1 /*-
2 * Low level routines for the Advanced Systems Inc. SCSI controllers chips
3 *
4 * Copyright (c) 1996-1997, 1999-2000 Justin Gibbs.
5 * All rights reserved.
6 *
7 * Redistribution and use in source and binary forms, with or without
8 * modification, are permitted provided that the following conditions
9 * are met:
10 * 1. Redistributions of source code must retain the above copyright
11 * notice, this list of conditions, and the following disclaimer,
12 * without modification, immediately at the beginning of the file.
13 * 2. Redistributions in binary form must reproduce the above copyright
14 * notice, this list of conditions and the following disclaimer in the
15 * documentation and/or other materials provided with the distribution.
16 * 3. The name of the author may not be used to endorse or promote products
17 * derived from this software without specific prior written permission.
18 *
19 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
20 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
21 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
22 * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE FOR
23 * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
24 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
25 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
26 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
27 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
28 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
29 * SUCH DAMAGE.
30 */
31 /*-
32 * Ported from:
33 * advansys.c - Linux Host Driver for AdvanSys SCSI Adapters
34 *
35 * Copyright (c) 1995-1996 Advanced System Products, Inc.
36 * All Rights Reserved.
37 *
38 * Redistribution and use in source and binary forms, with or without
39 * modification, are permitted provided that redistributions of source
40 * code retain the above copyright notice and this comment without
41 * modification.
42 */
43
44 #include <sys/cdefs.h>
45 __FBSDID("$FreeBSD: releng/11.1/sys/dev/advansys/advlib.c 298955 2016-05-03 03:41:25Z pfg $");
46
47 #include <sys/param.h>
48 #include <sys/conf.h>
49 #include <sys/lock.h>
50 #include <sys/kernel.h>
51 #include <sys/mutex.h>
52 #include <sys/systm.h>
53
54 #include <machine/bus.h>
55 #include <machine/resource.h>
56 #include <sys/bus.h>
57 #include <sys/rman.h>
58
59 #include <cam/cam.h>
60 #include <cam/cam_ccb.h>
61 #include <cam/cam_sim.h>
62 #include <cam/cam_xpt_sim.h>
63
64 #include <cam/scsi/scsi_all.h>
65 #include <cam/scsi/scsi_message.h>
66 #include <cam/scsi/scsi_da.h>
67 #include <cam/scsi/scsi_cd.h>
68
69 #include <vm/vm.h>
70 #include <vm/vm_param.h>
71 #include <vm/pmap.h>
72
73 #include <dev/advansys/advansys.h>
74 #include <dev/advansys/advmcode.h>
75
76 struct adv_quirk_entry {
77 struct scsi_inquiry_pattern inq_pat;
78 u_int8_t quirks;
79 #define ADV_QUIRK_FIX_ASYN_XFER_ALWAYS 0x01
80 #define ADV_QUIRK_FIX_ASYN_XFER 0x02
81 };
82
83 static struct adv_quirk_entry adv_quirk_table[] =
84 {
85 {
86 { T_CDROM, SIP_MEDIA_REMOVABLE, "HP", "*", "*" },
87 ADV_QUIRK_FIX_ASYN_XFER_ALWAYS|ADV_QUIRK_FIX_ASYN_XFER
88 },
89 {
90 { T_CDROM, SIP_MEDIA_REMOVABLE, "NEC", "CD-ROM DRIVE", "*" },
91 0
92 },
93 {
94 {
95 T_SEQUENTIAL, SIP_MEDIA_REMOVABLE,
96 "TANDBERG", " TDC 36", "*"
97 },
98 0
99 },
100 {
101 { T_SEQUENTIAL, SIP_MEDIA_REMOVABLE, "WANGTEK", "*", "*" },
102 0
103 },
104 {
105 {
106 T_PROCESSOR, SIP_MEDIA_REMOVABLE|SIP_MEDIA_FIXED,
107 "*", "*", "*"
108 },
109 0
110 },
111 {
112 {
113 T_SCANNER, SIP_MEDIA_REMOVABLE|SIP_MEDIA_FIXED,
114 "*", "*", "*"
115 },
116 0
117 },
118 {
119 /* Default quirk entry */
120 {
121 T_ANY, SIP_MEDIA_REMOVABLE|SIP_MEDIA_FIXED,
122 /*vendor*/"*", /*product*/"*", /*revision*/"*"
123 },
124 ADV_QUIRK_FIX_ASYN_XFER,
125 }
126 };
127
128 /*
129 * Allowable periods in ns
130 */
131 static u_int8_t adv_sdtr_period_tbl[] =
132 {
133 25,
134 30,
135 35,
136 40,
137 50,
138 60,
139 70,
140 85
141 };
142
143 static u_int8_t adv_sdtr_period_tbl_ultra[] =
144 {
145 12,
146 19,
147 25,
148 32,
149 38,
150 44,
151 50,
152 57,
153 63,
154 69,
155 75,
156 82,
157 88,
158 94,
159 100,
160 107
161 };
162
163 struct ext_msg {
164 u_int8_t msg_type;
165 u_int8_t msg_len;
166 u_int8_t msg_req;
167 union {
168 struct {
169 u_int8_t sdtr_xfer_period;
170 u_int8_t sdtr_req_ack_offset;
171 } sdtr;
172 struct {
173 u_int8_t wdtr_width;
174 } wdtr;
175 struct {
176 u_int8_t mdp[4];
177 } mdp;
178 } u_ext_msg;
179 u_int8_t res;
180 };
181
182 #define xfer_period u_ext_msg.sdtr.sdtr_xfer_period
183 #define req_ack_offset u_ext_msg.sdtr.sdtr_req_ack_offset
184 #define wdtr_width u_ext_msg.wdtr.wdtr_width
185 #define mdp_b3 u_ext_msg.mdp_b3
186 #define mdp_b2 u_ext_msg.mdp_b2
187 #define mdp_b1 u_ext_msg.mdp_b1
188 #define mdp_b0 u_ext_msg.mdp_b0
189
190 /*
191 * Some of the early PCI adapters have problems with
192 * async transfers. Instead use an offset of 1.
193 */
194 #define ASYN_SDTR_DATA_FIX_PCI_REV_AB 0x41
195
196 /* LRAM routines */
197 static void adv_read_lram_16_multi(struct adv_softc *adv, u_int16_t s_addr,
198 u_int16_t *buffer, int count);
199 static void adv_write_lram_16_multi(struct adv_softc *adv,
200 u_int16_t s_addr, u_int16_t *buffer,
201 int count);
202 static void adv_mset_lram_16(struct adv_softc *adv, u_int16_t s_addr,
203 u_int16_t set_value, int count);
204 static u_int32_t adv_msum_lram_16(struct adv_softc *adv, u_int16_t s_addr,
205 int count);
206
207 static int adv_write_and_verify_lram_16(struct adv_softc *adv,
208 u_int16_t addr, u_int16_t value);
209 static u_int32_t adv_read_lram_32(struct adv_softc *adv, u_int16_t addr);
210
211
212 static void adv_write_lram_32(struct adv_softc *adv, u_int16_t addr,
213 u_int32_t value);
214 static void adv_write_lram_32_multi(struct adv_softc *adv,
215 u_int16_t s_addr, u_int32_t *buffer,
216 int count);
217
218 /* EEPROM routines */
219 static u_int16_t adv_read_eeprom_16(struct adv_softc *adv, u_int8_t addr);
220 static u_int16_t adv_write_eeprom_16(struct adv_softc *adv, u_int8_t addr,
221 u_int16_t value);
222 static int adv_write_eeprom_cmd_reg(struct adv_softc *adv,
223 u_int8_t cmd_reg);
224 static int adv_set_eeprom_config_once(struct adv_softc *adv,
225 struct adv_eeprom_config *eeconfig);
226
227 /* Initialization */
228 static u_int32_t adv_load_microcode(struct adv_softc *adv, u_int16_t s_addr,
229 u_int16_t *mcode_buf, u_int16_t mcode_size);
230
231 static void adv_reinit_lram(struct adv_softc *adv);
232 static void adv_init_lram(struct adv_softc *adv);
233 static int adv_init_microcode_var(struct adv_softc *adv);
234 static void adv_init_qlink_var(struct adv_softc *adv);
235
236 /* Interrupts */
237 static void adv_disable_interrupt(struct adv_softc *adv);
238 static void adv_enable_interrupt(struct adv_softc *adv);
239 static void adv_toggle_irq_act(struct adv_softc *adv);
240
241 /* Chip Control */
242 static int adv_host_req_chip_halt(struct adv_softc *adv);
243 static void adv_set_chip_ih(struct adv_softc *adv, u_int16_t ins_code);
244 #if 0
245 static u_int8_t adv_get_chip_scsi_ctrl(struct adv_softc *adv);
246 #endif
247
248 /* Queue handling and execution */
249 static __inline int
250 adv_sgcount_to_qcount(int sgcount);
251
252 static __inline int
253 adv_sgcount_to_qcount(int sgcount)
254 {
255 int n_sg_list_qs;
256
257 n_sg_list_qs = ((sgcount - 1) / ADV_SG_LIST_PER_Q);
258 if (((sgcount - 1) % ADV_SG_LIST_PER_Q) != 0)
259 n_sg_list_qs++;
260 return (n_sg_list_qs + 1);
261 }
262
263 #if BYTE_ORDER == BIG_ENDIAN
264 static void adv_adj_endian_qdone_info(struct adv_q_done_info *);
265 static void adv_adj_scsiq_endian(struct adv_scsi_q *);
266 #endif
267 static void adv_get_q_info(struct adv_softc *adv, u_int16_t s_addr,
268 u_int16_t *inbuf, int words);
269 static u_int adv_get_num_free_queues(struct adv_softc *adv, u_int8_t n_qs);
270 static u_int8_t adv_alloc_free_queues(struct adv_softc *adv,
271 u_int8_t free_q_head, u_int8_t n_free_q);
272 static u_int8_t adv_alloc_free_queue(struct adv_softc *adv,
273 u_int8_t free_q_head);
274 static int adv_send_scsi_queue(struct adv_softc *adv,
275 struct adv_scsi_q *scsiq,
276 u_int8_t n_q_required);
277 static void adv_put_ready_sg_list_queue(struct adv_softc *adv,
278 struct adv_scsi_q *scsiq,
279 u_int q_no);
280 static void adv_put_ready_queue(struct adv_softc *adv,
281 struct adv_scsi_q *scsiq, u_int q_no);
282 static void adv_put_scsiq(struct adv_softc *adv, u_int16_t s_addr,
283 u_int16_t *buffer, int words);
284
285 /* Messages */
286 static void adv_handle_extmsg_in(struct adv_softc *adv,
287 u_int16_t halt_q_addr, u_int8_t q_cntl,
288 target_bit_vector target_id,
289 int tid);
290 static void adv_msgout_sdtr(struct adv_softc *adv, u_int8_t sdtr_period,
291 u_int8_t sdtr_offset);
292 static void adv_set_sdtr_reg_at_id(struct adv_softc *adv, int id,
293 u_int8_t sdtr_data);
294
295
296 /* Exported functions first */
297
298 void
299 advasync(void *callback_arg, u_int32_t code, struct cam_path *path, void *arg)
300 {
301 struct adv_softc *adv;
302
303 adv = (struct adv_softc *)callback_arg;
304 mtx_assert(&adv->lock, MA_OWNED);
305 switch (code) {
306 case AC_FOUND_DEVICE:
307 {
308 struct ccb_getdev *cgd;
309 target_bit_vector target_mask;
310 int num_entries;
311 caddr_t match;
312 struct adv_quirk_entry *entry;
313 struct adv_target_transinfo* tinfo;
314
315 cgd = (struct ccb_getdev *)arg;
316
317 target_mask = ADV_TID_TO_TARGET_MASK(cgd->ccb_h.target_id);
318
319 num_entries = nitems(adv_quirk_table);
320 match = cam_quirkmatch((caddr_t)&cgd->inq_data,
321 (caddr_t)adv_quirk_table,
322 num_entries, sizeof(*adv_quirk_table),
323 scsi_inquiry_match);
324
325 if (match == NULL)
326 panic("advasync: device didn't match wildcard entry!!");
327
328 entry = (struct adv_quirk_entry *)match;
329
330 if (adv->bug_fix_control & ADV_BUG_FIX_ASYN_USE_SYN) {
331 if ((entry->quirks & ADV_QUIRK_FIX_ASYN_XFER_ALWAYS)!=0)
332 adv->fix_asyn_xfer_always |= target_mask;
333 else
334 adv->fix_asyn_xfer_always &= ~target_mask;
335 /*
336 * We start out life with all bits set and clear them
337 * after we've determined that the fix isn't necessary.
338 * It may well be that we've already cleared a target
339 * before the full inquiry session completes, so don't
340 * gratuitously set a target bit even if it has this
341 * quirk. But, if the quirk exonerates a device, clear
342 * the bit now.
343 */
344 if ((entry->quirks & ADV_QUIRK_FIX_ASYN_XFER) == 0)
345 adv->fix_asyn_xfer &= ~target_mask;
346 }
347 /*
348 * Reset our sync settings now that we've determined
349 * what quirks are in effect for the device.
350 */
351 tinfo = &adv->tinfo[cgd->ccb_h.target_id];
352 adv_set_syncrate(adv, cgd->ccb_h.path,
353 cgd->ccb_h.target_id,
354 tinfo->current.period,
355 tinfo->current.offset,
356 ADV_TRANS_CUR);
357 break;
358 }
359 case AC_LOST_DEVICE:
360 {
361 u_int target_mask;
362
363 if (adv->bug_fix_control & ADV_BUG_FIX_ASYN_USE_SYN) {
364 target_mask = 0x01 << xpt_path_target_id(path);
365 adv->fix_asyn_xfer |= target_mask;
366 }
367
368 /*
369 * Revert to async transfers
370 * for the next device.
371 */
372 adv_set_syncrate(adv, /*path*/NULL,
373 xpt_path_target_id(path),
374 /*period*/0,
375 /*offset*/0,
376 ADV_TRANS_GOAL|ADV_TRANS_CUR);
377 }
378 default:
379 break;
380 }
381 }
382
383 void
384 adv_set_bank(struct adv_softc *adv, u_int8_t bank)
385 {
386 u_int8_t control;
387
388 /*
389 * Start out with the bank reset to 0
390 */
391 control = ADV_INB(adv, ADV_CHIP_CTRL)
392 & (~(ADV_CC_SINGLE_STEP | ADV_CC_TEST
393 | ADV_CC_DIAG | ADV_CC_SCSI_RESET
394 | ADV_CC_CHIP_RESET | ADV_CC_BANK_ONE));
395 if (bank == 1) {
396 control |= ADV_CC_BANK_ONE;
397 } else if (bank == 2) {
398 control |= ADV_CC_DIAG | ADV_CC_BANK_ONE;
399 }
400 ADV_OUTB(adv, ADV_CHIP_CTRL, control);
401 }
402
403 u_int8_t
404 adv_read_lram_8(struct adv_softc *adv, u_int16_t addr)
405 {
406 u_int8_t byte_data;
407 u_int16_t word_data;
408
409 /*
410 * LRAM is accessed on 16bit boundaries.
411 */
412 ADV_OUTW(adv, ADV_LRAM_ADDR, addr & 0xFFFE);
413 word_data = ADV_INW(adv, ADV_LRAM_DATA);
414 if (addr & 1) {
415 #if BYTE_ORDER == BIG_ENDIAN
416 byte_data = (u_int8_t)(word_data & 0xFF);
417 #else
418 byte_data = (u_int8_t)((word_data >> 8) & 0xFF);
419 #endif
420 } else {
421 #if BYTE_ORDER == BIG_ENDIAN
422 byte_data = (u_int8_t)((word_data >> 8) & 0xFF);
423 #else
424 byte_data = (u_int8_t)(word_data & 0xFF);
425 #endif
426 }
427 return (byte_data);
428 }
429
430 void
431 adv_write_lram_8(struct adv_softc *adv, u_int16_t addr, u_int8_t value)
432 {
433 u_int16_t word_data;
434
435 word_data = adv_read_lram_16(adv, addr & 0xFFFE);
436 if (addr & 1) {
437 word_data &= 0x00FF;
438 word_data |= (((u_int8_t)value << 8) & 0xFF00);
439 } else {
440 word_data &= 0xFF00;
441 word_data |= ((u_int8_t)value & 0x00FF);
442 }
443 adv_write_lram_16(adv, addr & 0xFFFE, word_data);
444 }
445
446
447 u_int16_t
448 adv_read_lram_16(struct adv_softc *adv, u_int16_t addr)
449 {
450 ADV_OUTW(adv, ADV_LRAM_ADDR, addr);
451 return (ADV_INW(adv, ADV_LRAM_DATA));
452 }
453
454 void
455 adv_write_lram_16(struct adv_softc *adv, u_int16_t addr, u_int16_t value)
456 {
457 ADV_OUTW(adv, ADV_LRAM_ADDR, addr);
458 ADV_OUTW(adv, ADV_LRAM_DATA, value);
459 }
460
461 /*
462 * Determine if there is a board at "iobase" by looking
463 * for the AdvanSys signatures. Return 1 if a board is
464 * found, 0 otherwise.
465 */
466 int
467 adv_find_signature(struct resource *res)
468 {
469 u_int16_t signature;
470
471 if (bus_read_1(res, ADV_SIGNATURE_BYTE) == ADV_1000_ID1B) {
472 signature = bus_read_2(res, ADV_SIGNATURE_WORD);
473 if ((signature == ADV_1000_ID0W)
474 || (signature == ADV_1000_ID0W_FIX))
475 return (1);
476 }
477 return (0);
478 }
479
480 void
481 adv_lib_init(struct adv_softc *adv)
482 {
483 if ((adv->type & ADV_ULTRA) != 0) {
484 adv->sdtr_period_tbl = adv_sdtr_period_tbl_ultra;
485 adv->sdtr_period_tbl_size = sizeof(adv_sdtr_period_tbl_ultra);
486 } else {
487 adv->sdtr_period_tbl = adv_sdtr_period_tbl;
488 adv->sdtr_period_tbl_size = sizeof(adv_sdtr_period_tbl);
489 }
490 }
491
492 u_int16_t
493 adv_get_eeprom_config(struct adv_softc *adv, struct
494 adv_eeprom_config *eeprom_config)
495 {
496 u_int16_t sum;
497 u_int16_t *wbuf;
498 u_int8_t cfg_beg;
499 u_int8_t cfg_end;
500 u_int8_t s_addr;
501
502 wbuf = (u_int16_t *)eeprom_config;
503 sum = 0;
504
505 for (s_addr = 0; s_addr < 2; s_addr++, wbuf++) {
506 *wbuf = adv_read_eeprom_16(adv, s_addr);
507 sum += *wbuf;
508 }
509
510 if (adv->type & ADV_VL) {
511 cfg_beg = ADV_EEPROM_CFG_BEG_VL;
512 cfg_end = ADV_EEPROM_MAX_ADDR_VL;
513 } else {
514 cfg_beg = ADV_EEPROM_CFG_BEG;
515 cfg_end = ADV_EEPROM_MAX_ADDR;
516 }
517
518 for (s_addr = cfg_beg; s_addr <= (cfg_end - 1); s_addr++, wbuf++) {
519 *wbuf = adv_read_eeprom_16(adv, s_addr);
520 sum += *wbuf;
521 #ifdef ADV_DEBUG_EEPROM
522 printf("Addr 0x%x: 0x%04x\n", s_addr, *wbuf);
523 #endif
524 }
525 *wbuf = adv_read_eeprom_16(adv, s_addr);
526 return (sum);
527 }
528
529 int
530 adv_set_eeprom_config(struct adv_softc *adv,
531 struct adv_eeprom_config *eeprom_config)
532 {
533 int retry;
534
535 retry = 0;
536 while (1) {
537 if (adv_set_eeprom_config_once(adv, eeprom_config) == 0) {
538 break;
539 }
540 if (++retry > ADV_EEPROM_MAX_RETRY) {
541 break;
542 }
543 }
544 return (retry > ADV_EEPROM_MAX_RETRY);
545 }
546
547 int
548 adv_reset_chip(struct adv_softc *adv, int reset_bus)
549 {
550 adv_stop_chip(adv);
551 ADV_OUTB(adv, ADV_CHIP_CTRL, ADV_CC_CHIP_RESET | ADV_CC_HALT
552 | (reset_bus ? ADV_CC_SCSI_RESET : 0));
553 DELAY(60);
554
555 adv_set_chip_ih(adv, ADV_INS_RFLAG_WTM);
556 adv_set_chip_ih(adv, ADV_INS_HALT);
557
558 if (reset_bus)
559 ADV_OUTB(adv, ADV_CHIP_CTRL, ADV_CC_CHIP_RESET | ADV_CC_HALT);
560
561 ADV_OUTB(adv, ADV_CHIP_CTRL, ADV_CC_HALT);
562 if (reset_bus)
563 DELAY(200 * 1000);
564
565 ADV_OUTW(adv, ADV_CHIP_STATUS, ADV_CIW_CLR_SCSI_RESET_INT);
566 ADV_OUTW(adv, ADV_CHIP_STATUS, 0);
567 return (adv_is_chip_halted(adv));
568 }
569
570 int
571 adv_test_external_lram(struct adv_softc* adv)
572 {
573 u_int16_t q_addr;
574 u_int16_t saved_value;
575 int success;
576
577 success = 0;
578
579 q_addr = ADV_QNO_TO_QADDR(241);
580 saved_value = adv_read_lram_16(adv, q_addr);
581 if (adv_write_and_verify_lram_16(adv, q_addr, 0x55AA) == 0) {
582 success = 1;
583 adv_write_lram_16(adv, q_addr, saved_value);
584 }
585 return (success);
586 }
587
588
589 int
590 adv_init_lram_and_mcode(struct adv_softc *adv)
591 {
592 u_int32_t retval;
593
594 adv_disable_interrupt(adv);
595
596 adv_init_lram(adv);
597
598 retval = adv_load_microcode(adv, 0, (u_int16_t *)adv_mcode,
599 adv_mcode_size);
600 if (retval != adv_mcode_chksum) {
601 device_printf(adv->dev,
602 "Microcode download failed checksum!\n");
603 return (1);
604 }
605
606 if (adv_init_microcode_var(adv) != 0)
607 return (1);
608
609 adv_enable_interrupt(adv);
610 return (0);
611 }
612
613 u_int8_t
614 adv_get_chip_irq(struct adv_softc *adv)
615 {
616 u_int16_t cfg_lsw;
617 u_int8_t chip_irq;
618
619 cfg_lsw = ADV_INW(adv, ADV_CONFIG_LSW);
620
621 if ((adv->type & ADV_VL) != 0) {
622 chip_irq = (u_int8_t)(((cfg_lsw >> 2) & 0x07));
623 if ((chip_irq == 0) ||
624 (chip_irq == 4) ||
625 (chip_irq == 7)) {
626 return (0);
627 }
628 return (chip_irq + (ADV_MIN_IRQ_NO - 1));
629 }
630 chip_irq = (u_int8_t)(((cfg_lsw >> 2) & 0x03));
631 if (chip_irq == 3)
632 chip_irq += 2;
633 return (chip_irq + ADV_MIN_IRQ_NO);
634 }
635
636 u_int8_t
637 adv_set_chip_irq(struct adv_softc *adv, u_int8_t irq_no)
638 {
639 u_int16_t cfg_lsw;
640
641 if ((adv->type & ADV_VL) != 0) {
642 if (irq_no != 0) {
643 if ((irq_no < ADV_MIN_IRQ_NO)
644 || (irq_no > ADV_MAX_IRQ_NO)) {
645 irq_no = 0;
646 } else {
647 irq_no -= ADV_MIN_IRQ_NO - 1;
648 }
649 }
650 cfg_lsw = ADV_INW(adv, ADV_CONFIG_LSW) & 0xFFE3;
651 cfg_lsw |= 0x0010;
652 ADV_OUTW(adv, ADV_CONFIG_LSW, cfg_lsw);
653 adv_toggle_irq_act(adv);
654
655 cfg_lsw = ADV_INW(adv, ADV_CONFIG_LSW) & 0xFFE0;
656 cfg_lsw |= (irq_no & 0x07) << 2;
657 ADV_OUTW(adv, ADV_CONFIG_LSW, cfg_lsw);
658 adv_toggle_irq_act(adv);
659 } else if ((adv->type & ADV_ISA) != 0) {
660 if (irq_no == 15)
661 irq_no -= 2;
662 irq_no -= ADV_MIN_IRQ_NO;
663 cfg_lsw = ADV_INW(adv, ADV_CONFIG_LSW) & 0xFFF3;
664 cfg_lsw |= (irq_no & 0x03) << 2;
665 ADV_OUTW(adv, ADV_CONFIG_LSW, cfg_lsw);
666 }
667 return (adv_get_chip_irq(adv));
668 }
669
670 void
671 adv_set_chip_scsiid(struct adv_softc *adv, int new_id)
672 {
673 u_int16_t cfg_lsw;
674
675 cfg_lsw = ADV_INW(adv, ADV_CONFIG_LSW);
676 if (ADV_CONFIG_SCSIID(cfg_lsw) == new_id)
677 return;
678 cfg_lsw &= ~ADV_CFG_LSW_SCSIID;
679 cfg_lsw |= (new_id & ADV_MAX_TID) << ADV_CFG_LSW_SCSIID_SHIFT;
680 ADV_OUTW(adv, ADV_CONFIG_LSW, cfg_lsw);
681 }
682
683 int
684 adv_execute_scsi_queue(struct adv_softc *adv, struct adv_scsi_q *scsiq,
685 u_int32_t datalen)
686 {
687 struct adv_target_transinfo* tinfo;
688 u_int32_t *p_data_addr;
689 u_int32_t *p_data_bcount;
690 int disable_syn_offset_one_fix;
691 int retval;
692 u_int n_q_required;
693 u_int32_t addr;
694 u_int8_t sg_entry_cnt;
695 u_int8_t target_ix;
696 u_int8_t sg_entry_cnt_minus_one;
697 u_int8_t tid_no;
698
699 if (!dumping)
700 mtx_assert(&adv->lock, MA_OWNED);
701 scsiq->q1.q_no = 0;
702 retval = 1; /* Default to error case */
703 target_ix = scsiq->q2.target_ix;
704 tid_no = ADV_TIX_TO_TID(target_ix);
705 tinfo = &adv->tinfo[tid_no];
706
707 if (scsiq->cdbptr[0] == REQUEST_SENSE) {
708 /* Renegotiate if appropriate. */
709 adv_set_syncrate(adv, /*struct cam_path */NULL,
710 tid_no, /*period*/0, /*offset*/0,
711 ADV_TRANS_CUR);
712 if (tinfo->current.period != tinfo->goal.period) {
713 adv_msgout_sdtr(adv, tinfo->goal.period,
714 tinfo->goal.offset);
715 scsiq->q1.cntl |= (QC_MSG_OUT | QC_URGENT);
716 }
717 }
718
719 if ((scsiq->q1.cntl & QC_SG_HEAD) != 0) {
720 sg_entry_cnt = scsiq->sg_head->entry_cnt;
721 sg_entry_cnt_minus_one = sg_entry_cnt - 1;
722
723 #ifdef DIAGNOSTIC
724 if (sg_entry_cnt <= 1)
725 panic("adv_execute_scsi_queue: Queue "
726 "with QC_SG_HEAD set but %d segs.", sg_entry_cnt);
727
728 if (sg_entry_cnt > ADV_MAX_SG_LIST)
729 panic("adv_execute_scsi_queue: "
730 "Queue with too many segs.");
731
732 if ((adv->type & (ADV_ISA | ADV_VL | ADV_EISA)) != 0) {
733 int i;
734
735 for (i = 0; i < sg_entry_cnt_minus_one; i++) {
736 addr = scsiq->sg_head->sg_list[i].addr +
737 scsiq->sg_head->sg_list[i].bytes;
738
739 if ((addr & 0x0003) != 0)
740 panic("adv_execute_scsi_queue: SG "
741 "with odd address or byte count");
742 }
743 }
744 #endif
745 p_data_addr =
746 &scsiq->sg_head->sg_list[sg_entry_cnt_minus_one].addr;
747 p_data_bcount =
748 &scsiq->sg_head->sg_list[sg_entry_cnt_minus_one].bytes;
749
750 n_q_required = adv_sgcount_to_qcount(sg_entry_cnt);
751 scsiq->sg_head->queue_cnt = n_q_required - 1;
752 } else {
753 p_data_addr = &scsiq->q1.data_addr;
754 p_data_bcount = &scsiq->q1.data_cnt;
755 n_q_required = 1;
756 }
757
758 disable_syn_offset_one_fix = FALSE;
759
760 if ((adv->fix_asyn_xfer & scsiq->q1.target_id) != 0
761 && (adv->fix_asyn_xfer_always & scsiq->q1.target_id) == 0) {
762
763 if (datalen != 0) {
764 if (datalen < 512) {
765 disable_syn_offset_one_fix = TRUE;
766 } else {
767 if (scsiq->cdbptr[0] == INQUIRY
768 || scsiq->cdbptr[0] == REQUEST_SENSE
769 || scsiq->cdbptr[0] == READ_CAPACITY
770 || scsiq->cdbptr[0] == MODE_SELECT_6
771 || scsiq->cdbptr[0] == MODE_SENSE_6
772 || scsiq->cdbptr[0] == MODE_SENSE_10
773 || scsiq->cdbptr[0] == MODE_SELECT_10
774 || scsiq->cdbptr[0] == READ_TOC) {
775 disable_syn_offset_one_fix = TRUE;
776 }
777 }
778 }
779 }
780
781 if (disable_syn_offset_one_fix) {
782 scsiq->q2.tag_code &=
783 ~(MSG_SIMPLE_Q_TAG|MSG_HEAD_OF_Q_TAG|MSG_ORDERED_Q_TAG);
784 scsiq->q2.tag_code |= (ADV_TAG_FLAG_DISABLE_ASYN_USE_SYN_FIX
785 | ADV_TAG_FLAG_DISABLE_DISCONNECT);
786 }
787
788 if ((adv->bug_fix_control & ADV_BUG_FIX_IF_NOT_DWB) != 0
789 && (scsiq->cdbptr[0] == READ_10 || scsiq->cdbptr[0] == READ_6)) {
790 u_int8_t extra_bytes;
791
792 addr = *p_data_addr + *p_data_bcount;
793 extra_bytes = addr & 0x0003;
794 if (extra_bytes != 0
795 && ((scsiq->q1.cntl & QC_SG_HEAD) != 0
796 || (scsiq->q1.data_cnt & 0x01FF) == 0)) {
797 scsiq->q2.tag_code |= ADV_TAG_FLAG_EXTRA_BYTES;
798 scsiq->q1.extra_bytes = extra_bytes;
799 *p_data_bcount -= extra_bytes;
800 }
801 }
802
803 if ((adv_get_num_free_queues(adv, n_q_required) >= n_q_required)
804 || ((scsiq->q1.cntl & QC_URGENT) != 0))
805 retval = adv_send_scsi_queue(adv, scsiq, n_q_required);
806
807 return (retval);
808 }
809
810
811 u_int8_t
812 adv_copy_lram_doneq(struct adv_softc *adv, u_int16_t q_addr,
813 struct adv_q_done_info *scsiq, u_int32_t max_dma_count)
814 {
815 u_int16_t val;
816 u_int8_t sg_queue_cnt;
817
818 adv_get_q_info(adv, q_addr + ADV_SCSIQ_DONE_INFO_BEG,
819 (u_int16_t *)scsiq,
820 (sizeof(scsiq->d2) + sizeof(scsiq->d3)) / 2);
821
822 #if BYTE_ORDER == BIG_ENDIAN
823 adv_adj_endian_qdone_info(scsiq);
824 #endif
825
826 val = adv_read_lram_16(adv, q_addr + ADV_SCSIQ_B_STATUS);
827 scsiq->q_status = val & 0xFF;
828 scsiq->q_no = (val >> 8) & 0XFF;
829
830 val = adv_read_lram_16(adv, q_addr + ADV_SCSIQ_B_CNTL);
831 scsiq->cntl = val & 0xFF;
832 sg_queue_cnt = (val >> 8) & 0xFF;
833
834 val = adv_read_lram_16(adv,q_addr + ADV_SCSIQ_B_SENSE_LEN);
835 scsiq->sense_len = val & 0xFF;
836 scsiq->extra_bytes = (val >> 8) & 0xFF;
837
838 /*
839 * Due to a bug in accessing LRAM on the 940UA, the residual
840 * is split into separate high and low 16bit quantities.
841 */
842 scsiq->remain_bytes =
843 adv_read_lram_16(adv, q_addr + ADV_SCSIQ_DW_REMAIN_XFER_CNT);
844 scsiq->remain_bytes |=
845 adv_read_lram_16(adv, q_addr + ADV_SCSIQ_W_ALT_DC1) << 16;
846
847 /*
848 * XXX Is this just a safeguard or will the counter really
849 * have bogus upper bits?
850 */
851 scsiq->remain_bytes &= max_dma_count;
852
853 return (sg_queue_cnt);
854 }
855
856 int
857 adv_start_chip(struct adv_softc *adv)
858 {
859 ADV_OUTB(adv, ADV_CHIP_CTRL, 0);
860 if ((ADV_INW(adv, ADV_CHIP_STATUS) & ADV_CSW_HALTED) != 0)
861 return (0);
862 return (1);
863 }
864
865 int
866 adv_stop_execution(struct adv_softc *adv)
867 {
868 int count;
869
870 count = 0;
871 if (adv_read_lram_8(adv, ADV_STOP_CODE_B) == 0) {
872 adv_write_lram_8(adv, ADV_STOP_CODE_B,
873 ADV_STOP_REQ_RISC_STOP);
874 do {
875 if (adv_read_lram_8(adv, ADV_STOP_CODE_B) &
876 ADV_STOP_ACK_RISC_STOP) {
877 return (1);
878 }
879 DELAY(1000);
880 } while (count++ < 20);
881 }
882 return (0);
883 }
884
885 int
886 adv_is_chip_halted(struct adv_softc *adv)
887 {
888 if ((ADV_INW(adv, ADV_CHIP_STATUS) & ADV_CSW_HALTED) != 0) {
889 if ((ADV_INB(adv, ADV_CHIP_CTRL) & ADV_CC_HALT) != 0) {
890 return (1);
891 }
892 }
893 return (0);
894 }
895
896 /*
897 * XXX The numeric constants and the loops in this routine
898 * need to be documented.
899 */
900 void
901 adv_ack_interrupt(struct adv_softc *adv)
902 {
903 u_int8_t host_flag;
904 u_int8_t risc_flag;
905 int loop;
906
907 loop = 0;
908 do {
909 risc_flag = adv_read_lram_8(adv, ADVV_RISC_FLAG_B);
910 if (loop++ > 0x7FFF) {
911 break;
912 }
913 } while ((risc_flag & ADV_RISC_FLAG_GEN_INT) != 0);
914
915 host_flag = adv_read_lram_8(adv, ADVV_HOST_FLAG_B);
916 adv_write_lram_8(adv, ADVV_HOST_FLAG_B,
917 host_flag | ADV_HOST_FLAG_ACK_INT);
918
919 ADV_OUTW(adv, ADV_CHIP_STATUS, ADV_CIW_INT_ACK);
920 loop = 0;
921 while (ADV_INW(adv, ADV_CHIP_STATUS) & ADV_CSW_INT_PENDING) {
922 ADV_OUTW(adv, ADV_CHIP_STATUS, ADV_CIW_INT_ACK);
923 if (loop++ > 3) {
924 break;
925 }
926 }
927
928 adv_write_lram_8(adv, ADVV_HOST_FLAG_B, host_flag);
929 }
930
931 /*
932 * Handle all conditions that may halt the chip waiting
933 * for us to intervene.
934 */
935 void
936 adv_isr_chip_halted(struct adv_softc *adv)
937 {
938 u_int16_t int_halt_code;
939 u_int16_t halt_q_addr;
940 target_bit_vector target_mask;
941 target_bit_vector scsi_busy;
942 u_int8_t halt_qp;
943 u_int8_t target_ix;
944 u_int8_t q_cntl;
945 u_int8_t tid_no;
946
947 if (!dumping)
948 mtx_assert(&adv->lock, MA_OWNED);
949 int_halt_code = adv_read_lram_16(adv, ADVV_HALTCODE_W);
950 halt_qp = adv_read_lram_8(adv, ADVV_CURCDB_B);
951 halt_q_addr = ADV_QNO_TO_QADDR(halt_qp);
952 target_ix = adv_read_lram_8(adv, halt_q_addr + ADV_SCSIQ_B_TARGET_IX);
953 q_cntl = adv_read_lram_8(adv, halt_q_addr + ADV_SCSIQ_B_CNTL);
954 tid_no = ADV_TIX_TO_TID(target_ix);
955 target_mask = ADV_TID_TO_TARGET_MASK(tid_no);
956 if (int_halt_code == ADV_HALT_DISABLE_ASYN_USE_SYN_FIX) {
957 /*
958 * Temporarily disable the async fix by removing
959 * this target from the list of affected targets,
960 * setting our async rate, and then putting us
961 * back into the mask.
962 */
963 adv->fix_asyn_xfer &= ~target_mask;
964 adv_set_syncrate(adv, /*struct cam_path */NULL,
965 tid_no, /*period*/0, /*offset*/0,
966 ADV_TRANS_ACTIVE);
967 adv->fix_asyn_xfer |= target_mask;
968 } else if (int_halt_code == ADV_HALT_ENABLE_ASYN_USE_SYN_FIX) {
969 adv_set_syncrate(adv, /*struct cam_path */NULL,
970 tid_no, /*period*/0, /*offset*/0,
971 ADV_TRANS_ACTIVE);
972 } else if (int_halt_code == ADV_HALT_EXTMSG_IN) {
973 adv_handle_extmsg_in(adv, halt_q_addr, q_cntl,
974 target_mask, tid_no);
975 } else if (int_halt_code == ADV_HALT_CHK_CONDITION) {
976 struct adv_target_transinfo* tinfo;
977 struct adv_ccb_info *cinfo;
978 union ccb *ccb;
979 u_int32_t cinfo_index;
980 u_int8_t tag_code;
981 u_int8_t q_status;
982
983 tinfo = &adv->tinfo[tid_no];
984 q_cntl |= QC_REQ_SENSE;
985
986 /* Renegotiate if appropriate. */
987 adv_set_syncrate(adv, /*struct cam_path */NULL,
988 tid_no, /*period*/0, /*offset*/0,
989 ADV_TRANS_CUR);
990 if (tinfo->current.period != tinfo->goal.period) {
991 adv_msgout_sdtr(adv, tinfo->goal.period,
992 tinfo->goal.offset);
993 q_cntl |= QC_MSG_OUT;
994 }
995 adv_write_lram_8(adv, halt_q_addr + ADV_SCSIQ_B_CNTL, q_cntl);
996
997 /* Don't tag request sense commands */
998 tag_code = adv_read_lram_8(adv,
999 halt_q_addr + ADV_SCSIQ_B_TAG_CODE);
1000 tag_code &=
1001 ~(MSG_SIMPLE_Q_TAG|MSG_HEAD_OF_Q_TAG|MSG_ORDERED_Q_TAG);
1002
1003 if ((adv->fix_asyn_xfer & target_mask) != 0
1004 && (adv->fix_asyn_xfer_always & target_mask) == 0) {
1005 tag_code |= (ADV_TAG_FLAG_DISABLE_DISCONNECT
1006 | ADV_TAG_FLAG_DISABLE_ASYN_USE_SYN_FIX);
1007 }
1008 adv_write_lram_8(adv, halt_q_addr + ADV_SCSIQ_B_TAG_CODE,
1009 tag_code);
1010 q_status = adv_read_lram_8(adv,
1011 halt_q_addr + ADV_SCSIQ_B_STATUS);
1012 q_status |= (QS_READY | QS_BUSY);
1013 adv_write_lram_8(adv, halt_q_addr + ADV_SCSIQ_B_STATUS,
1014 q_status);
1015 /*
1016 * Freeze the devq until we can handle the sense condition.
1017 */
1018 cinfo_index =
1019 adv_read_lram_32(adv, halt_q_addr + ADV_SCSIQ_D_CINFO_IDX);
1020 cinfo = &adv->ccb_infos[cinfo_index];
1021 ccb = adv->ccb_infos[cinfo_index].ccb;
1022 xpt_freeze_devq(ccb->ccb_h.path, /*count*/1);
1023 ccb->ccb_h.status |= CAM_DEV_QFRZN;
1024 adv_abort_ccb(adv, tid_no, ADV_TIX_TO_LUN(target_ix),
1025 /*ccb*/NULL, CAM_REQUEUE_REQ,
1026 /*queued_only*/TRUE);
1027 scsi_busy = adv_read_lram_8(adv, ADVV_SCSIBUSY_B);
1028 scsi_busy &= ~target_mask;
1029 adv_write_lram_8(adv, ADVV_SCSIBUSY_B, scsi_busy);
1030 /*
1031 * Ensure we have enough time to actually
1032 * retrieve the sense.
1033 */
1034 callout_reset(&cinfo->timer, 5 * hz, adv_timeout, ccb);
1035 } else if (int_halt_code == ADV_HALT_SDTR_REJECTED) {
1036 struct ext_msg out_msg;
1037
1038 adv_read_lram_16_multi(adv, ADVV_MSGOUT_BEG,
1039 (u_int16_t *) &out_msg,
1040 sizeof(out_msg)/2);
1041
1042 if ((out_msg.msg_type == MSG_EXTENDED)
1043 && (out_msg.msg_len == MSG_EXT_SDTR_LEN)
1044 && (out_msg.msg_req == MSG_EXT_SDTR)) {
1045
1046 /* Revert to Async */
1047 adv_set_syncrate(adv, /*struct cam_path */NULL,
1048 tid_no, /*period*/0, /*offset*/0,
1049 ADV_TRANS_GOAL|ADV_TRANS_ACTIVE);
1050 }
1051 q_cntl &= ~QC_MSG_OUT;
1052 adv_write_lram_8(adv, halt_q_addr + ADV_SCSIQ_B_CNTL, q_cntl);
1053 } else if (int_halt_code == ADV_HALT_SS_QUEUE_FULL) {
1054 union ccb *ccb;
1055 u_int32_t cinfo_index;
1056
1057 adv_read_lram_8(adv, halt_q_addr + ADV_SCSIQ_SCSI_STATUS);
1058 cinfo_index =
1059 adv_read_lram_32(adv, halt_q_addr + ADV_SCSIQ_D_CINFO_IDX);
1060 ccb = adv->ccb_infos[cinfo_index].ccb;
1061 xpt_freeze_devq(ccb->ccb_h.path, /*count*/1);
1062 ccb->ccb_h.status |= CAM_DEV_QFRZN|CAM_SCSI_STATUS_ERROR;
1063 ccb->csio.scsi_status = SCSI_STATUS_QUEUE_FULL;
1064 adv_abort_ccb(adv, tid_no, ADV_TIX_TO_LUN(target_ix),
1065 /*ccb*/NULL, CAM_REQUEUE_REQ,
1066 /*queued_only*/TRUE);
1067 scsi_busy = adv_read_lram_8(adv, ADVV_SCSIBUSY_B);
1068 scsi_busy &= ~target_mask;
1069 adv_write_lram_8(adv, ADVV_SCSIBUSY_B, scsi_busy);
1070 } else {
1071 printf("Unhandled Halt Code %x\n", int_halt_code);
1072 }
1073 adv_write_lram_16(adv, ADVV_HALTCODE_W, 0);
1074 }
1075
1076 void
1077 adv_sdtr_to_period_offset(struct adv_softc *adv,
1078 u_int8_t sync_data, u_int8_t *period,
1079 u_int8_t *offset, int tid)
1080 {
1081 if (adv->fix_asyn_xfer & ADV_TID_TO_TARGET_MASK(tid)
1082 && (sync_data == ASYN_SDTR_DATA_FIX_PCI_REV_AB)) {
1083 *period = *offset = 0;
1084 } else {
1085 *period = adv->sdtr_period_tbl[((sync_data >> 4) & 0xF)];
1086 *offset = sync_data & 0xF;
1087 }
1088 }
1089
1090 void
1091 adv_set_syncrate(struct adv_softc *adv, struct cam_path *path,
1092 u_int tid, u_int period, u_int offset, u_int type)
1093 {
1094 struct adv_target_transinfo* tinfo;
1095 u_int old_period;
1096 u_int old_offset;
1097 u_int8_t sdtr_data;
1098
1099 mtx_assert(&adv->lock, MA_OWNED);
1100 tinfo = &adv->tinfo[tid];
1101
1102 /* Filter our input */
1103 sdtr_data = adv_period_offset_to_sdtr(adv, &period,
1104 &offset, tid);
1105
1106 old_period = tinfo->current.period;
1107 old_offset = tinfo->current.offset;
1108
1109 if ((type & ADV_TRANS_CUR) != 0
1110 && ((old_period != period || old_offset != offset)
1111 || period == 0 || offset == 0) /*Changes in asyn fix settings*/) {
1112 int halted;
1113
1114 halted = adv_is_chip_halted(adv);
1115 if (halted == 0)
1116 /* Must halt the chip first */
1117 adv_host_req_chip_halt(adv);
1118
1119 /* Update current hardware settings */
1120 adv_set_sdtr_reg_at_id(adv, tid, sdtr_data);
1121
1122 /*
1123 * If a target can run in sync mode, we don't need
1124 * to check it for sync problems.
1125 */
1126 if (offset != 0)
1127 adv->fix_asyn_xfer &= ~ADV_TID_TO_TARGET_MASK(tid);
1128
1129 if (halted == 0)
1130 /* Start the chip again */
1131 adv_start_chip(adv);
1132
1133 tinfo->current.period = period;
1134 tinfo->current.offset = offset;
1135
1136 if (path != NULL) {
1137 /*
1138 * Tell the SCSI layer about the
1139 * new transfer parameters.
1140 */
1141 struct ccb_trans_settings neg;
1142 memset(&neg, 0, sizeof (neg));
1143 struct ccb_trans_settings_spi *spi =
1144 &neg.xport_specific.spi;
1145
1146 neg.protocol = PROTO_SCSI;
1147 neg.protocol_version = SCSI_REV_2;
1148 neg.transport = XPORT_SPI;
1149 neg.transport_version = 2;
1150
1151 spi->sync_offset = offset;
1152 spi->sync_period = period;
1153 spi->valid |= CTS_SPI_VALID_SYNC_OFFSET;
1154 spi->valid |= CTS_SPI_VALID_SYNC_RATE;
1155 xpt_setup_ccb(&neg.ccb_h, path, /*priority*/1);
1156 xpt_async(AC_TRANSFER_NEG, path, &neg);
1157 }
1158 }
1159
1160 if ((type & ADV_TRANS_GOAL) != 0) {
1161 tinfo->goal.period = period;
1162 tinfo->goal.offset = offset;
1163 }
1164
1165 if ((type & ADV_TRANS_USER) != 0) {
1166 tinfo->user.period = period;
1167 tinfo->user.offset = offset;
1168 }
1169 }
1170
1171 u_int8_t
1172 adv_period_offset_to_sdtr(struct adv_softc *adv, u_int *period,
1173 u_int *offset, int tid)
1174 {
1175 u_int i;
1176 u_int dummy_offset;
1177 u_int dummy_period;
1178
1179 if (offset == NULL) {
1180 dummy_offset = 0;
1181 offset = &dummy_offset;
1182 }
1183
1184 if (period == NULL) {
1185 dummy_period = 0;
1186 period = &dummy_period;
1187 }
1188
1189 *offset = MIN(ADV_SYN_MAX_OFFSET, *offset);
1190 if (*period != 0 && *offset != 0) {
1191 for (i = 0; i < adv->sdtr_period_tbl_size; i++) {
1192 if (*period <= adv->sdtr_period_tbl[i]) {
1193 /*
1194 * When responding to a target that requests
1195 * sync, the requested rate may fall between
1196 * two rates that we can output, but still be
1197 * a rate that we can receive. Because of this,
1198 * we want to respond to the target with
1199 * the same rate that it sent to us even
1200 * if the period we use to send data to it
1201 * is lower. Only lower the response period
1202 * if we must.
1203 */
1204 if (i == 0 /* Our maximum rate */)
1205 *period = adv->sdtr_period_tbl[0];
1206 return ((i << 4) | *offset);
1207 }
1208 }
1209 }
1210
1211 /* Must go async */
1212 *period = 0;
1213 *offset = 0;
1214 if (adv->fix_asyn_xfer & ADV_TID_TO_TARGET_MASK(tid))
1215 return (ASYN_SDTR_DATA_FIX_PCI_REV_AB);
1216 return (0);
1217 }
1218
1219 /* Internal Routines */
1220
1221 static void
1222 adv_read_lram_16_multi(struct adv_softc *adv, u_int16_t s_addr,
1223 u_int16_t *buffer, int count)
1224 {
1225 ADV_OUTW(adv, ADV_LRAM_ADDR, s_addr);
1226 ADV_INSW(adv, ADV_LRAM_DATA, buffer, count);
1227 }
1228
1229 static void
1230 adv_write_lram_16_multi(struct adv_softc *adv, u_int16_t s_addr,
1231 u_int16_t *buffer, int count)
1232 {
1233 ADV_OUTW(adv, ADV_LRAM_ADDR, s_addr);
1234 ADV_OUTSW(adv, ADV_LRAM_DATA, buffer, count);
1235 }
1236
1237 static void
1238 adv_mset_lram_16(struct adv_softc *adv, u_int16_t s_addr,
1239 u_int16_t set_value, int count)
1240 {
1241 ADV_OUTW(adv, ADV_LRAM_ADDR, s_addr);
1242 bus_set_multi_2(adv->res, adv->reg_off + ADV_LRAM_DATA,
1243 set_value, count);
1244 }
1245
1246 static u_int32_t
1247 adv_msum_lram_16(struct adv_softc *adv, u_int16_t s_addr, int count)
1248 {
1249 u_int32_t sum;
1250 int i;
1251
1252 sum = 0;
1253 ADV_OUTW(adv, ADV_LRAM_ADDR, s_addr);
1254 for (i = 0; i < count; i++)
1255 sum += ADV_INW(adv, ADV_LRAM_DATA);
1256 return (sum);
1257 }
1258
1259 static int
1260 adv_write_and_verify_lram_16(struct adv_softc *adv, u_int16_t addr,
1261 u_int16_t value)
1262 {
1263 int retval;
1264
1265 retval = 0;
1266 ADV_OUTW(adv, ADV_LRAM_ADDR, addr);
1267 ADV_OUTW(adv, ADV_LRAM_DATA, value);
1268 DELAY(10000);
1269 ADV_OUTW(adv, ADV_LRAM_ADDR, addr);
1270 if (value != ADV_INW(adv, ADV_LRAM_DATA))
1271 retval = 1;
1272 return (retval);
1273 }
1274
1275 static u_int32_t
1276 adv_read_lram_32(struct adv_softc *adv, u_int16_t addr)
1277 {
1278 u_int16_t val_low, val_high;
1279
1280 ADV_OUTW(adv, ADV_LRAM_ADDR, addr);
1281
1282 #if BYTE_ORDER == BIG_ENDIAN
1283 val_high = ADV_INW(adv, ADV_LRAM_DATA);
1284 val_low = ADV_INW(adv, ADV_LRAM_DATA);
1285 #else
1286 val_low = ADV_INW(adv, ADV_LRAM_DATA);
1287 val_high = ADV_INW(adv, ADV_LRAM_DATA);
1288 #endif
1289
1290 return (((u_int32_t)val_high << 16) | (u_int32_t)val_low);
1291 }
1292
1293 static void
1294 adv_write_lram_32(struct adv_softc *adv, u_int16_t addr, u_int32_t value)
1295 {
1296 ADV_OUTW(adv, ADV_LRAM_ADDR, addr);
1297
1298 #if BYTE_ORDER == BIG_ENDIAN
1299 ADV_OUTW(adv, ADV_LRAM_DATA, (u_int16_t)((value >> 16) & 0xFFFF));
1300 ADV_OUTW(adv, ADV_LRAM_DATA, (u_int16_t)(value & 0xFFFF));
1301 #else
1302 ADV_OUTW(adv, ADV_LRAM_DATA, (u_int16_t)(value & 0xFFFF));
1303 ADV_OUTW(adv, ADV_LRAM_DATA, (u_int16_t)((value >> 16) & 0xFFFF));
1304 #endif
1305 }
1306
1307 static void
1308 adv_write_lram_32_multi(struct adv_softc *adv, u_int16_t s_addr,
1309 u_int32_t *buffer, int count)
1310 {
1311 ADV_OUTW(adv, ADV_LRAM_ADDR, s_addr);
1312 ADV_OUTSW(adv, ADV_LRAM_DATA, (u_int16_t *)buffer, count * 2);
1313 }
1314
1315 static u_int16_t
1316 adv_read_eeprom_16(struct adv_softc *adv, u_int8_t addr)
1317 {
1318 u_int16_t read_wval;
1319 u_int8_t cmd_reg;
1320
1321 adv_write_eeprom_cmd_reg(adv, ADV_EEPROM_CMD_WRITE_DISABLE);
1322 DELAY(1000);
1323 cmd_reg = addr | ADV_EEPROM_CMD_READ;
1324 adv_write_eeprom_cmd_reg(adv, cmd_reg);
1325 DELAY(1000);
1326 read_wval = ADV_INW(adv, ADV_EEPROM_DATA);
1327 DELAY(1000);
1328 return (read_wval);
1329 }
1330
1331 static u_int16_t
1332 adv_write_eeprom_16(struct adv_softc *adv, u_int8_t addr, u_int16_t value)
1333 {
1334 u_int16_t read_value;
1335
1336 read_value = adv_read_eeprom_16(adv, addr);
1337 if (read_value != value) {
1338 adv_write_eeprom_cmd_reg(adv, ADV_EEPROM_CMD_WRITE_ENABLE);
1339 DELAY(1000);
1340
1341 ADV_OUTW(adv, ADV_EEPROM_DATA, value);
1342 DELAY(1000);
1343
1344 adv_write_eeprom_cmd_reg(adv, ADV_EEPROM_CMD_WRITE | addr);
1345 DELAY(20 * 1000);
1346
1347 adv_write_eeprom_cmd_reg(adv, ADV_EEPROM_CMD_WRITE_DISABLE);
1348 DELAY(1000);
1349 read_value = adv_read_eeprom_16(adv, addr);
1350 }
1351 return (read_value);
1352 }
1353
1354 static int
1355 adv_write_eeprom_cmd_reg(struct adv_softc *adv, u_int8_t cmd_reg)
1356 {
1357 u_int8_t read_back;
1358 int retry;
1359
1360 retry = 0;
1361 while (1) {
1362 ADV_OUTB(adv, ADV_EEPROM_CMD, cmd_reg);
1363 DELAY(1000);
1364 read_back = ADV_INB(adv, ADV_EEPROM_CMD);
1365 if (read_back == cmd_reg) {
1366 return (1);
1367 }
1368 if (retry++ > ADV_EEPROM_MAX_RETRY) {
1369 return (0);
1370 }
1371 }
1372 }
1373
1374 static int
1375 adv_set_eeprom_config_once(struct adv_softc *adv,
1376 struct adv_eeprom_config *eeprom_config)
1377 {
1378 int n_error;
1379 u_int16_t *wbuf;
1380 u_int16_t sum;
1381 u_int8_t s_addr;
1382 u_int8_t cfg_beg;
1383 u_int8_t cfg_end;
1384
1385 wbuf = (u_int16_t *)eeprom_config;
1386 n_error = 0;
1387 sum = 0;
1388 for (s_addr = 0; s_addr < 2; s_addr++, wbuf++) {
1389 sum += *wbuf;
1390 if (*wbuf != adv_write_eeprom_16(adv, s_addr, *wbuf)) {
1391 n_error++;
1392 }
1393 }
1394 if (adv->type & ADV_VL) {
1395 cfg_beg = ADV_EEPROM_CFG_BEG_VL;
1396 cfg_end = ADV_EEPROM_MAX_ADDR_VL;
1397 } else {
1398 cfg_beg = ADV_EEPROM_CFG_BEG;
1399 cfg_end = ADV_EEPROM_MAX_ADDR;
1400 }
1401
1402 for (s_addr = cfg_beg; s_addr <= (cfg_end - 1); s_addr++, wbuf++) {
1403 sum += *wbuf;
1404 if (*wbuf != adv_write_eeprom_16(adv, s_addr, *wbuf)) {
1405 n_error++;
1406 }
1407 }
1408 *wbuf = sum;
1409 if (sum != adv_write_eeprom_16(adv, s_addr, sum)) {
1410 n_error++;
1411 }
1412 wbuf = (u_int16_t *)eeprom_config;
1413 for (s_addr = 0; s_addr < 2; s_addr++, wbuf++) {
1414 if (*wbuf != adv_read_eeprom_16(adv, s_addr)) {
1415 n_error++;
1416 }
1417 }
1418 for (s_addr = cfg_beg; s_addr <= cfg_end; s_addr++, wbuf++) {
1419 if (*wbuf != adv_read_eeprom_16(adv, s_addr)) {
1420 n_error++;
1421 }
1422 }
1423 return (n_error);
1424 }
1425
1426 static u_int32_t
1427 adv_load_microcode(struct adv_softc *adv, u_int16_t s_addr,
1428 u_int16_t *mcode_buf, u_int16_t mcode_size)
1429 {
1430 u_int32_t chksum;
1431 u_int16_t mcode_lram_size;
1432 u_int16_t mcode_chksum;
1433
1434 mcode_lram_size = mcode_size >> 1;
1435 /* XXX Why zero the memory just before you write the whole thing?? */
1436 adv_mset_lram_16(adv, s_addr, 0, mcode_lram_size);
1437 adv_write_lram_16_multi(adv, s_addr, mcode_buf, mcode_lram_size);
1438
1439 chksum = adv_msum_lram_16(adv, s_addr, mcode_lram_size);
1440 mcode_chksum = (u_int16_t)adv_msum_lram_16(adv, ADV_CODE_SEC_BEG,
1441 ((mcode_size - s_addr
1442 - ADV_CODE_SEC_BEG) >> 1));
1443 adv_write_lram_16(adv, ADVV_MCODE_CHKSUM_W, mcode_chksum);
1444 adv_write_lram_16(adv, ADVV_MCODE_SIZE_W, mcode_size);
1445 return (chksum);
1446 }
1447
1448 static void
1449 adv_reinit_lram(struct adv_softc *adv) {
1450 adv_init_lram(adv);
1451 adv_init_qlink_var(adv);
1452 }
1453
1454 static void
1455 adv_init_lram(struct adv_softc *adv)
1456 {
1457 u_int8_t i;
1458 u_int16_t s_addr;
1459
1460 adv_mset_lram_16(adv, ADV_QADR_BEG, 0,
1461 (((adv->max_openings + 2 + 1) * 64) >> 1));
1462
1463 i = ADV_MIN_ACTIVE_QNO;
1464 s_addr = ADV_QADR_BEG + ADV_QBLK_SIZE;
1465
1466 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_FWD, i + 1);
1467 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_BWD, adv->max_openings);
1468 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_QNO, i);
1469 i++;
1470 s_addr += ADV_QBLK_SIZE;
1471 for (; i < adv->max_openings; i++, s_addr += ADV_QBLK_SIZE) {
1472 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_FWD, i + 1);
1473 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_BWD, i - 1);
1474 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_QNO, i);
1475 }
1476
1477 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_FWD, ADV_QLINK_END);
1478 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_BWD, adv->max_openings - 1);
1479 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_QNO, adv->max_openings);
1480 i++;
1481 s_addr += ADV_QBLK_SIZE;
1482
1483 for (; i <= adv->max_openings + 3; i++, s_addr += ADV_QBLK_SIZE) {
1484 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_FWD, i);
1485 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_BWD, i);
1486 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_QNO, i);
1487 }
1488 }
1489
1490 static int
1491 adv_init_microcode_var(struct adv_softc *adv)
1492 {
1493 int i;
1494
1495 for (i = 0; i <= ADV_MAX_TID; i++) {
1496
1497 /* Start out async all around */
1498 adv_set_syncrate(adv, /*path*/NULL,
1499 i, 0, 0,
1500 ADV_TRANS_GOAL|ADV_TRANS_CUR);
1501 }
1502
1503 adv_init_qlink_var(adv);
1504
1505 adv_write_lram_8(adv, ADVV_DISC_ENABLE_B, adv->disc_enable);
1506 adv_write_lram_8(adv, ADVV_HOSTSCSI_ID_B, 0x01 << adv->scsi_id);
1507
1508 adv_write_lram_32(adv, ADVV_OVERRUN_PADDR_D, adv->overrun_physbase);
1509
1510 adv_write_lram_32(adv, ADVV_OVERRUN_BSIZE_D, ADV_OVERRUN_BSIZE);
1511
1512 ADV_OUTW(adv, ADV_REG_PROG_COUNTER, ADV_MCODE_START_ADDR);
1513 if (ADV_INW(adv, ADV_REG_PROG_COUNTER) != ADV_MCODE_START_ADDR) {
1514 device_printf(adv->dev,
1515 "Unable to set program counter. Aborting.\n");
1516 return (1);
1517 }
1518 return (0);
1519 }
1520
1521 static void
1522 adv_init_qlink_var(struct adv_softc *adv)
1523 {
1524 int i;
1525 u_int16_t lram_addr;
1526
1527 adv_write_lram_8(adv, ADVV_NEXTRDY_B, 1);
1528 adv_write_lram_8(adv, ADVV_DONENEXT_B, adv->max_openings);
1529
1530 adv_write_lram_16(adv, ADVV_FREE_Q_HEAD_W, 1);
1531 adv_write_lram_16(adv, ADVV_DONE_Q_TAIL_W, adv->max_openings);
1532
1533 adv_write_lram_8(adv, ADVV_BUSY_QHEAD_B,
1534 (u_int8_t)((int) adv->max_openings + 1));
1535 adv_write_lram_8(adv, ADVV_DISC1_QHEAD_B,
1536 (u_int8_t)((int) adv->max_openings + 2));
1537
1538 adv_write_lram_8(adv, ADVV_TOTAL_READY_Q_B, adv->max_openings);
1539
1540 adv_write_lram_16(adv, ADVV_ASCDVC_ERR_CODE_W, 0);
1541 adv_write_lram_16(adv, ADVV_HALTCODE_W, 0);
1542 adv_write_lram_8(adv, ADVV_STOP_CODE_B, 0);
1543 adv_write_lram_8(adv, ADVV_SCSIBUSY_B, 0);
1544 adv_write_lram_8(adv, ADVV_WTM_FLAG_B, 0);
1545 adv_write_lram_8(adv, ADVV_Q_DONE_IN_PROGRESS_B, 0);
1546
1547 lram_addr = ADV_QADR_BEG;
1548 for (i = 0; i < 32; i++, lram_addr += 2)
1549 adv_write_lram_16(adv, lram_addr, 0);
1550 }
1551
1552 static void
1553 adv_disable_interrupt(struct adv_softc *adv)
1554 {
1555 u_int16_t cfg;
1556
1557 cfg = ADV_INW(adv, ADV_CONFIG_LSW);
1558 ADV_OUTW(adv, ADV_CONFIG_LSW, cfg & ~ADV_CFG_LSW_HOST_INT_ON);
1559 }
1560
1561 static void
1562 adv_enable_interrupt(struct adv_softc *adv)
1563 {
1564 u_int16_t cfg;
1565
1566 cfg = ADV_INW(adv, ADV_CONFIG_LSW);
1567 ADV_OUTW(adv, ADV_CONFIG_LSW, cfg | ADV_CFG_LSW_HOST_INT_ON);
1568 }
1569
1570 static void
1571 adv_toggle_irq_act(struct adv_softc *adv)
1572 {
1573 ADV_OUTW(adv, ADV_CHIP_STATUS, ADV_CIW_IRQ_ACT);
1574 ADV_OUTW(adv, ADV_CHIP_STATUS, 0);
1575 }
1576
1577 void
1578 adv_start_execution(struct adv_softc *adv)
1579 {
1580 if (adv_read_lram_8(adv, ADV_STOP_CODE_B) != 0) {
1581 adv_write_lram_8(adv, ADV_STOP_CODE_B, 0);
1582 }
1583 }
1584
1585 int
1586 adv_stop_chip(struct adv_softc *adv)
1587 {
1588 u_int8_t cc_val;
1589
1590 cc_val = ADV_INB(adv, ADV_CHIP_CTRL)
1591 & (~(ADV_CC_SINGLE_STEP | ADV_CC_TEST | ADV_CC_DIAG));
1592 ADV_OUTB(adv, ADV_CHIP_CTRL, cc_val | ADV_CC_HALT);
1593 adv_set_chip_ih(adv, ADV_INS_HALT);
1594 adv_set_chip_ih(adv, ADV_INS_RFLAG_WTM);
1595 if ((ADV_INW(adv, ADV_CHIP_STATUS) & ADV_CSW_HALTED) == 0) {
1596 return (0);
1597 }
1598 return (1);
1599 }
1600
1601 static int
1602 adv_host_req_chip_halt(struct adv_softc *adv)
1603 {
1604 int count;
1605 u_int8_t saved_stop_code;
1606
1607 if (adv_is_chip_halted(adv))
1608 return (1);
1609
1610 count = 0;
1611 saved_stop_code = adv_read_lram_8(adv, ADVV_STOP_CODE_B);
1612 adv_write_lram_8(adv, ADVV_STOP_CODE_B,
1613 ADV_STOP_HOST_REQ_RISC_HALT | ADV_STOP_REQ_RISC_STOP);
1614 while (adv_is_chip_halted(adv) == 0
1615 && count++ < 2000)
1616 ;
1617
1618 adv_write_lram_8(adv, ADVV_STOP_CODE_B, saved_stop_code);
1619 return (count < 2000);
1620 }
1621
1622 static void
1623 adv_set_chip_ih(struct adv_softc *adv, u_int16_t ins_code)
1624 {
1625 adv_set_bank(adv, 1);
1626 ADV_OUTW(adv, ADV_REG_IH, ins_code);
1627 adv_set_bank(adv, 0);
1628 }
1629
1630 #if 0
1631 static u_int8_t
1632 adv_get_chip_scsi_ctrl(struct adv_softc *adv)
1633 {
1634 u_int8_t scsi_ctrl;
1635
1636 adv_set_bank(adv, 1);
1637 scsi_ctrl = ADV_INB(adv, ADV_REG_SC);
1638 adv_set_bank(adv, 0);
1639 return (scsi_ctrl);
1640 }
1641 #endif
1642
1643 /*
1644 * XXX Looks like more padding issues in this routine as well.
1645 * There has to be a way to turn this into an insw.
1646 */
1647 static void
1648 adv_get_q_info(struct adv_softc *adv, u_int16_t s_addr,
1649 u_int16_t *inbuf, int words)
1650 {
1651 int i;
1652
1653 ADV_OUTW(adv, ADV_LRAM_ADDR, s_addr);
1654 for (i = 0; i < words; i++, inbuf++) {
1655 if (i == 5) {
1656 continue;
1657 }
1658 *inbuf = ADV_INW(adv, ADV_LRAM_DATA);
1659 }
1660 }
1661
1662 static u_int
1663 adv_get_num_free_queues(struct adv_softc *adv, u_int8_t n_qs)
1664 {
1665 u_int cur_used_qs;
1666 u_int cur_free_qs;
1667
1668 cur_used_qs = adv->cur_active + ADV_MIN_FREE_Q;
1669
1670 if ((cur_used_qs + n_qs) <= adv->max_openings) {
1671 cur_free_qs = adv->max_openings - cur_used_qs;
1672 return (cur_free_qs);
1673 }
1674 adv->openings_needed = n_qs;
1675 return (0);
1676 }
1677
1678 static u_int8_t
1679 adv_alloc_free_queues(struct adv_softc *adv, u_int8_t free_q_head,
1680 u_int8_t n_free_q)
1681 {
1682 int i;
1683
1684 for (i = 0; i < n_free_q; i++) {
1685 free_q_head = adv_alloc_free_queue(adv, free_q_head);
1686 if (free_q_head == ADV_QLINK_END)
1687 break;
1688 }
1689 return (free_q_head);
1690 }
1691
1692 static u_int8_t
1693 adv_alloc_free_queue(struct adv_softc *adv, u_int8_t free_q_head)
1694 {
1695 u_int16_t q_addr;
1696 u_int8_t next_qp;
1697 u_int8_t q_status;
1698
1699 next_qp = ADV_QLINK_END;
1700 q_addr = ADV_QNO_TO_QADDR(free_q_head);
1701 q_status = adv_read_lram_8(adv, q_addr + ADV_SCSIQ_B_STATUS);
1702
1703 if ((q_status & QS_READY) == 0)
1704 next_qp = adv_read_lram_8(adv, q_addr + ADV_SCSIQ_B_FWD);
1705
1706 return (next_qp);
1707 }
1708
1709 static int
1710 adv_send_scsi_queue(struct adv_softc *adv, struct adv_scsi_q *scsiq,
1711 u_int8_t n_q_required)
1712 {
1713 u_int8_t free_q_head;
1714 u_int8_t next_qp;
1715 int retval;
1716
1717 retval = 1;
1718 free_q_head = adv_read_lram_16(adv, ADVV_FREE_Q_HEAD_W) & 0xFF;
1719 if ((next_qp = adv_alloc_free_queues(adv, free_q_head, n_q_required))
1720 != ADV_QLINK_END) {
1721 scsiq->q1.q_no = free_q_head;
1722
1723 /*
1724 * Now that we know our Q number, point our sense
1725 * buffer pointer to a bus dma mapped area where
1726 * we can dma the data to.
1727 */
1728 scsiq->q1.sense_addr = adv->sense_physbase
1729 + ((free_q_head - 1) * sizeof(struct scsi_sense_data));
1730 adv_put_ready_sg_list_queue(adv, scsiq, free_q_head);
1731 adv_write_lram_16(adv, ADVV_FREE_Q_HEAD_W, next_qp);
1732 adv->cur_active += n_q_required;
1733 retval = 0;
1734 }
1735 return (retval);
1736 }
1737
1738
1739 static void
1740 adv_put_ready_sg_list_queue(struct adv_softc *adv, struct adv_scsi_q *scsiq,
1741 u_int q_no)
1742 {
1743 u_int8_t sg_list_dwords;
1744 u_int8_t sg_index, i;
1745 u_int8_t sg_entry_cnt;
1746 u_int8_t next_qp;
1747 u_int16_t q_addr;
1748 struct adv_sg_head *sg_head;
1749 struct adv_sg_list_q scsi_sg_q;
1750
1751 sg_head = scsiq->sg_head;
1752
1753 if (sg_head) {
1754 sg_entry_cnt = sg_head->entry_cnt - 1;
1755 #ifdef DIAGNOSTIC
1756 if (sg_entry_cnt == 0)
1757 panic("adv_put_ready_sg_list_queue: ScsiQ with "
1758 "a SG list but only one element");
1759 if ((scsiq->q1.cntl & QC_SG_HEAD) == 0)
1760 panic("adv_put_ready_sg_list_queue: ScsiQ with "
1761 "a SG list but QC_SG_HEAD not set");
1762 #endif
1763 q_addr = ADV_QNO_TO_QADDR(q_no);
1764 sg_index = 1;
1765 scsiq->q1.sg_queue_cnt = sg_head->queue_cnt;
1766 scsi_sg_q.sg_head_qp = q_no;
1767 scsi_sg_q.cntl = QCSG_SG_XFER_LIST;
1768 for (i = 0; i < sg_head->queue_cnt; i++) {
1769 u_int8_t segs_this_q;
1770
1771 if (sg_entry_cnt > ADV_SG_LIST_PER_Q)
1772 segs_this_q = ADV_SG_LIST_PER_Q;
1773 else {
1774 /* This will be the last segment then */
1775 segs_this_q = sg_entry_cnt;
1776 scsi_sg_q.cntl |= QCSG_SG_XFER_END;
1777 }
1778 scsi_sg_q.seq_no = i + 1;
1779 sg_list_dwords = segs_this_q << 1;
1780 if (i == 0) {
1781 scsi_sg_q.sg_list_cnt = segs_this_q;
1782 scsi_sg_q.sg_cur_list_cnt = segs_this_q;
1783 } else {
1784 scsi_sg_q.sg_list_cnt = segs_this_q - 1;
1785 scsi_sg_q.sg_cur_list_cnt = segs_this_q - 1;
1786 }
1787 next_qp = adv_read_lram_8(adv, q_addr + ADV_SCSIQ_B_FWD);
1788 scsi_sg_q.q_no = next_qp;
1789 q_addr = ADV_QNO_TO_QADDR(next_qp);
1790
1791 adv_write_lram_16_multi(adv,
1792 q_addr + ADV_SCSIQ_SGHD_CPY_BEG,
1793 (u_int16_t *)&scsi_sg_q,
1794 sizeof(scsi_sg_q) >> 1);
1795 adv_write_lram_32_multi(adv, q_addr + ADV_SGQ_LIST_BEG,
1796 (u_int32_t *)&sg_head->sg_list[sg_index],
1797 sg_list_dwords);
1798 sg_entry_cnt -= segs_this_q;
1799 sg_index += ADV_SG_LIST_PER_Q;
1800 }
1801 }
1802 adv_put_ready_queue(adv, scsiq, q_no);
1803 }
1804
1805 static void
1806 adv_put_ready_queue(struct adv_softc *adv, struct adv_scsi_q *scsiq,
1807 u_int q_no)
1808 {
1809 struct adv_target_transinfo* tinfo;
1810 u_int q_addr;
1811 u_int tid_no;
1812
1813 tid_no = ADV_TIX_TO_TID(scsiq->q2.target_ix);
1814 tinfo = &adv->tinfo[tid_no];
1815 if ((tinfo->current.period != tinfo->goal.period)
1816 || (tinfo->current.offset != tinfo->goal.offset)) {
1817
1818 adv_msgout_sdtr(adv, tinfo->goal.period, tinfo->goal.offset);
1819 scsiq->q1.cntl |= QC_MSG_OUT;
1820 }
1821 q_addr = ADV_QNO_TO_QADDR(q_no);
1822
1823 scsiq->q1.status = QS_FREE;
1824
1825 adv_write_lram_16_multi(adv, q_addr + ADV_SCSIQ_CDB_BEG,
1826 (u_int16_t *)scsiq->cdbptr,
1827 scsiq->q2.cdb_len >> 1);
1828
1829 #if BYTE_ORDER == BIG_ENDIAN
1830 adv_adj_scsiq_endian(scsiq);
1831 #endif
1832
1833 adv_put_scsiq(adv, q_addr + ADV_SCSIQ_CPY_BEG,
1834 (u_int16_t *) &scsiq->q1.cntl,
1835 ((sizeof(scsiq->q1) + sizeof(scsiq->q2)) / 2) - 1);
1836
1837 #ifdef CC_WRITE_IO_COUNT
1838 adv_write_lram_16(adv, q_addr + ADV_SCSIQ_W_REQ_COUNT,
1839 adv->req_count);
1840 #endif
1841
1842 #ifdef CC_CLEAR_DMA_REMAIN
1843
1844 adv_write_lram_32(adv, q_addr + ADV_SCSIQ_DW_REMAIN_XFER_ADDR, 0);
1845 adv_write_lram_32(adv, q_addr + ADV_SCSIQ_DW_REMAIN_XFER_CNT, 0);
1846 #endif
1847
1848 adv_write_lram_16(adv, q_addr + ADV_SCSIQ_B_STATUS,
1849 (scsiq->q1.q_no << 8) | QS_READY);
1850 }
1851
1852 static void
1853 adv_put_scsiq(struct adv_softc *adv, u_int16_t s_addr,
1854 u_int16_t *buffer, int words)
1855 {
1856 int i;
1857
1858 /*
1859 * XXX This routine makes *gross* assumptions
1860 * about padding in the data structures.
1861 * Either the data structures should have explicit
1862 * padding members added, or they should have padding
1863 * turned off via compiler attributes depending on
1864 * which yields better overall performance. My hunch
1865 * would be that turning off padding would be the
1866 * faster approach as an outsw is much faster than
1867 * this crude loop and accessing un-aligned data
1868 * members isn't *that* expensive. The other choice
1869 * would be to modify the ASC script so that the
1870 * the adv_scsiq_1 structure can be re-arranged so
1871 * padding isn't required.
1872 */
1873 ADV_OUTW(adv, ADV_LRAM_ADDR, s_addr);
1874 for (i = 0; i < words; i++, buffer++) {
1875 if (i == 2 || i == 10) {
1876 continue;
1877 }
1878 ADV_OUTW(adv, ADV_LRAM_DATA, *buffer);
1879 }
1880 }
1881
1882 #if BYTE_ORDER == BIG_ENDIAN
1883 void
1884 adv_adj_endian_qdone_info(struct adv_q_done_info *scsiq)
1885 {
1886
1887 panic("adv(4) not supported on big-endian machines.\n");
1888 }
1889
1890 void
1891 adv_adj_scsiq_endian(struct adv_scsi_q *scsiq)
1892 {
1893
1894 panic("adv(4) not supported on big-endian machines.\n");
1895 }
1896 #endif
1897
1898 static void
1899 adv_handle_extmsg_in(struct adv_softc *adv, u_int16_t halt_q_addr,
1900 u_int8_t q_cntl, target_bit_vector target_mask,
1901 int tid_no)
1902 {
1903 struct ext_msg ext_msg;
1904
1905 adv_read_lram_16_multi(adv, ADVV_MSGIN_BEG, (u_int16_t *) &ext_msg,
1906 sizeof(ext_msg) >> 1);
1907 if ((ext_msg.msg_type == MSG_EXTENDED)
1908 && (ext_msg.msg_req == MSG_EXT_SDTR)
1909 && (ext_msg.msg_len == MSG_EXT_SDTR_LEN)) {
1910 union ccb *ccb;
1911 struct adv_target_transinfo* tinfo;
1912 u_int32_t cinfo_index;
1913 u_int period;
1914 u_int offset;
1915 int sdtr_accept;
1916 u_int8_t orig_offset;
1917
1918 cinfo_index =
1919 adv_read_lram_32(adv, halt_q_addr + ADV_SCSIQ_D_CINFO_IDX);
1920 ccb = adv->ccb_infos[cinfo_index].ccb;
1921 tinfo = &adv->tinfo[tid_no];
1922 sdtr_accept = TRUE;
1923
1924 orig_offset = ext_msg.req_ack_offset;
1925 if (ext_msg.xfer_period < tinfo->goal.period) {
1926 sdtr_accept = FALSE;
1927 ext_msg.xfer_period = tinfo->goal.period;
1928 }
1929
1930 /* Perform range checking */
1931 period = ext_msg.xfer_period;
1932 offset = ext_msg.req_ack_offset;
1933 adv_period_offset_to_sdtr(adv, &period, &offset, tid_no);
1934 ext_msg.xfer_period = period;
1935 ext_msg.req_ack_offset = offset;
1936
1937 /* Record our current sync settings */
1938 adv_set_syncrate(adv, ccb->ccb_h.path,
1939 tid_no, ext_msg.xfer_period,
1940 ext_msg.req_ack_offset,
1941 ADV_TRANS_GOAL|ADV_TRANS_ACTIVE);
1942
1943 /* Offset too high or large period forced async */
1944 if (orig_offset != ext_msg.req_ack_offset)
1945 sdtr_accept = FALSE;
1946
1947 if (sdtr_accept && (q_cntl & QC_MSG_OUT)) {
1948 /* Valid response to our requested negotiation */
1949 q_cntl &= ~QC_MSG_OUT;
1950 } else {
1951 /* Must Respond */
1952 q_cntl |= QC_MSG_OUT;
1953 adv_msgout_sdtr(adv, ext_msg.xfer_period,
1954 ext_msg.req_ack_offset);
1955 }
1956
1957 } else if (ext_msg.msg_type == MSG_EXTENDED
1958 && ext_msg.msg_req == MSG_EXT_WDTR
1959 && ext_msg.msg_len == MSG_EXT_WDTR_LEN) {
1960
1961 ext_msg.wdtr_width = 0;
1962 adv_write_lram_16_multi(adv, ADVV_MSGOUT_BEG,
1963 (u_int16_t *)&ext_msg,
1964 sizeof(ext_msg) >> 1);
1965 q_cntl |= QC_MSG_OUT;
1966 } else {
1967
1968 ext_msg.msg_type = MSG_MESSAGE_REJECT;
1969 adv_write_lram_16_multi(adv, ADVV_MSGOUT_BEG,
1970 (u_int16_t *)&ext_msg,
1971 sizeof(ext_msg) >> 1);
1972 q_cntl |= QC_MSG_OUT;
1973 }
1974 adv_write_lram_8(adv, halt_q_addr + ADV_SCSIQ_B_CNTL, q_cntl);
1975 }
1976
1977 static void
1978 adv_msgout_sdtr(struct adv_softc *adv, u_int8_t sdtr_period,
1979 u_int8_t sdtr_offset)
1980 {
1981 struct ext_msg sdtr_buf;
1982
1983 sdtr_buf.msg_type = MSG_EXTENDED;
1984 sdtr_buf.msg_len = MSG_EXT_SDTR_LEN;
1985 sdtr_buf.msg_req = MSG_EXT_SDTR;
1986 sdtr_buf.xfer_period = sdtr_period;
1987 sdtr_offset &= ADV_SYN_MAX_OFFSET;
1988 sdtr_buf.req_ack_offset = sdtr_offset;
1989 adv_write_lram_16_multi(adv, ADVV_MSGOUT_BEG,
1990 (u_int16_t *) &sdtr_buf,
1991 sizeof(sdtr_buf) / 2);
1992 }
1993
1994 int
1995 adv_abort_ccb(struct adv_softc *adv, int target, int lun, union ccb *ccb,
1996 u_int32_t status, int queued_only)
1997 {
1998 u_int16_t q_addr;
1999 u_int8_t q_no;
2000 struct adv_q_done_info scsiq_buf;
2001 struct adv_q_done_info *scsiq;
2002 u_int8_t target_ix;
2003 int count;
2004
2005 if (!dumping)
2006 mtx_assert(&adv->lock, MA_OWNED);
2007 scsiq = &scsiq_buf;
2008 target_ix = ADV_TIDLUN_TO_IX(target, lun);
2009 count = 0;
2010 for (q_no = ADV_MIN_ACTIVE_QNO; q_no <= adv->max_openings; q_no++) {
2011 struct adv_ccb_info *ccb_info;
2012 q_addr = ADV_QNO_TO_QADDR(q_no);
2013
2014 adv_copy_lram_doneq(adv, q_addr, scsiq, adv->max_dma_count);
2015 ccb_info = &adv->ccb_infos[scsiq->d2.ccb_index];
2016 if (((scsiq->q_status & QS_READY) != 0)
2017 && ((scsiq->q_status & QS_ABORTED) == 0)
2018 && ((scsiq->cntl & QCSG_SG_XFER_LIST) == 0)
2019 && (scsiq->d2.target_ix == target_ix)
2020 && (queued_only == 0
2021 || !(scsiq->q_status & (QS_DISC1|QS_DISC2|QS_BUSY|QS_DONE)))
2022 && (ccb == NULL || (ccb == ccb_info->ccb))) {
2023 union ccb *aborted_ccb;
2024 struct adv_ccb_info *cinfo;
2025
2026 scsiq->q_status |= QS_ABORTED;
2027 adv_write_lram_8(adv, q_addr + ADV_SCSIQ_B_STATUS,
2028 scsiq->q_status);
2029 aborted_ccb = ccb_info->ccb;
2030 /* Don't clobber earlier error codes */
2031 if ((aborted_ccb->ccb_h.status & CAM_STATUS_MASK)
2032 == CAM_REQ_INPROG)
2033 aborted_ccb->ccb_h.status |= status;
2034 cinfo = (struct adv_ccb_info *)
2035 aborted_ccb->ccb_h.ccb_cinfo_ptr;
2036 cinfo->state |= ACCB_ABORT_QUEUED;
2037 count++;
2038 }
2039 }
2040 return (count);
2041 }
2042
2043 int
2044 adv_reset_bus(struct adv_softc *adv, int initiate_bus_reset)
2045 {
2046 int count;
2047 int i;
2048 union ccb *ccb;
2049
2050 if (!dumping)
2051 mtx_assert(&adv->lock, MA_OWNED);
2052 i = 200;
2053 while ((ADV_INW(adv, ADV_CHIP_STATUS) & ADV_CSW_SCSI_RESET_ACTIVE) != 0
2054 && i--)
2055 DELAY(1000);
2056 adv_reset_chip(adv, initiate_bus_reset);
2057 adv_reinit_lram(adv);
2058 for (i = 0; i <= ADV_MAX_TID; i++)
2059 adv_set_syncrate(adv, NULL, i, /*period*/0,
2060 /*offset*/0, ADV_TRANS_CUR);
2061 ADV_OUTW(adv, ADV_REG_PROG_COUNTER, ADV_MCODE_START_ADDR);
2062
2063 /* Tell the XPT layer that a bus reset occurred */
2064 if (adv->path != NULL)
2065 xpt_async(AC_BUS_RESET, adv->path, NULL);
2066
2067 count = 0;
2068 while ((ccb = (union ccb *)LIST_FIRST(&adv->pending_ccbs)) != NULL) {
2069 if ((ccb->ccb_h.status & CAM_STATUS_MASK) == CAM_REQ_INPROG)
2070 ccb->ccb_h.status |= CAM_SCSI_BUS_RESET;
2071 adv_done(adv, ccb, QD_ABORTED_BY_HOST, 0, 0, 0);
2072 count++;
2073 }
2074
2075 adv_start_chip(adv);
2076 return (count);
2077 }
2078
2079 static void
2080 adv_set_sdtr_reg_at_id(struct adv_softc *adv, int tid, u_int8_t sdtr_data)
2081 {
2082 int orig_id;
2083
2084 adv_set_bank(adv, 1);
2085 orig_id = ffs(ADV_INB(adv, ADV_HOST_SCSIID)) - 1;
2086 ADV_OUTB(adv, ADV_HOST_SCSIID, tid);
2087 if (ADV_INB(adv, ADV_HOST_SCSIID) == (0x01 << tid)) {
2088 adv_set_bank(adv, 0);
2089 ADV_OUTB(adv, ADV_SYN_OFFSET, sdtr_data);
2090 }
2091 adv_set_bank(adv, 1);
2092 ADV_OUTB(adv, ADV_HOST_SCSIID, orig_id);
2093 adv_set_bank(adv, 0);
2094 }
Cache object: 65476722b764b0abb4a812a9125ec86c
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