| blob | 8b5334c56f0a9668fb1f132b7a657cae329104e4 |
1 /* NCR53C9x.c: Generic SCSI driver code for NCR53C9x chips.
2 *
3 * Originally esp.c : EnhancedScsiProcessor Sun SCSI driver code.
4 *
5 * Copyright (C) 1995, 1998 David S. Miller (davem@caip.rutgers.edu)
6 *
7 * Most DMA dependencies put in driver specific files by
8 * Jesper Skov (jskov@cygnus.co.uk)
9 *
10 * Set up to use esp_read/esp_write (preprocessor macros in NCR53c9x.h) by
11 * Tymm Twillman (tymm@coe.missouri.edu)
12 */
14 /* TODO:
15 *
16 * 1) Maybe disable parity checking in config register one for SCSI1
17 * targets. (Gilmore says parity error on the SBus can lock up
18 * old sun4c's)
19 * 2) Add support for DMA2 pipelining.
20 * 3) Add tagged queueing.
21 * 4) Maybe change use of "esp" to something more "NCR"'ish.
22 */
24 #include <linux/module.h>
26 #include <linux/kernel.h>
27 #include <linux/delay.h>
28 #include <linux/types.h>
29 #include <linux/string.h>
30 #include <linux/slab.h>
31 #include <linux/blkdev.h>
32 #include <linux/interrupt.h>
33 #include <linux/proc_fs.h>
34 #include <linux/stat.h>
35 #include <linux/init.h>
38 #include <scsi/scsi_host.h>
41 #include <asm/system.h>
42 #include <asm/ptrace.h>
43 #include <asm/pgtable.h>
44 #include <asm/io.h>
45 #include <asm/irq.h>
47 /* Command phase enumeration. */
51 /* Various forms of selecting a target. */
52 #define in_slct_mask 0x10
59 /* Any post selection activity. */
60 #define in_phases_mask 0x20
75 /* Special states, ie. not normal bus transitions... */
76 #define in_spec_mask 0x80
82 };
85 /* Zero has special meaning, see skipahead[12]. */
92 /*5*/ do_intr_end
93 };
95 /* The master ring of all esp hosts we are managing in this driver. */
101 /* Debugging routines */
103 unchar cmdchar;
106 /* Miscellaneous */
111 /* Disconnected State Group */
120 /* Target State Group */
132 /* Initiator State Group */
139 };
140 #define NUM_ESP_COMMANDS ((sizeof(esp_cmd_strings)) / (sizeof(struct esp_cmdstrings)))
142 /* Print textual representation of an ESP command */
144 {
154 else
157 }
159 /* Print the status register's value */
161 {
162 unchar phase;
184 }
186 /* Print the interrupt register's value */
188 {
207 }
209 /* Print the sequence step registers contents */
211 {
220 }
223 {
275 };
276 }
278 #ifdef DEBUG_STATE_MACHINE
280 {
284 }
285 #else
286 #define esp_advance_phase(__s, __newphase) \
287 (__s)->SCp.sent_command = (__s)->SCp.phase; \
288 (__s)->SCp.phase = (__newphase);
289 #endif
291 #ifdef DEBUG_ESP_CMDS
293 unchar cmd)
294 {
298 }
299 #else
300 #define esp_cmd(__esp, __eregs, __cmd) esp_write((__eregs)->esp_cmnd, (__cmd))
301 #endif
303 /* How we use the various Linux SCSI data structures for operation.
304 *
305 * struct scsi_cmnd:
306 *
307 * We keep track of the syncronous capabilities of a target
308 * in the device member, using sync_min_period and
309 * sync_max_offset. These are the values we directly write
310 * into the ESP registers while running a command. If offset
311 * is zero the ESP will use asynchronous transfers.
312 * If the borken flag is set we assume we shouldn't even bother
313 * trying to negotiate for synchronous transfer as this target
314 * is really stupid. If we notice the target is dropping the
315 * bus, and we have been allowing it to disconnect, we clear
316 * the disconnect flag.
317 */
319 /* Manipulation of the ESP command queues. Thanks to the aha152x driver
320 * and its author, Juergen E. Fischer, for the methods used here.
321 * Note that these are per-ESP queues, not global queues like
322 * the aha152x driver uses.
323 */
325 {
333 ;
335 }
336 }
339 {
342 }
345 {
352 }
355 {
361 ;
365 else
367 }
369 }
371 /* Resetting various pieces of the ESP scsi driver chipset */
373 /* Reset the ESP chip, _not_ the SCSI bus. */
375 {
379 /* Now reset the ESP chip */
386 /* This is the only point at which it is reliable to read
387 * the ID-code for a fast ESP chip variant.
388 */
398 "unknown!"
399 };
406 else
413 else
418 else
423 else
434 }
436 /* Reload the configuration registers */
449 /* nothing to do */
455 /* Slow 236 */
467 /* Fast ESP variants */
475 else
477 /* Different timeout constant for these chips */
483 /* Enable Active Negotiation if possible */
488 /* Fast 100a */
499 };
501 /* Eat any bitrot in the chip */
504 }
506 /* This places the ESP into a known state at boot time. */
508 {
511 /* Reset the DMA */
515 /* Reset the ESP */
518 /* Reset the SCSI bus, but tell ESP not to generate an irq */
524 /* Eat any bitrot in the chip and we are done... */
526 }
528 /* Allocate structure and insert basic data such as SCSI chip frequency
529 * data and a pointer to the device
530 */
533 {
539 else
550 /* Set bitshift value (only used on Amiga with multiple ESPs) */
553 /* Put into the chain of esp chips detected */
560 }
564 }
567 {
576 }
577 nesps--;
578 }
580 /* Complete initialization of ESP structure and device
581 * Caller must have initialized appropriate parts of the ESP structure
582 * between the call to esp_allocate and this function.
583 */
585 {
588 unchar ccf;
591 /* Check out the clock properties of the chip. */
593 /* This is getting messy but it has to be done
594 * correctly or else you get weird behavior all
595 * over the place. We are trying to basically
596 * figure out three pieces of information.
597 *
598 * a) Clock Conversion Factor
599 *
600 * This is a representation of the input
601 * crystal clock frequency going into the
602 * ESP on this machine. Any operation whose
603 * timing is longer than 400ns depends on this
604 * value being correct. For example, you'll
605 * get blips for arbitration/selection during
606 * high load or with multiple targets if this
607 * is not set correctly.
608 *
609 * b) Selection Time-Out
610 *
611 * The ESP isn't very bright and will arbitrate
612 * for the bus and try to select a target
613 * forever if you let it. This value tells
614 * the ESP when it has taken too long to
615 * negotiate and that it should interrupt
616 * the CPU so we can see what happened.
617 * The value is computed as follows (from
618 * NCR/Symbios chip docs).
619 *
620 * (Time Out Period) * (Input Clock)
621 * STO = ----------------------------------
622 * (8192) * (Clock Conversion Factor)
623 *
624 * You usually want the time out period to be
625 * around 250ms, I think we'll set it a little
626 * bit higher to account for fully loaded SCSI
627 * bus's and slow devices that don't respond so
628 * quickly to selection attempts. (yeah, I know
629 * this is out of spec. but there is a lot of
630 * buggy pieces of firmware out there so bite me)
631 *
632 * c) Imperical constants for synchronous offset
633 * and transfer period register values
634 *
635 * This entails the smallest and largest sync
636 * period we could ever handle on this ESP.
637 */
643 else
646 /* If we can't find anything reasonable,
647 * just assume 20MHZ. This is the clock
648 * frequency of the older sun4c's where I've
649 * been unable to find the clock-frequency
650 * PROM property. All other machines provide
651 * useful values it seems.
652 */
655 }
660 else
672 /* Fill in ehost data */
677 /* SCSI id mask */
680 /* Probe the revision of this esp */
709 }
710 }
711 }
713 /* Initialize the command queues */
718 /* Clear the state machines. */
732 }
736 /* Clear the one behind caches to hold unmatchable values. */
739 /* Reset the thing before we try anything... */
742 esps_in_use++;
743 }
745 /* The info function will return whatever useful
746 * information the developer sees fit. If not provided, then
747 * the name field will be used instead.
748 */
750 {
773 };
774 }
776 /* From Wolfgang Stanglmeier's NCR scsi driver. */
777 struct info_str
778 {
783 };
786 {
793 }
797 }
802 }
803 }
806 {
817 }
820 {
864 };
869 }
872 /* Now describe the state of each existing target. */
888 }
891 }
893 /* ESP proc filesystem code. */
894 int esp_proc_info(struct Scsi_Host *shost, char *buffer, char **start, off_t offset, int length,
896 {
904 }
907 {
914 else
923 else
926 }
927 }
930 {
937 }
938 }
941 {
948 }
951 {
958 }
960 /* Some rules:
961 *
962 * 1) Never ever panic while something is live on the bus.
963 * If there is to be any chance of syncing the disks this
964 * rule is to be obeyed.
965 *
966 * 2) Any target that causes a foul condition will no longer
967 * have synchronous transfers done to it, no questions
968 * asked.
969 *
970 * 3) Keep register accesses to a minimum. Think about some
971 * day when we have Xbus machines this is running on and
972 * the ESP chip is on the other end of the machine on a
973 * different board from the cpu where this is running.
974 */
976 /* Fire off a command. We assume the bus is free and that the only
977 * case where we could see an interrupt is where we have disconnected
978 * commands active and they are trying to reselect us.
979 */
981 {
994 };
995 }
998 {
1005 }
1008 {
1018 /* Hold off if we have disconnected commands and
1019 * an IRQ is showing...
1020 */
1024 /* Grab first member of the issue queue. */
1027 /* Safe to panic here because current_SC is null. */
1039 /* Send it out whole, or piece by piece? The ESP
1040 * only knows how to automatically send out 6, 10,
1041 * and 12 byte commands. I used to think that the
1042 * Linux SCSI code would never throw anything other
1043 * than that to us, but then again there is the
1044 * SCSI generic driver which can send us anything.
1045 */
1048 /* If arbitration/selection is successful, the ESP will leave
1049 * ATN asserted, causing the target to go into message out
1050 * phase. The ESP will feed the target the identify and then
1051 * the target can only legally go to one of command,
1052 * datain/out, status, or message in phase, or stay in message
1053 * out phase (should we be trying to send a sync negotiation
1054 * message after the identify). It is not allowed to drop
1055 * BSY, but some buggy targets do and we check for this
1056 * condition in the selection complete code. Most of the time
1057 * we'll make the command bytes available to the ESP and it
1058 * will not interrupt us until it finishes command phase, we
1059 * cannot do this for command sizes the ESP does not
1060 * understand and in this case we'll get interrupted right
1061 * when the target goes into command phase.
1062 *
1063 * It is absolutely _illegal_ in the presence of SCSI-2 devices
1064 * to use the ESP select w/o ATN command. When SCSI-2 devices are
1065 * present on the bus we _must_ always go straight to message out
1066 * phase with an identify message for the target. Being that
1067 * selection attempts in SCSI-1 w/o ATN was an option, doing SCSI-2
1068 * selections should not confuse SCSI-1 we hope.
1069 */
1072 /* this targets sync is known */
1073 #ifdef CONFIG_SCSI_MAC_ESP
1074 do_sync_known:
1075 #endif
1078 else
1087 }
1089 /* After the bootup SCSI code sends both the
1090 * TEST_UNIT_READY and INQUIRY commands we want
1091 * to at least attempt allowing the device to
1092 * disconnect.
1093 */
1104 /* Take no chances... */
1110 #ifdef CONFIG_SCSI_MAC_ESP
1111 /* Never allow synchronous transfers (disconnect OK) on
1112 * Macintosh. Well, maybe later when we figured out how to
1113 * do DMA on the machines that support it ...
1114 */
1121 #endif
1122 /* We've talked to this guy before,
1123 * but never negotiated. Let's try
1124 * sync negotiation.
1125 */
1129 /* Nice try sucker... */
1136 }
1139 }
1143 /* A fix for broken SCSI1 targets, when they disconnect
1144 * they lock up the bus and confuse ESP. So disallow
1145 * disconnects for SCSI1 targets for now until we
1146 * find a better fix.
1147 *
1148 * Addendum: This is funny, I figured out what was going
1149 * on. The blotzed SCSI1 target would disconnect,
1150 * one of the other SCSI2 targets or both would be
1151 * disconnected as well. The SCSI1 target would
1152 * stay disconnected long enough that we start
1153 * up a command on one of the SCSI2 targets. As
1154 * the ESP is arbitrating for the bus the SCSI1
1155 * target begins to arbitrate as well to reselect
1156 * the ESP. The SCSI1 target refuses to drop it's
1157 * ID bit on the data bus even though the ESP is
1158 * at ID 7 and is the obvious winner for any
1159 * arbitration. The ESP is a poor sport and refuses
1160 * to lose arbitration, it will continue indefinitely
1161 * trying to arbitrate for the bus and can only be
1162 * stopped via a chip reset or SCSI bus reset.
1163 * Therefore _no_ disconnects for SCSI1 targets
1164 * thank you very much. ;-)
1165 */
1174 }
1176 /* ESP fifo is only so big...
1177 * Make this look like a slow command.
1178 */
1185 }
1203 }
1204 }
1207 /* Set up the DMA and ESP counters */
1211 /*
1212 * XXX MSch:
1213 *
1214 * It seems this is required, at least to clean up
1215 * after failed commands when using PIO mode ...
1216 */
1223 /* Tell ESP to "go". */
1226 /* Set up the ESP counters */
1231 /* Tell ESP to "go". */
1233 }
1234 }
1236 /* Queue a SCSI command delivered from the mid-level Linux SCSI code. */
1238 {
1241 /* Set up func ptr and initial driver cmd-phase. */
1250 /* We use the scratch area. */
1261 /* Place into our queue. */
1268 }
1270 /* Run it now if we can. */
1275 }
1277 /* Dump driver state. */
1279 {
1285 }
1289 {
1291 #ifdef DEBUG_ESP_CMDS
1293 #endif
1297 /* Print DMA status */
1305 #ifdef DEBUG_ESP_CMDS
1329 }
1336 }
1338 }
1340 /* Abort a command. The host_lock is acquired by caller. */
1342 {
1350 /* Wheee, if this is the current command on the bus, the
1351 * best we can do is assert ATN and wait for msgout phase.
1352 * This should even fix a hung SCSI bus when we lose state
1353 * in the driver and timeout because the eventual phase change
1354 * will cause the ESP to (eventually) give an interrupt.
1355 */
1362 }
1364 /* If it is still in the issue queue then we can safely
1365 * call the completion routine and report abort success.
1366 */
1371 }
1387 }
1388 }
1389 }
1391 /* Yuck, the command to abort is disconnected, it is not
1392 * worth trying to abort it now if something else is live
1393 * on the bus at this time. So, we let the SCSI code wait
1394 * a little bit and try again later.
1395 */
1400 }
1402 /* It's disconnected, we have to reconnect to re-establish
1403 * the nexus and tell the device to abort. However, we really
1404 * cannot 'reconnect' per se. Don't try to be fancy, just
1405 * indicate failure, which causes our caller to reset the whole
1406 * bus.
1407 */
1412 }
1414 /* We've sent ESP_CMD_RS to the ESP, the interrupt had just
1415 * arrived indicating the end of the SCSI bus reset. Our job
1416 * is to clean out the command queues and begin re-execution
1417 * of SCSI commands once more.
1418 */
1421 {
1424 /* Clean up currently executing command, if any. */
1430 }
1432 /* Clean up disconnected queue, they have been invalidated
1433 * by the bus reset.
1434 */
1440 }
1441 }
1443 /* SCSI bus reset is complete. */
1447 /* Ok, now it is safe to get commands going once more. */
1452 }
1456 {
1462 }
1464 /* Reset ESP chip, reset hanging bus, then kill active and
1465 * disconnected commands for targets without soft reset.
1466 *
1467 * The host_lock is acquired by caller.
1468 */
1470 {
1480 }
1482 /* Internal ESP done function. */
1484 {
1494 /* Bus is free, issue any commands in the queue. */
1498 /* Panic is safe as current_SC is null so we may still
1499 * be able to accept more commands to sync disk buffers.
1500 */
1503 }
1504 }
1506 /* Wheee, ESP interrupt engine. */
1508 /* Forward declarations. */
1519 #define sreg_datainp(__sreg) (((__sreg) & ESP_STAT_PMASK) == ESP_DIP)
1520 #define sreg_dataoutp(__sreg) (((__sreg) & ESP_STAT_PMASK) == ESP_DOP)
1522 /* We try to avoid some interrupts by jumping ahead and see if the ESP
1523 * has gotten far enough yet. Hence the following.
1524 */
1527 {
1532 /* Yes, we are able to save an interrupt. */
1537 else
1539 }
1540 /* Ho hum, target is taking forever... */
1543 }
1549 {
1554 /* Yes, we are able to save an interrupt. */
1559 else
1561 }
1562 /* Ho hum, target is taking forever... */
1565 }
1567 /* Misc. esp helper macros. */
1568 #define esp_setcount(__eregs, __cnt) \
1569 esp_write((__eregs)->esp_tclow, ((__cnt) & 0xff)); \
1570 esp_write((__eregs)->esp_tcmed, (((__cnt) >> 8) & 0xff))
1572 #define esp_getcount(__eregs) \
1573 ((esp_read((__eregs)->esp_tclow)&0xff) | \
1574 ((esp_read((__eregs)->esp_tcmed)&0xff) << 8))
1576 #define fcount(__esp, __eregs) \
1577 (esp_read((__eregs)->esp_fflags) & ESP_FF_FBYTES)
1579 #define fnzero(__esp, __eregs) \
1580 (esp_read((__eregs)->esp_fflags) & ESP_FF_ONOTZERO)
1582 /* XXX speculative nops unnecessary when continuing amidst a data phase
1583 * XXX even on esp100!!! another case of flooding the bus with I/O reg
1584 * XXX writes...
1585 */
1586 #define esp_maybe_nop(__esp, __eregs) \
1587 if((__esp)->erev == esp100) \
1588 esp_cmd((__esp), (__eregs), ESP_CMD_NULL)
1590 #define sreg_to_dataphase(__sreg) \
1591 ((((__sreg) & ESP_STAT_PMASK) == ESP_DOP) ? in_dataout : in_datain)
1593 /* The ESP100 when in synchronous data phase, can mistake a long final
1594 * REQ pulse from the target as an extra byte, it places whatever is on
1595 * the data lines into the fifo. For now, we will assume when this
1596 * happens that the target is a bit quirky and we don't want to
1597 * be talking synchronously to it anyways. Regardless, we need to
1598 * tell the ESP to eat the extraneous byte so that we can proceed
1599 * to the next phase.
1600 */
1603 {
1604 /* Do not touch this piece of code. */
1612 /* Async mode for this guy. */
1615 /* Ack the bogus byte, but set ATN first. */
1619 }
1620 }
1622 /* This closes the window during a selection with a reselect pending, because
1623 * we use DMA for the selection process the FIFO should hold the correct
1624 * contents if we get reselected during this process. So we just need to
1625 * ack the possible illegal cmd interrupt pending on the esp100.
1626 */
1629 {
1639 }
1641 /* This verifies the BUSID bits during a reselection so that we know which
1642 * target is talking to us.
1643 */
1645 {
1659 }
1661 /* This verifies the identify from the target so that we know which lun is
1662 * being reconnected.
1663 */
1665 {
1672 /* Yes, you read this correctly. We report lun of zero
1673 * if we see parity error. ESP reports parity error for
1674 * the lun byte, and this is the only way to hope to recover
1675 * because the target is connected.
1676 */
1680 /* Check for illegal bits being set in the lun. */
1685 }
1687 /* This puts the driver in a state where it can revitalize a command that
1688 * is being continued due to reselection.
1689 */
1692 {
1707 }
1708 }
1710 }
1712 /* This will place the current working command back into the issue queue
1713 * if we are to receive a reselection amidst a selection attempt.
1714 */
1716 {
1724 }
1726 /* Begin message in phase. */
1728 {
1736 }
1739 {
1745 else
1746 sp->SCp.ptr = (char *) virt_to_phys((page_address(sp->SCp.buffer->page) + sp->SCp.buffer->offset));
1748 }
1750 /* Please note that the way I've coded these routines is that I _always_
1751 * check for a disconnect during any and all information transfer
1752 * phases. The SCSI standard states that the target _can_ cause a BUS
1753 * FREE condition by dropping all MSG/CD/IO/BSY signals. Also note
1754 * that during information transfer phases the target controls every
1755 * change in phase, the only thing the initiator can do is "ask" for
1756 * a message out phase by driving ATN true. The target can, and sometimes
1757 * will, completely ignore this request so we cannot assume anything when
1758 * we try to force a message out phase to abort/reset a target. Most of
1759 * the time the target will eventually be nice and go to message out, so
1760 * we may have to hold on to our state about what we want to tell the target
1761 * for some period of time.
1762 */
1764 /* I think I have things working here correctly. Even partial transfers
1765 * within a buffer or sub-buffer should not upset us at all no matter
1766 * how bad the target and/or ESP fucks things up.
1767 */
1769 {
1780 /*
1781 * XXX MSch: cater for PIO transfer here; PIO used if hmuch == 0
1782 */
1784 /*
1785 * DMA
1786 */
1796 /*
1797 * end DMA
1798 */
1800 /*
1801 * PIO
1802 */
1809 /*
1810 * polled transfer; ugly, can we make this happen in a DRQ
1811 * interrupt handler ??
1812 * requires keeping track of state information in host or
1813 * command struct!
1814 * Problem: I've never seen a DRQ happen on Mac, not even
1815 * with ESP_CMD_DMA ...
1816 */
1818 /* figure out how much needs to be transferred */
1823 /* tell the ESP ... */
1826 /* loop */
1830 #if 0
1832 #endif
1833 #if 0
1836 else
1838 #endif
1839 #if 0
1841 #endif
1843 /* 'go' ... */
1846 /* wait for data */
1855 /* see how much we got ... */
1859 fifo_stuck++;
1860 else
1865 /* read fifo */
1871 /* how many to go ?? */
1874 /* break if status phase !! */
1876 /* clear int. */
1879 }
1881 #define MAX_FIFO 8
1882 /* how much will fit ? */
1887 /* fill fifo */
1891 /* how many left if this goes out ?? */
1894 /* 'go' ... */
1897 /* wait for 'got it' */
1906 /* need to check how much was sent ?? */
1913 /* break if status phase !! */
1915 /* clear int. */
1918 }
1920 }
1922 /* clear int. */
1930 #if 0
1932 #endif
1934 /* check new bus phase */
1936 /* something happened; disconnect ?? */
1939 }
1941 /* check int. status */
1943 /* disconnect */
1947 /* function done */
1950 }
1952 /* XXX fixme: bail out on stall */
1954 /* we're stuck */
1957 }
1958 }
1961 /* check successful completion ?? */
1966 /* tell do_data_finale how much was transferred */
1969 /* still not completely sure on this one ... */
1972 /*
1973 * end PIO
1974 */
1975 }
1977 }
1979 /* See how successful the data transfer was. */
1982 {
1994 /* Yuck, parity error. The ESP asserts ATN
1995 * so that we can go to message out phase
1996 * immediately and inform the target that
1997 * something bad happened.
1998 */
2003 }
2006 }
2010 /* This could happen for the above parity error case. */
2012 /* Please go to msgout phase, please please please... */
2016 }
2018 /* Check for partial transfers and other horrible events. */
2034 /* If we were in synchronous mode, check for peculiarities. */
2037 else
2040 /* Until we are sure of what has happened, we are certainly
2041 * in the dark.
2042 */
2045 /* Check for premature interrupt condition. Can happen on FAS2x6
2046 * chips. QLogic recommends a workaround by overprogramming the
2047 * transfer counters, but this makes doing scatter-gather impossible.
2048 * Until there is a way to disable scatter-gather for a single target,
2049 * and not only for the entire host adapter as it is now, the workaround
2050 * is way to expensive performance wise.
2051 * Instead, it turns out that when this happens the target has disconnected
2052 * already but it doesn't show in the interrupt register. Compensate for
2053 * that here to try and avoid a SCSI bus reset.
2054 */
2059 #if 0
2060 /* Disable scatter-gather operations, they are not possible
2061 * when using this workaround.
2062 */
2078 }
2079 #else
2080 /* Just set the disconnected bit. That's what appears to
2081 * happen anyway. The state machine will pick it up when
2082 * we return.
2083 */
2085 #endif
2086 }
2089 /* I've seen this happen due to lost state in this
2090 * driver. No idea why it happened, but allowing
2091 * this value to be negative caused things to
2092 * lock up. This allows greater chance of recovery.
2093 * In fact every time I've seen this, it has been
2094 * a driver bug without question.
2095 */
2108 }
2110 /* Update the state of our transfer. */
2114 /* shit */
2117 }
2119 /* Maybe continue. */
2122 /* NO MATTER WHAT, we advance the scatterlist,
2123 * if the target should decide to disconnect
2124 * in between scatter chunks (which is common)
2125 * we could die horribly! I used to have the sg
2126 * advance occur only if we are going back into
2127 * (or are staying in) a data phase, you can
2128 * imagine the hell I went through trying to
2129 * figure this out.
2130 */
2133 #ifdef DEBUG_ESP_DATA
2138 }
2139 #endif
2141 }
2142 /* Bogus data, just wait for next interrupt. */
2146 }
2148 /* We received a non-good status return at the end of
2149 * running a SCSI command. This is used to decide if
2150 * we should clear our synchronous transfer state for
2151 * such a device when that happens.
2152 *
2153 * The idea is that when spinning up a disk or rewinding
2154 * a tape, we don't want to go into a loop re-negotiating
2155 * synchronous capabilities over and over.
2156 */
2158 {
2161 /* These cases are for spinning up a disk and
2162 * waiting for that spinup to complete.
2163 */
2170 /* One more special case for SCSI tape drives,
2171 * this is what is used to probe the device for
2172 * completion of a rewind or tape load operation.
2173 */
2178 }
2180 /* Either a command is completing or a target is dropping off the bus
2181 * to continue the command in the background so we can do other work.
2182 */
2184 {
2195 }
2200 /* Normal end of nexus. */
2208 /* SCSI standard says that the synchronous capabilities
2209 * should be renegotiated at this point. Most likely
2210 * we are about to request sense from this target
2211 * in which case we want to avoid using sync
2212 * transfers until we are sure of the current target
2213 * state.
2214 */
2218 /* But don't do this when spinning up a disk at
2219 * boot time while we poll for completion as it
2220 * fills up the console with messages. Also, tapes
2221 * can report not ready many times right after
2222 * loading up a tape.
2223 */
2226 }
2232 /* Normal disconnect. */
2240 /* Driver bug, we do not expect a disconnect here
2241 * and should not have advanced the state engine
2242 * to in_freeing.
2243 */
2247 }
2249 }
2251 /* When a reselect occurs, and we cannot find the command to
2252 * reconnect to in our queues, we do this.
2253 */
2255 {
2266 }
2273 }
2280 }
2283 }
2285 /* Do the needy when a target tries to reconnect to us. */
2288 {
2292 /* Check for all bogus conditions first. */
2297 }
2302 }
2304 /* Things look ok... */
2319 /* Reconnect implies a restore pointers operation. */
2325 }
2327 /* End of NEXUS (hopefully), pick up status + message byte then leave if
2328 * all goes well.
2329 */
2331 {
2344 /* Ack the message. */
2352 /* ESP chimes in with one of
2353 *
2354 * 1) function done interrupt:
2355 * both status and message in bytes
2356 * are available
2357 *
2358 * 2) bus service interrupt:
2359 * only status byte was acquired
2360 *
2361 * 3) Anything else:
2362 * can't happen, but we test for it
2363 * anyways
2364 *
2365 * ALSO: If bad parity was detected on either
2366 * the status _or_ the message byte then
2367 * the ESP has asserted ATN on the bus
2368 * and we must therefore wait for the
2369 * next phase change.
2370 */
2372 /* We got it all, hallejulia. */
2379 /* There was bad parity for the
2380 * message byte, the status byte
2381 * was ok.
2382 */
2384 }
2386 /* Only got status byte. */
2392 /* The status byte had bad parity.
2393 * we leave the scsi_pointer Status
2394 * field alone as we set it to a default
2395 * of CHECK_CONDITION in esp_queue.
2396 */
2398 }
2400 /* This shouldn't happen ever. */
2404 }
2419 }
2421 /* With luck we'll be able to let the target
2422 * know that bad parity happened, it will know
2423 * which byte caused the problems and send it
2424 * again. For the case where the status byte
2425 * receives bad parity, I do not believe most
2426 * targets recover very well. We'll see.
2427 */
2434 }
2436 /* If we disconnect now, all hell breaks loose. */
2440 }
2441 }
2445 {
2465 }
2468 }
2472 {
2476 /* This means real problems if we see this
2477 * here. Unless we were actually trying
2478 * to force the device to abort/reset.
2479 */
2490 /* We didn't expect this to happen at all. */
2511 };
2513 }
2517 {
2520 }
2524 {
2527 }
2531 {
2534 }
2538 {
2542 }
2556 };
2558 /* The target has control of the bus and we have to see where it has
2559 * taken us.
2560 */
2563 {
2567 }
2569 /* First interrupt after exec'ing a cmd comes here. */
2571 {
2581 /* Let's check to see if a reselect happened
2582 * while we we're trying to select. This must
2583 * be checked first.
2584 */
2588 }
2590 /* Looks like things worked, we should see a bus service &
2591 * a function complete interrupt at this point. Note we
2592 * are doing a direct comparison because we don't want to
2593 * be fooled into thinking selection was successful if
2594 * ESP_INTR_DC is set, see below.
2595 */
2597 /* target speaks... */
2600 /* What if the target ignores the sdtr? */
2604 /* See how far, if at all, we got in getting
2605 * the information out to the target.
2606 */
2611 /* Arbitration won, target selected, but
2612 * we are in some phase which is not command
2613 * phase nor is it message out phase.
2614 *
2615 * XXX We've confused the target, obviously.
2616 * XXX So clear it's state, but we also end
2617 * XXX up clearing everyone elses. That isn't
2618 * XXX so nice. I'd like to just reset this
2619 * XXX target, but if I cannot even get it's
2620 * XXX attention and finish selection to talk
2621 * XXX to it, there is not much more I can do.
2622 * XXX If we have a loaded bus we're going to
2623 * XXX spend the next second or so renegotiating
2624 * XXX for synchronous transfers.
2625 */
2630 /* Arbitration won, target selected, went
2631 * to message out phase, sent one message
2632 * byte, then we stopped. ATN is asserted
2633 * on the SCSI bus and the target is still
2634 * there hanging on. This is a legal
2635 * sequence step if we gave the ESP a select
2636 * and stop command.
2637 *
2638 * XXX See above, I could set the borken flag
2639 * XXX in the device struct and retry the
2640 * XXX command. But would that help for
2641 * XXX tagged capable targets?
2642 */
2645 /* Arbitration won, target selected, maybe
2646 * sent the one message byte in message out
2647 * phase, but we did not go to command phase
2648 * in the end. Actually, we could have sent
2649 * only some of the message bytes if we tried
2650 * to send out the entire identify and tag
2651 * message using ESP_CMD_SA3.
2652 */
2657 /* No, not the powerPC pinhead. Arbitration
2658 * won, all message bytes sent if we went to
2659 * message out phase, went to command phase
2660 * but only part of the command was sent.
2661 *
2662 * XXX I've seen this, but usually in conjunction
2663 * XXX with a gross error which appears to have
2664 * XXX occurred between the time I told the
2665 * XXX ESP to arbitrate and when I got the
2666 * XXX interrupt. Could I have misloaded the
2667 * XXX command bytes into the fifo? Actually,
2668 * XXX I most likely missed a phase, and therefore
2669 * XXX went into never never land and didn't even
2670 * XXX know it. That was the old driver though.
2671 * XXX What is even more peculiar is that the ESP
2672 * XXX showed the proper function complete and
2673 * XXX bus service bits in the interrupt register.
2674 */
2680 /* Account for the identify message */
2683 };
2686 /* Be careful, we could really get fucked during synchronous
2687 * data transfers if we try to flush the fifo now.
2688 */
2690 /* either we are not doing synchronous transfers or... */
2692 /* We are not going into data in phase. */
2696 /* See how far we got if this is not a slow command. */
2701 /* Crapola, mark it as a slowcmd
2702 * so that we have some chance of
2703 * keeping the command alive with
2704 * good luck.
2705 *
2706 * XXX Actually, if we didn't send it all
2707 * XXX this means either we didn't set things
2708 * XXX up properly (driver bug) or the target
2709 * XXX or the ESP detected parity on one of
2710 * XXX the command bytes. This makes much
2711 * XXX more sense, and therefore this code
2712 * XXX should be changed to send out a
2713 * XXX parity error message or if the status
2714 * XXX register shows no parity error then
2715 * XXX just expect the target to bring the
2716 * XXX bus into message in phase so that it
2717 * XXX can send us the parity error message.
2718 * XXX SCSI sucks...
2719 */
2723 }
2724 }
2726 /* Now figure out where we went. */
2729 }
2731 /* Did the target even make it? */
2733 /* wheee... nobody there or they didn't like
2734 * what we told it to do, clean up.
2735 */
2737 /* If anyone is off the bus, but working on
2738 * a command in the background for us, tell
2739 * the ESP to listen for them.
2740 */
2748 /* shit */
2756 /* Run the command again, this time though we
2757 * won't try to negotiate for synchronous transfers.
2758 *
2759 * XXX I'd like to do something like send an
2760 * XXX INITIATOR_ERROR or ABORT message to the
2761 * XXX target to tell it, "Sorry I confused you,
2762 * XXX please come back and I will be nicer next
2763 * XXX time". But that requires having the target
2764 * XXX on the bus, and it has dropped BSY on us.
2765 */
2771 }
2773 /* Ok, this is normal, this is what we see during boot
2774 * or whenever when we are scanning the bus for targets.
2775 * But first make sure that is really what is happening.
2776 */
2781 /* This _CAN_ happen. The SCSI standard states that
2782 * the target is to _not_ respond to selection if
2783 * _it_ detects bad parity on the bus for any reason.
2784 * Therefore, we assume that if we've talked successfully
2785 * to this target before, bad parity is the problem.
2786 */
2789 /* Else, there really isn't anyone there. */
2794 }
2796 }
2819 }
2821 /* Continue reading bytes for msgin phase. */
2823 {
2825 /* in the right phase too? */
2827 /* phew... */
2831 }
2833 /* We changed phase but ESP shows bus service,
2834 * in this case it is most likely that we, the
2835 * hacker who has been up for 20hrs straight
2836 * staring at the screen, drowned in coffee
2837 * smelling like retched cigarette ashes
2838 * have miscoded something..... so, try to
2839 * recover as best we can.
2840 */
2842 }
2845 }
2849 {
2852 /* wheee... */
2862 }
2866 /* We don't want to hear about it. */
2877 /* In this case we might also have to backup the
2878 * "slow command" pointer. It is rare to get such
2879 * a save/restore pointer sequence so early in the
2880 * bus transition sequences, but cover it.
2881 */
2885 }
2895 /* Freeing the bus, let it go. */
2904 /* Doesn't look like this target can
2905 * do synchronous or WIDE transfers.
2906 */
2916 }
2917 };
2918 }
2920 /* Target negotiates for synchronous transfers before we do, this
2921 * is legal although very strange. What is even funnier is that
2922 * the SCSI2 standard specifically recommends against targets doing
2923 * this because so many initiators cannot cope with this occurring.
2924 */
2928 {
2930 /* sorry, no can do */
2938 }
2940 /* Ok, we'll check them out... */
2942 }
2945 {
2959 }
2961 /* Do not transform this back into one big printk
2962 * again, it triggers a bug in our sparc64-gcc272
2963 * sibling call optimization. -DaveM
2964 */
2975 }
2976 }
2980 {
2995 /* Target negotiates first! */
3001 }
3005 /* Offset cannot be larger than ESP fifo size. */
3012 }
3015 /* Yeee, async for this slow device. */
3026 else
3036 regval--;
3037 }
3038 }
3041 unchar bit;
3048 else
3052 else
3056 }
3069 unchar bit;
3071 /* back to async mode */
3082 else
3087 }
3088 }
3101 }
3112 }
3115 }
3118 {
3131 /* We certainly dropped the ball somewhere. */
3138 /* it is ok and we want it */
3142 }
3146 }
3149 }
3162 }
3165 }
3168 }
3169 }
3180 }
3189 }
3192 {
3203 }
3206 {
3211 }
3215 }
3218 {
3237 }
3256 }
3277 }
3281 /* whoops */
3288 }
3291 }
3295 {
3303 /* whoops, parity error */
3320 };
3321 }
3323 /* If we sent out a synchronous negotiation message, update
3324 * our state.
3325 */
3329 }
3335 }
3338 {
3342 }
3345 esp_do_data_finale,
3346 esp_do_data_finale,
3347 esp_bus_unexpected,
3348 esp_do_msgin,
3349 esp_do_msgincont,
3350 esp_do_msgindone,
3351 esp_do_msgout,
3352 esp_do_msgoutdone,
3353 esp_do_cmdbegin,
3354 esp_do_cmddone,
3355 esp_do_status,
3356 esp_do_freebus,
3357 esp_do_phase_determine,
3358 esp_bus_unexpected,
3359 esp_bus_unexpected,
3360 esp_bus_unexpected,
3361 };
3363 /* This is the second tier in our dual-level SCSI state machine. */
3365 {
3373 }
3379 else
3381 }
3384 NULL,
3385 esp_do_phase_determine,
3386 esp_do_resetbus,
3387 esp_finish_reset,
3388 esp_work_bus
3389 };
3391 /* Main interrupt handler for an esp adapter. */
3393 {
3403 /* Check for errors. */
3411 /* Gross error, could be due to one of:
3412 *
3413 * - top of fifo overwritten, could be because
3414 * we tried to do a synchronous transfer with
3415 * an offset greater than ESP fifo size
3416 *
3417 * - top of command register overwritten
3418 *
3419 * - DMA setup to go in one direction, SCSI
3420 * bus points in the other, whoops
3421 *
3422 * - weird phase change during asynchronous
3423 * data phase while we are initiator
3424 */
3427 /* If a command is live on the bus we cannot safely
3428 * reset the bus, so we'll just let the pieces fall
3429 * where they may. Here we are hoping that the
3430 * target will be able to cleanly go away soon
3431 * so we can safely reset things.
3432 */
3438 }
3439 }
3441 /* No current cmd is only valid at this point when there are
3442 * commands off the bus or we are trying a reset.
3443 */
3445 /* Panic is safe, since current_SC is null. */
3448 }
3451 /* Illegal command fed to ESP. Outside of obvious
3452 * software bugs that could cause this, there is
3453 * a condition with ESP100 where we can confuse the
3454 * ESP into an erroneous illegal command interrupt
3455 * because it does not scrape the FIFO properly
3456 * for reselection. See esp100_reconnect_hwbug()
3457 * to see how we try very hard to avoid this.
3458 */
3464 /* Devices with very buggy firmware can drop BSY
3465 * during a scatter list interrupt when using sync
3466 * mode transfers. We continue the transfer as
3467 * expected, the target drops the bus, the ESP
3468 * gets confused, and we get a illegal command
3469 * interrupt because the bus is in the disconnected
3470 * state now and ESP_CMD_TI is only allowed when
3471 * a nexus is alive on the bus.
3472 */
3476 }
3492 }
3497 }
3507 /* This is ok. */
3510 /* Only selection code knows how to clean
3511 * up properly.
3512 */
3519 }
3520 }
3522 /* This is tier-one in our dual level SCSI state machine. */
3523 state_machine:
3529 /* state is completely lost ;-( */
3533 }
3534 }
3537 }
3539 #ifndef CONFIG_SMP
3541 {
3547 /* Handle all ESP interrupts showing at this IRQ level. */
3549 repeat:
3552 #ifndef __mips__
3554 #endif
3565 }
3566 #ifndef __mips__
3567 }
3568 #endif
3569 }
3574 }
3575 #else
3576 /* For SMP we only service one ESP on the list list at our IRQ level! */
3578 {
3583 /* Handle all ESP interrupts showing at this IRQ level. */
3597 }
3598 }
3599 }
3600 out:
3603 }
3604 #endif
3607 {
3616 }
3619 {
3625 }
3627 #ifdef MODULE
3631 {
3632 esps_in_use--;
3634 }
3635 #endif