1 /*
2 * Device driver for the SYMBIOS/LSILOGIC 53C8XX and 53C1010 family
3 * of PCI-SCSI IO processors.
4 *
5 * Copyright (C) 1999-2001 Gerard Roudier <groudier@free.fr>
6 * Copyright (c) 2003-2005 Matthew Wilcox <matthew@wil.cx>
7 *
8 * This driver is derived from the Linux sym53c8xx driver.
9 * Copyright (C) 1998-2000 Gerard Roudier
10 *
11 * The sym53c8xx driver is derived from the ncr53c8xx driver that had been
12 * a port of the FreeBSD ncr driver to Linux-1.2.13.
13 *
14 * The original ncr driver has been written for 386bsd and FreeBSD by
15 * Wolfgang Stanglmeier <wolf@cologne.de>
16 * Stefan Esser <se@mi.Uni-Koeln.de>
17 * Copyright (C) 1994 Wolfgang Stanglmeier
18 *
19 * Other major contributions:
20 *
21 * NVRAM detection and reading.
22 * Copyright (C) 1997 Richard Waltham <dormouse@farsrobt.demon.co.uk>
23 *
24 *-----------------------------------------------------------------------------
25 *
26 * This program is free software; you can redistribute it and/or modify
27 * it under the terms of the GNU General Public License as published by
28 * the Free Software Foundation; either version 2 of the License, or
29 * (at your option) any later version.
30 *
31 * This program is distributed in the hope that it will be useful,
32 * but WITHOUT ANY WARRANTY; without even the implied warranty of
33 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
34 * GNU General Public License for more details.
35 *
36 * You should have received a copy of the GNU General Public License
37 * along with this program; if not, write to the Free Software
38 * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
39 */
40
41 #include <linux/slab.h>
42 #include <asm/param.h> /* for timeouts in units of HZ */
43
44 #include "sym_glue.h"
45 #include "sym_nvram.h"
46
47 #if 0
48 #define SYM_DEBUG_GENERIC_SUPPORT
49 #endif
50
51 /*
52 * Needed function prototypes.
53 */
54 static void sym_int_ma (struct sym_hcb *np);
55 static void sym_int_sir(struct sym_hcb *);
56 static struct sym_ccb *sym_alloc_ccb(struct sym_hcb *np);
57 static struct sym_ccb *sym_ccb_from_dsa(struct sym_hcb *np, u32 dsa);
58 static void sym_alloc_lcb_tags (struct sym_hcb *np, u_char tn, u_char ln);
59 static void sym_complete_error (struct sym_hcb *np, struct sym_ccb *cp);
60 static void sym_complete_ok (struct sym_hcb *np, struct sym_ccb *cp);
61 static int sym_compute_residual(struct sym_hcb *np, struct sym_ccb *cp);
62
63 /*
64 * Print a buffer in hexadecimal format with a ".\n" at end.
65 */
sym_printl_hex(u_char * p,int n)66 static void sym_printl_hex(u_char *p, int n)
67 {
68 while (n-- > 0)
69 printf (" %x", *p++);
70 printf (".\n");
71 }
72
sym_print_msg(struct sym_ccb * cp,char * label,u_char * msg)73 static void sym_print_msg(struct sym_ccb *cp, char *label, u_char *msg)
74 {
75 sym_print_addr(cp->cmd, "%s: ", label);
76
77 spi_print_msg(msg);
78 printf("\n");
79 }
80
sym_print_nego_msg(struct sym_hcb * np,int target,char * label,u_char * msg)81 static void sym_print_nego_msg(struct sym_hcb *np, int target, char *label, u_char *msg)
82 {
83 struct sym_tcb *tp = &np->target[target];
84 dev_info(&tp->starget->dev, "%s: ", label);
85
86 spi_print_msg(msg);
87 printf("\n");
88 }
89
90 /*
91 * Print something that tells about extended errors.
92 */
sym_print_xerr(struct scsi_cmnd * cmd,int x_status)93 void sym_print_xerr(struct scsi_cmnd *cmd, int x_status)
94 {
95 if (x_status & XE_PARITY_ERR) {
96 sym_print_addr(cmd, "unrecovered SCSI parity error.\n");
97 }
98 if (x_status & XE_EXTRA_DATA) {
99 sym_print_addr(cmd, "extraneous data discarded.\n");
100 }
101 if (x_status & XE_BAD_PHASE) {
102 sym_print_addr(cmd, "illegal scsi phase (4/5).\n");
103 }
104 if (x_status & XE_SODL_UNRUN) {
105 sym_print_addr(cmd, "ODD transfer in DATA OUT phase.\n");
106 }
107 if (x_status & XE_SWIDE_OVRUN) {
108 sym_print_addr(cmd, "ODD transfer in DATA IN phase.\n");
109 }
110 }
111
112 /*
113 * Return a string for SCSI BUS mode.
114 */
sym_scsi_bus_mode(int mode)115 static char *sym_scsi_bus_mode(int mode)
116 {
117 switch(mode) {
118 case SMODE_HVD: return "HVD";
119 case SMODE_SE: return "SE";
120 case SMODE_LVD: return "LVD";
121 }
122 return "??";
123 }
124
125 /*
126 * Soft reset the chip.
127 *
128 * Raising SRST when the chip is running may cause
129 * problems on dual function chips (see below).
130 * On the other hand, LVD devices need some delay
131 * to settle and report actual BUS mode in STEST4.
132 */
sym_chip_reset(struct sym_hcb * np)133 static void sym_chip_reset (struct sym_hcb *np)
134 {
135 OUTB(np, nc_istat, SRST);
136 INB(np, nc_mbox1);
137 udelay(10);
138 OUTB(np, nc_istat, 0);
139 INB(np, nc_mbox1);
140 udelay(2000); /* For BUS MODE to settle */
141 }
142
143 /*
144 * Really soft reset the chip.:)
145 *
146 * Some 896 and 876 chip revisions may hang-up if we set
147 * the SRST (soft reset) bit at the wrong time when SCRIPTS
148 * are running.
149 * So, we need to abort the current operation prior to
150 * soft resetting the chip.
151 */
sym_soft_reset(struct sym_hcb * np)152 static void sym_soft_reset (struct sym_hcb *np)
153 {
154 u_char istat = 0;
155 int i;
156
157 if (!(np->features & FE_ISTAT1) || !(INB(np, nc_istat1) & SCRUN))
158 goto do_chip_reset;
159
160 OUTB(np, nc_istat, CABRT);
161 for (i = 100000 ; i ; --i) {
162 istat = INB(np, nc_istat);
163 if (istat & SIP) {
164 INW(np, nc_sist);
165 }
166 else if (istat & DIP) {
167 if (INB(np, nc_dstat) & ABRT)
168 break;
169 }
170 udelay(5);
171 }
172 OUTB(np, nc_istat, 0);
173 if (!i)
174 printf("%s: unable to abort current chip operation, "
175 "ISTAT=0x%02x.\n", sym_name(np), istat);
176 do_chip_reset:
177 sym_chip_reset(np);
178 }
179
180 /*
181 * Start reset process.
182 *
183 * The interrupt handler will reinitialize the chip.
184 */
sym_start_reset(struct sym_hcb * np)185 static void sym_start_reset(struct sym_hcb *np)
186 {
187 sym_reset_scsi_bus(np, 1);
188 }
189
sym_reset_scsi_bus(struct sym_hcb * np,int enab_int)190 int sym_reset_scsi_bus(struct sym_hcb *np, int enab_int)
191 {
192 u32 term;
193 int retv = 0;
194
195 sym_soft_reset(np); /* Soft reset the chip */
196 if (enab_int)
197 OUTW(np, nc_sien, RST);
198 /*
199 * Enable Tolerant, reset IRQD if present and
200 * properly set IRQ mode, prior to resetting the bus.
201 */
202 OUTB(np, nc_stest3, TE);
203 OUTB(np, nc_dcntl, (np->rv_dcntl & IRQM));
204 OUTB(np, nc_scntl1, CRST);
205 INB(np, nc_mbox1);
206 udelay(200);
207
208 if (!SYM_SETUP_SCSI_BUS_CHECK)
209 goto out;
210 /*
211 * Check for no terminators or SCSI bus shorts to ground.
212 * Read SCSI data bus, data parity bits and control signals.
213 * We are expecting RESET to be TRUE and other signals to be
214 * FALSE.
215 */
216 term = INB(np, nc_sstat0);
217 term = ((term & 2) << 7) + ((term & 1) << 17); /* rst sdp0 */
218 term |= ((INB(np, nc_sstat2) & 0x01) << 26) | /* sdp1 */
219 ((INW(np, nc_sbdl) & 0xff) << 9) | /* d7-0 */
220 ((INW(np, nc_sbdl) & 0xff00) << 10) | /* d15-8 */
221 INB(np, nc_sbcl); /* req ack bsy sel atn msg cd io */
222
223 if (!np->maxwide)
224 term &= 0x3ffff;
225
226 if (term != (2<<7)) {
227 printf("%s: suspicious SCSI data while resetting the BUS.\n",
228 sym_name(np));
229 printf("%s: %sdp0,d7-0,rst,req,ack,bsy,sel,atn,msg,c/d,i/o = "
230 "0x%lx, expecting 0x%lx\n",
231 sym_name(np),
232 (np->features & FE_WIDE) ? "dp1,d15-8," : "",
233 (u_long)term, (u_long)(2<<7));
234 if (SYM_SETUP_SCSI_BUS_CHECK == 1)
235 retv = 1;
236 }
237 out:
238 OUTB(np, nc_scntl1, 0);
239 return retv;
240 }
241
242 /*
243 * Select SCSI clock frequency
244 */
sym_selectclock(struct sym_hcb * np,u_char scntl3)245 static void sym_selectclock(struct sym_hcb *np, u_char scntl3)
246 {
247 /*
248 * If multiplier not present or not selected, leave here.
249 */
250 if (np->multiplier <= 1) {
251 OUTB(np, nc_scntl3, scntl3);
252 return;
253 }
254
255 if (sym_verbose >= 2)
256 printf ("%s: enabling clock multiplier\n", sym_name(np));
257
258 OUTB(np, nc_stest1, DBLEN); /* Enable clock multiplier */
259 /*
260 * Wait for the LCKFRQ bit to be set if supported by the chip.
261 * Otherwise wait 50 micro-seconds (at least).
262 */
263 if (np->features & FE_LCKFRQ) {
264 int i = 20;
265 while (!(INB(np, nc_stest4) & LCKFRQ) && --i > 0)
266 udelay(20);
267 if (!i)
268 printf("%s: the chip cannot lock the frequency\n",
269 sym_name(np));
270 } else {
271 INB(np, nc_mbox1);
272 udelay(50+10);
273 }
274 OUTB(np, nc_stest3, HSC); /* Halt the scsi clock */
275 OUTB(np, nc_scntl3, scntl3);
276 OUTB(np, nc_stest1, (DBLEN|DBLSEL));/* Select clock multiplier */
277 OUTB(np, nc_stest3, 0x00); /* Restart scsi clock */
278 }
279
280
281 /*
282 * Determine the chip's clock frequency.
283 *
284 * This is essential for the negotiation of the synchronous
285 * transfer rate.
286 *
287 * Note: we have to return the correct value.
288 * THERE IS NO SAFE DEFAULT VALUE.
289 *
290 * Most NCR/SYMBIOS boards are delivered with a 40 Mhz clock.
291 * 53C860 and 53C875 rev. 1 support fast20 transfers but
292 * do not have a clock doubler and so are provided with a
293 * 80 MHz clock. All other fast20 boards incorporate a doubler
294 * and so should be delivered with a 40 MHz clock.
295 * The recent fast40 chips (895/896/895A/1010) use a 40 Mhz base
296 * clock and provide a clock quadrupler (160 Mhz).
297 */
298
299 /*
300 * calculate SCSI clock frequency (in KHz)
301 */
getfreq(struct sym_hcb * np,int gen)302 static unsigned getfreq (struct sym_hcb *np, int gen)
303 {
304 unsigned int ms = 0;
305 unsigned int f;
306
307 /*
308 * Measure GEN timer delay in order
309 * to calculate SCSI clock frequency
310 *
311 * This code will never execute too
312 * many loop iterations (if DELAY is
313 * reasonably correct). It could get
314 * too low a delay (too high a freq.)
315 * if the CPU is slow executing the
316 * loop for some reason (an NMI, for
317 * example). For this reason we will
318 * if multiple measurements are to be
319 * performed trust the higher delay
320 * (lower frequency returned).
321 */
322 OUTW(np, nc_sien, 0); /* mask all scsi interrupts */
323 INW(np, nc_sist); /* clear pending scsi interrupt */
324 OUTB(np, nc_dien, 0); /* mask all dma interrupts */
325 INW(np, nc_sist); /* another one, just to be sure :) */
326 /*
327 * The C1010-33 core does not report GEN in SIST,
328 * if this interrupt is masked in SIEN.
329 * I don't know yet if the C1010-66 behaves the same way.
330 */
331 if (np->features & FE_C10) {
332 OUTW(np, nc_sien, GEN);
333 OUTB(np, nc_istat1, SIRQD);
334 }
335 OUTB(np, nc_scntl3, 4); /* set pre-scaler to divide by 3 */
336 OUTB(np, nc_stime1, 0); /* disable general purpose timer */
337 OUTB(np, nc_stime1, gen); /* set to nominal delay of 1<<gen * 125us */
338 while (!(INW(np, nc_sist) & GEN) && ms++ < 100000)
339 udelay(1000/4); /* count in 1/4 of ms */
340 OUTB(np, nc_stime1, 0); /* disable general purpose timer */
341 /*
342 * Undo C1010-33 specific settings.
343 */
344 if (np->features & FE_C10) {
345 OUTW(np, nc_sien, 0);
346 OUTB(np, nc_istat1, 0);
347 }
348 /*
349 * set prescaler to divide by whatever 0 means
350 * 0 ought to choose divide by 2, but appears
351 * to set divide by 3.5 mode in my 53c810 ...
352 */
353 OUTB(np, nc_scntl3, 0);
354
355 /*
356 * adjust for prescaler, and convert into KHz
357 */
358 f = ms ? ((1 << gen) * (4340*4)) / ms : 0;
359
360 /*
361 * The C1010-33 result is biased by a factor
362 * of 2/3 compared to earlier chips.
363 */
364 if (np->features & FE_C10)
365 f = (f * 2) / 3;
366
367 if (sym_verbose >= 2)
368 printf ("%s: Delay (GEN=%d): %u msec, %u KHz\n",
369 sym_name(np), gen, ms/4, f);
370
371 return f;
372 }
373
sym_getfreq(struct sym_hcb * np)374 static unsigned sym_getfreq (struct sym_hcb *np)
375 {
376 u_int f1, f2;
377 int gen = 8;
378
379 getfreq (np, gen); /* throw away first result */
380 f1 = getfreq (np, gen);
381 f2 = getfreq (np, gen);
382 if (f1 > f2) f1 = f2; /* trust lower result */
383 return f1;
384 }
385
386 /*
387 * Get/probe chip SCSI clock frequency
388 */
sym_getclock(struct sym_hcb * np,int mult)389 static void sym_getclock (struct sym_hcb *np, int mult)
390 {
391 unsigned char scntl3 = np->sv_scntl3;
392 unsigned char stest1 = np->sv_stest1;
393 unsigned f1;
394
395 np->multiplier = 1;
396 f1 = 40000;
397 /*
398 * True with 875/895/896/895A with clock multiplier selected
399 */
400 if (mult > 1 && (stest1 & (DBLEN+DBLSEL)) == DBLEN+DBLSEL) {
401 if (sym_verbose >= 2)
402 printf ("%s: clock multiplier found\n", sym_name(np));
403 np->multiplier = mult;
404 }
405
406 /*
407 * If multiplier not found or scntl3 not 7,5,3,
408 * reset chip and get frequency from general purpose timer.
409 * Otherwise trust scntl3 BIOS setting.
410 */
411 if (np->multiplier != mult || (scntl3 & 7) < 3 || !(scntl3 & 1)) {
412 OUTB(np, nc_stest1, 0); /* make sure doubler is OFF */
413 f1 = sym_getfreq (np);
414
415 if (sym_verbose)
416 printf ("%s: chip clock is %uKHz\n", sym_name(np), f1);
417
418 if (f1 < 45000) f1 = 40000;
419 else if (f1 < 55000) f1 = 50000;
420 else f1 = 80000;
421
422 if (f1 < 80000 && mult > 1) {
423 if (sym_verbose >= 2)
424 printf ("%s: clock multiplier assumed\n",
425 sym_name(np));
426 np->multiplier = mult;
427 }
428 } else {
429 if ((scntl3 & 7) == 3) f1 = 40000;
430 else if ((scntl3 & 7) == 5) f1 = 80000;
431 else f1 = 160000;
432
433 f1 /= np->multiplier;
434 }
435
436 /*
437 * Compute controller synchronous parameters.
438 */
439 f1 *= np->multiplier;
440 np->clock_khz = f1;
441 }
442
443 /*
444 * Get/probe PCI clock frequency
445 */
sym_getpciclock(struct sym_hcb * np)446 static int sym_getpciclock (struct sym_hcb *np)
447 {
448 int f = 0;
449
450 /*
451 * For now, we only need to know about the actual
452 * PCI BUS clock frequency for C1010-66 chips.
453 */
454 #if 1
455 if (np->features & FE_66MHZ) {
456 #else
457 if (1) {
458 #endif
459 OUTB(np, nc_stest1, SCLK); /* Use the PCI clock as SCSI clock */
460 f = sym_getfreq(np);
461 OUTB(np, nc_stest1, 0);
462 }
463 np->pciclk_khz = f;
464
465 return f;
466 }
467
468 /*
469 * SYMBIOS chip clock divisor table.
470 *
471 * Divisors are multiplied by 10,000,000 in order to make
472 * calculations more simple.
473 */
474 #define _5M 5000000
475 static const u32 div_10M[] = {2*_5M, 3*_5M, 4*_5M, 6*_5M, 8*_5M, 12*_5M, 16*_5M};
476
477 /*
478 * Get clock factor and sync divisor for a given
479 * synchronous factor period.
480 */
481 static int
482 sym_getsync(struct sym_hcb *np, u_char dt, u_char sfac, u_char *divp, u_char *fakp)
483 {
484 u32 clk = np->clock_khz; /* SCSI clock frequency in kHz */
485 int div = np->clock_divn; /* Number of divisors supported */
486 u32 fak; /* Sync factor in sxfer */
487 u32 per; /* Period in tenths of ns */
488 u32 kpc; /* (per * clk) */
489 int ret;
490
491 /*
492 * Compute the synchronous period in tenths of nano-seconds
493 */
494 if (dt && sfac <= 9) per = 125;
495 else if (sfac <= 10) per = 250;
496 else if (sfac == 11) per = 303;
497 else if (sfac == 12) per = 500;
498 else per = 40 * sfac;
499 ret = per;
500
501 kpc = per * clk;
502 if (dt)
503 kpc <<= 1;
504
505 /*
506 * For earliest C10 revision 0, we cannot use extra
507 * clocks for the setting of the SCSI clocking.
508 * Note that this limits the lowest sync data transfer
509 * to 5 Mega-transfers per second and may result in
510 * using higher clock divisors.
511 */
512 #if 1
513 if ((np->features & (FE_C10|FE_U3EN)) == FE_C10) {
514 /*
515 * Look for the lowest clock divisor that allows an
516 * output speed not faster than the period.
517 */
518 while (div > 0) {
519 --div;
520 if (kpc > (div_10M[div] << 2)) {
521 ++div;
522 break;
523 }
524 }
525 fak = 0; /* No extra clocks */
526 if (div == np->clock_divn) { /* Are we too fast ? */
527 ret = -1;
528 }
529 *divp = div;
530 *fakp = fak;
531 return ret;
532 }
533 #endif
534
535 /*
536 * Look for the greatest clock divisor that allows an
537 * input speed faster than the period.
538 */
539 while (div-- > 0)
540 if (kpc >= (div_10M[div] << 2)) break;
541
542 /*
543 * Calculate the lowest clock factor that allows an output
544 * speed not faster than the period, and the max output speed.
545 * If fak >= 1 we will set both XCLKH_ST and XCLKH_DT.
546 * If fak >= 2 we will also set XCLKS_ST and XCLKS_DT.
547 */
548 if (dt) {
549 fak = (kpc - 1) / (div_10M[div] << 1) + 1 - 2;
550 /* ret = ((2+fak)*div_10M[div])/np->clock_khz; */
551 } else {
552 fak = (kpc - 1) / div_10M[div] + 1 - 4;
553 /* ret = ((4+fak)*div_10M[div])/np->clock_khz; */
554 }
555
556 /*
557 * Check against our hardware limits, or bugs :).
558 */
559 if (fak > 2) {
560 fak = 2;
561 ret = -1;
562 }
563
564 /*
565 * Compute and return sync parameters.
566 */
567 *divp = div;
568 *fakp = fak;
569
570 return ret;
571 }
572
573 /*
574 * SYMBIOS chips allow burst lengths of 2, 4, 8, 16, 32, 64,
575 * 128 transfers. All chips support at least 16 transfers
576 * bursts. The 825A, 875 and 895 chips support bursts of up
577 * to 128 transfers and the 895A and 896 support bursts of up
578 * to 64 transfers. All other chips support up to 16
579 * transfers bursts.
580 *
581 * For PCI 32 bit data transfers each transfer is a DWORD.
582 * It is a QUADWORD (8 bytes) for PCI 64 bit data transfers.
583 *
584 * We use log base 2 (burst length) as internal code, with
585 * value 0 meaning "burst disabled".
586 */
587
588 /*
589 * Burst length from burst code.
590 */
591 #define burst_length(bc) (!(bc))? 0 : 1 << (bc)
592
593 /*
594 * Burst code from io register bits.
595 */
596 #define burst_code(dmode, ctest4, ctest5) \
597 (ctest4) & 0x80? 0 : (((dmode) & 0xc0) >> 6) + ((ctest5) & 0x04) + 1
598
599 /*
600 * Set initial io register bits from burst code.
601 */
602 static inline void sym_init_burst(struct sym_hcb *np, u_char bc)
603 {
604 np->rv_ctest4 &= ~0x80;
605 np->rv_dmode &= ~(0x3 << 6);
606 np->rv_ctest5 &= ~0x4;
607
608 if (!bc) {
609 np->rv_ctest4 |= 0x80;
610 }
611 else {
612 --bc;
613 np->rv_dmode |= ((bc & 0x3) << 6);
614 np->rv_ctest5 |= (bc & 0x4);
615 }
616 }
617
618 /*
619 * Save initial settings of some IO registers.
620 * Assumed to have been set by BIOS.
621 * We cannot reset the chip prior to reading the
622 * IO registers, since informations will be lost.
623 * Since the SCRIPTS processor may be running, this
624 * is not safe on paper, but it seems to work quite
625 * well. :)
626 */
627 static void sym_save_initial_setting (struct sym_hcb *np)
628 {
629 np->sv_scntl0 = INB(np, nc_scntl0) & 0x0a;
630 np->sv_scntl3 = INB(np, nc_scntl3) & 0x07;
631 np->sv_dmode = INB(np, nc_dmode) & 0xce;
632 np->sv_dcntl = INB(np, nc_dcntl) & 0xa8;
633 np->sv_ctest3 = INB(np, nc_ctest3) & 0x01;
634 np->sv_ctest4 = INB(np, nc_ctest4) & 0x80;
635 np->sv_gpcntl = INB(np, nc_gpcntl);
636 np->sv_stest1 = INB(np, nc_stest1);
637 np->sv_stest2 = INB(np, nc_stest2) & 0x20;
638 np->sv_stest4 = INB(np, nc_stest4);
639 if (np->features & FE_C10) { /* Always large DMA fifo + ultra3 */
640 np->sv_scntl4 = INB(np, nc_scntl4);
641 np->sv_ctest5 = INB(np, nc_ctest5) & 0x04;
642 }
643 else
644 np->sv_ctest5 = INB(np, nc_ctest5) & 0x24;
645 }
646
647 /*
648 * Set SCSI BUS mode.
649 * - LVD capable chips (895/895A/896/1010) report the current BUS mode
650 * through the STEST4 IO register.
651 * - For previous generation chips (825/825A/875), the user has to tell us
652 * how to check against HVD, since a 100% safe algorithm is not possible.
653 */
654 static void sym_set_bus_mode(struct sym_hcb *np, struct sym_nvram *nvram)
655 {
656 if (np->scsi_mode)
657 return;
658
659 np->scsi_mode = SMODE_SE;
660 if (np->features & (FE_ULTRA2|FE_ULTRA3))
661 np->scsi_mode = (np->sv_stest4 & SMODE);
662 else if (np->features & FE_DIFF) {
663 if (SYM_SETUP_SCSI_DIFF == 1) {
664 if (np->sv_scntl3) {
665 if (np->sv_stest2 & 0x20)
666 np->scsi_mode = SMODE_HVD;
667 } else if (nvram->type == SYM_SYMBIOS_NVRAM) {
668 if (!(INB(np, nc_gpreg) & 0x08))
669 np->scsi_mode = SMODE_HVD;
670 }
671 } else if (SYM_SETUP_SCSI_DIFF == 2)
672 np->scsi_mode = SMODE_HVD;
673 }
674 if (np->scsi_mode == SMODE_HVD)
675 np->rv_stest2 |= 0x20;
676 }
677
678 /*
679 * Prepare io register values used by sym_start_up()
680 * according to selected and supported features.
681 */
682 static int sym_prepare_setting(struct Scsi_Host *shost, struct sym_hcb *np, struct sym_nvram *nvram)
683 {
684 struct sym_data *sym_data = shost_priv(shost);
685 struct pci_dev *pdev = sym_data->pdev;
686 u_char burst_max;
687 u32 period;
688 int i;
689
690 np->maxwide = (np->features & FE_WIDE) ? 1 : 0;
691
692 /*
693 * Guess the frequency of the chip's clock.
694 */
695 if (np->features & (FE_ULTRA3 | FE_ULTRA2))
696 np->clock_khz = 160000;
697 else if (np->features & FE_ULTRA)
698 np->clock_khz = 80000;
699 else
700 np->clock_khz = 40000;
701
702 /*
703 * Get the clock multiplier factor.
704 */
705 if (np->features & FE_QUAD)
706 np->multiplier = 4;
707 else if (np->features & FE_DBLR)
708 np->multiplier = 2;
709 else
710 np->multiplier = 1;
711
712 /*
713 * Measure SCSI clock frequency for chips
714 * it may vary from assumed one.
715 */
716 if (np->features & FE_VARCLK)
717 sym_getclock(np, np->multiplier);
718
719 /*
720 * Divisor to be used for async (timer pre-scaler).
721 */
722 i = np->clock_divn - 1;
723 while (--i >= 0) {
724 if (10ul * SYM_CONF_MIN_ASYNC * np->clock_khz > div_10M[i]) {
725 ++i;
726 break;
727 }
728 }
729 np->rv_scntl3 = i+1;
730
731 /*
732 * The C1010 uses hardwired divisors for async.
733 * So, we just throw away, the async. divisor.:-)
734 */
735 if (np->features & FE_C10)
736 np->rv_scntl3 = 0;
737
738 /*
739 * Minimum synchronous period factor supported by the chip.
740 * Btw, 'period' is in tenths of nanoseconds.
741 */
742 period = (4 * div_10M[0] + np->clock_khz - 1) / np->clock_khz;
743
744 if (period <= 250) np->minsync = 10;
745 else if (period <= 303) np->minsync = 11;
746 else if (period <= 500) np->minsync = 12;
747 else np->minsync = (period + 40 - 1) / 40;
748
749 /*
750 * Check against chip SCSI standard support (SCSI-2,ULTRA,ULTRA2).
751 */
752 if (np->minsync < 25 &&
753 !(np->features & (FE_ULTRA|FE_ULTRA2|FE_ULTRA3)))
754 np->minsync = 25;
755 else if (np->minsync < 12 &&
756 !(np->features & (FE_ULTRA2|FE_ULTRA3)))
757 np->minsync = 12;
758
759 /*
760 * Maximum synchronous period factor supported by the chip.
761 */
762 period = (11 * div_10M[np->clock_divn - 1]) / (4 * np->clock_khz);
763 np->maxsync = period > 2540 ? 254 : period / 10;
764
765 /*
766 * If chip is a C1010, guess the sync limits in DT mode.
767 */
768 if ((np->features & (FE_C10|FE_ULTRA3)) == (FE_C10|FE_ULTRA3)) {
769 if (np->clock_khz == 160000) {
770 np->minsync_dt = 9;
771 np->maxsync_dt = 50;
772 np->maxoffs_dt = nvram->type ? 62 : 31;
773 }
774 }
775
776 /*
777 * 64 bit addressing (895A/896/1010) ?
778 */
779 if (np->features & FE_DAC) {
780 if (!use_dac(np))
781 np->rv_ccntl1 |= (DDAC);
782 else if (SYM_CONF_DMA_ADDRESSING_MODE == 1)
783 np->rv_ccntl1 |= (XTIMOD | EXTIBMV);
784 else if (SYM_CONF_DMA_ADDRESSING_MODE == 2)
785 np->rv_ccntl1 |= (0 | EXTIBMV);
786 }
787
788 /*
789 * Phase mismatch handled by SCRIPTS (895A/896/1010) ?
790 */
791 if (np->features & FE_NOPM)
792 np->rv_ccntl0 |= (ENPMJ);
793
794 /*
795 * C1010-33 Errata: Part Number:609-039638 (rev. 1) is fixed.
796 * In dual channel mode, contention occurs if internal cycles
797 * are used. Disable internal cycles.
798 */
799 if (pdev->device == PCI_DEVICE_ID_LSI_53C1010_33 &&
800 pdev->revision < 0x1)
801 np->rv_ccntl0 |= DILS;
802
803 /*
804 * Select burst length (dwords)
805 */
806 burst_max = SYM_SETUP_BURST_ORDER;
807 if (burst_max == 255)
808 burst_max = burst_code(np->sv_dmode, np->sv_ctest4,
809 np->sv_ctest5);
810 if (burst_max > 7)
811 burst_max = 7;
812 if (burst_max > np->maxburst)
813 burst_max = np->maxburst;
814
815 /*
816 * DEL 352 - 53C810 Rev x11 - Part Number 609-0392140 - ITEM 2.
817 * This chip and the 860 Rev 1 may wrongly use PCI cache line
818 * based transactions on LOAD/STORE instructions. So we have
819 * to prevent these chips from using such PCI transactions in
820 * this driver. The generic ncr driver that does not use
821 * LOAD/STORE instructions does not need this work-around.
822 */
823 if ((pdev->device == PCI_DEVICE_ID_NCR_53C810 &&
824 pdev->revision >= 0x10 && pdev->revision <= 0x11) ||
825 (pdev->device == PCI_DEVICE_ID_NCR_53C860 &&
826 pdev->revision <= 0x1))
827 np->features &= ~(FE_WRIE|FE_ERL|FE_ERMP);
828
829 /*
830 * Select all supported special features.
831 * If we are using on-board RAM for scripts, prefetch (PFEN)
832 * does not help, but burst op fetch (BOF) does.
833 * Disabling PFEN makes sure BOF will be used.
834 */
835 if (np->features & FE_ERL)
836 np->rv_dmode |= ERL; /* Enable Read Line */
837 if (np->features & FE_BOF)
838 np->rv_dmode |= BOF; /* Burst Opcode Fetch */
839 if (np->features & FE_ERMP)
840 np->rv_dmode |= ERMP; /* Enable Read Multiple */
841 #if 1
842 if ((np->features & FE_PFEN) && !np->ram_ba)
843 #else
844 if (np->features & FE_PFEN)
845 #endif
846 np->rv_dcntl |= PFEN; /* Prefetch Enable */
847 if (np->features & FE_CLSE)
848 np->rv_dcntl |= CLSE; /* Cache Line Size Enable */
849 if (np->features & FE_WRIE)
850 np->rv_ctest3 |= WRIE; /* Write and Invalidate */
851 if (np->features & FE_DFS)
852 np->rv_ctest5 |= DFS; /* Dma Fifo Size */
853
854 /*
855 * Select some other
856 */
857 np->rv_ctest4 |= MPEE; /* Master parity checking */
858 np->rv_scntl0 |= 0x0a; /* full arb., ena parity, par->ATN */
859
860 /*
861 * Get parity checking, host ID and verbose mode from NVRAM
862 */
863 np->myaddr = 255;
864 np->scsi_mode = 0;
865 sym_nvram_setup_host(shost, np, nvram);
866
867 /*
868 * Get SCSI addr of host adapter (set by bios?).
869 */
870 if (np->myaddr == 255) {
871 np->myaddr = INB(np, nc_scid) & 0x07;
872 if (!np->myaddr)
873 np->myaddr = SYM_SETUP_HOST_ID;
874 }
875
876 /*
877 * Prepare initial io register bits for burst length
878 */
879 sym_init_burst(np, burst_max);
880
881 sym_set_bus_mode(np, nvram);
882
883 /*
884 * Set LED support from SCRIPTS.
885 * Ignore this feature for boards known to use a
886 * specific GPIO wiring and for the 895A, 896
887 * and 1010 that drive the LED directly.
888 */
889 if ((SYM_SETUP_SCSI_LED ||
890 (nvram->type == SYM_SYMBIOS_NVRAM ||
891 (nvram->type == SYM_TEKRAM_NVRAM &&
892 pdev->device == PCI_DEVICE_ID_NCR_53C895))) &&
893 !(np->features & FE_LEDC) && !(np->sv_gpcntl & 0x01))
894 np->features |= FE_LED0;
895
896 /*
897 * Set irq mode.
898 */
899 switch(SYM_SETUP_IRQ_MODE & 3) {
900 case 2:
901 np->rv_dcntl |= IRQM;
902 break;
903 case 1:
904 np->rv_dcntl |= (np->sv_dcntl & IRQM);
905 break;
906 default:
907 break;
908 }
909
910 /*
911 * Configure targets according to driver setup.
912 * If NVRAM present get targets setup from NVRAM.
913 */
914 for (i = 0 ; i < SYM_CONF_MAX_TARGET ; i++) {
915 struct sym_tcb *tp = &np->target[i];
916
917 tp->usrflags |= (SYM_DISC_ENABLED | SYM_TAGS_ENABLED);
918 tp->usrtags = SYM_SETUP_MAX_TAG;
919 tp->usr_width = np->maxwide;
920 tp->usr_period = 9;
921
922 sym_nvram_setup_target(tp, i, nvram);
923
924 if (!tp->usrtags)
925 tp->usrflags &= ~SYM_TAGS_ENABLED;
926 }
927
928 /*
929 * Let user know about the settings.
930 */
931 printf("%s: %s, ID %d, Fast-%d, %s, %s\n", sym_name(np),
932 sym_nvram_type(nvram), np->myaddr,
933 (np->features & FE_ULTRA3) ? 80 :
934 (np->features & FE_ULTRA2) ? 40 :
935 (np->features & FE_ULTRA) ? 20 : 10,
936 sym_scsi_bus_mode(np->scsi_mode),
937 (np->rv_scntl0 & 0xa) ? "parity checking" : "NO parity");
938 /*
939 * Tell him more on demand.
940 */
941 if (sym_verbose) {
942 printf("%s: %s IRQ line driver%s\n",
943 sym_name(np),
944 np->rv_dcntl & IRQM ? "totem pole" : "open drain",
945 np->ram_ba ? ", using on-chip SRAM" : "");
946 printf("%s: using %s firmware.\n", sym_name(np), np->fw_name);
947 if (np->features & FE_NOPM)
948 printf("%s: handling phase mismatch from SCRIPTS.\n",
949 sym_name(np));
950 }
951 /*
952 * And still more.
953 */
954 if (sym_verbose >= 2) {
955 printf ("%s: initial SCNTL3/DMODE/DCNTL/CTEST3/4/5 = "
956 "(hex) %02x/%02x/%02x/%02x/%02x/%02x\n",
957 sym_name(np), np->sv_scntl3, np->sv_dmode, np->sv_dcntl,
958 np->sv_ctest3, np->sv_ctest4, np->sv_ctest5);
959
960 printf ("%s: final SCNTL3/DMODE/DCNTL/CTEST3/4/5 = "
961 "(hex) %02x/%02x/%02x/%02x/%02x/%02x\n",
962 sym_name(np), np->rv_scntl3, np->rv_dmode, np->rv_dcntl,
963 np->rv_ctest3, np->rv_ctest4, np->rv_ctest5);
964 }
965
966 return 0;
967 }
968
969 /*
970 * Test the pci bus snoop logic :-(
971 *
972 * Has to be called with interrupts disabled.
973 */
974 #ifdef CONFIG_SCSI_SYM53C8XX_MMIO
975 static int sym_regtest(struct sym_hcb *np)
976 {
977 register volatile u32 data;
978 /*
979 * chip registers may NOT be cached.
980 * write 0xffffffff to a read only register area,
981 * and try to read it back.
982 */
983 data = 0xffffffff;
984 OUTL(np, nc_dstat, data);
985 data = INL(np, nc_dstat);
986 #if 1
987 if (data == 0xffffffff) {
988 #else
989 if ((data & 0xe2f0fffd) != 0x02000080) {
990 #endif
991 printf ("CACHE TEST FAILED: reg dstat-sstat2 readback %x.\n",
992 (unsigned) data);
993 return 0x10;
994 }
995 return 0;
996 }
997 #else
998 static inline int sym_regtest(struct sym_hcb *np)
999 {
1000 return 0;
1001 }
1002 #endif
1003
1004 static int sym_snooptest(struct sym_hcb *np)
1005 {
1006 u32 sym_rd, sym_wr, sym_bk, host_rd, host_wr, pc, dstat;
1007 int i, err;
1008
1009 err = sym_regtest(np);
1010 if (err)
1011 return err;
1012 restart_test:
1013 /*
1014 * Enable Master Parity Checking as we intend
1015 * to enable it for normal operations.
1016 */
1017 OUTB(np, nc_ctest4, (np->rv_ctest4 & MPEE));
1018 /*
1019 * init
1020 */
1021 pc = SCRIPTZ_BA(np, snooptest);
1022 host_wr = 1;
1023 sym_wr = 2;
1024 /*
1025 * Set memory and register.
1026 */
1027 np->scratch = cpu_to_scr(host_wr);
1028 OUTL(np, nc_temp, sym_wr);
1029 /*
1030 * Start script (exchange values)
1031 */
1032 OUTL(np, nc_dsa, np->hcb_ba);
1033 OUTL_DSP(np, pc);
1034 /*
1035 * Wait 'til done (with timeout)
1036 */
1037 for (i=0; i<SYM_SNOOP_TIMEOUT; i++)
1038 if (INB(np, nc_istat) & (INTF|SIP|DIP))
1039 break;
1040 if (i>=SYM_SNOOP_TIMEOUT) {
1041 printf ("CACHE TEST FAILED: timeout.\n");
1042 return (0x20);
1043 }
1044 /*
1045 * Check for fatal DMA errors.
1046 */
1047 dstat = INB(np, nc_dstat);
1048 #if 1 /* Band aiding for broken hardwares that fail PCI parity */
1049 if ((dstat & MDPE) && (np->rv_ctest4 & MPEE)) {
1050 printf ("%s: PCI DATA PARITY ERROR DETECTED - "
1051 "DISABLING MASTER DATA PARITY CHECKING.\n",
1052 sym_name(np));
1053 np->rv_ctest4 &= ~MPEE;
1054 goto restart_test;
1055 }
1056 #endif
1057 if (dstat & (MDPE|BF|IID)) {
1058 printf ("CACHE TEST FAILED: DMA error (dstat=0x%02x).", dstat);
1059 return (0x80);
1060 }
1061 /*
1062 * Save termination position.
1063 */
1064 pc = INL(np, nc_dsp);
1065 /*
1066 * Read memory and register.
1067 */
1068 host_rd = scr_to_cpu(np->scratch);
1069 sym_rd = INL(np, nc_scratcha);
1070 sym_bk = INL(np, nc_temp);
1071 /*
1072 * Check termination position.
1073 */
1074 if (pc != SCRIPTZ_BA(np, snoopend)+8) {
1075 printf ("CACHE TEST FAILED: script execution failed.\n");
1076 printf ("start=%08lx, pc=%08lx, end=%08lx\n",
1077 (u_long) SCRIPTZ_BA(np, snooptest), (u_long) pc,
1078 (u_long) SCRIPTZ_BA(np, snoopend) +8);
1079 return (0x40);
1080 }
1081 /*
1082 * Show results.
1083 */
1084 if (host_wr != sym_rd) {
1085 printf ("CACHE TEST FAILED: host wrote %d, chip read %d.\n",
1086 (int) host_wr, (int) sym_rd);
1087 err |= 1;
1088 }
1089 if (host_rd != sym_wr) {
1090 printf ("CACHE TEST FAILED: chip wrote %d, host read %d.\n",
1091 (int) sym_wr, (int) host_rd);
1092 err |= 2;
1093 }
1094 if (sym_bk != sym_wr) {
1095 printf ("CACHE TEST FAILED: chip wrote %d, read back %d.\n",
1096 (int) sym_wr, (int) sym_bk);
1097 err |= 4;
1098 }
1099
1100 return err;
1101 }
1102
1103 /*
1104 * log message for real hard errors
1105 *
1106 * sym0 targ 0?: ERROR (ds:si) (so-si-sd) (sx/s3/s4) @ name (dsp:dbc).
1107 * reg: r0 r1 r2 r3 r4 r5 r6 ..... rf.
1108 *
1109 * exception register:
1110 * ds: dstat
1111 * si: sist
1112 *
1113 * SCSI bus lines:
1114 * so: control lines as driven by chip.
1115 * si: control lines as seen by chip.
1116 * sd: scsi data lines as seen by chip.
1117 *
1118 * wide/fastmode:
1119 * sx: sxfer (see the manual)
1120 * s3: scntl3 (see the manual)
1121 * s4: scntl4 (see the manual)
1122 *
1123 * current script command:
1124 * dsp: script address (relative to start of script).
1125 * dbc: first word of script command.
1126 *
1127 * First 24 register of the chip:
1128 * r0..rf
1129 */
1130 static void sym_log_hard_error(struct Scsi_Host *shost, u_short sist, u_char dstat)
1131 {
1132 struct sym_hcb *np = sym_get_hcb(shost);
1133 u32 dsp;
1134 int script_ofs;
1135 int script_size;
1136 char *script_name;
1137 u_char *script_base;
1138 int i;
1139
1140 dsp = INL(np, nc_dsp);
1141
1142 if (dsp > np->scripta_ba &&
1143 dsp <= np->scripta_ba + np->scripta_sz) {
1144 script_ofs = dsp - np->scripta_ba;
1145 script_size = np->scripta_sz;
1146 script_base = (u_char *) np->scripta0;
1147 script_name = "scripta";
1148 }
1149 else if (np->scriptb_ba < dsp &&
1150 dsp <= np->scriptb_ba + np->scriptb_sz) {
1151 script_ofs = dsp - np->scriptb_ba;
1152 script_size = np->scriptb_sz;
1153 script_base = (u_char *) np->scriptb0;
1154 script_name = "scriptb";
1155 } else {
1156 script_ofs = dsp;
1157 script_size = 0;
1158 script_base = NULL;
1159 script_name = "mem";
1160 }
1161
1162 printf ("%s:%d: ERROR (%x:%x) (%x-%x-%x) (%x/%x/%x) @ (%s %x:%08x).\n",
1163 sym_name(np), (unsigned)INB(np, nc_sdid)&0x0f, dstat, sist,
1164 (unsigned)INB(np, nc_socl), (unsigned)INB(np, nc_sbcl),
1165 (unsigned)INB(np, nc_sbdl), (unsigned)INB(np, nc_sxfer),
1166 (unsigned)INB(np, nc_scntl3),
1167 (np->features & FE_C10) ? (unsigned)INB(np, nc_scntl4) : 0,
1168 script_name, script_ofs, (unsigned)INL(np, nc_dbc));
1169
1170 if (((script_ofs & 3) == 0) &&
1171 (unsigned)script_ofs < script_size) {
1172 printf ("%s: script cmd = %08x\n", sym_name(np),
1173 scr_to_cpu((int) *(u32 *)(script_base + script_ofs)));
1174 }
1175
1176 printf("%s: regdump:", sym_name(np));
1177 for (i = 0; i < 24; i++)
1178 printf(" %02x", (unsigned)INB_OFF(np, i));
1179 printf(".\n");
1180
1181 /*
1182 * PCI BUS error.
1183 */
1184 if (dstat & (MDPE|BF))
1185 sym_log_bus_error(shost);
1186 }
1187
1188 void sym_dump_registers(struct Scsi_Host *shost)
1189 {
1190 struct sym_hcb *np = sym_get_hcb(shost);
1191 u_short sist;
1192 u_char dstat;
1193
1194 sist = INW(np, nc_sist);
1195 dstat = INB(np, nc_dstat);
1196 sym_log_hard_error(shost, sist, dstat);
1197 }
1198
1199 static struct sym_chip sym_dev_table[] = {
1200 {PCI_DEVICE_ID_NCR_53C810, 0x0f, "810", 4, 8, 4, 64,
1201 FE_ERL}
1202 ,
1203 #ifdef SYM_DEBUG_GENERIC_SUPPORT
1204 {PCI_DEVICE_ID_NCR_53C810, 0xff, "810a", 4, 8, 4, 1,
1205 FE_BOF}
1206 ,
1207 #else
1208 {PCI_DEVICE_ID_NCR_53C810, 0xff, "810a", 4, 8, 4, 1,
1209 FE_CACHE_SET|FE_LDSTR|FE_PFEN|FE_BOF}
1210 ,
1211 #endif
1212 {PCI_DEVICE_ID_NCR_53C815, 0xff, "815", 4, 8, 4, 64,
1213 FE_BOF|FE_ERL}
1214 ,
1215 {PCI_DEVICE_ID_NCR_53C825, 0x0f, "825", 6, 8, 4, 64,
1216 FE_WIDE|FE_BOF|FE_ERL|FE_DIFF}
1217 ,
1218 {PCI_DEVICE_ID_NCR_53C825, 0xff, "825a", 6, 8, 4, 2,
1219 FE_WIDE|FE_CACHE0_SET|FE_BOF|FE_DFS|FE_LDSTR|FE_PFEN|FE_RAM|FE_DIFF}
1220 ,
1221 {PCI_DEVICE_ID_NCR_53C860, 0xff, "860", 4, 8, 5, 1,
1222 FE_ULTRA|FE_CACHE_SET|FE_BOF|FE_LDSTR|FE_PFEN}
1223 ,
1224 {PCI_DEVICE_ID_NCR_53C875, 0x01, "875", 6, 16, 5, 2,
1225 FE_WIDE|FE_ULTRA|FE_CACHE0_SET|FE_BOF|FE_DFS|FE_LDSTR|FE_PFEN|
1226 FE_RAM|FE_DIFF|FE_VARCLK}
1227 ,
1228 {PCI_DEVICE_ID_NCR_53C875, 0xff, "875", 6, 16, 5, 2,
1229 FE_WIDE|FE_ULTRA|FE_DBLR|FE_CACHE0_SET|FE_BOF|FE_DFS|FE_LDSTR|FE_PFEN|
1230 FE_RAM|FE_DIFF|FE_VARCLK}
1231 ,
1232 {PCI_DEVICE_ID_NCR_53C875J, 0xff, "875J", 6, 16, 5, 2,
1233 FE_WIDE|FE_ULTRA|FE_DBLR|FE_CACHE0_SET|FE_BOF|FE_DFS|FE_LDSTR|FE_PFEN|
1234 FE_RAM|FE_DIFF|FE_VARCLK}
1235 ,
1236 {PCI_DEVICE_ID_NCR_53C885, 0xff, "885", 6, 16, 5, 2,
1237 FE_WIDE|FE_ULTRA|FE_DBLR|FE_CACHE0_SET|FE_BOF|FE_DFS|FE_LDSTR|FE_PFEN|
1238 FE_RAM|FE_DIFF|FE_VARCLK}
1239 ,
1240 #ifdef SYM_DEBUG_GENERIC_SUPPORT
1241 {PCI_DEVICE_ID_NCR_53C895, 0xff, "895", 6, 31, 7, 2,
1242 FE_WIDE|FE_ULTRA2|FE_QUAD|FE_CACHE_SET|FE_BOF|FE_DFS|
1243 FE_RAM|FE_LCKFRQ}
1244 ,
1245 #else
1246 {PCI_DEVICE_ID_NCR_53C895, 0xff, "895", 6, 31, 7, 2,
1247 FE_WIDE|FE_ULTRA2|FE_QUAD|FE_CACHE_SET|FE_BOF|FE_DFS|FE_LDSTR|FE_PFEN|
1248 FE_RAM|FE_LCKFRQ}
1249 ,
1250 #endif
1251 {PCI_DEVICE_ID_NCR_53C896, 0xff, "896", 6, 31, 7, 4,
1252 FE_WIDE|FE_ULTRA2|FE_QUAD|FE_CACHE_SET|FE_BOF|FE_DFS|FE_LDSTR|FE_PFEN|
1253 FE_RAM|FE_RAM8K|FE_64BIT|FE_DAC|FE_IO256|FE_NOPM|FE_LEDC|FE_LCKFRQ}
1254 ,
1255 {PCI_DEVICE_ID_LSI_53C895A, 0xff, "895a", 6, 31, 7, 4,
1256 FE_WIDE|FE_ULTRA2|FE_QUAD|FE_CACHE_SET|FE_BOF|FE_DFS|FE_LDSTR|FE_PFEN|
1257 FE_RAM|FE_RAM8K|FE_DAC|FE_IO256|FE_NOPM|FE_LEDC|FE_LCKFRQ}
1258 ,
1259 {PCI_DEVICE_ID_LSI_53C875A, 0xff, "875a", 6, 31, 7, 4,
1260 FE_WIDE|FE_ULTRA|FE_QUAD|FE_CACHE_SET|FE_BOF|FE_DFS|FE_LDSTR|FE_PFEN|
1261 FE_RAM|FE_DAC|FE_IO256|FE_NOPM|FE_LEDC|FE_LCKFRQ}
1262 ,
1263 {PCI_DEVICE_ID_LSI_53C1010_33, 0x00, "1010-33", 6, 31, 7, 8,
1264 FE_WIDE|FE_ULTRA3|FE_QUAD|FE_CACHE_SET|FE_BOF|FE_DFBC|FE_LDSTR|FE_PFEN|
1265 FE_RAM|FE_RAM8K|FE_64BIT|FE_DAC|FE_IO256|FE_NOPM|FE_LEDC|FE_CRC|
1266 FE_C10}
1267 ,
1268 {PCI_DEVICE_ID_LSI_53C1010_33, 0xff, "1010-33", 6, 31, 7, 8,
1269 FE_WIDE|FE_ULTRA3|FE_QUAD|FE_CACHE_SET|FE_BOF|FE_DFBC|FE_LDSTR|FE_PFEN|
1270 FE_RAM|FE_RAM8K|FE_64BIT|FE_DAC|FE_IO256|FE_NOPM|FE_LEDC|FE_CRC|
1271 FE_C10|FE_U3EN}
1272 ,
1273 {PCI_DEVICE_ID_LSI_53C1010_66, 0xff, "1010-66", 6, 31, 7, 8,
1274 FE_WIDE|FE_ULTRA3|FE_QUAD|FE_CACHE_SET|FE_BOF|FE_DFBC|FE_LDSTR|FE_PFEN|
1275 FE_RAM|FE_RAM8K|FE_64BIT|FE_DAC|FE_IO256|FE_NOPM|FE_LEDC|FE_66MHZ|FE_CRC|
1276 FE_C10|FE_U3EN}
1277 ,
1278 {PCI_DEVICE_ID_LSI_53C1510, 0xff, "1510d", 6, 31, 7, 4,
1279 FE_WIDE|FE_ULTRA2|FE_QUAD|FE_CACHE_SET|FE_BOF|FE_DFS|FE_LDSTR|FE_PFEN|
1280 FE_RAM|FE_IO256|FE_LEDC}
1281 };
1282
1283 #define sym_num_devs (ARRAY_SIZE(sym_dev_table))
1284
1285 /*
1286 * Look up the chip table.
1287 *
1288 * Return a pointer to the chip entry if found,
1289 * zero otherwise.
1290 */
1291 struct sym_chip *
1292 sym_lookup_chip_table (u_short device_id, u_char revision)
1293 {
1294 struct sym_chip *chip;
1295 int i;
1296
1297 for (i = 0; i < sym_num_devs; i++) {
1298 chip = &sym_dev_table[i];
1299 if (device_id != chip->device_id)
1300 continue;
1301 if (revision > chip->revision_id)
1302 continue;
1303 return chip;
1304 }
1305
1306 return NULL;
1307 }
1308
1309 #if SYM_CONF_DMA_ADDRESSING_MODE == 2
1310 /*
1311 * Lookup the 64 bit DMA segments map.
1312 * This is only used if the direct mapping
1313 * has been unsuccessful.
1314 */
1315 int sym_lookup_dmap(struct sym_hcb *np, u32 h, int s)
1316 {
1317 int i;
1318
1319 if (!use_dac(np))
1320 goto weird;
1321
1322 /* Look up existing mappings */
1323 for (i = SYM_DMAP_SIZE-1; i > 0; i--) {
1324 if (h == np->dmap_bah[i])
1325 return i;
1326 }
1327 /* If direct mapping is free, get it */
1328 if (!np->dmap_bah[s])
1329 goto new;
1330 /* Collision -> lookup free mappings */
1331 for (s = SYM_DMAP_SIZE-1; s > 0; s--) {
1332 if (!np->dmap_bah[s])
1333 goto new;
1334 }
1335 weird:
1336 panic("sym: ran out of 64 bit DMA segment registers");
1337 return -1;
1338 new:
1339 np->dmap_bah[s] = h;
1340 np->dmap_dirty = 1;
1341 return s;
1342 }
1343
1344 /*
1345 * Update IO registers scratch C..R so they will be
1346 * in sync. with queued CCB expectations.
1347 */
1348 static void sym_update_dmap_regs(struct sym_hcb *np)
1349 {
1350 int o, i;
1351
1352 if (!np->dmap_dirty)
1353 return;
1354 o = offsetof(struct sym_reg, nc_scrx[0]);
1355 for (i = 0; i < SYM_DMAP_SIZE; i++) {
1356 OUTL_OFF(np, o, np->dmap_bah[i]);
1357 o += 4;
1358 }
1359 np->dmap_dirty = 0;
1360 }
1361 #endif
1362
1363 /* Enforce all the fiddly SPI rules and the chip limitations */
1364 static void sym_check_goals(struct sym_hcb *np, struct scsi_target *starget,
1365 struct sym_trans *goal)
1366 {
1367 if (!spi_support_wide(starget))
1368 goal->width = 0;
1369
1370 if (!spi_support_sync(starget)) {
1371 goal->iu = 0;
1372 goal->dt = 0;
1373 goal->qas = 0;
1374 goal->offset = 0;
1375 return;
1376 }
1377
1378 if (spi_support_dt(starget)) {
1379 if (spi_support_dt_only(starget))
1380 goal->dt = 1;
1381
1382 if (goal->offset == 0)
1383 goal->dt = 0;
1384 } else {
1385 goal->dt = 0;
1386 }
1387
1388 /* Some targets fail to properly negotiate DT in SE mode */
1389 if ((np->scsi_mode != SMODE_LVD) || !(np->features & FE_U3EN))
1390 goal->dt = 0;
1391
1392 if (goal->dt) {
1393 /* all DT transfers must be wide */
1394 goal->width = 1;
1395 if (goal->offset > np->maxoffs_dt)
1396 goal->offset = np->maxoffs_dt;
1397 if (goal->period < np->minsync_dt)
1398 goal->period = np->minsync_dt;
1399 if (goal->period > np->maxsync_dt)
1400 goal->period = np->maxsync_dt;
1401 } else {
1402 goal->iu = goal->qas = 0;
1403 if (goal->offset > np->maxoffs)
1404 goal->offset = np->maxoffs;
1405 if (goal->period < np->minsync)
1406 goal->period = np->minsync;
1407 if (goal->period > np->maxsync)
1408 goal->period = np->maxsync;
1409 }
1410 }
1411
1412 /*
1413 * Prepare the next negotiation message if needed.
1414 *
1415 * Fill in the part of message buffer that contains the
1416 * negotiation and the nego_status field of the CCB.
1417 * Returns the size of the message in bytes.
1418 */
1419 static int sym_prepare_nego(struct sym_hcb *np, struct sym_ccb *cp, u_char *msgptr)
1420 {
1421 struct sym_tcb *tp = &np->target[cp->target];
1422 struct scsi_target *starget = tp->starget;
1423 struct sym_trans *goal = &tp->tgoal;
1424 int msglen = 0;
1425 int nego;
1426
1427 sym_check_goals(np, starget, goal);
1428
1429 /*
1430 * Many devices implement PPR in a buggy way, so only use it if we
1431 * really want to.
1432 */
1433 if (goal->renego == NS_PPR || (goal->offset &&
1434 (goal->iu || goal->dt || goal->qas || (goal->period < 0xa)))) {
1435 nego = NS_PPR;
1436 } else if (goal->renego == NS_WIDE || goal->width) {
1437 nego = NS_WIDE;
1438 } else if (goal->renego == NS_SYNC || goal->offset) {
1439 nego = NS_SYNC;
1440 } else {
1441 goal->check_nego = 0;
1442 nego = 0;
1443 }
1444
1445 switch (nego) {
1446 case NS_SYNC:
1447 msglen += spi_populate_sync_msg(msgptr + msglen, goal->period,
1448 goal->offset);
1449 break;
1450 case NS_WIDE:
1451 msglen += spi_populate_width_msg(msgptr + msglen, goal->width);
1452 break;
1453 case NS_PPR:
1454 msglen += spi_populate_ppr_msg(msgptr + msglen, goal->period,
1455 goal->offset, goal->width,
1456 (goal->iu ? PPR_OPT_IU : 0) |
1457 (goal->dt ? PPR_OPT_DT : 0) |
1458 (goal->qas ? PPR_OPT_QAS : 0));
1459 break;
1460 }
1461
1462 cp->nego_status = nego;
1463
1464 if (nego) {
1465 tp->nego_cp = cp; /* Keep track a nego will be performed */
1466 if (DEBUG_FLAGS & DEBUG_NEGO) {
1467 sym_print_nego_msg(np, cp->target,
1468 nego == NS_SYNC ? "sync msgout" :
1469 nego == NS_WIDE ? "wide msgout" :
1470 "ppr msgout", msgptr);
1471 }
1472 }
1473
1474 return msglen;
1475 }
1476
1477 /*
1478 * Insert a job into the start queue.
1479 */
1480 void sym_put_start_queue(struct sym_hcb *np, struct sym_ccb *cp)
1481 {
1482 u_short qidx;
1483
1484 #ifdef SYM_CONF_IARB_SUPPORT
1485 /*
1486 * If the previously queued CCB is not yet done,
1487 * set the IARB hint. The SCRIPTS will go with IARB
1488 * for this job when starting the previous one.
1489 * We leave devices a chance to win arbitration by
1490 * not using more than 'iarb_max' consecutive
1491 * immediate arbitrations.
1492 */
1493 if (np->last_cp && np->iarb_count < np->iarb_max) {
1494 np->last_cp->host_flags |= HF_HINT_IARB;
1495 ++np->iarb_count;
1496 }
1497 else
1498 np->iarb_count = 0;
1499 np->last_cp = cp;
1500 #endif
1501
1502 #if SYM_CONF_DMA_ADDRESSING_MODE == 2
1503 /*
1504 * Make SCRIPTS aware of the 64 bit DMA
1505 * segment registers not being up-to-date.
1506 */
1507 if (np->dmap_dirty)
1508 cp->host_xflags |= HX_DMAP_DIRTY;
1509 #endif
1510
1511 /*
1512 * Insert first the idle task and then our job.
1513 * The MBs should ensure proper ordering.
1514 */
1515 qidx = np->squeueput + 2;
1516 if (qidx >= MAX_QUEUE*2) qidx = 0;
1517
1518 np->squeue [qidx] = cpu_to_scr(np->idletask_ba);
1519 MEMORY_WRITE_BARRIER();
1520 np->squeue [np->squeueput] = cpu_to_scr(cp->ccb_ba);
1521
1522 np->squeueput = qidx;
1523
1524 if (DEBUG_FLAGS & DEBUG_QUEUE)
1525 scmd_printk(KERN_DEBUG, cp->cmd, "queuepos=%d\n",
1526 np->squeueput);
1527
1528 /*
1529 * Script processor may be waiting for reselect.
1530 * Wake it up.
1531 */
1532 MEMORY_WRITE_BARRIER();
1533 OUTB(np, nc_istat, SIGP|np->istat_sem);
1534 }
1535
1536 #ifdef SYM_OPT_HANDLE_DEVICE_QUEUEING
1537 /*
1538 * Start next ready-to-start CCBs.
1539 */
1540 void sym_start_next_ccbs(struct sym_hcb *np, struct sym_lcb *lp, int maxn)
1541 {
1542 SYM_QUEHEAD *qp;
1543 struct sym_ccb *cp;
1544
1545 /*
1546 * Paranoia, as usual. :-)
1547 */
1548 assert(!lp->started_tags || !lp->started_no_tag);
1549
1550 /*
1551 * Try to start as many commands as asked by caller.
1552 * Prevent from having both tagged and untagged
1553 * commands queued to the device at the same time.
1554 */
1555 while (maxn--) {
1556 qp = sym_remque_head(&lp->waiting_ccbq);
1557 if (!qp)
1558 break;
1559 cp = sym_que_entry(qp, struct sym_ccb, link2_ccbq);
1560 if (cp->tag != NO_TAG) {
1561 if (lp->started_no_tag ||
1562 lp->started_tags >= lp->started_max) {
1563 sym_insque_head(qp, &lp->waiting_ccbq);
1564 break;
1565 }
1566 lp->itlq_tbl[cp->tag] = cpu_to_scr(cp->ccb_ba);
1567 lp->head.resel_sa =
1568 cpu_to_scr(SCRIPTA_BA(np, resel_tag));
1569 ++lp->started_tags;
1570 } else {
1571 if (lp->started_no_tag || lp->started_tags) {
1572 sym_insque_head(qp, &lp->waiting_ccbq);
1573 break;
1574 }
1575 lp->head.itl_task_sa = cpu_to_scr(cp->ccb_ba);
1576 lp->head.resel_sa =
1577 cpu_to_scr(SCRIPTA_BA(np, resel_no_tag));
1578 ++lp->started_no_tag;
1579 }
1580 cp->started = 1;
1581 sym_insque_tail(qp, &lp->started_ccbq);
1582 sym_put_start_queue(np, cp);
1583 }
1584 }
1585 #endif /* SYM_OPT_HANDLE_DEVICE_QUEUEING */
1586
1587 /*
1588 * The chip may have completed jobs. Look at the DONE QUEUE.
1589 *
1590 * On paper, memory read barriers may be needed here to
1591 * prevent out of order LOADs by the CPU from having
1592 * prefetched stale data prior to DMA having occurred.
1593 */
1594 static int sym_wakeup_done (struct sym_hcb *np)
1595 {
1596 struct sym_ccb *cp;
1597 int i, n;
1598 u32 dsa;
1599
1600 n = 0;
1601 i = np->dqueueget;
1602
1603 /* MEMORY_READ_BARRIER(); */
1604 while (1) {
1605 dsa = scr_to_cpu(np->dqueue[i]);
1606 if (!dsa)
1607 break;
1608 np->dqueue[i] = 0;
1609 if ((i = i+2) >= MAX_QUEUE*2)
1610 i = 0;
1611
1612 cp = sym_ccb_from_dsa(np, dsa);
1613 if (cp) {
1614 MEMORY_READ_BARRIER();
1615 sym_complete_ok (np, cp);
1616 ++n;
1617 }
1618 else
1619 printf ("%s: bad DSA (%x) in done queue.\n",
1620 sym_name(np), (u_int) dsa);
1621 }
1622 np->dqueueget = i;
1623
1624 return n;
1625 }
1626
1627 /*
1628 * Complete all CCBs queued to the COMP queue.
1629 *
1630 * These CCBs are assumed:
1631 * - Not to be referenced either by devices or
1632 * SCRIPTS-related queues and datas.
1633 * - To have to be completed with an error condition
1634 * or requeued.
1635 *
1636 * The device queue freeze count is incremented
1637 * for each CCB that does not prevent this.
1638 * This function is called when all CCBs involved
1639 * in error handling/recovery have been reaped.
1640 */
1641 static void sym_flush_comp_queue(struct sym_hcb *np, int cam_status)
1642 {
1643 SYM_QUEHEAD *qp;
1644 struct sym_ccb *cp;
1645
1646 while ((qp = sym_remque_head(&np->comp_ccbq)) != NULL) {
1647 struct scsi_cmnd *cmd;
1648 cp = sym_que_entry(qp, struct sym_ccb, link_ccbq);
1649 sym_insque_tail(&cp->link_ccbq, &np->busy_ccbq);
1650 /* Leave quiet CCBs waiting for resources */
1651 if (cp->host_status == HS_WAIT)
1652 continue;
1653 cmd = cp->cmd;
1654 if (cam_status)
1655 sym_set_cam_status(cmd, cam_status);
1656 #ifdef SYM_OPT_HANDLE_DEVICE_QUEUEING
1657 if (sym_get_cam_status(cmd) == DID_SOFT_ERROR) {
1658 struct sym_tcb *tp = &np->target[cp->target];
1659 struct sym_lcb *lp = sym_lp(tp, cp->lun);
1660 if (lp) {
1661 sym_remque(&cp->link2_ccbq);
1662 sym_insque_tail(&cp->link2_ccbq,
1663 &lp->waiting_ccbq);
1664 if (cp->started) {
1665 if (cp->tag != NO_TAG)
1666 --lp->started_tags;
1667 else
1668 --lp->started_no_tag;
1669 }
1670 }
1671 cp->started = 0;
1672 continue;
1673 }
1674 #endif
1675 sym_free_ccb(np, cp);
1676 sym_xpt_done(np, cmd);
1677 }
1678 }
1679
1680 /*
1681 * Complete all active CCBs with error.
1682 * Used on CHIP/SCSI RESET.
1683 */
1684 static void sym_flush_busy_queue (struct sym_hcb *np, int cam_status)
1685 {
1686 /*
1687 * Move all active CCBs to the COMP queue
1688 * and flush this queue.
1689 */
1690 sym_que_splice(&np->busy_ccbq, &np->comp_ccbq);
1691 sym_que_init(&np->busy_ccbq);
1692 sym_flush_comp_queue(np, cam_status);
1693 }
1694
1695 /*
1696 * Start chip.
1697 *
1698 * 'reason' means:
1699 * 0: initialisation.
1700 * 1: SCSI BUS RESET delivered or received.
1701 * 2: SCSI BUS MODE changed.
1702 */
1703 void sym_start_up(struct Scsi_Host *shost, int reason)
1704 {
1705 struct sym_data *sym_data = shost_priv(shost);
1706 struct pci_dev *pdev = sym_data->pdev;
1707 struct sym_hcb *np = sym_data->ncb;
1708 int i;
1709 u32 phys;
1710
1711 /*
1712 * Reset chip if asked, otherwise just clear fifos.
1713 */
1714 if (reason == 1)
1715 sym_soft_reset(np);
1716 else {
1717 OUTB(np, nc_stest3, TE|CSF);
1718 OUTONB(np, nc_ctest3, CLF);
1719 }
1720
1721 /*
1722 * Clear Start Queue
1723 */
1724 phys = np->squeue_ba;
1725 for (i = 0; i < MAX_QUEUE*2; i += 2) {
1726 np->squeue[i] = cpu_to_scr(np->idletask_ba);
1727 np->squeue[i+1] = cpu_to_scr(phys + (i+2)*4);
1728 }
1729 np->squeue[MAX_QUEUE*2-1] = cpu_to_scr(phys);
1730
1731 /*
1732 * Start at first entry.
1733 */
1734 np->squeueput = 0;
1735
1736 /*
1737 * Clear Done Queue
1738 */
1739 phys = np->dqueue_ba;
1740 for (i = 0; i < MAX_QUEUE*2; i += 2) {
1741 np->dqueue[i] = 0;
1742 np->dqueue[i+1] = cpu_to_scr(phys + (i+2)*4);
1743 }
1744 np->dqueue[MAX_QUEUE*2-1] = cpu_to_scr(phys);
1745
1746 /*
1747 * Start at first entry.
1748 */
1749 np->dqueueget = 0;
1750
1751 /*
1752 * Install patches in scripts.
1753 * This also let point to first position the start
1754 * and done queue pointers used from SCRIPTS.
1755 */
1756 np->fw_patch(shost);
1757
1758 /*
1759 * Wakeup all pending jobs.
1760 */
1761 sym_flush_busy_queue(np, DID_RESET);
1762
1763 /*
1764 * Init chip.
1765 */
1766 OUTB(np, nc_istat, 0x00); /* Remove Reset, abort */
1767 INB(np, nc_mbox1);
1768 udelay(2000); /* The 895 needs time for the bus mode to settle */
1769
1770 OUTB(np, nc_scntl0, np->rv_scntl0 | 0xc0);
1771 /* full arb., ena parity, par->ATN */
1772 OUTB(np, nc_scntl1, 0x00); /* odd parity, and remove CRST!! */
1773
1774 sym_selectclock(np, np->rv_scntl3); /* Select SCSI clock */
1775
1776 OUTB(np, nc_scid , RRE|np->myaddr); /* Adapter SCSI address */
1777 OUTW(np, nc_respid, 1ul<<np->myaddr); /* Id to respond to */
1778 OUTB(np, nc_istat , SIGP ); /* Signal Process */
1779 OUTB(np, nc_dmode , np->rv_dmode); /* Burst length, dma mode */
1780 OUTB(np, nc_ctest5, np->rv_ctest5); /* Large fifo + large burst */
1781
1782 OUTB(np, nc_dcntl , NOCOM|np->rv_dcntl); /* Protect SFBR */
1783 OUTB(np, nc_ctest3, np->rv_ctest3); /* Write and invalidate */
1784 OUTB(np, nc_ctest4, np->rv_ctest4); /* Master parity checking */
1785
1786 /* Extended Sreq/Sack filtering not supported on the C10 */
1787 if (np->features & FE_C10)
1788 OUTB(np, nc_stest2, np->rv_stest2);
1789 else
1790 OUTB(np, nc_stest2, EXT|np->rv_stest2);
1791
1792 OUTB(np, nc_stest3, TE); /* TolerANT enable */
1793 OUTB(np, nc_stime0, 0x0c); /* HTH disabled STO 0.25 sec */
1794
1795 /*
1796 * For now, disable AIP generation on C1010-66.
1797 */
1798 if (pdev->device == PCI_DEVICE_ID_LSI_53C1010_66)
1799 OUTB(np, nc_aipcntl1, DISAIP);
1800
1801 /*
1802 * C10101 rev. 0 errata.
1803 * Errant SGE's when in narrow. Write bits 4 & 5 of
1804 * STEST1 register to disable SGE. We probably should do
1805 * that from SCRIPTS for each selection/reselection, but
1806 * I just don't want. :)
1807 */
1808 if (pdev->device == PCI_DEVICE_ID_LSI_53C1010_33 &&
1809 pdev->revision < 1)
1810 OUTB(np, nc_stest1, INB(np, nc_stest1) | 0x30);
1811
1812 /*
1813 * DEL 441 - 53C876 Rev 5 - Part Number 609-0392787/2788 - ITEM 2.
1814 * Disable overlapped arbitration for some dual function devices,
1815 * regardless revision id (kind of post-chip-design feature. ;-))
1816 */
1817 if (pdev->device == PCI_DEVICE_ID_NCR_53C875)
1818 OUTB(np, nc_ctest0, (1<<5));
1819 else if (pdev->device == PCI_DEVICE_ID_NCR_53C896)
1820 np->rv_ccntl0 |= DPR;
1821
1822 /*
1823 * Write CCNTL0/CCNTL1 for chips capable of 64 bit addressing
1824 * and/or hardware phase mismatch, since only such chips
1825 * seem to support those IO registers.
1826 */
1827 if (np->features & (FE_DAC|FE_NOPM)) {
1828 OUTB(np, nc_ccntl0, np->rv_ccntl0);
1829 OUTB(np, nc_ccntl1, np->rv_ccntl1);
1830 }
1831
1832 #if SYM_CONF_DMA_ADDRESSING_MODE == 2
1833 /*
1834 * Set up scratch C and DRS IO registers to map the 32 bit
1835 * DMA address range our data structures are located in.
1836 */
1837 if (use_dac(np)) {
1838 np->dmap_bah[0] = 0; /* ??? */
1839 OUTL(np, nc_scrx[0], np->dmap_bah[0]);
1840 OUTL(np, nc_drs, np->dmap_bah[0]);
1841 }
1842 #endif
1843
1844 /*
1845 * If phase mismatch handled by scripts (895A/896/1010),
1846 * set PM jump addresses.
1847 */
1848 if (np->features & FE_NOPM) {
1849 OUTL(np, nc_pmjad1, SCRIPTB_BA(np, pm_handle));
1850 OUTL(np, nc_pmjad2, SCRIPTB_BA(np, pm_handle));
1851 }
1852
1853 /*
1854 * Enable GPIO0 pin for writing if LED support from SCRIPTS.
1855 * Also set GPIO5 and clear GPIO6 if hardware LED control.
1856 */
1857 if (np->features & FE_LED0)
1858 OUTB(np, nc_gpcntl, INB(np, nc_gpcntl) & ~0x01);
1859 else if (np->features & FE_LEDC)
1860 OUTB(np, nc_gpcntl, (INB(np, nc_gpcntl) & ~0x41) | 0x20);
1861
1862 /*
1863 * enable ints
1864 */
1865 OUTW(np, nc_sien , STO|HTH|MA|SGE|UDC|RST|PAR);
1866 OUTB(np, nc_dien , MDPE|BF|SSI|SIR|IID);
1867
1868 /*
1869 * For 895/6 enable SBMC interrupt and save current SCSI bus mode.
1870 * Try to eat the spurious SBMC interrupt that may occur when
1871 * we reset the chip but not the SCSI BUS (at initialization).
1872 */
1873 if (np->features & (FE_ULTRA2|FE_ULTRA3)) {
1874 OUTONW(np, nc_sien, SBMC);
1875 if (reason == 0) {
1876 INB(np, nc_mbox1);
1877 mdelay(100);
1878 INW(np, nc_sist);
1879 }
1880 np->scsi_mode = INB(np, nc_stest4) & SMODE;
1881 }
1882
1883 /*
1884 * Fill in target structure.
1885 * Reinitialize usrsync.
1886 * Reinitialize usrwide.
1887 * Prepare sync negotiation according to actual SCSI bus mode.
1888 */
1889 for (i=0;i<SYM_CONF_MAX_TARGET;i++) {
1890 struct sym_tcb *tp = &np->target[i];
1891
1892 tp->to_reset = 0;
1893 tp->head.sval = 0;
1894 tp->head.wval = np->rv_scntl3;
1895 tp->head.uval = 0;
1896 if (tp->lun0p)
1897 tp->lun0p->to_clear = 0;
1898 if (tp->lunmp) {
1899 int ln;
1900
1901 for (ln = 1; ln < SYM_CONF_MAX_LUN; ln++)
1902 if (tp->lunmp[ln])
1903 tp->lunmp[ln]->to_clear = 0;
1904 }
1905 }
1906
1907 /*
1908 * Download SCSI SCRIPTS to on-chip RAM if present,
1909 * and start script processor.
1910 * We do the download preferently from the CPU.
1911 * For platforms that may not support PCI memory mapping,
1912 * we use simple SCRIPTS that performs MEMORY MOVEs.
1913 */
1914 phys = SCRIPTA_BA(np, init);
1915 if (np->ram_ba) {
1916 if (sym_verbose >= 2)
1917 printf("%s: Downloading SCSI SCRIPTS.\n", sym_name(np));
1918 memcpy_toio(np->s.ramaddr, np->scripta0, np->scripta_sz);
1919 if (np->features & FE_RAM8K) {
1920 memcpy_toio(np->s.ramaddr + 4096, np->scriptb0, np->scriptb_sz);
1921 phys = scr_to_cpu(np->scr_ram_seg);
1922 OUTL(np, nc_mmws, phys);
1923 OUTL(np, nc_mmrs, phys);
1924 OUTL(np, nc_sfs, phys);
1925 phys = SCRIPTB_BA(np, start64);
1926 }
1927 }
1928
1929 np->istat_sem = 0;
1930
1931 OUTL(np, nc_dsa, np->hcb_ba);
1932 OUTL_DSP(np, phys);
1933
1934 /*
1935 * Notify the XPT about the RESET condition.
1936 */
1937 if (reason != 0)
1938 sym_xpt_async_bus_reset(np);
1939 }
1940
1941 /*
1942 * Switch trans mode for current job and its target.
1943 */
1944 static void sym_settrans(struct sym_hcb *np, int target, u_char opts, u_char ofs,
1945 u_char per, u_char wide, u_char div, u_char fak)
1946 {
1947 SYM_QUEHEAD *qp;
1948 u_char sval, wval, uval;
1949 struct sym_tcb *tp = &np->target[target];
1950
1951 assert(target == (INB(np, nc_sdid) & 0x0f));
1952
1953 sval = tp->head.sval;
1954 wval = tp->head.wval;
1955 uval = tp->head.uval;
1956
1957 #if 0
1958 printf("XXXX sval=%x wval=%x uval=%x (%x)\n",
1959 sval, wval, uval, np->rv_scntl3);
1960 #endif
1961 /*
1962 * Set the offset.
1963 */
1964 if (!(np->features & FE_C10))
1965 sval = (sval & ~0x1f) | ofs;
1966 else
1967 sval = (sval & ~0x3f) | ofs;
1968
1969 /*
1970 * Set the sync divisor and extra clock factor.
1971 */
1972 if (ofs != 0) {
1973 wval = (wval & ~0x70) | ((div+1) << 4);
1974 if (!(np->features & FE_C10))
1975 sval = (sval & ~0xe0) | (fak << 5);
1976 else {
1977 uval = uval & ~(XCLKH_ST|XCLKH_DT|XCLKS_ST|XCLKS_DT);
1978 if (fak >= 1) uval |= (XCLKH_ST|XCLKH_DT);
1979 if (fak >= 2) uval |= (XCLKS_ST|XCLKS_DT);
1980 }
1981 }
1982
1983 /*
1984 * Set the bus width.
1985 */
1986 wval = wval & ~EWS;
1987 if (wide != 0)
1988 wval |= EWS;
1989
1990 /*
1991 * Set misc. ultra enable bits.
1992 */
1993 if (np->features & FE_C10) {
1994 uval = uval & ~(U3EN|AIPCKEN);
1995 if (opts) {
1996 assert(np->features & FE_U3EN);
1997 uval |= U3EN;
1998 }
1999 } else {
2000 wval = wval & ~ULTRA;
2001 if (per <= 12) wval |= ULTRA;
2002 }
2003
2004 /*
2005 * Stop there if sync parameters are unchanged.
2006 */
2007 if (tp->head.sval == sval &&
2008 tp->head.wval == wval &&
2009 tp->head.uval == uval)
2010 return;
2011 tp->head.sval = sval;
2012 tp->head.wval = wval;
2013 tp->head.uval = uval;
2014
2015 /*
2016 * Disable extended Sreq/Sack filtering if per < 50.
2017 * Not supported on the C1010.
2018 */
2019 if (per < 50 && !(np->features & FE_C10))
2020 OUTOFFB(np, nc_stest2, EXT);
2021
2022 /*
2023 * set actual value and sync_status
2024 */
2025 OUTB(np, nc_sxfer, tp->head.sval);
2026 OUTB(np, nc_scntl3, tp->head.wval);
2027
2028 if (np->features & FE_C10) {
2029 OUTB(np, nc_scntl4, tp->head.uval);
2030 }
2031
2032 /*
2033 * patch ALL busy ccbs of this target.
2034 */
2035 FOR_EACH_QUEUED_ELEMENT(&np->busy_ccbq, qp) {
2036 struct sym_ccb *cp;
2037 cp = sym_que_entry(qp, struct sym_ccb, link_ccbq);
2038 if (cp->target != target)
2039 continue;
2040 cp->phys.select.sel_scntl3 = tp->head.wval;
2041 cp->phys.select.sel_sxfer = tp->head.sval;
2042 if (np->features & FE_C10) {
2043 cp->phys.select.sel_scntl4 = tp->head.uval;
2044 }
2045 }
2046 }
2047
2048 static void sym_announce_transfer_rate(struct sym_tcb *tp)
2049 {
2050 struct scsi_target *starget = tp->starget;
2051
2052 if (tp->tprint.period != spi_period(starget) ||
2053 tp->tprint.offset != spi_offset(starget) ||
2054 tp->tprint.width != spi_width(starget) ||
2055 tp->tprint.iu != spi_iu(starget) ||
2056 tp->tprint.dt != spi_dt(starget) ||
2057 tp->tprint.qas != spi_qas(starget) ||
2058 !tp->tprint.check_nego) {
2059 tp->tprint.period = spi_period(starget);
2060 tp->tprint.offset = spi_offset(starget);
2061 tp->tprint.width = spi_width(starget);
2062 tp->tprint.iu = spi_iu(starget);
2063 tp->tprint.dt = spi_dt(starget);
2064 tp->tprint.qas = spi_qas(starget);
2065 tp->tprint.check_nego = 1;
2066
2067 spi_display_xfer_agreement(starget);
2068 }
2069 }
2070
2071 /*
2072 * We received a WDTR.
2073 * Let everything be aware of the changes.
2074 */
2075 static void sym_setwide(struct sym_hcb *np, int target, u_char wide)
2076 {
2077 struct sym_tcb *tp = &np->target[target];
2078 struct scsi_target *starget = tp->starget;
2079
2080 sym_settrans(np, target, 0, 0, 0, wide, 0, 0);
2081
2082 if (wide)
2083 tp->tgoal.renego = NS_WIDE;
2084 else
2085 tp->tgoal.renego = 0;
2086 tp->tgoal.check_nego = 0;
2087 tp->tgoal.width = wide;
2088 spi_offset(starget) = 0;
2089 spi_period(starget) = 0;
2090 spi_width(starget) = wide;
2091 spi_iu(starget) = 0;
2092 spi_dt(starget) = 0;
2093 spi_qas(starget) = 0;
2094
2095 if (sym_verbose >= 3)
2096 sym_announce_transfer_rate(tp);
2097 }
2098
2099 /*
2100 * We received a SDTR.
2101 * Let everything be aware of the changes.
2102 */
2103 static void
2104 sym_setsync(struct sym_hcb *np, int target,
2105 u_char ofs, u_char per, u_char div, u_char fak)
2106 {
2107 struct sym_tcb *tp = &np->target[target];
2108 struct scsi_target *starget = tp->starget;
2109 u_char wide = (tp->head.wval & EWS) ? BUS_16_BIT : BUS_8_BIT;
2110
2111 sym_settrans(np, target, 0, ofs, per, wide, div, fak);
2112
2113 if (wide)
2114 tp->tgoal.renego = NS_WIDE;
2115 else if (ofs)
2116 tp->tgoal.renego = NS_SYNC;
2117 else
2118 tp->tgoal.renego = 0;
2119 spi_period(starget) = per;
2120 spi_offset(starget) = ofs;
2121 spi_iu(starget) = spi_dt(starget) = spi_qas(starget) = 0;
2122
2123 if (!tp->tgoal.dt && !tp->tgoal.iu && !tp->tgoal.qas) {
2124 tp->tgoal.period = per;
2125 tp->tgoal.offset = ofs;
2126 tp->tgoal.check_nego = 0;
2127 }
2128
2129 sym_announce_transfer_rate(tp);
2130 }
2131
2132 /*
2133 * We received a PPR.
2134 * Let everything be aware of the changes.
2135 */
2136 static void
2137 sym_setpprot(struct sym_hcb *np, int target, u_char opts, u_char ofs,
2138 u_char per, u_char wide, u_char div, u_char fak)
2139 {
2140 struct sym_tcb *tp = &np->target[target];
2141 struct scsi_target *starget = tp->starget;
2142
2143 sym_settrans(np, target, opts, ofs, per, wide, div, fak);
2144
2145 if (wide || ofs)
2146 tp->tgoal.renego = NS_PPR;
2147 else
2148 tp->tgoal.renego = 0;
2149 spi_width(starget) = tp->tgoal.width = wide;
2150 spi_period(starget) = tp->tgoal.period = per;
2151 spi_offset(starget) = tp->tgoal.offset = ofs;
2152 spi_iu(starget) = tp->tgoal.iu = !!(opts & PPR_OPT_IU);
2153 spi_dt(starget) = tp->tgoal.dt = !!(opts & PPR_OPT_DT);
2154 spi_qas(starget) = tp->tgoal.qas = !!(opts & PPR_OPT_QAS);
2155 tp->tgoal.check_nego = 0;
2156
2157 sym_announce_transfer_rate(tp);
2158 }
2159
2160 /*
2161 * generic recovery from scsi interrupt
2162 *
2163 * The doc says that when the chip gets an SCSI interrupt,
2164 * it tries to stop in an orderly fashion, by completing
2165 * an instruction fetch that had started or by flushing
2166 * the DMA fifo for a write to memory that was executing.
2167 * Such a fashion is not enough to know if the instruction
2168 * that was just before the current DSP value has been
2169 * executed or not.
2170 *
2171 * There are some small SCRIPTS sections that deal with
2172 * the start queue and the done queue that may break any
2173 * assomption from the C code if we are interrupted
2174 * inside, so we reset if this happens. Btw, since these
2175 * SCRIPTS sections are executed while the SCRIPTS hasn't
2176 * started SCSI operations, it is very unlikely to happen.
2177 *
2178 * All the driver data structures are supposed to be
2179 * allocated from the same 4 GB memory window, so there
2180 * is a 1 to 1 relationship between DSA and driver data
2181 * structures. Since we are careful :) to invalidate the
2182 * DSA when we complete a command or when the SCRIPTS
2183 * pushes a DSA into a queue, we can trust it when it
2184 * points to a CCB.
2185 */
2186 static void sym_recover_scsi_int (struct sym_hcb *np, u_char hsts)
2187 {
2188 u32 dsp = INL(np, nc_dsp);
2189 u32 dsa = INL(np, nc_dsa);
2190 struct sym_ccb *cp = sym_ccb_from_dsa(np, dsa);
2191
2192 /*
2193 * If we haven't been interrupted inside the SCRIPTS
2194 * critical pathes, we can safely restart the SCRIPTS
2195 * and trust the DSA value if it matches a CCB.
2196 */
2197 if ((!(dsp > SCRIPTA_BA(np, getjob_begin) &&
2198 dsp < SCRIPTA_BA(np, getjob_end) + 1)) &&
2199 (!(dsp > SCRIPTA_BA(np, ungetjob) &&
2200 dsp < SCRIPTA_BA(np, reselect) + 1)) &&
2201 (!(dsp > SCRIPTB_BA(np, sel_for_abort) &&
2202 dsp < SCRIPTB_BA(np, sel_for_abort_1) + 1)) &&
2203 (!(dsp > SCRIPTA_BA(np, done) &&
2204 dsp < SCRIPTA_BA(np, done_end) + 1))) {
2205 OUTB(np, nc_ctest3, np->rv_ctest3 | CLF); /* clear dma fifo */
2206 OUTB(np, nc_stest3, TE|CSF); /* clear scsi fifo */
2207 /*
2208 * If we have a CCB, let the SCRIPTS call us back for
2209 * the handling of the error with SCRATCHA filled with
2210 * STARTPOS. This way, we will be able to freeze the
2211 * device queue and requeue awaiting IOs.
2212 */
2213 if (cp) {
2214 cp->host_status = hsts;
2215 OUTL_DSP(np, SCRIPTA_BA(np, complete_error));
2216 }
2217 /*
2218 * Otherwise just restart the SCRIPTS.
2219 */
2220 else {
2221 OUTL(np, nc_dsa, 0xffffff);
2222 OUTL_DSP(np, SCRIPTA_BA(np, start));
2223 }
2224 }
2225 else
2226 goto reset_all;
2227
2228 return;
2229
2230 reset_all:
2231 sym_start_reset(np);
2232 }
2233
2234 /*
2235 * chip exception handler for selection timeout
2236 */
2237 static void sym_int_sto (struct sym_hcb *np)
2238 {
2239 u32 dsp = INL(np, nc_dsp);
2240
2241 if (DEBUG_FLAGS & DEBUG_TINY) printf ("T");
2242
2243 if (dsp == SCRIPTA_BA(np, wf_sel_done) + 8)
2244 sym_recover_scsi_int(np, HS_SEL_TIMEOUT);
2245 else
2246 sym_start_reset(np);
2247 }
2248
2249 /*
2250 * chip exception handler for unexpected disconnect
2251 */
2252 static void sym_int_udc (struct sym_hcb *np)
2253 {
2254 printf ("%s: unexpected disconnect\n", sym_name(np));
2255 sym_recover_scsi_int(np, HS_UNEXPECTED);
2256 }
2257
2258 /*
2259 * chip exception handler for SCSI bus mode change
2260 *
2261 * spi2-r12 11.2.3 says a transceiver mode change must
2262 * generate a reset event and a device that detects a reset
2263 * event shall initiate a hard reset. It says also that a
2264 * device that detects a mode change shall set data transfer
2265 * mode to eight bit asynchronous, etc...
2266 * So, just reinitializing all except chip should be enough.
2267 */
2268 static void sym_int_sbmc(struct Scsi_Host *shost)
2269 {
2270 struct sym_hcb *np = sym_get_hcb(shost);
2271 u_char scsi_mode = INB(np, nc_stest4) & SMODE;
2272
2273 /*
2274 * Notify user.
2275 */
2276 printf("%s: SCSI BUS mode change from %s to %s.\n", sym_name(np),
2277 sym_scsi_bus_mode(np->scsi_mode), sym_scsi_bus_mode(scsi_mode));
2278
2279 /*
2280 * Should suspend command processing for a few seconds and
2281 * reinitialize all except the chip.
2282 */
2283 sym_start_up(shost, 2);
2284 }
2285
2286 /*
2287 * chip exception handler for SCSI parity error.
2288 *
2289 * When the chip detects a SCSI parity error and is
2290 * currently executing a (CH)MOV instruction, it does
2291 * not interrupt immediately, but tries to finish the
2292 * transfer of the current scatter entry before
2293 * interrupting. The following situations may occur:
2294 *
2295 * - The complete scatter entry has been transferred
2296 * without the device having changed phase.
2297 * The chip will then interrupt with the DSP pointing
2298 * to the instruction that follows the MOV.
2299 *
2300 * - A phase mismatch occurs before the MOV finished
2301 * and phase errors are to be handled by the C code.
2302 * The chip will then interrupt with both PAR and MA
2303 * conditions set.
2304 *
2305 * - A phase mismatch occurs before the MOV finished and
2306 * phase errors are to be handled by SCRIPTS.
2307 * The chip will load the DSP with the phase mismatch
2308 * JUMP address and interrupt the host processor.
2309 */
2310 static void sym_int_par (struct sym_hcb *np, u_short sist)
2311 {
2312 u_char hsts = INB(np, HS_PRT);
2313 u32 dsp = INL(np, nc_dsp);
2314 u32 dbc = INL(np, nc_dbc);
2315 u32 dsa = INL(np, nc_dsa);
2316 u_char sbcl = INB(np, nc_sbcl);
2317 u_char cmd = dbc >> 24;
2318 int phase = cmd & 7;
2319 struct sym_ccb *cp = sym_ccb_from_dsa(np, dsa);
2320
2321 if (printk_ratelimit())
2322 printf("%s: SCSI parity error detected: SCR1=%d DBC=%x SBCL=%x\n",
2323 sym_name(np), hsts, dbc, sbcl);
2324
2325 /*
2326 * Check that the chip is connected to the SCSI BUS.
2327 */
2328 if (!(INB(np, nc_scntl1) & ISCON)) {
2329 sym_recover_scsi_int(np, HS_UNEXPECTED);
2330 return;
2331 }
2332
2333 /*
2334 * If the nexus is not clearly identified, reset the bus.
2335 * We will try to do better later.
2336 */
2337 if (!cp)
2338 goto reset_all;
2339
2340 /*
2341 * Check instruction was a MOV, direction was INPUT and
2342 * ATN is asserted.
2343 */
2344 if ((cmd & 0xc0) || !(phase & 1) || !(sbcl & 0x8))
2345 goto reset_all;
2346
2347 /*
2348 * Keep track of the parity error.
2349 */
2350 OUTONB(np, HF_PRT, HF_EXT_ERR);
2351 cp->xerr_status |= XE_PARITY_ERR;
2352
2353 /*
2354 * Prepare the message to send to the device.
2355 */
2356 np->msgout[0] = (phase == 7) ? M_PARITY : M_ID_ERROR;
2357
2358 /*
2359 * If the old phase was DATA IN phase, we have to deal with
2360 * the 3 situations described above.
2361 * For other input phases (MSG IN and STATUS), the device
2362 * must resend the whole thing that failed parity checking
2363 * or signal error. So, jumping to dispatcher should be OK.
2364 */
2365 if (phase == 1 || phase == 5) {
2366 /* Phase mismatch handled by SCRIPTS */
2367 if (dsp == SCRIPTB_BA(np, pm_handle))
2368 OUTL_DSP(np, dsp);
2369 /* Phase mismatch handled by the C code */
2370 else if (sist & MA)
2371 sym_int_ma (np);
2372 /* No phase mismatch occurred */
2373 else {
2374 sym_set_script_dp (np, cp, dsp);
2375 OUTL_DSP(np, SCRIPTA_BA(np, dispatch));
2376 }
2377 }
2378 else if (phase == 7) /* We definitely cannot handle parity errors */
2379 #if 1 /* in message-in phase due to the relection */
2380 goto reset_all; /* path and various message anticipations. */
2381 #else
2382 OUTL_DSP(np, SCRIPTA_BA(np, clrack));
2383 #endif
2384 else
2385 OUTL_DSP(np, SCRIPTA_BA(np, dispatch));
2386 return;
2387
2388 reset_all:
2389 sym_start_reset(np);
2390 return;
2391 }
2392
2393 /*
2394 * chip exception handler for phase errors.
2395 *
2396 * We have to construct a new transfer descriptor,
2397 * to transfer the rest of the current block.
2398 */
2399 static void sym_int_ma (struct sym_hcb *np)
2400 {
2401 u32 dbc;
2402 u32 rest;
2403 u32 dsp;
2404 u32 dsa;
2405 u32 nxtdsp;
2406 u32 *vdsp;
2407 u32 oadr, olen;
2408 u32 *tblp;
2409 u32 newcmd;
2410 u_int delta;
2411 u_char cmd;
2412 u_char hflags, hflags0;
2413 struct sym_pmc *pm;
2414 struct sym_ccb *cp;
2415
2416 dsp = INL(np, nc_dsp);
2417 dbc = INL(np, nc_dbc);
2418 dsa = INL(np, nc_dsa);
2419
2420 cmd = dbc >> 24;
2421 rest = dbc & 0xffffff;
2422 delta = 0;
2423
2424 /*
2425 * locate matching cp if any.
2426 */
2427 cp = sym_ccb_from_dsa(np, dsa);
2428
2429 /*
2430 * Donnot take into account dma fifo and various buffers in
2431 * INPUT phase since the chip flushes everything before
2432 * raising the MA interrupt for interrupted INPUT phases.
2433 * For DATA IN phase, we will check for the SWIDE later.
2434 */
2435 if ((cmd & 7) != 1 && (cmd & 7) != 5) {
2436 u_char ss0, ss2;
2437
2438 if (np->features & FE_DFBC)
2439 delta = INW(np, nc_dfbc);
2440 else {
2441 u32 dfifo;
2442
2443 /*
2444 * Read DFIFO, CTEST[4-6] using 1 PCI bus ownership.
2445 */
2446 dfifo = INL(np, nc_dfifo);
2447
2448 /*
2449 * Calculate remaining bytes in DMA fifo.
2450 * (CTEST5 = dfifo >> 16)
2451 */
2452 if (dfifo & (DFS << 16))
2453 delta = ((((dfifo >> 8) & 0x300) |
2454 (dfifo & 0xff)) - rest) & 0x3ff;
2455 else
2456 delta = ((dfifo & 0xff) - rest) & 0x7f;
2457 }
2458
2459 /*
2460 * The data in the dma fifo has not been transferred to
2461 * the target -> add the amount to the rest
2462 * and clear the data.
2463 * Check the sstat2 register in case of wide transfer.
2464 */
2465 rest += delta;
2466 ss0 = INB(np, nc_sstat0);
2467 if (ss0 & OLF) rest++;
2468 if (!(np->features & FE_C10))
2469 if (ss0 & ORF) rest++;
2470 if (cp && (cp->phys.select.sel_scntl3 & EWS)) {
2471 ss2 = INB(np, nc_sstat2);
2472 if (ss2 & OLF1) rest++;
2473 if (!(np->features & FE_C10))
2474 if (ss2 & ORF1) rest++;
2475 }
2476
2477 /*
2478 * Clear fifos.
2479 */
2480 OUTB(np, nc_ctest3, np->rv_ctest3 | CLF); /* dma fifo */
2481 OUTB(np, nc_stest3, TE|CSF); /* scsi fifo */
2482 }
2483
2484 /*
2485 * log the information
2486 */
2487 if (DEBUG_FLAGS & (DEBUG_TINY|DEBUG_PHASE))
2488 printf ("P%x%x RL=%d D=%d ", cmd&7, INB(np, nc_sbcl)&7,
2489 (unsigned) rest, (unsigned) delta);
2490
2491 /*
2492 * try to find the interrupted script command,
2493 * and the address at which to continue.
2494 */
2495 vdsp = NULL;
2496 nxtdsp = 0;
2497 if (dsp > np->scripta_ba &&
2498 dsp <= np->scripta_ba + np->scripta_sz) {
2499 vdsp = (u32 *)((char*)np->scripta0 + (dsp-np->scripta_ba-8));
2500 nxtdsp = dsp;
2501 }
2502 else if (dsp > np->scriptb_ba &&
2503 dsp <= np->scriptb_ba + np->scriptb_sz) {
2504 vdsp = (u32 *)((char*)np->scriptb0 + (dsp-np->scriptb_ba-8));
2505 nxtdsp = dsp;
2506 }
2507
2508 /*
2509 * log the information
2510 */
2511 if (DEBUG_FLAGS & DEBUG_PHASE) {
2512 printf ("\nCP=%p DSP=%x NXT=%x VDSP=%p CMD=%x ",
2513 cp, (unsigned)dsp, (unsigned)nxtdsp, vdsp, cmd);
2514 }
2515
2516 if (!vdsp) {
2517 printf ("%s: interrupted SCRIPT address not found.\n",
2518 sym_name (np));
2519 goto reset_all;
2520 }
2521
2522 if (!cp) {
2523 printf ("%s: SCSI phase error fixup: CCB already dequeued.\n",
2524 sym_name (np));
2525 goto reset_all;
2526 }
2527
2528 /*
2529 * get old startaddress and old length.
2530 */
2531 oadr = scr_to_cpu(vdsp[1]);
2532
2533 if (cmd & 0x10) { /* Table indirect */
2534 tblp = (u32 *) ((char*) &cp->phys + oadr);
2535 olen = scr_to_cpu(tblp[0]);
2536 oadr = scr_to_cpu(tblp[1]);
2537 } else {
2538 tblp = (u32 *) 0;
2539 olen = scr_to_cpu(vdsp[0]) & 0xffffff;
2540 }
2541
2542 if (DEBUG_FLAGS & DEBUG_PHASE) {
2543 printf ("OCMD=%x\nTBLP=%p OLEN=%x OADR=%x\n",
2544 (unsigned) (scr_to_cpu(vdsp[0]) >> 24),
2545 tblp,
2546 (unsigned) olen,
2547 (unsigned) oadr);
2548 }
2549
2550 /*
2551 * check cmd against assumed interrupted script command.
2552 * If dt data phase, the MOVE instruction hasn't bit 4 of
2553 * the phase.
2554 */
2555 if (((cmd & 2) ? cmd : (cmd & ~4)) != (scr_to_cpu(vdsp[0]) >> 24)) {
2556 sym_print_addr(cp->cmd,
2557 "internal error: cmd=%02x != %02x=(vdsp[0] >> 24)\n",
2558 cmd, scr_to_cpu(vdsp[0]) >> 24);
2559
2560 goto reset_all;
2561 }
2562
2563 /*
2564 * if old phase not dataphase, leave here.
2565 */
2566 if (cmd & 2) {
2567 sym_print_addr(cp->cmd,
2568 "phase change %x-%x %d@%08x resid=%d.\n",
2569 cmd&7, INB(np, nc_sbcl)&7, (unsigned)olen,
2570 (unsigned)oadr, (unsigned)rest);
2571 goto unexpected_phase;
2572 }
2573
2574 /*
2575 * Choose the correct PM save area.
2576 *
2577 * Look at the PM_SAVE SCRIPT if you want to understand
2578 * this stuff. The equivalent code is implemented in
2579 * SCRIPTS for the 895A, 896 and 1010 that are able to
2580 * handle PM from the SCRIPTS processor.
2581 */
2582 hflags0 = INB(np, HF_PRT);
2583 hflags = hflags0;
2584
2585 if (hflags & (HF_IN_PM0 | HF_IN_PM1 | HF_DP_SAVED)) {
2586 if (hflags & HF_IN_PM0)
2587 nxtdsp = scr_to_cpu(cp->phys.pm0.ret);
2588 else if (hflags & HF_IN_PM1)
2589 nxtdsp = scr_to_cpu(cp->phys.pm1.ret);
2590
2591 if (hflags & HF_DP_SAVED)
2592 hflags ^= HF_ACT_PM;
2593 }
2594
2595 if (!(hflags & HF_ACT_PM)) {
2596 pm = &cp->phys.pm0;
2597 newcmd = SCRIPTA_BA(np, pm0_data);
2598 }
2599 else {
2600 pm = &cp->phys.pm1;
2601 newcmd = SCRIPTA_BA(np, pm1_data);
2602 }
2603
2604 hflags &= ~(HF_IN_PM0 | HF_IN_PM1 | HF_DP_SAVED);
2605 if (hflags != hflags0)
2606 OUTB(np, HF_PRT, hflags);
2607
2608 /*
2609 * fillin the phase mismatch context
2610 */
2611 pm->sg.addr = cpu_to_scr(oadr + olen - rest);
2612 pm->sg.size = cpu_to_scr(rest);
2613 pm->ret = cpu_to_scr(nxtdsp);
2614
2615 /*
2616 * If we have a SWIDE,
2617 * - prepare the address to write the SWIDE from SCRIPTS,
2618 * - compute the SCRIPTS address to restart from,
2619 * - move current data pointer context by one byte.
2620 */
2621 nxtdsp = SCRIPTA_BA(np, dispatch);
2622 if ((cmd & 7) == 1 && cp && (cp->phys.select.sel_scntl3 & EWS) &&
2623 (INB(np, nc_scntl2) & WSR)) {
2624 u32 tmp;
2625
2626 /*
2627 * Set up the table indirect for the MOVE
2628 * of the residual byte and adjust the data
2629 * pointer context.
2630 */
2631 tmp = scr_to_cpu(pm->sg.addr);
2632 cp->phys.wresid.addr = cpu_to_scr(tmp);
2633 pm->sg.addr = cpu_to_scr(tmp + 1);
2634 tmp = scr_to_cpu(pm->sg.size);
2635 cp->phys.wresid.size = cpu_to_scr((tmp&0xff000000) | 1);
2636 pm->sg.size = cpu_to_scr(tmp - 1);
2637
2638 /*
2639 * If only the residual byte is to be moved,
2640 * no PM context is needed.
2641 */
2642 if ((tmp&0xffffff) == 1)
2643 newcmd = pm->ret;
2644
2645 /*
2646 * Prepare the address of SCRIPTS that will
2647 * move the residual byte to memory.
2648 */
2649 nxtdsp = SCRIPTB_BA(np, wsr_ma_helper);
2650 }
2651
2652 if (DEBUG_FLAGS & DEBUG_PHASE) {
2653 sym_print_addr(cp->cmd, "PM %x %x %x / %x %x %x.\n",
2654 hflags0, hflags, newcmd,
2655 (unsigned)scr_to_cpu(pm->sg.addr),
2656 (unsigned)scr_to_cpu(pm->sg.size),
2657 (unsigned)scr_to_cpu(pm->ret));
2658 }
2659
2660 /*
2661 * Restart the SCRIPTS processor.
2662 */
2663 sym_set_script_dp (np, cp, newcmd);
2664 OUTL_DSP(np, nxtdsp);
2665 return;
2666
2667 /*
2668 * Unexpected phase changes that occurs when the current phase
2669 * is not a DATA IN or DATA OUT phase are due to error conditions.
2670 * Such event may only happen when the SCRIPTS is using a
2671 * multibyte SCSI MOVE.
2672 *
2673 * Phase change Some possible cause
2674 *
2675 * COMMAND --> MSG IN SCSI parity error detected by target.
2676 * COMMAND --> STATUS Bad command or refused by target.
2677 * MSG OUT --> MSG IN Message rejected by target.
2678 * MSG OUT --> COMMAND Bogus target that discards extended
2679 * negotiation messages.
2680 *
2681 * The code below does not care of the new phase and so
2682 * trusts the target. Why to annoy it ?
2683 * If the interrupted phase is COMMAND phase, we restart at
2684 * dispatcher.
2685 * If a target does not get all the messages after selection,
2686 * the code assumes blindly that the target discards extended
2687 * messages and clears the negotiation status.
2688 * If the target does not want all our response to negotiation,
2689 * we force a SIR_NEGO_PROTO interrupt (it is a hack that avoids
2690 * bloat for such a should_not_happen situation).
2691 * In all other situation, we reset the BUS.
2692 * Are these assumptions reasonable ? (Wait and see ...)
2693 */
2694 unexpected_phase:
2695 dsp -= 8;
2696 nxtdsp = 0;
2697
2698 switch (cmd & 7) {
2699 case 2: /* COMMAND phase */
2700 nxtdsp = SCRIPTA_BA(np, dispatch);
2701 break;
2702 #if 0
2703 case 3: /* STATUS phase */
2704 nxtdsp = SCRIPTA_BA(np, dispatch);
2705 break;
2706 #endif
2707 case 6: /* MSG OUT phase */
2708 /*
2709 * If the device may want to use untagged when we want
2710 * tagged, we prepare an IDENTIFY without disc. granted,
2711 * since we will not be able to handle reselect.
2712 * Otherwise, we just don't care.
2713 */
2714 if (dsp == SCRIPTA_BA(np, send_ident)) {
2715 if (cp->tag != NO_TAG && olen - rest <= 3) {
2716 cp->host_status = HS_BUSY;
2717 np->msgout[0] = IDENTIFY(0, cp->lun);
2718 nxtdsp = SCRIPTB_BA(np, ident_break_atn);
2719 }
2720 else
2721 nxtdsp = SCRIPTB_BA(np, ident_break);
2722 }
2723 else if (dsp == SCRIPTB_BA(np, send_wdtr) ||
2724 dsp == SCRIPTB_BA(np, send_sdtr) ||
2725 dsp == SCRIPTB_BA(np, send_ppr)) {
2726 nxtdsp = SCRIPTB_BA(np, nego_bad_phase);
2727 if (dsp == SCRIPTB_BA(np, send_ppr)) {
2728 struct scsi_device *dev = cp->cmd->device;
2729 dev->ppr = 0;
2730 }
2731 }
2732 break;
2733 #if 0
2734 case 7: /* MSG IN phase */
2735 nxtdsp = SCRIPTA_BA(np, clrack);
2736 break;
2737 #endif
2738 }
2739
2740 if (nxtdsp) {
2741 OUTL_DSP(np, nxtdsp);
2742 return;
2743 }
2744
2745 reset_all:
2746 sym_start_reset(np);
2747 }
2748
2749 /*
2750 * chip interrupt handler
2751 *
2752 * In normal situations, interrupt conditions occur one at
2753 * a time. But when something bad happens on the SCSI BUS,
2754 * the chip may raise several interrupt flags before
2755 * stopping and interrupting the CPU. The additionnal
2756 * interrupt flags are stacked in some extra registers
2757 * after the SIP and/or DIP flag has been raised in the
2758 * ISTAT. After the CPU has read the interrupt condition
2759 * flag from SIST or DSTAT, the chip unstacks the other
2760 * interrupt flags and sets the corresponding bits in
2761 * SIST or DSTAT. Since the chip starts stacking once the
2762 * SIP or DIP flag is set, there is a small window of time
2763 * where the stacking does not occur.
2764 *
2765 * Typically, multiple interrupt conditions may happen in
2766 * the following situations:
2767 *
2768 * - SCSI parity error + Phase mismatch (PAR|MA)
2769 * When an parity error is detected in input phase
2770 * and the device switches to msg-in phase inside a
2771 * block MOV.
2772 * - SCSI parity error + Unexpected disconnect (PAR|UDC)
2773 * When a stupid device does not want to handle the
2774 * recovery of an SCSI parity error.
2775 * - Some combinations of STO, PAR, UDC, ...
2776 * When using non compliant SCSI stuff, when user is
2777 * doing non compliant hot tampering on the BUS, when
2778 * something really bad happens to a device, etc ...
2779 *
2780 * The heuristic suggested by SYMBIOS to handle
2781 * multiple interrupts is to try unstacking all
2782 * interrupts conditions and to handle them on some
2783 * priority based on error severity.
2784 * This will work when the unstacking has been
2785 * successful, but we cannot be 100 % sure of that,
2786 * since the CPU may have been faster to unstack than
2787 * the chip is able to stack. Hmmm ... But it seems that
2788 * such a situation is very unlikely to happen.
2789 *
2790 * If this happen, for example STO caught by the CPU
2791 * then UDC happenning before the CPU have restarted
2792 * the SCRIPTS, the driver may wrongly complete the
2793 * same command on UDC, since the SCRIPTS didn't restart
2794 * and the DSA still points to the same command.
2795 * We avoid this situation by setting the DSA to an
2796 * invalid value when the CCB is completed and before
2797 * restarting the SCRIPTS.
2798 *
2799 * Another issue is that we need some section of our
2800 * recovery procedures to be somehow uninterruptible but
2801 * the SCRIPTS processor does not provides such a
2802 * feature. For this reason, we handle recovery preferently
2803 * from the C code and check against some SCRIPTS critical
2804 * sections from the C code.
2805 *
2806 * Hopefully, the interrupt handling of the driver is now
2807 * able to resist to weird BUS error conditions, but donnot
2808 * ask me for any guarantee that it will never fail. :-)
2809 * Use at your own decision and risk.
2810 */
2811
2812 irqreturn_t sym_interrupt(struct Scsi_Host *shost)
2813 {
2814 struct sym_data *sym_data = shost_priv(shost);
2815 struct sym_hcb *np = sym_data->ncb;
2816 struct pci_dev *pdev = sym_data->pdev;
2817 u_char istat, istatc;
2818 u_char dstat;
2819 u_short sist;
2820
2821 /*
2822 * interrupt on the fly ?
2823 * (SCRIPTS may still be running)
2824 *
2825 * A `dummy read' is needed to ensure that the
2826 * clear of the INTF flag reaches the device
2827 * and that posted writes are flushed to memory
2828 * before the scanning of the DONE queue.
2829 * Note that SCRIPTS also (dummy) read to memory
2830 * prior to deliver the INTF interrupt condition.
2831 */
2832 istat = INB(np, nc_istat);
2833 if (istat & INTF) {
2834 OUTB(np, nc_istat, (istat & SIGP) | INTF | np->istat_sem);
2835 istat |= INB(np, nc_istat); /* DUMMY READ */
2836 if (DEBUG_FLAGS & DEBUG_TINY) printf ("F ");
2837 sym_wakeup_done(np);
2838 }
2839
2840 if (!(istat & (SIP|DIP)))
2841 return (istat & INTF) ? IRQ_HANDLED : IRQ_NONE;
2842
2843 #if 0 /* We should never get this one */
2844 if (istat & CABRT)
2845 OUTB(np, nc_istat, CABRT);
2846 #endif
2847
2848 /*
2849 * PAR and MA interrupts may occur at the same time,
2850 * and we need to know of both in order to handle
2851 * this situation properly. We try to unstack SCSI
2852 * interrupts for that reason. BTW, I dislike a LOT
2853 * such a loop inside the interrupt routine.
2854 * Even if DMA interrupt stacking is very unlikely to
2855 * happen, we also try unstacking these ones, since
2856 * this has no performance impact.
2857 */
2858 sist = 0;
2859 dstat = 0;
2860 istatc = istat;
2861 do {
2862 if (istatc & SIP)
2863 sist |= INW(np, nc_sist);
2864 if (istatc & DIP)
2865 dstat |= INB(np, nc_dstat);
2866 istatc = INB(np, nc_istat);
2867 istat |= istatc;
2868
2869 /* Prevent deadlock waiting on a condition that may
2870 * never clear. */
2871 if (unlikely(sist == 0xffff && dstat == 0xff)) {
2872 if (pci_channel_offline(pdev))
2873 return IRQ_NONE;
2874 }
2875 } while (istatc & (SIP|DIP));
2876
2877 if (DEBUG_FLAGS & DEBUG_TINY)
2878 printf ("<%d|%x:%x|%x:%x>",
2879 (int)INB(np, nc_scr0),
2880 dstat,sist,
2881 (unsigned)INL(np, nc_dsp),
2882 (unsigned)INL(np, nc_dbc));
2883 /*
2884 * On paper, a memory read barrier may be needed here to
2885 * prevent out of order LOADs by the CPU from having
2886 * prefetched stale data prior to DMA having occurred.
2887 * And since we are paranoid ... :)
2888 */
2889 MEMORY_READ_BARRIER();
2890
2891 /*
2892 * First, interrupts we want to service cleanly.
2893 *
2894 * Phase mismatch (MA) is the most frequent interrupt
2895 * for chip earlier than the 896 and so we have to service
2896 * it as quickly as possible.
2897 * A SCSI parity error (PAR) may be combined with a phase
2898 * mismatch condition (MA).
2899 * Programmed interrupts (SIR) are used to call the C code
2900 * from SCRIPTS.
2901 * The single step interrupt (SSI) is not used in this
2902 * driver.
2903 */
2904 if (!(sist & (STO|GEN|HTH|SGE|UDC|SBMC|RST)) &&
2905 !(dstat & (MDPE|BF|ABRT|IID))) {
2906 if (sist & PAR) sym_int_par (np, sist);
2907 else if (sist & MA) sym_int_ma (np);
2908 else if (dstat & SIR) sym_int_sir(np);
2909 else if (dstat & SSI) OUTONB_STD();
2910 else goto unknown_int;
2911 return IRQ_HANDLED;
2912 }
2913
2914 /*
2915 * Now, interrupts that donnot happen in normal
2916 * situations and that we may need to recover from.
2917 *
2918 * On SCSI RESET (RST), we reset everything.
2919 * On SCSI BUS MODE CHANGE (SBMC), we complete all
2920 * active CCBs with RESET status, prepare all devices
2921 * for negotiating again and restart the SCRIPTS.
2922 * On STO and UDC, we complete the CCB with the corres-
2923 * ponding status and restart the SCRIPTS.
2924 */
2925 if (sist & RST) {
2926 printf("%s: SCSI BUS reset detected.\n", sym_name(np));
2927 sym_start_up(shost, 1);
2928 return IRQ_HANDLED;
2929 }
2930
2931 OUTB(np, nc_ctest3, np->rv_ctest3 | CLF); /* clear dma fifo */
2932 OUTB(np, nc_stest3, TE|CSF); /* clear scsi fifo */
2933
2934 if (!(sist & (GEN|HTH|SGE)) &&
2935 !(dstat & (MDPE|BF|ABRT|IID))) {
2936 if (sist & SBMC) sym_int_sbmc(shost);
2937 else if (sist & STO) sym_int_sto (np);
2938 else if (sist & UDC) sym_int_udc (np);
2939 else goto unknown_int;
2940 return IRQ_HANDLED;
2941 }
2942
2943 /*
2944 * Now, interrupts we are not able to recover cleanly.
2945 *
2946 * Log message for hard errors.
2947 * Reset everything.
2948 */
2949
2950 sym_log_hard_error(shost, sist, dstat);
2951
2952 if ((sist & (GEN|HTH|SGE)) ||
2953 (dstat & (MDPE|BF|ABRT|IID))) {
2954 sym_start_reset(np);
2955 return IRQ_HANDLED;
2956 }
2957
2958 unknown_int:
2959 /*
2960 * We just miss the cause of the interrupt. :(
2961 * Print a message. The timeout will do the real work.
2962 */
2963 printf( "%s: unknown interrupt(s) ignored, "
2964 "ISTAT=0x%x DSTAT=0x%x SIST=0x%x\n",
2965 sym_name(np), istat, dstat, sist);
2966 return IRQ_NONE;
2967 }
2968
2969 /*
2970 * Dequeue from the START queue all CCBs that match
2971 * a given target/lun/task condition (-1 means all),
2972 * and move them from the BUSY queue to the COMP queue
2973 * with DID_SOFT_ERROR status condition.
2974 * This function is used during error handling/recovery.
2975 * It is called with SCRIPTS not running.
2976 */
2977 static int
2978 sym_dequeue_from_squeue(struct sym_hcb *np, int i, int target, int lun, int task)
2979 {
2980 int j;
2981 struct sym_ccb *cp;
2982
2983 /*
2984 * Make sure the starting index is within range.
2985 */
2986 assert((i >= 0) && (i < 2*MAX_QUEUE));
2987
2988 /*
2989 * Walk until end of START queue and dequeue every job
2990 * that matches the target/lun/task condition.
2991 */
2992 j = i;
2993 while (i != np->squeueput) {
2994 cp = sym_ccb_from_dsa(np, scr_to_cpu(np->squeue[i]));
2995 assert(cp);
2996 #ifdef SYM_CONF_IARB_SUPPORT
2997 /* Forget hints for IARB, they may be no longer relevant */
2998 cp->host_flags &= ~HF_HINT_IARB;
2999 #endif
3000 if ((target == -1 || cp->target == target) &&
3001 (lun == -1 || cp->lun == lun) &&
3002 (task == -1 || cp->tag == task)) {
3003 #ifdef SYM_OPT_HANDLE_DEVICE_QUEUEING
3004 sym_set_cam_status(cp->cmd, DID_SOFT_ERROR);
3005 #else
3006 sym_set_cam_status(cp->cmd, DID_REQUEUE);
3007 #endif
3008 sym_remque(&cp->link_ccbq);
3009 sym_insque_tail(&cp->link_ccbq, &np->comp_ccbq);
3010 }
3011 else {
3012 if (i != j)
3013 np->squeue[j] = np->squeue[i];
3014 if ((j += 2) >= MAX_QUEUE*2) j = 0;
3015 }
3016 if ((i += 2) >= MAX_QUEUE*2) i = 0;
3017 }
3018 if (i != j) /* Copy back the idle task if needed */
3019 np->squeue[j] = np->squeue[i];
3020 np->squeueput = j; /* Update our current start queue pointer */
3021
3022 return (i - j) / 2;
3023 }
3024
3025 /*
3026 * chip handler for bad SCSI status condition
3027 *
3028 * In case of bad SCSI status, we unqueue all the tasks
3029 * currently queued to the controller but not yet started
3030 * and then restart the SCRIPTS processor immediately.
3031 *
3032 * QUEUE FULL and BUSY conditions are handled the same way.
3033 * Basically all the not yet started tasks are requeued in
3034 * device queue and the queue is frozen until a completion.
3035 *
3036 * For CHECK CONDITION and COMMAND TERMINATED status, we use
3037 * the CCB of the failed command to prepare a REQUEST SENSE
3038 * SCSI command and queue it to the controller queue.
3039 *
3040 * SCRATCHA is assumed to have been loaded with STARTPOS
3041 * before the SCRIPTS called the C code.
3042 */
3043 static void sym_sir_bad_scsi_status(struct sym_hcb *np, int num, struct sym_ccb *cp)
3044 {
3045 u32 startp;
3046 u_char s_status = cp->ssss_status;
3047 u_char h_flags = cp->host_flags;
3048 int msglen;
3049 int i;
3050
3051 /*
3052 * Compute the index of the next job to start from SCRIPTS.
3053 */
3054 i = (INL(np, nc_scratcha) - np->squeue_ba) / 4;
3055
3056 /*
3057 * The last CCB queued used for IARB hint may be
3058 * no longer relevant. Forget it.
3059 */
3060 #ifdef SYM_CONF_IARB_SUPPORT
3061 if (np->last_cp)
3062 np->last_cp = 0;
3063 #endif
3064
3065 /*
3066 * Now deal with the SCSI status.
3067 */
3068 switch(s_status) {
3069 case S_BUSY:
3070 case S_QUEUE_FULL:
3071 if (sym_verbose >= 2) {
3072 sym_print_addr(cp->cmd, "%s\n",
3073 s_status == S_BUSY ? "BUSY" : "QUEUE FULL\n");
3074 }
3075 default: /* S_INT, S_INT_COND_MET, S_CONFLICT */
3076 sym_complete_error (np, cp);
3077 break;
3078 case S_TERMINATED:
3079 case S_CHECK_COND:
3080 /*
3081 * If we get an SCSI error when requesting sense, give up.
3082 */
3083 if (h_flags & HF_SENSE) {
3084 sym_complete_error (np, cp);
3085 break;
3086 }
3087
3088 /*
3089 * Dequeue all queued CCBs for that device not yet started,
3090 * and restart the SCRIPTS processor immediately.
3091 */
3092 sym_dequeue_from_squeue(np, i, cp->target, cp->lun, -1);
3093 OUTL_DSP(np, SCRIPTA_BA(np, start));
3094
3095 /*
3096 * Save some info of the actual IO.
3097 * Compute the data residual.
3098 */
3099 cp->sv_scsi_status = cp->ssss_status;
3100 cp->sv_xerr_status = cp->xerr_status;
3101 cp->sv_resid = sym_compute_residual(np, cp);
3102
3103 /*
3104 * Prepare all needed data structures for
3105 * requesting sense data.
3106 */
3107
3108 cp->scsi_smsg2[0] = IDENTIFY(0, cp->lun);
3109 msglen = 1;
3110
3111 /*
3112 * If we are currently using anything different from
3113 * async. 8 bit data transfers with that target,
3114 * start a negotiation, since the device may want
3115 * to report us a UNIT ATTENTION condition due to
3116 * a cause we currently ignore, and we donnot want
3117 * to be stuck with WIDE and/or SYNC data transfer.
3118 *
3119 * cp->nego_status is filled by sym_prepare_nego().
3120 */
3121 cp->nego_status = 0;
3122 msglen += sym_prepare_nego(np, cp, &cp->scsi_smsg2[msglen]);
3123 /*
3124 * Message table indirect structure.
3125 */
3126 cp->phys.smsg.addr = CCB_BA(cp, scsi_smsg2);
3127 cp->phys.smsg.size = cpu_to_scr(msglen);
3128
3129 /*
3130 * sense command
3131 */
3132 cp->phys.cmd.addr = CCB_BA(cp, sensecmd);
3133 cp->phys.cmd.size = cpu_to_scr(6);
3134
3135 /*
3136 * patch requested size into sense command
3137 */
3138 cp->sensecmd[0] = REQUEST_SENSE;
3139 cp->sensecmd[1] = 0;
3140 if (cp->cmd->device->scsi_level <= SCSI_2 && cp->lun <= 7)
3141 cp->sensecmd[1] = cp->lun << 5;
3142 cp->sensecmd[4] = SYM_SNS_BBUF_LEN;
3143 cp->data_len = SYM_SNS_BBUF_LEN;
3144
3145 /*
3146 * sense data
3147 */
3148 memset(cp->sns_bbuf, 0, SYM_SNS_BBUF_LEN);
3149 cp->phys.sense.addr = CCB_BA(cp, sns_bbuf);
3150 cp->phys.sense.size = cpu_to_scr(SYM_SNS_BBUF_LEN);
3151
3152 /*
3153 * requeue the command.
3154 */
3155 startp = SCRIPTB_BA(np, sdata_in);
3156
3157 cp->phys.head.savep = cpu_to_scr(startp);
3158 cp->phys.head.lastp = cpu_to_scr(startp);
3159 cp->startp = cpu_to_scr(startp);
3160 cp->goalp = cpu_to_scr(startp + 16);
3161
3162 cp->host_xflags = 0;
3163 cp->host_status = cp->nego_status ? HS_NEGOTIATE : HS_BUSY;
3164 cp->ssss_status = S_ILLEGAL;
3165 cp->host_flags = (HF_SENSE|HF_DATA_IN);
3166 cp->xerr_status = 0;
3167 cp->extra_bytes = 0;
3168
3169 cp->phys.head.go.start = cpu_to_scr(SCRIPTA_BA(np, select));
3170
3171 /*
3172 * Requeue the command.
3173 */
3174 sym_put_start_queue(np, cp);
3175
3176 /*
3177 * Give back to upper layer everything we have dequeued.
3178 */
3179 sym_flush_comp_queue(np, 0);
3180 break;
3181 }
3182 }
3183
3184 /*
3185 * After a device has accepted some management message
3186 * as BUS DEVICE RESET, ABORT TASK, etc ..., or when
3187 * a device signals a UNIT ATTENTION condition, some
3188 * tasks are thrown away by the device. We are required
3189 * to reflect that on our tasks list since the device
3190 * will never complete these tasks.
3191 *
3192 * This function move from the BUSY queue to the COMP
3193 * queue all disconnected CCBs for a given target that
3194 * match the following criteria:
3195 * - lun=-1 means any logical UNIT otherwise a given one.
3196 * - task=-1 means any task, otherwise a given one.
3197 */
3198 int sym_clear_tasks(struct sym_hcb *np, int cam_status, int target, int lun, int task)
3199 {
3200 SYM_QUEHEAD qtmp, *qp;
3201 int i = 0;
3202 struct sym_ccb *cp;
3203
3204 /*
3205 * Move the entire BUSY queue to our temporary queue.
3206 */
3207 sym_que_init(&qtmp);
3208 sym_que_splice(&np->busy_ccbq, &qtmp);
3209 sym_que_init(&np->busy_ccbq);
3210
3211 /*
3212 * Put all CCBs that matches our criteria into
3213 * the COMP queue and put back other ones into
3214 * the BUSY queue.
3215 */
3216 while ((qp = sym_remque_head(&qtmp)) != NULL) {
3217 struct scsi_cmnd *cmd;
3218 cp = sym_que_entry(qp, struct sym_ccb, link_ccbq);
3219 cmd = cp->cmd;
3220 if (cp->host_status != HS_DISCONNECT ||
3221 cp->target != target ||
3222 (lun != -1 && cp->lun != lun) ||
3223 (task != -1 &&
3224 (cp->tag != NO_TAG && cp->scsi_smsg[2] != task))) {
3225 sym_insque_tail(&cp->link_ccbq, &np->busy_ccbq);
3226 continue;
3227 }
3228 sym_insque_tail(&cp->link_ccbq, &np->comp_ccbq);
3229
3230 /* Preserve the software timeout condition */
3231 if (sym_get_cam_status(cmd) != DID_TIME_OUT)
3232 sym_set_cam_status(cmd, cam_status);
3233 ++i;
3234 #if 0
3235 printf("XXXX TASK @%p CLEARED\n", cp);
3236 #endif
3237 }
3238 return i;
3239 }
3240
3241 /*
3242 * chip handler for TASKS recovery
3243 *
3244 * We cannot safely abort a command, while the SCRIPTS
3245 * processor is running, since we just would be in race
3246 * with it.
3247 *
3248 * As long as we have tasks to abort, we keep the SEM
3249 * bit set in the ISTAT. When this bit is set, the
3250 * SCRIPTS processor interrupts (SIR_SCRIPT_STOPPED)
3251 * each time it enters the scheduler.
3252 *
3253 * If we have to reset a target, clear tasks of a unit,
3254 * or to perform the abort of a disconnected job, we
3255 * restart the SCRIPTS for selecting the target. Once
3256 * selected, the SCRIPTS interrupts (SIR_TARGET_SELECTED).
3257 * If it loses arbitration, the SCRIPTS will interrupt again
3258 * the next time it will enter its scheduler, and so on ...
3259 *
3260 * On SIR_TARGET_SELECTED, we scan for the more
3261 * appropriate thing to do:
3262 *
3263 * - If nothing, we just sent a M_ABORT message to the
3264 * target to get rid of the useless SCSI bus ownership.
3265 * According to the specs, no tasks shall be affected.
3266 * - If the target is to be reset, we send it a M_RESET
3267 * message.
3268 * - If a logical UNIT is to be cleared , we send the
3269 * IDENTIFY(lun) + M_ABORT.
3270 * - If an untagged task is to be aborted, we send the
3271 * IDENTIFY(lun) + M_ABORT.
3272 * - If a tagged task is to be aborted, we send the
3273 * IDENTIFY(lun) + task attributes + M_ABORT_TAG.
3274 *
3275 * Once our 'kiss of death' :) message has been accepted
3276 * by the target, the SCRIPTS interrupts again
3277 * (SIR_ABORT_SENT). On this interrupt, we complete
3278 * all the CCBs that should have been aborted by the
3279 * target according to our message.
3280 */
3281 static void sym_sir_task_recovery(struct sym_hcb *np, int num)
3282 {
3283 SYM_QUEHEAD *qp;
3284 struct sym_ccb *cp;
3285 struct sym_tcb *tp = NULL; /* gcc isn't quite smart enough yet */
3286 struct scsi_target *starget;
3287 int target=-1, lun=-1, task;
3288 int i, k;
3289
3290 switch(num) {
3291 /*
3292 * The SCRIPTS processor stopped before starting
3293 * the next command in order to allow us to perform
3294 * some task recovery.
3295 */
3296 case SIR_SCRIPT_STOPPED:
3297 /*
3298 * Do we have any target to reset or unit to clear ?
3299 */
3300 for (i = 0 ; i < SYM_CONF_MAX_TARGET ; i++) {
3301 tp = &np->target[i];
3302 if (tp->to_reset ||
3303 (tp->lun0p && tp->lun0p->to_clear)) {
3304 target = i;
3305 break;
3306 }
3307 if (!tp->lunmp)
3308 continue;
3309 for (k = 1 ; k < SYM_CONF_MAX_LUN ; k++) {
3310 if (tp->lunmp[k] && tp->lunmp[k]->to_clear) {
3311 target = i;
3312 break;
3313 }
3314 }
3315 if (target != -1)
3316 break;
3317 }
3318
3319 /*
3320 * If not, walk the busy queue for any
3321 * disconnected CCB to be aborted.
3322 */
3323 if (target == -1) {
3324 FOR_EACH_QUEUED_ELEMENT(&np->busy_ccbq, qp) {
3325 cp = sym_que_entry(qp,struct sym_ccb,link_ccbq);
3326 if (cp->host_status != HS_DISCONNECT)
3327 continue;
3328 if (cp->to_abort) {
3329 target = cp->target;
3330 break;
3331 }
3332 }
3333 }
3334
3335 /*
3336 * If some target is to be selected,
3337 * prepare and start the selection.
3338 */
3339 if (target != -1) {
3340 tp = &np->target[target];
3341 np->abrt_sel.sel_id = target;
3342 np->abrt_sel.sel_scntl3 = tp->head.wval;
3343 np->abrt_sel.sel_sxfer = tp->head.sval;
3344 OUTL(np, nc_dsa, np->hcb_ba);
3345 OUTL_DSP(np, SCRIPTB_BA(np, sel_for_abort));
3346 return;
3347 }
3348
3349 /*
3350 * Now look for a CCB to abort that haven't started yet.
3351 * Btw, the SCRIPTS processor is still stopped, so
3352 * we are not in race.
3353 */
3354 i = 0;
3355 cp = NULL;
3356 FOR_EACH_QUEUED_ELEMENT(&np->busy_ccbq, qp) {
3357 cp = sym_que_entry(qp, struct sym_ccb, link_ccbq);
3358 if (cp->host_status != HS_BUSY &&
3359 cp->host_status != HS_NEGOTIATE)
3360 continue;
3361 if (!cp->to_abort)
3362 continue;
3363 #ifdef SYM_CONF_IARB_SUPPORT
3364 /*
3365 * If we are using IMMEDIATE ARBITRATION, we donnot
3366 * want to cancel the last queued CCB, since the
3367 * SCRIPTS may have anticipated the selection.
3368 */
3369 if (cp == np->last_cp) {
3370 cp->to_abort = 0;
3371 continue;
3372 }
3373 #endif
3374 i = 1; /* Means we have found some */
3375 break;
3376 }
3377 if (!i) {
3378 /*
3379 * We are done, so we donnot need
3380 * to synchronize with the SCRIPTS anylonger.
3381 * Remove the SEM flag from the ISTAT.
3382 */
3383 np->istat_sem = 0;
3384 OUTB(np, nc_istat, SIGP);
3385 break;
3386 }
3387 /*
3388 * Compute index of next position in the start
3389 * queue the SCRIPTS intends to start and dequeue
3390 * all CCBs for that device that haven't been started.
3391 */
3392 i = (INL(np, nc_scratcha) - np->squeue_ba) / 4;
3393 i = sym_dequeue_from_squeue(np, i, cp->target, cp->lun, -1);
3394
3395 /*
3396 * Make sure at least our IO to abort has been dequeued.
3397 */
3398 #ifndef SYM_OPT_HANDLE_DEVICE_QUEUEING
3399 assert(i && sym_get_cam_status(cp->cmd) == DID_SOFT_ERROR);
3400 #else
3401 sym_remque(&cp->link_ccbq);
3402 sym_insque_tail(&cp->link_ccbq, &np->comp_ccbq);
3403 #endif
3404 /*
3405 * Keep track in cam status of the reason of the abort.
3406 */
3407 if (cp->to_abort == 2)
3408 sym_set_cam_status(cp->cmd, DID_TIME_OUT);
3409 else
3410 sym_set_cam_status(cp->cmd, DID_ABORT);
3411
3412 /*
3413 * Complete with error everything that we have dequeued.
3414 */
3415 sym_flush_comp_queue(np, 0);
3416 break;
3417 /*
3418 * The SCRIPTS processor has selected a target
3419 * we may have some manual recovery to perform for.
3420 */
3421 case SIR_TARGET_SELECTED:
3422 target = INB(np, nc_sdid) & 0xf;
3423 tp = &np->target[target];
3424
3425 np->abrt_tbl.addr = cpu_to_scr(vtobus(np->abrt_msg));
3426
3427 /*
3428 * If the target is to be reset, prepare a
3429 * M_RESET message and clear the to_reset flag
3430 * since we donnot expect this operation to fail.
3431 */
3432 if (tp->to_reset) {
3433 np->abrt_msg[0] = M_RESET;
3434 np->abrt_tbl.size = 1;
3435 tp->to_reset = 0;
3436 break;
3437 }
3438
3439 /*
3440 * Otherwise, look for some logical unit to be cleared.
3441 */
3442 if (tp->lun0p && tp->lun0p->to_clear)
3443 lun = 0;
3444 else if (tp->lunmp) {
3445 for (k = 1 ; k < SYM_CONF_MAX_LUN ; k++) {
3446 if (tp->lunmp[k] && tp->lunmp[k]->to_clear) {
3447 lun = k;
3448 break;
3449 }
3450 }
3451 }
3452
3453 /*
3454 * If a logical unit is to be cleared, prepare
3455 * an IDENTIFY(lun) + ABORT MESSAGE.
3456 */
3457 if (lun != -1) {
3458 struct sym_lcb *lp = sym_lp(tp, lun);
3459 lp->to_clear = 0; /* We don't expect to fail here */
3460 np->abrt_msg[0] = IDENTIFY(0, lun);
3461 np->abrt_msg[1] = M_ABORT;
3462 np->abrt_tbl.size = 2;
3463 break;
3464 }
3465
3466 /*
3467 * Otherwise, look for some disconnected job to
3468 * abort for this target.
3469 */
3470 i = 0;
3471 cp = NULL;
3472 FOR_EACH_QUEUED_ELEMENT(&np->busy_ccbq, qp) {
3473 cp = sym_que_entry(qp, struct sym_ccb, link_ccbq);
3474 if (cp->host_status != HS_DISCONNECT)
3475 continue;
3476 if (cp->target != target)
3477 continue;
3478 if (!cp->to_abort)
3479 continue;
3480 i = 1; /* Means we have some */
3481 break;
3482 }
3483
3484 /*
3485 * If we have none, probably since the device has
3486 * completed the command before we won abitration,
3487 * send a M_ABORT message without IDENTIFY.
3488 * According to the specs, the device must just
3489 * disconnect the BUS and not abort any task.
3490 */
3491 if (!i) {
3492 np->abrt_msg[0] = M_ABORT;
3493 np->abrt_tbl.size = 1;
3494 break;
3495 }
3496
3497 /*
3498 * We have some task to abort.
3499 * Set the IDENTIFY(lun)
3500 */
3501 np->abrt_msg[0] = IDENTIFY(0, cp->lun);
3502
3503 /*
3504 * If we want to abort an untagged command, we
3505 * will send a IDENTIFY + M_ABORT.
3506 * Otherwise (tagged command), we will send
3507 * a IDENTITFY + task attributes + ABORT TAG.
3508 */
3509 if (cp->tag == NO_TAG) {
3510 np->abrt_msg[1] = M_ABORT;
3511 np->abrt_tbl.size = 2;
3512 } else {
3513 np->abrt_msg[1] = cp->scsi_smsg[1];
3514 np->abrt_msg[2] = cp->scsi_smsg[2];
3515 np->abrt_msg[3] = M_ABORT_TAG;
3516 np->abrt_tbl.size = 4;
3517 }
3518 /*
3519 * Keep track of software timeout condition, since the
3520 * peripheral driver may not count retries on abort
3521 * conditions not due to timeout.
3522 */
3523 if (cp->to_abort == 2)
3524 sym_set_cam_status(cp->cmd, DID_TIME_OUT);
3525 cp->to_abort = 0; /* We donnot expect to fail here */
3526 break;
3527
3528 /*
3529 * The target has accepted our message and switched
3530 * to BUS FREE phase as we expected.
3531 */
3532 case SIR_ABORT_SENT:
3533 target = INB(np, nc_sdid) & 0xf;
3534 tp = &np->target[target];
3535 starget = tp->starget;
3536
3537 /*
3538 ** If we didn't abort anything, leave here.
3539 */
3540 if (np->abrt_msg[0] == M_ABORT)
3541 break;
3542
3543 /*
3544 * If we sent a M_RESET, then a hardware reset has
3545 * been performed by the target.
3546 * - Reset everything to async 8 bit
3547 * - Tell ourself to negotiate next time :-)
3548 * - Prepare to clear all disconnected CCBs for
3549 * this target from our task list (lun=task=-1)
3550 */
3551 lun = -1;
3552 task = -1;
3553 if (np->abrt_msg[0] == M_RESET) {
3554 tp->head.sval = 0;
3555 tp->head.wval = np->rv_scntl3;
3556 tp->head.uval = 0;
3557 spi_period(starget) = 0;
3558 spi_offset(starget) = 0;
3559 spi_width(starget) = 0;
3560 spi_iu(starget) = 0;
3561 spi_dt(starget) = 0;
3562 spi_qas(starget) = 0;
3563 tp->tgoal.check_nego = 1;
3564 tp->tgoal.renego = 0;
3565 }
3566
3567 /*
3568 * Otherwise, check for the LUN and TASK(s)
3569 * concerned by the cancelation.
3570 * If it is not ABORT_TAG then it is CLEAR_QUEUE
3571 * or an ABORT message :-)
3572 */
3573 else {
3574 lun = np->abrt_msg[0] & 0x3f;
3575 if (np->abrt_msg[1] == M_ABORT_TAG)
3576 task = np->abrt_msg[2];
3577 }
3578
3579 /*
3580 * Complete all the CCBs the device should have
3581 * aborted due to our 'kiss of death' message.
3582 */
3583 i = (INL(np, nc_scratcha) - np->squeue_ba) / 4;
3584 sym_dequeue_from_squeue(np, i, target, lun, -1);
3585 sym_clear_tasks(np, DID_ABORT, target, lun, task);
3586 sym_flush_comp_queue(np, 0);
3587
3588 /*
3589 * If we sent a BDR, make upper layer aware of that.
3590 */
3591 if (np->abrt_msg[0] == M_RESET)
3592 starget_printk(KERN_NOTICE, starget,
3593 "has been reset\n");
3594 break;
3595 }
3596
3597 /*
3598 * Print to the log the message we intend to send.
3599 */
3600 if (num == SIR_TARGET_SELECTED) {
3601 dev_info(&tp->starget->dev, "control msgout:");
3602 sym_printl_hex(np->abrt_msg, np->abrt_tbl.size);
3603 np->abrt_tbl.size = cpu_to_scr(np->abrt_tbl.size);
3604 }
3605
3606 /*
3607 * Let the SCRIPTS processor continue.
3608 */
3609 OUTONB_STD();
3610 }
3611
3612 /*
3613 * Gerard's alchemy:) that deals with with the data
3614 * pointer for both MDP and the residual calculation.
3615 *
3616 * I didn't want to bloat the code by more than 200
3617 * lines for the handling of both MDP and the residual.
3618 * This has been achieved by using a data pointer
3619 * representation consisting in an index in the data
3620 * array (dp_sg) and a negative offset (dp_ofs) that
3621 * have the following meaning:
3622 *
3623 * - dp_sg = SYM_CONF_MAX_SG
3624 * we are at the end of the data script.
3625 * - dp_sg < SYM_CONF_MAX_SG
3626 * dp_sg points to the next entry of the scatter array
3627 * we want to transfer.
3628 * - dp_ofs < 0
3629 * dp_ofs represents the residual of bytes of the
3630 * previous entry scatter entry we will send first.
3631 * - dp_ofs = 0
3632 * no residual to send first.
3633 *
3634 * The function sym_evaluate_dp() accepts an arbitray
3635 * offset (basically from the MDP message) and returns
3636 * the corresponding values of dp_sg and dp_ofs.
3637 */
3638
3639 static int sym_evaluate_dp(struct sym_hcb *np, struct sym_ccb *cp, u32 scr, int *ofs)
3640 {
3641 u32 dp_scr;
3642 int dp_ofs, dp_sg, dp_sgmin;
3643 int tmp;
3644 struct sym_pmc *pm;
3645
3646 /*
3647 * Compute the resulted data pointer in term of a script
3648 * address within some DATA script and a signed byte offset.
3649 */
3650 dp_scr = scr;
3651 dp_ofs = *ofs;
3652 if (dp_scr == SCRIPTA_BA(np, pm0_data))
3653 pm = &cp->phys.pm0;
3654 else if (dp_scr == SCRIPTA_BA(np, pm1_data))
3655 pm = &cp->phys.pm1;
3656 else
3657 pm = NULL;
3658
3659 if (pm) {
3660 dp_scr = scr_to_cpu(pm->ret);
3661 dp_ofs -= scr_to_cpu(pm->sg.size) & 0x00ffffff;
3662 }
3663
3664 /*
3665 * If we are auto-sensing, then we are done.
3666 */
3667 if (cp->host_flags & HF_SENSE) {
3668 *ofs = dp_ofs;
3669 return 0;
3670 }
3671
3672 /*
3673 * Deduce the index of the sg entry.
3674 * Keep track of the index of the first valid entry.
3675 * If result is dp_sg = SYM_CONF_MAX_SG, then we are at the
3676 * end of the data.
3677 */
3678 tmp = scr_to_cpu(cp->goalp);
3679 dp_sg = SYM_CONF_MAX_SG;
3680 if (dp_scr != tmp)
3681 dp_sg -= (tmp - 8 - (int)dp_scr) / (2*4);
3682 dp_sgmin = SYM_CONF_MAX_SG - cp->segments;
3683
3684 /*
3685 * Move to the sg entry the data pointer belongs to.
3686 *
3687 * If we are inside the data area, we expect result to be:
3688 *
3689 * Either,
3690 * dp_ofs = 0 and dp_sg is the index of the sg entry
3691 * the data pointer belongs to (or the end of the data)
3692 * Or,
3693 * dp_ofs < 0 and dp_sg is the index of the sg entry
3694 * the data pointer belongs to + 1.
3695 */
3696 if (dp_ofs < 0) {
3697 int n;
3698 while (dp_sg > dp_sgmin) {
3699 --dp_sg;
3700 tmp = scr_to_cpu(cp->phys.data[dp_sg].size);
3701 n = dp_ofs + (tmp & 0xffffff);
3702 if (n > 0) {
3703 ++dp_sg;
3704 break;
3705 }
3706 dp_ofs = n;
3707 }
3708 }
3709 else if (dp_ofs > 0) {
3710 while (dp_sg < SYM_CONF_MAX_SG) {
3711 tmp = scr_to_cpu(cp->phys.data[dp_sg].size);
3712 dp_ofs -= (tmp & 0xffffff);
3713 ++dp_sg;
3714 if (dp_ofs <= 0)
3715 break;
3716 }
3717 }
3718
3719 /*
3720 * Make sure the data pointer is inside the data area.
3721 * If not, return some error.
3722 */
3723 if (dp_sg < dp_sgmin || (dp_sg == dp_sgmin && dp_ofs < 0))
3724 goto out_err;
3725 else if (dp_sg > SYM_CONF_MAX_SG ||
3726 (dp_sg == SYM_CONF_MAX_SG && dp_ofs > 0))
3727 goto out_err;
3728
3729 /*
3730 * Save the extreme pointer if needed.
3731 */
3732 if (dp_sg > cp->ext_sg ||
3733 (dp_sg == cp->ext_sg && dp_ofs > cp->ext_ofs)) {
3734 cp->ext_sg = dp_sg;
3735 cp->ext_ofs = dp_ofs;
3736 }
3737
3738 /*
3739 * Return data.
3740 */
3741 *ofs = dp_ofs;
3742 return dp_sg;
3743
3744 out_err:
3745 return -1;
3746 }
3747
3748 /*
3749 * chip handler for MODIFY DATA POINTER MESSAGE
3750 *
3751 * We also call this function on IGNORE WIDE RESIDUE
3752 * messages that do not match a SWIDE full condition.
3753 * Btw, we assume in that situation that such a message
3754 * is equivalent to a MODIFY DATA POINTER (offset=-1).
3755 */
3756
3757 static void sym_modify_dp(struct sym_hcb *np, struct sym_tcb *tp, struct sym_ccb *cp, int ofs)
3758 {
3759 int dp_ofs = ofs;
3760 u32 dp_scr = sym_get_script_dp (np, cp);
3761 u32 dp_ret;
3762 u32 tmp;
3763 u_char hflags;
3764 int dp_sg;
3765 struct sym_pmc *pm;
3766
3767 /*
3768 * Not supported for auto-sense.
3769 */
3770 if (cp->host_flags & HF_SENSE)
3771 goto out_reject;
3772
3773 /*
3774 * Apply our alchemy:) (see comments in sym_evaluate_dp()),
3775 * to the resulted data pointer.
3776 */
3777 dp_sg = sym_evaluate_dp(np, cp, dp_scr, &dp_ofs);
3778 if (dp_sg < 0)
3779 goto out_reject;
3780
3781 /*
3782 * And our alchemy:) allows to easily calculate the data
3783 * script address we want to return for the next data phase.
3784 */
3785 dp_ret = cpu_to_scr(cp->goalp);
3786 dp_ret = dp_ret - 8 - (SYM_CONF_MAX_SG - dp_sg) * (2*4);
3787
3788 /*
3789 * If offset / scatter entry is zero we donnot need
3790 * a context for the new current data pointer.
3791 */
3792 if (dp_ofs == 0) {
3793 dp_scr = dp_ret;
3794 goto out_ok;
3795 }
3796
3797 /*
3798 * Get a context for the new current data pointer.
3799 */
3800 hflags = INB(np, HF_PRT);
3801
3802 if (hflags & HF_DP_SAVED)
3803 hflags ^= HF_ACT_PM;
3804
3805 if (!(hflags & HF_ACT_PM)) {
3806 pm = &cp->phys.pm0;
3807 dp_scr = SCRIPTA_BA(np, pm0_data);
3808 }
3809 else {
3810 pm = &cp->phys.pm1;
3811 dp_scr = SCRIPTA_BA(np, pm1_data);
3812 }
3813
3814 hflags &= ~(HF_DP_SAVED);
3815
3816 OUTB(np, HF_PRT, hflags);
3817
3818 /*
3819 * Set up the new current data pointer.
3820 * ofs < 0 there, and for the next data phase, we
3821 * want to transfer part of the data of the sg entry
3822 * corresponding to index dp_sg-1 prior to returning
3823 * to the main data script.
3824 */
3825 pm->ret = cpu_to_scr(dp_ret);
3826 tmp = scr_to_cpu(cp->phys.data[dp_sg-1].addr);
3827 tmp += scr_to_cpu(cp->phys.data[dp_sg-1].size) + dp_ofs;
3828 pm->sg.addr = cpu_to_scr(tmp);
3829 pm->sg.size = cpu_to_scr(-dp_ofs);
3830
3831 out_ok:
3832 sym_set_script_dp (np, cp, dp_scr);
3833 OUTL_DSP(np, SCRIPTA_BA(np, clrack));
3834 return;
3835
3836 out_reject:
3837 OUTL_DSP(np, SCRIPTB_BA(np, msg_bad));
3838 }
3839
3840
3841 /*
3842 * chip calculation of the data residual.
3843 *
3844 * As I used to say, the requirement of data residual
3845 * in SCSI is broken, useless and cannot be achieved
3846 * without huge complexity.
3847 * But most OSes and even the official CAM require it.
3848 * When stupidity happens to be so widely spread inside
3849 * a community, it gets hard to convince.
3850 *
3851 * Anyway, I don't care, since I am not going to use
3852 * any software that considers this data residual as
3853 * a relevant information. :)
3854 */
3855
3856 int sym_compute_residual(struct sym_hcb *np, struct sym_ccb *cp)
3857 {
3858 int dp_sg, dp_sgmin, resid = 0;
3859 int dp_ofs = 0;
3860
3861 /*
3862 * Check for some data lost or just thrown away.
3863 * We are not required to be quite accurate in this
3864 * situation. Btw, if we are odd for output and the
3865 * device claims some more data, it may well happen
3866 * than our residual be zero. :-)
3867 */
3868 if (cp->xerr_status & (XE_EXTRA_DATA|XE_SODL_UNRUN|XE_SWIDE_OVRUN)) {
3869 if (cp->xerr_status & XE_EXTRA_DATA)
3870 resid -= cp->extra_bytes;
3871 if (cp->xerr_status & XE_SODL_UNRUN)
3872 ++resid;
3873 if (cp->xerr_status & XE_SWIDE_OVRUN)
3874 --resid;
3875 }
3876
3877 /*
3878 * If all data has been transferred,
3879 * there is no residual.
3880 */
3881 if (cp->phys.head.lastp == cp->goalp)
3882 return resid;
3883
3884 /*
3885 * If no data transfer occurs, or if the data
3886 * pointer is weird, return full residual.
3887 */
3888 if (cp->startp == cp->phys.head.lastp ||
3889 sym_evaluate_dp(np, cp, scr_to_cpu(cp->phys.head.lastp),
3890 &dp_ofs) < 0) {
3891 return cp->data_len - cp->odd_byte_adjustment;
3892 }
3893
3894 /*
3895 * If we were auto-sensing, then we are done.
3896 */
3897 if (cp->host_flags & HF_SENSE) {
3898 return -dp_ofs;
3899 }
3900
3901 /*
3902 * We are now full comfortable in the computation
3903 * of the data residual (2's complement).
3904 */
3905 dp_sgmin = SYM_CONF_MAX_SG - cp->segments;
3906 resid = -cp->ext_ofs;
3907 for (dp_sg = cp->ext_sg; dp_sg < SYM_CONF_MAX_SG; ++dp_sg) {
3908 u_int tmp = scr_to_cpu(cp->phys.data[dp_sg].size);
3909 resid += (tmp & 0xffffff);
3910 }
3911
3912 resid -= cp->odd_byte_adjustment;
3913
3914 /*
3915 * Hopefully, the result is not too wrong.
3916 */
3917 return resid;
3918 }
3919
3920 /*
3921 * Negotiation for WIDE and SYNCHRONOUS DATA TRANSFER.
3922 *
3923 * When we try to negotiate, we append the negotiation message
3924 * to the identify and (maybe) simple tag message.
3925 * The host status field is set to HS_NEGOTIATE to mark this
3926 * situation.
3927 *
3928 * If the target doesn't answer this message immediately
3929 * (as required by the standard), the SIR_NEGO_FAILED interrupt
3930 * will be raised eventually.
3931 * The handler removes the HS_NEGOTIATE status, and sets the
3932 * negotiated value to the default (async / nowide).
3933 *
3934 * If we receive a matching answer immediately, we check it
3935 * for validity, and set the values.
3936 *
3937 * If we receive a Reject message immediately, we assume the
3938 * negotiation has failed, and fall back to standard values.
3939 *
3940 * If we receive a negotiation message while not in HS_NEGOTIATE
3941 * state, it's a target initiated negotiation. We prepare a
3942 * (hopefully) valid answer, set our parameters, and send back
3943 * this answer to the target.
3944 *
3945 * If the target doesn't fetch the answer (no message out phase),
3946 * we assume the negotiation has failed, and fall back to default
3947 * settings (SIR_NEGO_PROTO interrupt).
3948 *
3949 * When we set the values, we adjust them in all ccbs belonging
3950 * to this target, in the controller's register, and in the "phys"
3951 * field of the controller's struct sym_hcb.
3952 */
3953
3954 /*
3955 * chip handler for SYNCHRONOUS DATA TRANSFER REQUEST (SDTR) message.
3956 */
3957 static int
3958 sym_sync_nego_check(struct sym_hcb *np, int req, struct sym_ccb *cp)
3959 {
3960 int target = cp->target;
3961 u_char chg, ofs, per, fak, div;
3962
3963 if (DEBUG_FLAGS & DEBUG_NEGO) {
3964 sym_print_nego_msg(np, target, "sync msgin", np->msgin);
3965 }
3966
3967 /*
3968 * Get requested values.
3969 */
3970 chg = 0;
3971 per = np->msgin[3];
3972 ofs = np->msgin[4];
3973
3974 /*
3975 * Check values against our limits.
3976 */
3977 if (ofs) {
3978 if (ofs > np->maxoffs)
3979 {chg = 1; ofs = np->maxoffs;}
3980 }
3981
3982 if (ofs) {
3983 if (per < np->minsync)
3984 {chg = 1; per = np->minsync;}
3985 }
3986
3987 /*
3988 * Get new chip synchronous parameters value.
3989 */
3990 div = fak = 0;
3991 if (ofs && sym_getsync(np, 0, per, &div, &fak) < 0)
3992 goto reject_it;
3993
3994 if (DEBUG_FLAGS & DEBUG_NEGO) {
3995 sym_print_addr(cp->cmd,
3996 "sdtr: ofs=%d per=%d div=%d fak=%d chg=%d.\n",
3997 ofs, per, div, fak, chg);
3998 }
3999
4000 /*
4001 * If it was an answer we want to change,
4002 * then it isn't acceptable. Reject it.
4003 */
4004 if (!req && chg)
4005 goto reject_it;
4006
4007 /*
4008 * Apply new values.
4009 */
4010 sym_setsync (np, target, ofs, per, div, fak);
4011
4012 /*
4013 * It was an answer. We are done.
4014 */
4015 if (!req)
4016 return 0;
4017
4018 /*
4019 * It was a request. Prepare an answer message.
4020 */
4021 spi_populate_sync_msg(np->msgout, per, ofs);
4022
4023 if (DEBUG_FLAGS & DEBUG_NEGO) {
4024 sym_print_nego_msg(np, target, "sync msgout", np->msgout);
4025 }
4026
4027 np->msgin [0] = M_NOOP;
4028
4029 return 0;
4030
4031 reject_it:
4032 sym_setsync (np, target, 0, 0, 0, 0);
4033 return -1;
4034 }
4035
4036 static void sym_sync_nego(struct sym_hcb *np, struct sym_tcb *tp, struct sym_ccb *cp)
4037 {
4038 int req = 1;
4039 int result;
4040
4041 /*
4042 * Request or answer ?
4043 */
4044 if (INB(np, HS_PRT) == HS_NEGOTIATE) {
4045 OUTB(np, HS_PRT, HS_BUSY);
4046 if (cp->nego_status && cp->nego_status != NS_SYNC)
4047 goto reject_it;
4048 req = 0;
4049 }
4050
4051 /*
4052 * Check and apply new values.
4053 */
4054 result = sym_sync_nego_check(np, req, cp);
4055 if (result) /* Not acceptable, reject it */
4056 goto reject_it;
4057 if (req) { /* Was a request, send response. */
4058 cp->nego_status = NS_SYNC;
4059 OUTL_DSP(np, SCRIPTB_BA(np, sdtr_resp));
4060 }
4061 else /* Was a response, we are done. */
4062 OUTL_DSP(np, SCRIPTA_BA(np, clrack));
4063 return;
4064
4065 reject_it:
4066 OUTL_DSP(np, SCRIPTB_BA(np, msg_bad));
4067 }
4068
4069 /*
4070 * chip handler for PARALLEL PROTOCOL REQUEST (PPR) message.
4071 */
4072 static int
4073 sym_ppr_nego_check(struct sym_hcb *np, int req, int target)
4074 {
4075 struct sym_tcb *tp = &np->target[target];
4076 unsigned char fak, div;
4077 int dt, chg = 0;
4078
4079 unsigned char per = np->msgin[3];
4080 unsigned char ofs = np->msgin[5];
4081 unsigned char wide = np->msgin[6];
4082 unsigned char opts = np->msgin[7] & PPR_OPT_MASK;
4083
4084 if (DEBUG_FLAGS & DEBUG_NEGO) {
4085 sym_print_nego_msg(np, target, "ppr msgin", np->msgin);
4086 }
4087
4088 /*
4089 * Check values against our limits.
4090 */
4091 if (wide > np->maxwide) {
4092 chg = 1;
4093 wide = np->maxwide;
4094 }
4095 if (!wide || !(np->features & FE_U3EN))
4096 opts = 0;
4097
4098 if (opts != (np->msgin[7] & PPR_OPT_MASK))
4099 chg = 1;
4100
4101 dt = opts & PPR_OPT_DT;
4102
4103 if (ofs) {
4104 unsigned char maxoffs = dt ? np->maxoffs_dt : np->maxoffs;
4105 if (ofs > maxoffs) {
4106 chg = 1;
4107 ofs = maxoffs;
4108 }
4109 }
4110
4111 if (ofs) {
4112 unsigned char minsync = dt ? np->minsync_dt : np->minsync;
4113 if (per < minsync) {
4114 chg = 1;
4115 per = minsync;
4116 }
4117 }
4118
4119 /*
4120 * Get new chip synchronous parameters value.
4121 */
4122 div = fak = 0;
4123 if (ofs && sym_getsync(np, dt, per, &div, &fak) < 0)
4124 goto reject_it;
4125
4126 /*
4127 * If it was an answer we want to change,
4128 * then it isn't acceptable. Reject it.
4129 */
4130 if (!req && chg)
4131 goto reject_it;
4132
4133 /*
4134 * Apply new values.
4135 */
4136 sym_setpprot(np, target, opts, ofs, per, wide, div, fak);
4137
4138 /*
4139 * It was an answer. We are done.
4140 */
4141 if (!req)
4142 return 0;
4143
4144 /*
4145 * It was a request. Prepare an answer message.
4146 */
4147 spi_populate_ppr_msg(np->msgout, per, ofs, wide, opts);
4148
4149 if (DEBUG_FLAGS & DEBUG_NEGO) {
4150 sym_print_nego_msg(np, target, "ppr msgout", np->msgout);
4151 }
4152
4153 np->msgin [0] = M_NOOP;
4154
4155 return 0;
4156
4157 reject_it:
4158 sym_setpprot (np, target, 0, 0, 0, 0, 0, 0);
4159 /*
4160 * If it is a device response that should result in
4161 * ST, we may want to try a legacy negotiation later.
4162 */
4163 if (!req && !opts) {
4164 tp->tgoal.period = per;
4165 tp->tgoal.offset = ofs;
4166 tp->tgoal.width = wide;
4167 tp->tgoal.iu = tp->tgoal.dt = tp->tgoal.qas = 0;
4168 tp->tgoal.check_nego = 1;
4169 }
4170 return -1;
4171 }
4172
4173 static void sym_ppr_nego(struct sym_hcb *np, struct sym_tcb *tp, struct sym_ccb *cp)
4174 {
4175 int req = 1;
4176 int result;
4177
4178 /*
4179 * Request or answer ?
4180 */
4181 if (INB(np, HS_PRT) == HS_NEGOTIATE) {
4182 OUTB(np, HS_PRT, HS_BUSY);
4183 if (cp->nego_status && cp->nego_status != NS_PPR)
4184 goto reject_it;
4185 req = 0;
4186 }
4187
4188 /*
4189 * Check and apply new values.
4190 */
4191 result = sym_ppr_nego_check(np, req, cp->target);
4192 if (result) /* Not acceptable, reject it */
4193 goto reject_it;
4194 if (req) { /* Was a request, send response. */
4195 cp->nego_status = NS_PPR;
4196 OUTL_DSP(np, SCRIPTB_BA(np, ppr_resp));
4197 }
4198 else /* Was a response, we are done. */
4199 OUTL_DSP(np, SCRIPTA_BA(np, clrack));
4200 return;
4201
4202 reject_it:
4203 OUTL_DSP(np, SCRIPTB_BA(np, msg_bad));
4204 }
4205
4206 /*
4207 * chip handler for WIDE DATA TRANSFER REQUEST (WDTR) message.
4208 */
4209 static int
4210 sym_wide_nego_check(struct sym_hcb *np, int req, struct sym_ccb *cp)
4211 {
4212 int target = cp->target;
4213 u_char chg, wide;
4214
4215 if (DEBUG_FLAGS & DEBUG_NEGO) {
4216 sym_print_nego_msg(np, target, "wide msgin", np->msgin);
4217 }
4218
4219 /*
4220 * Get requested values.
4221 */
4222 chg = 0;
4223 wide = np->msgin[3];
4224
4225 /*
4226 * Check values against our limits.
4227 */
4228 if (wide > np->maxwide) {
4229 chg = 1;
4230 wide = np->maxwide;
4231 }
4232
4233 if (DEBUG_FLAGS & DEBUG_NEGO) {
4234 sym_print_addr(cp->cmd, "wdtr: wide=%d chg=%d.\n",
4235 wide, chg);
4236 }
4237
4238 /*
4239 * If it was an answer we want to change,
4240 * then it isn't acceptable. Reject it.
4241 */
4242 if (!req && chg)
4243 goto reject_it;
4244
4245 /*
4246 * Apply new values.
4247 */
4248 sym_setwide (np, target, wide);
4249
4250 /*
4251 * It was an answer. We are done.
4252 */
4253 if (!req)
4254 return 0;
4255
4256 /*
4257 * It was a request. Prepare an answer message.
4258 */
4259 spi_populate_width_msg(np->msgout, wide);
4260
4261 np->msgin [0] = M_NOOP;
4262
4263 if (DEBUG_FLAGS & DEBUG_NEGO) {
4264 sym_print_nego_msg(np, target, "wide msgout", np->msgout);
4265 }
4266
4267 return 0;
4268
4269 reject_it:
4270 return -1;
4271 }
4272
4273 static void sym_wide_nego(struct sym_hcb *np, struct sym_tcb *tp, struct sym_ccb *cp)
4274 {
4275 int req = 1;
4276 int result;
4277
4278 /*
4279 * Request or answer ?
4280 */
4281 if (INB(np, HS_PRT) == HS_NEGOTIATE) {
4282 OUTB(np, HS_PRT, HS_BUSY);
4283 if (cp->nego_status && cp->nego_status != NS_WIDE)
4284 goto reject_it;
4285 req = 0;
4286 }
4287
4288 /*
4289 * Check and apply new values.
4290 */
4291 result = sym_wide_nego_check(np, req, cp);
4292 if (result) /* Not acceptable, reject it */
4293 goto reject_it;
4294 if (req) { /* Was a request, send response. */
4295 cp->nego_status = NS_WIDE;
4296 OUTL_DSP(np, SCRIPTB_BA(np, wdtr_resp));
4297 } else { /* Was a response. */
4298 /*
4299 * Negotiate for SYNC immediately after WIDE response.
4300 * This allows to negotiate for both WIDE and SYNC on
4301 * a single SCSI command (Suggested by Justin Gibbs).
4302 */
4303 if (tp->tgoal.offset) {
4304 spi_populate_sync_msg(np->msgout, tp->tgoal.period,
4305 tp->tgoal.offset);
4306
4307 if (DEBUG_FLAGS & DEBUG_NEGO) {
4308 sym_print_nego_msg(np, cp->target,
4309 "sync msgout", np->msgout);
4310 }
4311
4312 cp->nego_status = NS_SYNC;
4313 OUTB(np, HS_PRT, HS_NEGOTIATE);
4314 OUTL_DSP(np, SCRIPTB_BA(np, sdtr_resp));
4315 return;
4316 } else
4317 OUTL_DSP(np, SCRIPTA_BA(np, clrack));
4318 }
4319
4320 return;
4321
4322 reject_it:
4323 OUTL_DSP(np, SCRIPTB_BA(np, msg_bad));
4324 }
4325
4326 /*
4327 * Reset DT, SYNC or WIDE to default settings.
4328 *
4329 * Called when a negotiation does not succeed either
4330 * on rejection or on protocol error.
4331 *
4332 * A target that understands a PPR message should never
4333 * reject it, and messing with it is very unlikely.
4334 * So, if a PPR makes problems, we may just want to
4335 * try a legacy negotiation later.
4336 */
4337 static void sym_nego_default(struct sym_hcb *np, struct sym_tcb *tp, struct sym_ccb *cp)
4338 {
4339 switch (cp->nego_status) {
4340 case NS_PPR:
4341 #if 0
4342 sym_setpprot (np, cp->target, 0, 0, 0, 0, 0, 0);
4343 #else
4344 if (tp->tgoal.period < np->minsync)
4345 tp->tgoal.period = np->minsync;
4346 if (tp->tgoal.offset > np->maxoffs)
4347 tp->tgoal.offset = np->maxoffs;
4348 tp->tgoal.iu = tp->tgoal.dt = tp->tgoal.qas = 0;
4349 tp->tgoal.check_nego = 1;
4350 #endif
4351 break;
4352 case NS_SYNC:
4353 sym_setsync (np, cp->target, 0, 0, 0, 0);
4354 break;
4355 case NS_WIDE:
4356 sym_setwide (np, cp->target, 0);
4357 break;
4358 }
4359 np->msgin [0] = M_NOOP;
4360 np->msgout[0] = M_NOOP;
4361 cp->nego_status = 0;
4362 }
4363
4364 /*
4365 * chip handler for MESSAGE REJECT received in response to
4366 * PPR, WIDE or SYNCHRONOUS negotiation.
4367 */
4368 static void sym_nego_rejected(struct sym_hcb *np, struct sym_tcb *tp, struct sym_ccb *cp)
4369 {
4370 sym_nego_default(np, tp, cp);
4371 OUTB(np, HS_PRT, HS_BUSY);
4372 }
4373
4374 /*
4375 * chip exception handler for programmed interrupts.
4376 */
4377 static void sym_int_sir(struct sym_hcb *np)
4378 {
4379 u_char num = INB(np, nc_dsps);
4380 u32 dsa = INL(np, nc_dsa);
4381 struct sym_ccb *cp = sym_ccb_from_dsa(np, dsa);
4382 u_char target = INB(np, nc_sdid) & 0x0f;
4383 struct sym_tcb *tp = &np->target[target];
4384 int tmp;
4385
4386 if (DEBUG_FLAGS & DEBUG_TINY) printf ("I#%d", num);
4387
4388 switch (num) {
4389 #if SYM_CONF_DMA_ADDRESSING_MODE == 2
4390 /*
4391 * SCRIPTS tell us that we may have to update
4392 * 64 bit DMA segment registers.
4393 */
4394 case SIR_DMAP_DIRTY:
4395 sym_update_dmap_regs(np);
4396 goto out;
4397 #endif
4398 /*
4399 * Command has been completed with error condition
4400 * or has been auto-sensed.
4401 */
4402 case SIR_COMPLETE_ERROR:
4403 sym_complete_error(np, cp);
4404 return;
4405 /*
4406 * The C code is currently trying to recover from something.
4407 * Typically, user want to abort some command.
4408 */
4409 case SIR_SCRIPT_STOPPED:
4410 case SIR_TARGET_SELECTED:
4411 case SIR_ABORT_SENT:
4412 sym_sir_task_recovery(np, num);
4413 return;
4414 /*
4415 * The device didn't go to MSG OUT phase after having
4416 * been selected with ATN. We do not want to handle that.
4417 */
4418 case SIR_SEL_ATN_NO_MSG_OUT:
4419 scmd_printk(KERN_WARNING, cp->cmd,
4420 "No MSG OUT phase after selection with ATN\n");
4421 goto out_stuck;
4422 /*
4423 * The device didn't switch to MSG IN phase after
4424 * having reselected the initiator.
4425 */
4426 case SIR_RESEL_NO_MSG_IN:
4427 scmd_printk(KERN_WARNING, cp->cmd,
4428 "No MSG IN phase after reselection\n");
4429 goto out_stuck;
4430 /*
4431 * After reselection, the device sent a message that wasn't
4432 * an IDENTIFY.
4433 */
4434 case SIR_RESEL_NO_IDENTIFY:
4435 scmd_printk(KERN_WARNING, cp->cmd,
4436 "No IDENTIFY after reselection\n");
4437 goto out_stuck;
4438 /*
4439 * The device reselected a LUN we do not know about.
4440 */
4441 case SIR_RESEL_BAD_LUN:
4442 np->msgout[0] = M_RESET;
4443 goto out;
4444 /*
4445 * The device reselected for an untagged nexus and we
4446 * haven't any.
4447 */
4448 case SIR_RESEL_BAD_I_T_L:
4449 np->msgout[0] = M_ABORT;
4450 goto out;
4451 /*
4452 * The device reselected for a tagged nexus that we do not have.
4453 */
4454 case SIR_RESEL_BAD_I_T_L_Q:
4455 np->msgout[0] = M_ABORT_TAG;
4456 goto out;
4457 /*
4458 * The SCRIPTS let us know that the device has grabbed
4459 * our message and will abort the job.
4460 */
4461 case SIR_RESEL_ABORTED:
4462 np->lastmsg = np->msgout[0];
4463 np->msgout[0] = M_NOOP;
4464 scmd_printk(KERN_WARNING, cp->cmd,
4465 "message %x sent on bad reselection\n", np->lastmsg);
4466 goto out;
4467 /*
4468 * The SCRIPTS let us know that a message has been
4469 * successfully sent to the device.
4470 */
4471 case SIR_MSG_OUT_DONE:
4472 np->lastmsg = np->msgout[0];
4473 np->msgout[0] = M_NOOP;
4474 /* Should we really care of that */
4475 if (np->lastmsg == M_PARITY || np->lastmsg == M_ID_ERROR) {
4476 if (cp) {
4477 cp->xerr_status &= ~XE_PARITY_ERR;
4478 if (!cp->xerr_status)
4479 OUTOFFB(np, HF_PRT, HF_EXT_ERR);
4480 }
4481 }
4482 goto out;
4483 /*
4484 * The device didn't send a GOOD SCSI status.
4485 * We may have some work to do prior to allow
4486 * the SCRIPTS processor to continue.
4487 */
4488 case SIR_BAD_SCSI_STATUS:
4489 if (!cp)
4490 goto out;
4491 sym_sir_bad_scsi_status(np, num, cp);
4492 return;
4493 /*
4494 * We are asked by the SCRIPTS to prepare a
4495 * REJECT message.
4496 */
4497 case SIR_REJECT_TO_SEND:
4498 sym_print_msg(cp, "M_REJECT to send for ", np->msgin);
4499 np->msgout[0] = M_REJECT;
4500 goto out;
4501 /*
4502 * We have been ODD at the end of a DATA IN
4503 * transfer and the device didn't send a
4504 * IGNORE WIDE RESIDUE message.
4505 * It is a data overrun condition.
4506 */
4507 case SIR_SWIDE_OVERRUN:
4508 if (cp) {
4509 OUTONB(np, HF_PRT, HF_EXT_ERR);
4510 cp->xerr_status |= XE_SWIDE_OVRUN;
4511 }
4512 goto out;
4513 /*
4514 * We have been ODD at the end of a DATA OUT
4515 * transfer.
4516 * It is a data underrun condition.
4517 */
4518 case SIR_SODL_UNDERRUN:
4519 if (cp) {
4520 OUTONB(np, HF_PRT, HF_EXT_ERR);
4521 cp->xerr_status |= XE_SODL_UNRUN;
4522 }
4523 goto out;
4524 /*
4525 * The device wants us to tranfer more data than
4526 * expected or in the wrong direction.
4527 * The number of extra bytes is in scratcha.
4528 * It is a data overrun condition.
4529 */
4530 case SIR_DATA_OVERRUN:
4531 if (cp) {
4532 OUTONB(np, HF_PRT, HF_EXT_ERR);
4533 cp->xerr_status |= XE_EXTRA_DATA;
4534 cp->extra_bytes += INL(np, nc_scratcha);
4535 }
4536 goto out;
4537 /*
4538 * The device switched to an illegal phase (4/5).
4539 */
4540 case SIR_BAD_PHASE:
4541 if (cp) {
4542 OUTONB(np, HF_PRT, HF_EXT_ERR);
4543 cp->xerr_status |= XE_BAD_PHASE;
4544 }
4545 goto out;
4546 /*
4547 * We received a message.
4548 */
4549 case SIR_MSG_RECEIVED:
4550 if (!cp)
4551 goto out_stuck;
4552 switch (np->msgin [0]) {
4553 /*
4554 * We received an extended message.
4555 * We handle MODIFY DATA POINTER, SDTR, WDTR
4556 * and reject all other extended messages.
4557 */
4558 case M_EXTENDED:
4559 switch (np->msgin [2]) {
4560 case M_X_MODIFY_DP:
4561 if (DEBUG_FLAGS & DEBUG_POINTER)
4562 sym_print_msg(cp, "extended msg ",
4563 np->msgin);
4564 tmp = (np->msgin[3]<<24) + (np->msgin[4]<<16) +
4565 (np->msgin[5]<<8) + (np->msgin[6]);
4566 sym_modify_dp(np, tp, cp, tmp);
4567 return;
4568 case M_X_SYNC_REQ:
4569 sym_sync_nego(np, tp, cp);
4570 return;
4571 case M_X_PPR_REQ:
4572 sym_ppr_nego(np, tp, cp);
4573 return;
4574 case M_X_WIDE_REQ:
4575 sym_wide_nego(np, tp, cp);
4576 return;
4577 default:
4578 goto out_reject;
4579 }
4580 break;
4581 /*
4582 * We received a 1/2 byte message not handled from SCRIPTS.
4583 * We are only expecting MESSAGE REJECT and IGNORE WIDE
4584 * RESIDUE messages that haven't been anticipated by
4585 * SCRIPTS on SWIDE full condition. Unanticipated IGNORE
4586 * WIDE RESIDUE messages are aliased as MODIFY DP (-1).
4587 */
4588 case M_IGN_RESIDUE:
4589 if (DEBUG_FLAGS & DEBUG_POINTER)
4590 sym_print_msg(cp, "1 or 2 byte ", np->msgin);
4591 if (cp->host_flags & HF_SENSE)
4592 OUTL_DSP(np, SCRIPTA_BA(np, clrack));
4593 else
4594 sym_modify_dp(np, tp, cp, -1);
4595 return;
4596 case M_REJECT:
4597 if (INB(np, HS_PRT) == HS_NEGOTIATE)
4598 sym_nego_rejected(np, tp, cp);
4599 else {
4600 sym_print_addr(cp->cmd,
4601 "M_REJECT received (%x:%x).\n",
4602 scr_to_cpu(np->lastmsg), np->msgout[0]);
4603 }
4604 goto out_clrack;
4605 break;
4606 default:
4607 goto out_reject;
4608 }
4609 break;
4610 /*
4611 * We received an unknown message.
4612 * Ignore all MSG IN phases and reject it.
4613 */
4614 case SIR_MSG_WEIRD:
4615 sym_print_msg(cp, "WEIRD message received", np->msgin);
4616 OUTL_DSP(np, SCRIPTB_BA(np, msg_weird));
4617 return;
4618 /*
4619 * Negotiation failed.
4620 * Target does not send us the reply.
4621 * Remove the HS_NEGOTIATE status.
4622 */
4623 case SIR_NEGO_FAILED:
4624 OUTB(np, HS_PRT, HS_BUSY);
4625 /*
4626 * Negotiation failed.
4627 * Target does not want answer message.
4628 */
4629 case SIR_NEGO_PROTO:
4630 sym_nego_default(np, tp, cp);
4631 goto out;
4632 }
4633
4634 out:
4635 OUTONB_STD();
4636 return;
4637 out_reject:
4638 OUTL_DSP(np, SCRIPTB_BA(np, msg_bad));
4639 return;
4640 out_clrack:
4641 OUTL_DSP(np, SCRIPTA_BA(np, clrack));
4642 return;
4643 out_stuck:
4644 return;
4645 }
4646
4647 /*
4648 * Acquire a control block
4649 */
4650 struct sym_ccb *sym_get_ccb (struct sym_hcb *np, struct scsi_cmnd *cmd, u_char tag_order)
4651 {
4652 u_char tn = cmd->device->id;
4653 u_char ln = cmd->device->lun;
4654 struct sym_tcb *tp = &np->target[tn];
4655 struct sym_lcb *lp = sym_lp(tp, ln);
4656 u_short tag = NO_TAG;
4657 SYM_QUEHEAD *qp;
4658 struct sym_ccb *cp = NULL;
4659
4660 /*
4661 * Look for a free CCB
4662 */
4663 if (sym_que_empty(&np->free_ccbq))
4664 sym_alloc_ccb(np);
4665 qp = sym_remque_head(&np->free_ccbq);
4666 if (!qp)
4667 goto out;
4668 cp = sym_que_entry(qp, struct sym_ccb, link_ccbq);
4669
4670 {
4671 /*
4672 * If we have been asked for a tagged command.
4673 */
4674 if (tag_order) {
4675 /*
4676 * Debugging purpose.
4677 */
4678 #ifndef SYM_OPT_HANDLE_DEVICE_QUEUEING
4679 if (lp->busy_itl != 0)
4680 goto out_free;
4681 #endif
4682 /*
4683 * Allocate resources for tags if not yet.
4684 */
4685 if (!lp->cb_tags) {
4686 sym_alloc_lcb_tags(np, tn, ln);
4687 if (!lp->cb_tags)
4688 goto out_free;
4689 }
4690 /*
4691 * Get a tag for this SCSI IO and set up
4692 * the CCB bus address for reselection,
4693 * and count it for this LUN.
4694 * Toggle reselect path to tagged.
4695 */
4696 if (lp->busy_itlq < SYM_CONF_MAX_TASK) {
4697 tag = lp->cb_tags[lp->ia_tag];
4698 if (++lp->ia_tag == SYM_CONF_MAX_TASK)
4699 lp->ia_tag = 0;
4700 ++lp->busy_itlq;
4701 #ifndef SYM_OPT_HANDLE_DEVICE_QUEUEING
4702 lp->itlq_tbl[tag] = cpu_to_scr(cp->ccb_ba);
4703 lp->head.resel_sa =
4704 cpu_to_scr(SCRIPTA_BA(np, resel_tag));
4705 #endif
4706 #ifdef SYM_OPT_LIMIT_COMMAND_REORDERING
4707 cp->tags_si = lp->tags_si;
4708 ++lp->tags_sum[cp->tags_si];
4709 ++lp->tags_since;
4710 #endif
4711 }
4712 else
4713 goto out_free;
4714 }
4715 /*
4716 * This command will not be tagged.
4717 * If we already have either a tagged or untagged
4718 * one, refuse to overlap this untagged one.
4719 */
4720 else {
4721 /*
4722 * Debugging purpose.
4723 */
4724 #ifndef SYM_OPT_HANDLE_DEVICE_QUEUEING
4725 if (lp->busy_itl != 0 || lp->busy_itlq != 0)
4726 goto out_free;
4727 #endif
4728 /*
4729 * Count this nexus for this LUN.
4730 * Set up the CCB bus address for reselection.
4731 * Toggle reselect path to untagged.
4732 */
4733 ++lp->busy_itl;
4734 #ifndef SYM_OPT_HANDLE_DEVICE_QUEUEING
4735 if (lp->busy_itl == 1) {
4736 lp->head.itl_task_sa = cpu_to_scr(cp->ccb_ba);
4737 lp->head.resel_sa =
4738 cpu_to_scr(SCRIPTA_BA(np, resel_no_tag));
4739 }
4740 else
4741 goto out_free;
4742 #endif
4743 }
4744 }
4745 /*
4746 * Put the CCB into the busy queue.
4747 */
4748 sym_insque_tail(&cp->link_ccbq, &np->busy_ccbq);
4749 #ifdef SYM_OPT_HANDLE_DEVICE_QUEUEING
4750 if (lp) {
4751 sym_remque(&cp->link2_ccbq);
4752 sym_insque_tail(&cp->link2_ccbq, &lp->waiting_ccbq);
4753 }
4754
4755 #endif
4756 cp->to_abort = 0;
4757 cp->odd_byte_adjustment = 0;
4758 cp->tag = tag;
4759 cp->order = tag_order;
4760 cp->target = tn;
4761 cp->lun = ln;
4762
4763 if (DEBUG_FLAGS & DEBUG_TAGS) {
4764 sym_print_addr(cmd, "ccb @%p using tag %d.\n", cp, tag);
4765 }
4766
4767 out:
4768 return cp;
4769 out_free:
4770 sym_insque_head(&cp->link_ccbq, &np->free_ccbq);
4771 return NULL;
4772 }
4773
4774 /*
4775 * Release one control block
4776 */
4777 void sym_free_ccb (struct sym_hcb *np, struct sym_ccb *cp)
4778 {
4779 struct sym_tcb *tp = &np->target[cp->target];
4780 struct sym_lcb *lp = sym_lp(tp, cp->lun);
4781
4782 if (DEBUG_FLAGS & DEBUG_TAGS) {
4783 sym_print_addr(cp->cmd, "ccb @%p freeing tag %d.\n",
4784 cp, cp->tag);
4785 }
4786
4787 /*
4788 * If LCB available,
4789 */
4790 if (lp) {
4791 /*
4792 * If tagged, release the tag, set the relect path
4793 */
4794 if (cp->tag != NO_TAG) {
4795 #ifdef SYM_OPT_LIMIT_COMMAND_REORDERING
4796 --lp->tags_sum[cp->tags_si];
4797 #endif
4798 /*
4799 * Free the tag value.
4800 */
4801 lp->cb_tags[lp->if_tag] = cp->tag;
4802 if (++lp->if_tag == SYM_CONF_MAX_TASK)
4803 lp->if_tag = 0;
4804 /*
4805 * Make the reselect path invalid,
4806 * and uncount this CCB.
4807 */
4808 lp->itlq_tbl[cp->tag] = cpu_to_scr(np->bad_itlq_ba);
4809 --lp->busy_itlq;
4810 } else { /* Untagged */
4811 /*
4812 * Make the reselect path invalid,
4813 * and uncount this CCB.
4814 */
4815 lp->head.itl_task_sa = cpu_to_scr(np->bad_itl_ba);
4816 --lp->busy_itl;
4817 }
4818 /*
4819 * If no JOB active, make the LUN reselect path invalid.
4820 */
4821 if (lp->busy_itlq == 0 && lp->busy_itl == 0)
4822 lp->head.resel_sa =
4823 cpu_to_scr(SCRIPTB_BA(np, resel_bad_lun));
4824 }
4825
4826 /*
4827 * We donnot queue more than 1 ccb per target
4828 * with negotiation at any time. If this ccb was
4829 * used for negotiation, clear this info in the tcb.
4830 */
4831 if (cp == tp->nego_cp)
4832 tp->nego_cp = NULL;
4833
4834 #ifdef SYM_CONF_IARB_SUPPORT
4835 /*
4836 * If we just complete the last queued CCB,
4837 * clear this info that is no longer relevant.
4838 */
4839 if (cp == np->last_cp)
4840 np->last_cp = 0;
4841 #endif
4842
4843 /*
4844 * Make this CCB available.
4845 */
4846 cp->cmd = NULL;
4847 cp->host_status = HS_IDLE;
4848 sym_remque(&cp->link_ccbq);
4849 sym_insque_head(&cp->link_ccbq, &np->free_ccbq);
4850
4851 #ifdef SYM_OPT_HANDLE_DEVICE_QUEUEING
4852 if (lp) {
4853 sym_remque(&cp->link2_ccbq);
4854 sym_insque_tail(&cp->link2_ccbq, &np->dummy_ccbq);
4855 if (cp->started) {
4856 if (cp->tag != NO_TAG)
4857 --lp->started_tags;
4858 else
4859 --lp->started_no_tag;
4860 }
4861 }
4862 cp->started = 0;
4863 #endif
4864 }
4865
4866 /*
4867 * Allocate a CCB from memory and initialize its fixed part.
4868 */
4869 static struct sym_ccb *sym_alloc_ccb(struct sym_hcb *np)
4870 {
4871 struct sym_ccb *cp = NULL;
4872 int hcode;
4873
4874 /*
4875 * Prevent from allocating more CCBs than we can
4876 * queue to the controller.
4877 */
4878 if (np->actccbs >= SYM_CONF_MAX_START)
4879 return NULL;
4880
4881 /*
4882 * Allocate memory for this CCB.
4883 */
4884 cp = sym_calloc_dma(sizeof(struct sym_ccb), "CCB");
4885 if (!cp)
4886 goto out_free;
4887
4888 /*
4889 * Count it.
4890 */
4891 np->actccbs++;
4892
4893 /*
4894 * Compute the bus address of this ccb.
4895 */
4896 cp->ccb_ba = vtobus(cp);
4897
4898 /*
4899 * Insert this ccb into the hashed list.
4900 */
4901 hcode = CCB_HASH_CODE(cp->ccb_ba);
4902 cp->link_ccbh = np->ccbh[hcode];
4903 np->ccbh[hcode] = cp;
4904
4905 /*
4906 * Initialyze the start and restart actions.
4907 */
4908 cp->phys.head.go.start = cpu_to_scr(SCRIPTA_BA(np, idle));
4909 cp->phys.head.go.restart = cpu_to_scr(SCRIPTB_BA(np, bad_i_t_l));
4910
4911 /*
4912 * Initilialyze some other fields.
4913 */
4914 cp->phys.smsg_ext.addr = cpu_to_scr(HCB_BA(np, msgin[2]));
4915
4916 /*
4917 * Chain into free ccb queue.
4918 */
4919 sym_insque_head(&cp->link_ccbq, &np->free_ccbq);
4920
4921 /*
4922 * Chain into optionnal lists.
4923 */
4924 #ifdef SYM_OPT_HANDLE_DEVICE_QUEUEING
4925 sym_insque_head(&cp->link2_ccbq, &np->dummy_ccbq);
4926 #endif
4927 return cp;
4928 out_free:
4929 if (cp)
4930 sym_mfree_dma(cp, sizeof(*cp), "CCB");
4931 return NULL;
4932 }
4933
4934 /*
4935 * Look up a CCB from a DSA value.
4936 */
4937 static struct sym_ccb *sym_ccb_from_dsa(struct sym_hcb *np, u32 dsa)
4938 {
4939 int hcode;
4940 struct sym_ccb *cp;
4941
4942 hcode = CCB_HASH_CODE(dsa);
4943 cp = np->ccbh[hcode];
4944 while (cp) {
4945 if (cp->ccb_ba == dsa)
4946 break;
4947 cp = cp->link_ccbh;
4948 }
4949
4950 return cp;
4951 }
4952
4953 /*
4954 * Target control block initialisation.
4955 * Nothing important to do at the moment.
4956 */
4957 static void sym_init_tcb (struct sym_hcb *np, u_char tn)
4958 {
4959 #if 0 /* Hmmm... this checking looks paranoid. */
4960 /*
4961 * Check some alignments required by the chip.
4962 */
4963 assert (((offsetof(struct sym_reg, nc_sxfer) ^
4964 offsetof(struct sym_tcb, head.sval)) &3) == 0);
4965 assert (((offsetof(struct sym_reg, nc_scntl3) ^
4966 offsetof(struct sym_tcb, head.wval)) &3) == 0);
4967 #endif
4968 }
4969
4970 /*
4971 * Lun control block allocation and initialization.
4972 */
4973 struct sym_lcb *sym_alloc_lcb (struct sym_hcb *np, u_char tn, u_char ln)
4974 {
4975 struct sym_tcb *tp = &np->target[tn];
4976 struct sym_lcb *lp = NULL;
4977
4978 /*
4979 * Initialize the target control block if not yet.
4980 */
4981 sym_init_tcb (np, tn);
4982
4983 /*
4984 * Allocate the LCB bus address array.
4985 * Compute the bus address of this table.
4986 */
4987 if (ln && !tp->luntbl) {
4988 int i;
4989
4990 tp->luntbl = sym_calloc_dma(256, "LUNTBL");
4991 if (!tp->luntbl)
4992 goto fail;
4993 for (i = 0 ; i < 64 ; i++)
4994 tp->luntbl[i] = cpu_to_scr(vtobus(&np->badlun_sa));
4995 tp->head.luntbl_sa = cpu_to_scr(vtobus(tp->luntbl));
4996 }
4997
4998 /*
4999 * Allocate the table of pointers for LUN(s) > 0, if needed.
5000 */
5001 if (ln && !tp->lunmp) {
5002 tp->lunmp = kcalloc(SYM_CONF_MAX_LUN, sizeof(struct sym_lcb *),
5003 GFP_ATOMIC);
5004 if (!tp->lunmp)
5005 goto fail;
5006 }
5007
5008 /*
5009 * Allocate the lcb.
5010 * Make it available to the chip.
5011 */
5012 lp = sym_calloc_dma(sizeof(struct sym_lcb), "LCB");
5013 if (!lp)
5014 goto fail;
5015 if (ln) {
5016 tp->lunmp[ln] = lp;
5017 tp->luntbl[ln] = cpu_to_scr(vtobus(lp));
5018 }
5019 else {
5020 tp->lun0p = lp;
5021 tp->head.lun0_sa = cpu_to_scr(vtobus(lp));
5022 }
5023 tp->nlcb++;
5024
5025 /*
5026 * Let the itl task point to error handling.
5027 */
5028 lp->head.itl_task_sa = cpu_to_scr(np->bad_itl_ba);
5029
5030 /*
5031 * Set the reselect pattern to our default. :)
5032 */
5033 lp->head.resel_sa = cpu_to_scr(SCRIPTB_BA(np, resel_bad_lun));
5034
5035 /*
5036 * Set user capabilities.
5037 */
5038 lp->user_flags = tp->usrflags & (SYM_DISC_ENABLED | SYM_TAGS_ENABLED);
5039
5040 #ifdef SYM_OPT_HANDLE_DEVICE_QUEUEING
5041 /*
5042 * Initialize device queueing.
5043 */
5044 sym_que_init(&lp->waiting_ccbq);
5045 sym_que_init(&lp->started_ccbq);
5046 lp->started_max = SYM_CONF_MAX_TASK;
5047 lp->started_limit = SYM_CONF_MAX_TASK;
5048 #endif
5049
5050 fail:
5051 return lp;
5052 }
5053
5054 /*
5055 * Allocate LCB resources for tagged command queuing.
5056 */
5057 static void sym_alloc_lcb_tags (struct sym_hcb *np, u_char tn, u_char ln)
5058 {
5059 struct sym_tcb *tp = &np->target[tn];
5060 struct sym_lcb *lp = sym_lp(tp, ln);
5061 int i;
5062
5063 /*
5064 * Allocate the task table and and the tag allocation
5065 * circular buffer. We want both or none.
5066 */
5067 lp->itlq_tbl = sym_calloc_dma(SYM_CONF_MAX_TASK*4, "ITLQ_TBL");
5068 if (!lp->itlq_tbl)
5069 goto fail;
5070 lp->cb_tags = kcalloc(SYM_CONF_MAX_TASK, 1, GFP_ATOMIC);
5071 if (!lp->cb_tags) {
5072 sym_mfree_dma(lp->itlq_tbl, SYM_CONF_MAX_TASK*4, "ITLQ_TBL");
5073 lp->itlq_tbl = NULL;
5074 goto fail;
5075 }
5076
5077 /*
5078 * Initialize the task table with invalid entries.
5079 */
5080 for (i = 0 ; i < SYM_CONF_MAX_TASK ; i++)
5081 lp->itlq_tbl[i] = cpu_to_scr(np->notask_ba);
5082
5083 /*
5084 * Fill up the tag buffer with tag numbers.
5085 */
5086 for (i = 0 ; i < SYM_CONF_MAX_TASK ; i++)
5087 lp->cb_tags[i] = i;
5088
5089 /*
5090 * Make the task table available to SCRIPTS,
5091 * And accept tagged commands now.
5092 */
5093 lp->head.itlq_tbl_sa = cpu_to_scr(vtobus(lp->itlq_tbl));
5094
5095 return;
5096 fail:
5097 return;
5098 }
5099
5100 /*
5101 * Lun control block deallocation. Returns the number of valid remaining LCBs
5102 * for the target.
5103 */
5104 int sym_free_lcb(struct sym_hcb *np, u_char tn, u_char ln)
5105 {
5106 struct sym_tcb *tp = &np->target[tn];
5107 struct sym_lcb *lp = sym_lp(tp, ln);
5108
5109 tp->nlcb--;
5110
5111 if (ln) {
5112 if (!tp->nlcb) {
5113 kfree(tp->lunmp);
5114 sym_mfree_dma(tp->luntbl, 256, "LUNTBL");
5115 tp->lunmp = NULL;
5116 tp->luntbl = NULL;
5117 tp->head.luntbl_sa = cpu_to_scr(vtobus(np->badluntbl));
5118 } else {
5119 tp->luntbl[ln] = cpu_to_scr(vtobus(&np->badlun_sa));
5120 tp->lunmp[ln] = NULL;
5121 }
5122 } else {
5123 tp->lun0p = NULL;
5124 tp->head.lun0_sa = cpu_to_scr(vtobus(&np->badlun_sa));
5125 }
5126
5127 if (lp->itlq_tbl) {
5128 sym_mfree_dma(lp->itlq_tbl, SYM_CONF_MAX_TASK*4, "ITLQ_TBL");
5129 kfree(lp->cb_tags);
5130 }
5131
5132 sym_mfree_dma(lp, sizeof(*lp), "LCB");
5133
5134 return tp->nlcb;
5135 }
5136
5137 /*
5138 * Queue a SCSI IO to the controller.
5139 */
5140 int sym_queue_scsiio(struct sym_hcb *np, struct scsi_cmnd *cmd, struct sym_ccb *cp)
5141 {
5142 struct scsi_device *sdev = cmd->device;
5143 struct sym_tcb *tp;
5144 struct sym_lcb *lp;
5145 u_char *msgptr;
5146 u_int msglen;
5147 int can_disconnect;
5148
5149 /*
5150 * Keep track of the IO in our CCB.
5151 */
5152 cp->cmd = cmd;
5153
5154 /*
5155 * Retrieve the target descriptor.
5156 */
5157 tp = &np->target[cp->target];
5158
5159 /*
5160 * Retrieve the lun descriptor.
5161 */
5162 lp = sym_lp(tp, sdev->lun);
5163
5164 can_disconnect = (cp->tag != NO_TAG) ||
5165 (lp && (lp->curr_flags & SYM_DISC_ENABLED));
5166
5167 msgptr = cp->scsi_smsg;
5168 msglen = 0;
5169 msgptr[msglen++] = IDENTIFY(can_disconnect, sdev->lun);
5170
5171 /*
5172 * Build the tag message if present.
5173 */
5174 if (cp->tag != NO_TAG) {
5175 u_char order = cp->order;
5176
5177 switch(order) {
5178 case M_ORDERED_TAG:
5179 break;
5180 case M_HEAD_TAG:
5181 break;
5182 default:
5183 order = M_SIMPLE_TAG;
5184 }
5185 #ifdef SYM_OPT_LIMIT_COMMAND_REORDERING
5186 /*
5187 * Avoid too much reordering of SCSI commands.
5188 * The algorithm tries to prevent completion of any
5189 * tagged command from being delayed against more
5190 * than 3 times the max number of queued commands.
5191 */
5192 if (lp && lp->tags_since > 3*SYM_CONF_MAX_TAG) {
5193 lp->tags_si = !(lp->tags_si);
5194 if (lp->tags_sum[lp->tags_si]) {
5195 order = M_ORDERED_TAG;
5196 if ((DEBUG_FLAGS & DEBUG_TAGS)||sym_verbose>1) {
5197 sym_print_addr(cmd,
5198 "ordered tag forced.\n");
5199 }
5200 }
5201 lp->tags_since = 0;
5202 }
5203 #endif
5204 msgptr[msglen++] = order;
5205
5206 /*
5207 * For less than 128 tags, actual tags are numbered
5208 * 1,3,5,..2*MAXTAGS+1,since we may have to deal
5209 * with devices that have problems with #TAG 0 or too
5210 * great #TAG numbers. For more tags (up to 256),
5211 * we use directly our tag number.
5212 */
5213 #if SYM_CONF_MAX_TASK > (512/4)
5214 msgptr[msglen++] = cp->tag;
5215 #else
5216 msgptr[msglen++] = (cp->tag << 1) + 1;
5217 #endif
5218 }
5219
5220 /*
5221 * Build a negotiation message if needed.
5222 * (nego_status is filled by sym_prepare_nego())
5223 *
5224 * Always negotiate on INQUIRY and REQUEST SENSE.
5225 *
5226 */
5227 cp->nego_status = 0;
5228 if ((tp->tgoal.check_nego ||
5229 cmd->cmnd[0] == INQUIRY || cmd->cmnd[0] == REQUEST_SENSE) &&
5230 !tp->nego_cp && lp) {
5231 msglen += sym_prepare_nego(np, cp, msgptr + msglen);
5232 }
5233
5234 /*
5235 * Startqueue
5236 */
5237 cp->phys.head.go.start = cpu_to_scr(SCRIPTA_BA(np, select));
5238 cp->phys.head.go.restart = cpu_to_scr(SCRIPTA_BA(np, resel_dsa));
5239
5240 /*
5241 * select
5242 */
5243 cp->phys.select.sel_id = cp->target;
5244 cp->phys.select.sel_scntl3 = tp->head.wval;
5245 cp->phys.select.sel_sxfer = tp->head.sval;
5246 cp->phys.select.sel_scntl4 = tp->head.uval;
5247
5248 /*
5249 * message
5250 */
5251 cp->phys.smsg.addr = CCB_BA(cp, scsi_smsg);
5252 cp->phys.smsg.size = cpu_to_scr(msglen);
5253
5254 /*
5255 * status
5256 */
5257 cp->host_xflags = 0;
5258 cp->host_status = cp->nego_status ? HS_NEGOTIATE : HS_BUSY;
5259 cp->ssss_status = S_ILLEGAL;
5260 cp->xerr_status = 0;
5261 cp->host_flags = 0;
5262 cp->extra_bytes = 0;
5263
5264 /*
5265 * extreme data pointer.
5266 * shall be positive, so -1 is lower than lowest.:)
5267 */
5268 cp->ext_sg = -1;
5269 cp->ext_ofs = 0;
5270
5271 /*
5272 * Build the CDB and DATA descriptor block
5273 * and start the IO.
5274 */
5275 return sym_setup_data_and_start(np, cmd, cp);
5276 }
5277
5278 /*
5279 * Reset a SCSI target (all LUNs of this target).
5280 */
5281 int sym_reset_scsi_target(struct sym_hcb *np, int target)
5282 {
5283 struct sym_tcb *tp;
5284
5285 if (target == np->myaddr || (u_int)target >= SYM_CONF_MAX_TARGET)
5286 return -1;
5287
5288 tp = &np->target[target];
5289 tp->to_reset = 1;
5290
5291 np->istat_sem = SEM;
5292 OUTB(np, nc_istat, SIGP|SEM);
5293
5294 return 0;
5295 }
5296
5297 /*
5298 * Abort a SCSI IO.
5299 */
5300 static int sym_abort_ccb(struct sym_hcb *np, struct sym_ccb *cp, int timed_out)
5301 {
5302 /*
5303 * Check that the IO is active.
5304 */
5305 if (!cp || !cp->host_status || cp->host_status == HS_WAIT)
5306 return -1;
5307
5308 /*
5309 * If a previous abort didn't succeed in time,
5310 * perform a BUS reset.
5311 */
5312 if (cp->to_abort) {
5313 sym_reset_scsi_bus(np, 1);
5314 return 0;
5315 }
5316
5317 /*
5318 * Mark the CCB for abort and allow time for.
5319 */
5320 cp->to_abort = timed_out ? 2 : 1;
5321
5322 /*
5323 * Tell the SCRIPTS processor to stop and synchronize with us.
5324 */
5325 np->istat_sem = SEM;
5326 OUTB(np, nc_istat, SIGP|SEM);
5327 return 0;
5328 }
5329
5330 int sym_abort_scsiio(struct sym_hcb *np, struct scsi_cmnd *cmd, int timed_out)
5331 {
5332 struct sym_ccb *cp;
5333 SYM_QUEHEAD *qp;
5334
5335 /*
5336 * Look up our CCB control block.
5337 */
5338 cp = NULL;
5339 FOR_EACH_QUEUED_ELEMENT(&np->busy_ccbq, qp) {
5340 struct sym_ccb *cp2 = sym_que_entry(qp, struct sym_ccb, link_ccbq);
5341 if (cp2->cmd == cmd) {
5342 cp = cp2;
5343 break;
5344 }
5345 }
5346
5347 return sym_abort_ccb(np, cp, timed_out);
5348 }
5349
5350 /*
5351 * Complete execution of a SCSI command with extended
5352 * error, SCSI status error, or having been auto-sensed.
5353 *
5354 * The SCRIPTS processor is not running there, so we
5355 * can safely access IO registers and remove JOBs from
5356 * the START queue.
5357 * SCRATCHA is assumed to have been loaded with STARTPOS
5358 * before the SCRIPTS called the C code.
5359 */
5360 void sym_complete_error(struct sym_hcb *np, struct sym_ccb *cp)
5361 {
5362 struct scsi_device *sdev;
5363 struct scsi_cmnd *cmd;
5364 struct sym_tcb *tp;
5365 struct sym_lcb *lp;
5366 int resid;
5367 int i;
5368
5369 /*
5370 * Paranoid check. :)
5371 */
5372 if (!cp || !cp->cmd)
5373 return;
5374
5375 cmd = cp->cmd;
5376 sdev = cmd->device;
5377 if (DEBUG_FLAGS & (DEBUG_TINY|DEBUG_RESULT)) {
5378 dev_info(&sdev->sdev_gendev, "CCB=%p STAT=%x/%x/%x\n", cp,
5379 cp->host_status, cp->ssss_status, cp->host_flags);
5380 }
5381
5382 /*
5383 * Get target and lun pointers.
5384 */
5385 tp = &np->target[cp->target];
5386 lp = sym_lp(tp, sdev->lun);
5387
5388 /*
5389 * Check for extended errors.
5390 */
5391 if (cp->xerr_status) {
5392 if (sym_verbose)
5393 sym_print_xerr(cmd, cp->xerr_status);
5394 if (cp->host_status == HS_COMPLETE)
5395 cp->host_status = HS_COMP_ERR;
5396 }
5397
5398 /*
5399 * Calculate the residual.
5400 */
5401 resid = sym_compute_residual(np, cp);
5402
5403 if (!SYM_SETUP_RESIDUAL_SUPPORT) {/* If user does not want residuals */
5404 resid = 0; /* throw them away. :) */
5405 cp->sv_resid = 0;
5406 }
5407 #ifdef DEBUG_2_0_X
5408 if (resid)
5409 printf("XXXX RESID= %d - 0x%x\n", resid, resid);
5410 #endif
5411
5412 /*
5413 * Dequeue all queued CCBs for that device
5414 * not yet started by SCRIPTS.
5415 */
5416 i = (INL(np, nc_scratcha) - np->squeue_ba) / 4;
5417 i = sym_dequeue_from_squeue(np, i, cp->target, sdev->lun, -1);
5418
5419 /*
5420 * Restart the SCRIPTS processor.
5421 */
5422 OUTL_DSP(np, SCRIPTA_BA(np, start));
5423
5424 #ifdef SYM_OPT_HANDLE_DEVICE_QUEUEING
5425 if (cp->host_status == HS_COMPLETE &&
5426 cp->ssss_status == S_QUEUE_FULL) {
5427 if (!lp || lp->started_tags - i < 2)
5428 goto weirdness;
5429 /*
5430 * Decrease queue depth as needed.
5431 */
5432 lp->started_max = lp->started_tags - i - 1;
5433 lp->num_sgood = 0;
5434
5435 if (sym_verbose >= 2) {
5436 sym_print_addr(cmd, " queue depth is now %d\n",
5437 lp->started_max);
5438 }
5439
5440 /*
5441 * Repair the CCB.
5442 */
5443 cp->host_status = HS_BUSY;
5444 cp->ssss_status = S_ILLEGAL;
5445
5446 /*
5447 * Let's requeue it to device.
5448 */
5449 sym_set_cam_status(cmd, DID_SOFT_ERROR);
5450 goto finish;
5451 }
5452 weirdness:
5453 #endif
5454 /*
5455 * Build result in CAM ccb.
5456 */
5457 sym_set_cam_result_error(np, cp, resid);
5458
5459 #ifdef SYM_OPT_HANDLE_DEVICE_QUEUEING
5460 finish:
5461 #endif
5462 /*
5463 * Add this one to the COMP queue.
5464 */
5465 sym_remque(&cp->link_ccbq);
5466 sym_insque_head(&cp->link_ccbq, &np->comp_ccbq);
5467
5468 /*
5469 * Complete all those commands with either error
5470 * or requeue condition.
5471 */
5472 sym_flush_comp_queue(np, 0);
5473
5474 #ifdef SYM_OPT_HANDLE_DEVICE_QUEUEING
5475 /*
5476 * Donnot start more than 1 command after an error.
5477 */
5478 sym_start_next_ccbs(np, lp, 1);
5479 #endif
5480 }
5481
5482 /*
5483 * Complete execution of a successful SCSI command.
5484 *
5485 * Only successful commands go to the DONE queue,
5486 * since we need to have the SCRIPTS processor
5487 * stopped on any error condition.
5488 * The SCRIPTS processor is running while we are
5489 * completing successful commands.
5490 */
5491 void sym_complete_ok (struct sym_hcb *np, struct sym_ccb *cp)
5492 {
5493 struct sym_tcb *tp;
5494 struct sym_lcb *lp;
5495 struct scsi_cmnd *cmd;
5496 int resid;
5497
5498 /*
5499 * Paranoid check. :)
5500 */
5501 if (!cp || !cp->cmd)
5502 return;
5503 assert (cp->host_status == HS_COMPLETE);
5504
5505 /*
5506 * Get user command.
5507 */
5508 cmd = cp->cmd;
5509
5510 /*
5511 * Get target and lun pointers.
5512 */
5513 tp = &np->target[cp->target];
5514 lp = sym_lp(tp, cp->lun);
5515
5516 /*
5517 * If all data have been transferred, given than no
5518 * extended error did occur, there is no residual.
5519 */
5520 resid = 0;
5521 if (cp->phys.head.lastp != cp->goalp)
5522 resid = sym_compute_residual(np, cp);
5523
5524 /*
5525 * Wrong transfer residuals may be worse than just always
5526 * returning zero. User can disable this feature in
5527 * sym53c8xx.h. Residual support is enabled by default.
5528 */
5529 if (!SYM_SETUP_RESIDUAL_SUPPORT)
5530 resid = 0;
5531 #ifdef DEBUG_2_0_X
5532 if (resid)
5533 printf("XXXX RESID= %d - 0x%x\n", resid, resid);
5534 #endif
5535
5536 /*
5537 * Build result in CAM ccb.
5538 */
5539 sym_set_cam_result_ok(cp, cmd, resid);
5540
5541 #ifdef SYM_OPT_HANDLE_DEVICE_QUEUEING
5542 /*
5543 * If max number of started ccbs had been reduced,
5544 * increase it if 200 good status received.
5545 */
5546 if (lp && lp->started_max < lp->started_limit) {
5547 ++lp->num_sgood;
5548 if (lp->num_sgood >= 200) {
5549 lp->num_sgood = 0;
5550 ++lp->started_max;
5551 if (sym_verbose >= 2) {
5552 sym_print_addr(cmd, " queue depth is now %d\n",
5553 lp->started_max);
5554 }
5555 }
5556 }
5557 #endif
5558
5559 /*
5560 * Free our CCB.
5561 */
5562 sym_free_ccb (np, cp);
5563
5564 #ifdef SYM_OPT_HANDLE_DEVICE_QUEUEING
5565 /*
5566 * Requeue a couple of awaiting scsi commands.
5567 */
5568 if (!sym_que_empty(&lp->waiting_ccbq))
5569 sym_start_next_ccbs(np, lp, 2);
5570 #endif
5571 /*
5572 * Complete the command.
5573 */
5574 sym_xpt_done(np, cmd);
5575 }
5576
5577 /*
5578 * Soft-attach the controller.
5579 */
5580 int sym_hcb_attach(struct Scsi_Host *shost, struct sym_fw *fw, struct sym_nvram *nvram)
5581 {
5582 struct sym_hcb *np = sym_get_hcb(shost);
5583 int i;
5584
5585 /*
5586 * Get some info about the firmware.
5587 */
5588 np->scripta_sz = fw->a_size;
5589 np->scriptb_sz = fw->b_size;
5590 np->scriptz_sz = fw->z_size;
5591 np->fw_setup = fw->setup;
5592 np->fw_patch = fw->patch;
5593 np->fw_name = fw->name;
5594
5595 /*
5596 * Save setting of some IO registers, so we will
5597 * be able to probe specific implementations.
5598 */
5599 sym_save_initial_setting (np);
5600
5601 /*
5602 * Reset the chip now, since it has been reported
5603 * that SCSI clock calibration may not work properly
5604 * if the chip is currently active.
5605 */
5606 sym_chip_reset(np);
5607
5608 /*
5609 * Prepare controller and devices settings, according
5610 * to chip features, user set-up and driver set-up.
5611 */
5612 sym_prepare_setting(shost, np, nvram);
5613
5614 /*
5615 * Check the PCI clock frequency.
5616 * Must be performed after prepare_setting since it destroys
5617 * STEST1 that is used to probe for the clock doubler.
5618 */
5619 i = sym_getpciclock(np);
5620 if (i > 37000 && !(np->features & FE_66MHZ))
5621 printf("%s: PCI BUS clock seems too high: %u KHz.\n",
5622 sym_name(np), i);
5623
5624 /*
5625 * Allocate the start queue.
5626 */
5627 np->squeue = sym_calloc_dma(sizeof(u32)*(MAX_QUEUE*2),"SQUEUE");
5628 if (!np->squeue)
5629 goto attach_failed;
5630 np->squeue_ba = vtobus(np->squeue);
5631
5632 /*
5633 * Allocate the done queue.
5634 */
5635 np->dqueue = sym_calloc_dma(sizeof(u32)*(MAX_QUEUE*2),"DQUEUE");
5636 if (!np->dqueue)
5637 goto attach_failed;
5638 np->dqueue_ba = vtobus(np->dqueue);
5639
5640 /*
5641 * Allocate the target bus address array.
5642 */
5643 np->targtbl = sym_calloc_dma(256, "TARGTBL");
5644 if (!np->targtbl)
5645 goto attach_failed;
5646 np->targtbl_ba = vtobus(np->targtbl);
5647
5648 /*
5649 * Allocate SCRIPTS areas.
5650 */
5651 np->scripta0 = sym_calloc_dma(np->scripta_sz, "SCRIPTA0");
5652 np->scriptb0 = sym_calloc_dma(np->scriptb_sz, "SCRIPTB0");
5653 np->scriptz0 = sym_calloc_dma(np->scriptz_sz, "SCRIPTZ0");
5654 if (!np->scripta0 || !np->scriptb0 || !np->scriptz0)
5655 goto attach_failed;
5656
5657 /*
5658 * Allocate the array of lists of CCBs hashed by DSA.
5659 */
5660 np->ccbh = kcalloc(CCB_HASH_SIZE, sizeof(struct sym_ccb **), GFP_KERNEL);
5661 if (!np->ccbh)
5662 goto attach_failed;
5663
5664 /*
5665 * Initialyze the CCB free and busy queues.
5666 */
5667 sym_que_init(&np->free_ccbq);
5668 sym_que_init(&np->busy_ccbq);
5669 sym_que_init(&np->comp_ccbq);
5670
5671 /*
5672 * Initialization for optional handling
5673 * of device queueing.
5674 */
5675 #ifdef SYM_OPT_HANDLE_DEVICE_QUEUEING
5676 sym_que_init(&np->dummy_ccbq);
5677 #endif
5678 /*
5679 * Allocate some CCB. We need at least ONE.
5680 */
5681 if (!sym_alloc_ccb(np))
5682 goto attach_failed;
5683
5684 /*
5685 * Calculate BUS addresses where we are going
5686 * to load the SCRIPTS.
5687 */
5688 np->scripta_ba = vtobus(np->scripta0);
5689 np->scriptb_ba = vtobus(np->scriptb0);
5690 np->scriptz_ba = vtobus(np->scriptz0);
5691
5692 if (np->ram_ba) {
5693 np->scripta_ba = np->ram_ba;
5694 if (np->features & FE_RAM8K) {
5695 np->scriptb_ba = np->scripta_ba + 4096;
5696 #if 0 /* May get useful for 64 BIT PCI addressing */
5697 np->scr_ram_seg = cpu_to_scr(np->scripta_ba >> 32);
5698 #endif
5699 }
5700 }
5701
5702 /*
5703 * Copy scripts to controller instance.
5704 */
5705 memcpy(np->scripta0, fw->a_base, np->scripta_sz);
5706 memcpy(np->scriptb0, fw->b_base, np->scriptb_sz);
5707 memcpy(np->scriptz0, fw->z_base, np->scriptz_sz);
5708
5709 /*
5710 * Setup variable parts in scripts and compute
5711 * scripts bus addresses used from the C code.
5712 */
5713 np->fw_setup(np, fw);
5714
5715 /*
5716 * Bind SCRIPTS with physical addresses usable by the
5717 * SCRIPTS processor (as seen from the BUS = BUS addresses).
5718 */
5719 sym_fw_bind_script(np, (u32 *) np->scripta0, np->scripta_sz);
5720 sym_fw_bind_script(np, (u32 *) np->scriptb0, np->scriptb_sz);
5721 sym_fw_bind_script(np, (u32 *) np->scriptz0, np->scriptz_sz);
5722
5723 #ifdef SYM_CONF_IARB_SUPPORT
5724 /*
5725 * If user wants IARB to be set when we win arbitration
5726 * and have other jobs, compute the max number of consecutive
5727 * settings of IARB hints before we leave devices a chance to
5728 * arbitrate for reselection.
5729 */
5730 #ifdef SYM_SETUP_IARB_MAX
5731 np->iarb_max = SYM_SETUP_IARB_MAX;
5732 #else
5733 np->iarb_max = 4;
5734 #endif
5735 #endif
5736
5737 /*
5738 * Prepare the idle and invalid task actions.
5739 */
5740 np->idletask.start = cpu_to_scr(SCRIPTA_BA(np, idle));
5741 np->idletask.restart = cpu_to_scr(SCRIPTB_BA(np, bad_i_t_l));
5742 np->idletask_ba = vtobus(&np->idletask);
5743
5744 np->notask.start = cpu_to_scr(SCRIPTA_BA(np, idle));
5745 np->notask.restart = cpu_to_scr(SCRIPTB_BA(np, bad_i_t_l));
5746 np->notask_ba = vtobus(&np->notask);
5747
5748 np->bad_itl.start = cpu_to_scr(SCRIPTA_BA(np, idle));
5749 np->bad_itl.restart = cpu_to_scr(SCRIPTB_BA(np, bad_i_t_l));
5750 np->bad_itl_ba = vtobus(&np->bad_itl);
5751
5752 np->bad_itlq.start = cpu_to_scr(SCRIPTA_BA(np, idle));
5753 np->bad_itlq.restart = cpu_to_scr(SCRIPTB_BA(np,bad_i_t_l_q));
5754 np->bad_itlq_ba = vtobus(&np->bad_itlq);
5755
5756 /*
5757 * Allocate and prepare the lun JUMP table that is used
5758 * for a target prior the probing of devices (bad lun table).
5759 * A private table will be allocated for the target on the
5760 * first INQUIRY response received.
5761 */
5762 np->badluntbl = sym_calloc_dma(256, "BADLUNTBL");
5763 if (!np->badluntbl)
5764 goto attach_failed;
5765
5766 np->badlun_sa = cpu_to_scr(SCRIPTB_BA(np, resel_bad_lun));
5767 for (i = 0 ; i < 64 ; i++) /* 64 luns/target, no less */
5768 np->badluntbl[i] = cpu_to_scr(vtobus(&np->badlun_sa));
5769
5770 /*
5771 * Prepare the bus address array that contains the bus
5772 * address of each target control block.
5773 * For now, assume all logical units are wrong. :)
5774 */
5775 for (i = 0 ; i < SYM_CONF_MAX_TARGET ; i++) {
5776 np->targtbl[i] = cpu_to_scr(vtobus(&np->target[i]));
5777 np->target[i].head.luntbl_sa =
5778 cpu_to_scr(vtobus(np->badluntbl));
5779 np->target[i].head.lun0_sa =
5780 cpu_to_scr(vtobus(&np->badlun_sa));
5781 }
5782
5783 /*
5784 * Now check the cache handling of the pci chipset.
5785 */
5786 if (sym_snooptest (np)) {
5787 printf("%s: CACHE INCORRECTLY CONFIGURED.\n", sym_name(np));
5788 goto attach_failed;
5789 }
5790
5791 /*
5792 * Sigh! we are done.
5793 */
5794 return 0;
5795
5796 attach_failed:
5797 return -ENXIO;
5798 }
5799
5800 /*
5801 * Free everything that has been allocated for this device.
5802 */
5803 void sym_hcb_free(struct sym_hcb *np)
5804 {
5805 SYM_QUEHEAD *qp;
5806 struct sym_ccb *cp;
5807 struct sym_tcb *tp;
5808 int target;
5809
5810 if (np->scriptz0)
5811 sym_mfree_dma(np->scriptz0, np->scriptz_sz, "SCRIPTZ0");
5812 if (np->scriptb0)
5813 sym_mfree_dma(np->scriptb0, np->scriptb_sz, "SCRIPTB0");
5814 if (np->scripta0)
5815 sym_mfree_dma(np->scripta0, np->scripta_sz, "SCRIPTA0");
5816 if (np->squeue)
5817 sym_mfree_dma(np->squeue, sizeof(u32)*(MAX_QUEUE*2), "SQUEUE");
5818 if (np->dqueue)
5819 sym_mfree_dma(np->dqueue, sizeof(u32)*(MAX_QUEUE*2), "DQUEUE");
5820
5821 if (np->actccbs) {
5822 while ((qp = sym_remque_head(&np->free_ccbq)) != NULL) {
5823 cp = sym_que_entry(qp, struct sym_ccb, link_ccbq);
5824 sym_mfree_dma(cp, sizeof(*cp), "CCB");
5825 }
5826 }
5827 kfree(np->ccbh);
5828
5829 if (np->badluntbl)
5830 sym_mfree_dma(np->badluntbl, 256,"BADLUNTBL");
5831
5832 for (target = 0; target < SYM_CONF_MAX_TARGET ; target++) {
5833 tp = &np->target[target];
5834 if (tp->luntbl)
5835 sym_mfree_dma(tp->luntbl, 256, "LUNTBL");
5836 #if SYM_CONF_MAX_LUN > 1
5837 kfree(tp->lunmp);
5838 #endif
5839 }
5840 if (np->targtbl)
5841 sym_mfree_dma(np->targtbl, 256, "TARGTBL");
5842 }
5843