 begin
607 scl_oe = 1'b0 ;
608 scl_oe_en = 1'b1 ;
609 end
610
611 // after full clock period, release the sda line
612 if (clk_gen_cnt == period_cnt)
613 begin
614 sda_oe = 1'b0 ;
615 sda_oe_en = 1'b1 ;
616 stop_sent = 1'b1 ;
617
618 tx_rx_next_state = tx_rx_idle ;
619 end
620 end
621
622 endcase
623 end
624
625 reg [rw_seq_state_width - 1:0] rw_seq_state ;
626
627 reg doing_read ,
628 doing_write ,
629 doing_seq_read ,
630 adr_set ;
631
632 reg [ 3: 0] bits_transfered ;
633
634 always@(posedge clk_i or posedge reset_i)
635 begin
636 if (reset_i)
637 begin
638 rw_seq_state <= rw_seq_idle ;
639 adr_set <= 1'b0 ;
640 doing_read <= 1'b0 ;
641 doing_write <= 1'b0 ;
642 doing_seq_read <= 1'b0 ;
643 dat_o <= 'h0 ;
644 tx_shift_reg <= 'h0 ;
645 send_start <= 'h0 ;
646 send_stop <= 'h0 ;
647 send_bit <= 'h0 ;
648 send_nack <= 'h0 ;
649 rec_ack <= 'h0 ;
650 no_ack_o <= 'h0 ;
651 bits_transfered <= 'h0 ;
652 write_done_o <= 'h0 ;
653 dat_rdy_o <= 'h0 ;
654 send_ack <= 'h0 ;
655 rec_bit <= 'h0 ;
656 end
657 else
658 begin
659
660 case (rw_seq_state)
661
662 rw_seq_idle:
663 begin
664 tx_shift_reg <= {4'b1010, adr_i[10: 8], 1'b0} ;
665 adr_set <= 1'b0 ;
666
667 if ( tx_rx_sm_idle & ~(doing_write | doing_read | doing_seq_read) )
668 begin
669 if (do_write_i | do_rnd_read_i | do_seq_read_i)
670 begin
671 rw_seq_state <= rw_seq_tx_ctrl ;
672 send_start <= 1'b1 ;
673 end
674
675 if (do_write_i)
676 doing_write <= 1'b1 ;
677 else if (do_rnd_read_i)
678 doing_read <= 1'b1 ;
679 else if (do_seq_read_i)
680 doing_seq_read <= 1'b1 ;
681 end
682 else
683 begin
684 doing_write <= 1'b0 ;
685 doing_read <= 1'b0 ;
686 doing_seq_read <= 1'b0 ;
687 end
688 end
689
690 rw_seq_tx_ctrl:
691 begin
692 if (send_start)
693 begin
694 bits_transfered <= 'h0 ;
695
696 if (start_sent)
697 begin
698 send_start <= 1'b0 ;
699 send_bit <= 1'b1 ;
700 end
701 end
702 else if (send_bit)
703 begin
704 if (bit_sent)
705 begin
706 bits_transfered <= bits_transfered + 1'b1 ;
707 tx_shift_reg <= {tx_shift_reg[6:0], tx_shift_reg[0]} ;
708 end
709
710 if (bits_transfered == 'h8)
711 begin
712 send_bit <= 1'b0 ;
713 rec_ack <= 1'b1 ;
714 end
715 end
716 else if (rec_ack)
717 begin
718 bits_transfered <= 'h0 ;
719
720 if (ack_rec | nack_rec)
721 rec_ack <= 1'b0 ;
722
723 if (ack_rec)
724 begin
725 if (doing_write | ~adr_set)
726 begin
727 rw_seq_state <= rw_seq_tx_adr ;
728 tx_shift_reg <= adr_i[ 7: 0] ;
729 send_bit <= 1'b1 ;
730 end
731 else
732 begin
733 rw_seq_state <= rw_seq_rx_byte ;
734 rec_bit <= 1'b1 ;
735 end
736 end
737 else if (nack_rec)
738 begin
739 no_ack_o <= 1'b1 ;
740 send_stop <= 1'b1 ;
741 end
742 end
743 else if (send_stop)
744 begin
745 no_ack_o <= 1'b0 ;
746
747 if (stop_sent)
748 begin
749 send_stop <= 1'b0 ;
750 rw_seq_state <= rw_seq_idle ;
751 end
752 end
753 end
754
755 rw_seq_tx_adr:
756 begin
757 if (send_bit)
758 begin
759 if (bit_sent)
760 begin
761 bits_transfered <= bits_transfered + 1'b1 ;
762 tx_shift_reg <= {tx_shift_reg[6:0], tx_shift_reg[0]} ;
763 end
764
765 if (bits_transfered == 'h8)
766 begin
767 send_bit <= 1'b0 ;
768 rec_ack <= 1'b1 ;
769 end
770 end
771 else if (rec_ack)
772 begin
773 bits_transfered <= 'h0 ;
774
775 if (ack_rec | nack_rec)
776 rec_ack <= 1'b0 ;
777
778 if (ack_rec)
779 begin
780
781 adr_set <= 1'b1 ;
782
783 if (doing_write)
784 begin
785 send_bit <= 1'b1 ;
786 rw_seq_state <= rw_seq_tx_byte ;
787 tx_shift_reg <= dat_i ;
788 end
789 else if (doing_read | doing_seq_read)
790 begin
791 send_start <= 1'b1 ;
792 rw_seq_state <= rw_seq_tx_ctrl ;
793 tx_shift_reg <= 8'b10100001 ;
794 end
795 end
796 else if (nack_rec)
797 begin
798 no_ack_o <= 1'b1 ;
799 send_stop <= 1'b1 ;
800 end
801 end
802 else if (send_stop)
803 begin
804 no_ack_o <= 1'b0 ;
805
806 if (stop_sent)
807 begin
808 send_stop <= 1'b0 ;
809 rw_seq_state <= rw_seq_idle ;
810 end
811 end
812 end
813
814 rw_seq_tx_byte:
815 begin
816 if (send_bit)
817 begin
818 if (bit_sent)
819 begin
820 bits_transfered <= bits_transfered + 1'b1 ;
821 tx_shift_reg <= {tx_shift_reg[6:0], tx_shift_reg[0]} ;
822 end
823
824 if (bits_transfered == 'h8)
825 begin
826 send_bit <= 1'b0 ;
827 rec_ack <= 1'b1 ;
828 end
829 end
830 else if (rec_ack)
831 begin
832 bits_transfered <= 'h0 ;
833
834 if (ack_rec | nack_rec)
835 begin
836 rec_ack <= 1'b0 ;
837 send_stop <= 1'b1 ;
838 end
839
840 if (nack_rec)
841 no_ack_o <= 1'b1 ;
842
843 if (ack_rec)
844 write_done_o <= 1'b1 ;
845 end
846 else if (send_stop)
847 begin
848 no_ack_o <= 1'b0 ;
849 write_done_o <= 1'b0 ;
850
851 if (stop_sent)
852 begin
853 send_stop <= 1'b0 ;
854 rw_seq_state <= rw_seq_idle ;
855 end
856 end
857 end
858
859 rw_seq_rx_byte:
860 begin
861 if (rec_bit)
862 begin
863 if (bit_rec)
864 begin
865 bits_transfered <= bits_transfered + 1'b1 ;
866 dat_o <= {dat_o[6:0], sda_i_reg} ;
867 end
868
869 if (bits_transfered == 'h8)
870 begin
871 rec_bit <= 1'b0 ;
872 dat_rdy_o <= 1'b1 ;
873 if (doing_read)
874 send_nack <= 1'b1 ;
875 else
876 send_ack <= 1'b1 ;
877 end
878 end
879 else if (send_nack)
880 begin
881 dat_rdy_o <= 1'b0 ;
882 bits_transfered <= 'h0 ;
883
884 if (nack_sent)
885 begin
886 send_stop <= 1'b1 ;
887 send_nack <= 1'b0 ;
888 end
889 end
890 else if (send_ack)
891 begin
892 dat_rdy_o <= 1'b0 ;
893 bits_transfered <= 'h0 ;
894
895 if (~do_seq_read_i)
896 begin
897 send_ack <= 1'b0 ;
898 send_nack <= 1'b1 ;
899 end
900 else if (ack_sent)
901 begin
902 send_ack <= 1'b0 ;
903 rec_bit <= 1'b1 ;
904 end
905 end
906 else if (send_stop)
907 begin
908 if (stop_sent)
909 begin
910 send_stop <= 1'b0 ;
911 rw_seq_state <= rw_seq_idle ;
912 end
913 end
914 end
915 endcase
916 end
917 end
918
919 endmodule // pci_spoci_ctrl
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