/* $OpenBSD: mscp_subr.c,v 1.6 2002/11/29 20:15:43 deraadt Exp $ */ /* $NetBSD: mscp_subr.c,v 1.18 2001/11/13 07:38:28 lukem Exp $ */ /* * Copyright (c) 1996 Ludd, University of Lule}, Sweden. * Copyright (c) 1988 Regents of the University of California. * All rights reserved. * * This code is derived from software contributed to Berkeley by * Chris Torek. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Berkeley and its contributors. * 4. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * @(#)mscp.c 7.5 (Berkeley) 12/16/90 */ /* * MSCP generic driver routines */ #include #include #include #include #include #include #include #include #include #include #include #include "ra.h" #include "mt.h" #define b_forw b_hash.le_next int mscp_match(struct device *, struct cfdata *, void *); void mscp_attach(struct device *, struct device *, void *); void mscp_start(struct mscp_softc *); int mscp_init(struct mscp_softc *); void mscp_initds(struct mscp_softc *); int mscp_waitstep(struct mscp_softc *, int, int); struct cfattach mscpbus_ca = { sizeof(struct mscp_softc), (cfmatch_t)mscp_match, mscp_attach }; struct cfdriver mscpbus_cd = { NULL, "mscpbus", DV_DULL }; #define READ_SA (bus_space_read_2(mi->mi_iot, mi->mi_sah, 0)) #define READ_IP (bus_space_read_2(mi->mi_iot, mi->mi_iph, 0)) #define WRITE_IP(x) bus_space_write_2(mi->mi_iot, mi->mi_iph, 0, (x)) #define WRITE_SW(x) bus_space_write_2(mi->mi_iot, mi->mi_swh, 0, (x)) struct mscp slavereply; /* * This function is for delay during init. Some MSCP clone card (Dilog) * can't handle fast read from its registers, and therefore need * a delay between them. */ #define DELAYTEN 1000 int mscp_waitstep(mi, mask, result) struct mscp_softc *mi; int mask, result; { int status = 1; if ((READ_SA & mask) != result) { volatile int count = 0; while ((READ_SA & mask) != result) { DELAY(10000); count += 1; if (count > DELAYTEN) break; } if (count > DELAYTEN) status = 0; } return status; } int mscp_match(parent, match, aux) struct device *parent; struct cfdata *match; void *aux; { struct mscp_attach_args *ma = aux; #if NRA || NRX if (ma->ma_type & MSCPBUS_DISK) return 1; #endif #if NMT if (ma->ma_type & MSCPBUS_TAPE) return 1; #endif return 0; }; void mscp_attach(parent, self, aux) struct device *parent, *self; void *aux; { struct mscp_attach_args *ma = aux; struct mscp_softc *mi = (void *)self; volatile struct mscp *mp; volatile int i; int timeout, next = 0; mi->mi_mc = ma->ma_mc; mi->mi_me = NULL; mi->mi_type = ma->ma_type; mi->mi_uda = ma->ma_uda; mi->mi_dmat = ma->ma_dmat; mi->mi_dmam = ma->ma_dmam; mi->mi_iot = ma->ma_iot; mi->mi_iph = ma->ma_iph; mi->mi_sah = ma->ma_sah; mi->mi_swh = ma->ma_swh; mi->mi_ivec = ma->ma_ivec; mi->mi_adapnr = ma->ma_adapnr; mi->mi_ctlrnr = ma->ma_ctlrnr; *ma->ma_softc = mi; /* * Go out to init the bus, so that we can give commands * to its devices. */ mi->mi_cmd.mri_size = NCMD; mi->mi_cmd.mri_desc = mi->mi_uda->mp_ca.ca_cmddsc; mi->mi_cmd.mri_ring = mi->mi_uda->mp_cmd; mi->mi_rsp.mri_size = NRSP; mi->mi_rsp.mri_desc = mi->mi_uda->mp_ca.ca_rspdsc; mi->mi_rsp.mri_ring = mi->mi_uda->mp_rsp; SIMPLEQ_INIT(&mi->mi_resq); if (mscp_init(mi)) { printf("%s: can't init, controller hung\n", mi->mi_dev.dv_xname); return; } for (i = 0; i < NCMD; i++) { mi->mi_mxiuse |= (1 << i); if (bus_dmamap_create(mi->mi_dmat, (64*1024), 16, (64*1024), 0, BUS_DMA_NOWAIT, &mi->mi_xi[i].mxi_dmam)) { printf("Couldn't alloc dmamap %d\n", i); return; } } #if NRA if (ma->ma_type & MSCPBUS_DISK) { extern struct mscp_device ra_device; mi->mi_me = &ra_device; } #endif #if NMT if (ma->ma_type & MSCPBUS_TAPE) { extern struct mscp_device mt_device; mi->mi_me = &mt_device; } #endif /* * Go out and search for sub-units on this MSCP bus, * and call config_found for each found. */ findunit: mp = mscp_getcp(mi, MSCP_DONTWAIT); if (mp == NULL) panic("mscpattach: no packets"); mp->mscp_opcode = M_OP_GETUNITST; mp->mscp_unit = next; mp->mscp_modifier = M_GUM_NEXTUNIT; *mp->mscp_addr |= MSCP_OWN | MSCP_INT; slavereply.mscp_opcode = 0; i = bus_space_read_2(mi->mi_iot, mi->mi_iph, 0); mp = &slavereply; timeout = 1000; while (timeout-- > 0) { DELAY(10000); if (mp->mscp_opcode) goto gotit; } printf("%s: no response to Get Unit Status request\n", mi->mi_dev.dv_xname); return; gotit: /* * Got a slave response. If the unit is there, use it. */ switch (mp->mscp_status & M_ST_MASK) { case M_ST_SUCCESS: /* worked */ case M_ST_AVAILABLE: /* found another drive */ break; /* use it */ case M_ST_OFFLINE: /* * Figure out why it is off line. It may be because * it is nonexistent, or because it is spun down, or * for some other reason. */ switch (mp->mscp_status & ~M_ST_MASK) { case M_OFFLINE_UNKNOWN: /* * No such drive, and there are none with * higher unit numbers either, if we are * using M_GUM_NEXTUNIT. */ mi->mi_ierr = 3; return; case M_OFFLINE_UNMOUNTED: /* * The drive is not spun up. Use it anyway. * * N.B.: this seems to be a common occurrance * after a power failure. The first attempt * to bring it on line seems to spin it up * (and thus takes several minutes). Perhaps * we should note here that the on-line may * take longer than usual. */ break; default: /* * In service, or something else equally unusable. */ printf("%s: unit %d off line: ", mi->mi_dev.dv_xname, mp->mscp_unit); mscp_printevent((struct mscp *)mp); next++; goto findunit; } break; default: printf("%s: unable to get unit status: ", mi->mi_dev.dv_xname); mscp_printevent((struct mscp *)mp); return; } /* * If we get a lower number, we have circulated around all * devices and are finished, otherwise try to find next unit. * We shouldn't ever get this, it's a workaround. */ if (mp->mscp_unit < next) return; next = mp->mscp_unit + 1; goto findunit; } /* * The ctlr gets initialised, normally after boot but may also be * done if the ctlr gets in an unknown state. Returns 1 if init * fails, 0 otherwise. */ int mscp_init(mi) struct mscp_softc *mi; { struct mscp *mp; volatile int i; int status, count; unsigned int j = 0; /* * While we are thinking about it, reset the next command * and response indicies. */ mi->mi_cmd.mri_next = 0; mi->mi_rsp.mri_next = 0; mi->mi_flags |= MSC_IGNOREINTR; if ((mi->mi_type & MSCPBUS_KDB) == 0) WRITE_IP(0); /* Kick off */; status = mscp_waitstep(mi, MP_STEP1, MP_STEP1);/* Wait to it wakes up */ if (status == 0) return 1; /* Init failed */ if (READ_SA & MP_ERR) { (*mi->mi_mc->mc_saerror)(mi->mi_dev.dv_parent, 0); return 1; } /* step1 */ WRITE_SW(MP_ERR | (NCMDL2 << 11) | (NRSPL2 << 8) | MP_IE | (mi->mi_ivec >> 2)); status = mscp_waitstep(mi, STEP1MASK, STEP1GOOD); if (status == 0) { (*mi->mi_mc->mc_saerror)(mi->mi_dev.dv_parent, 0); return 1; } /* step2 */ WRITE_SW(((mi->mi_dmam->dm_segs[0].ds_addr & 0xffff) + offsetof(struct mscp_pack, mp_ca.ca_rspdsc[0])) | (vax_cputype == VAX_780 || vax_cputype == VAX_8600 ? MP_PI : 0)); status = mscp_waitstep(mi, STEP2MASK, STEP2GOOD(mi->mi_ivec >> 2)); if (status == 0) { (*mi->mi_mc->mc_saerror)(mi->mi_dev.dv_parent, 0); return 1; } /* step3 */ WRITE_SW((mi->mi_dmam->dm_segs[0].ds_addr >> 16)); status = mscp_waitstep(mi, STEP3MASK, STEP3GOOD); if (status == 0) { (*mi->mi_mc->mc_saerror)(mi->mi_dev.dv_parent, 0); return 1; } i = READ_SA & 0377; printf(": version %d model %d\n", i & 15, i >> 4); #define BURST 4 /* XXX */ if (mi->mi_type & MSCPBUS_UDA) { WRITE_SW(MP_GO | (BURST - 1) << 2); printf("%s: DMA burst size set to %d\n", mi->mi_dev.dv_xname, BURST); } WRITE_SW(MP_GO); mscp_initds(mi); mi->mi_flags &= ~MSC_IGNOREINTR; /* * Set up all necessary info in the bus softc struct, get a * mscp packet and set characteristics for this controller. */ mi->mi_credits = MSCP_MINCREDITS + 1; mp = mscp_getcp(mi, MSCP_DONTWAIT); mi->mi_credits = 0; mp->mscp_opcode = M_OP_SETCTLRC; mp->mscp_unit = mp->mscp_modifier = mp->mscp_flags = mp->mscp_sccc.sccc_version = mp->mscp_sccc.sccc_hosttimo = mp->mscp_sccc.sccc_time = mp->mscp_sccc.sccc_time1 = mp->mscp_sccc.sccc_errlgfl = 0; mp->mscp_sccc.sccc_ctlrflags = M_CF_ATTN | M_CF_MISC | M_CF_THIS; *mp->mscp_addr |= MSCP_OWN | MSCP_INT; i = READ_IP; count = 0; while (count < DELAYTEN) { if (((volatile int)mi->mi_flags & MSC_READY) != 0) break; if ((j = READ_SA) & MP_ERR) goto out; DELAY(10000); count += 1; } if (count == DELAYTEN) { out: printf("%s: couldn't set ctlr characteristics, sa=%x\n", mi->mi_dev.dv_xname, j); return 1; } return 0; } /* * Initialise the various data structures that control the mscp protocol. */ void mscp_initds(mi) struct mscp_softc *mi; { struct mscp_pack *ud = mi->mi_uda; struct mscp *mp; int i; for (i = 0, mp = ud->mp_rsp; i < NRSP; i++, mp++) { ud->mp_ca.ca_rspdsc[i] = MSCP_OWN | MSCP_INT | (mi->mi_dmam->dm_segs[0].ds_addr + offsetof(struct mscp_pack, mp_rsp[i].mscp_cmdref)); mp->mscp_addr = &ud->mp_ca.ca_rspdsc[i]; mp->mscp_msglen = MSCP_MSGLEN; } for (i = 0, mp = ud->mp_cmd; i < NCMD; i++, mp++) { ud->mp_ca.ca_cmddsc[i] = MSCP_INT | (mi->mi_dmam->dm_segs[0].ds_addr + offsetof(struct mscp_pack, mp_cmd[i].mscp_cmdref)); mp->mscp_addr = &ud->mp_ca.ca_cmddsc[i]; mp->mscp_msglen = MSCP_MSGLEN; if (mi->mi_type & MSCPBUS_TAPE) mp->mscp_vcid = 1; } } static void mscp_kickaway(struct mscp_softc *); void mscp_intr(mi) struct mscp_softc *mi; { struct mscp_pack *ud = mi->mi_uda; if (mi->mi_flags & MSC_IGNOREINTR) return; /* * Check for response and command ring transitions. */ if (ud->mp_ca.ca_rspint) { ud->mp_ca.ca_rspint = 0; mscp_dorsp(mi); } if (ud->mp_ca.ca_cmdint) { ud->mp_ca.ca_cmdint = 0; MSCP_DOCMD(mi); } /* * If there are any not-yet-handled request, try them now. */ if (SIMPLEQ_FIRST(&mi->mi_resq)) mscp_kickaway(mi); } int mscp_print(aux, name) void *aux; const char *name; { struct drive_attach_args *da = aux; struct mscp *mp = da->da_mp; int type = mp->mscp_guse.guse_mediaid; if (name) { printf("%c%c", MSCP_MID_CHAR(2, type), MSCP_MID_CHAR(1, type)); if (MSCP_MID_ECH(0, type)) printf("%c", MSCP_MID_CHAR(0, type)); printf("%d at %s drive %d", MSCP_MID_NUM(type), name, mp->mscp_unit); } return UNCONF; } /* * common strategy routine for all types of MSCP devices. */ void mscp_strategy(bp, usc) struct buf *bp; struct device *usc; { struct mscp_softc *mi = (void *)usc; int s = splimp(); /* SIMPLEQ_INSERT_TAIL(&mi->mi_resq, bp, xxx) */ bp->b_actf = NULL; *mi->mi_resq.sqh_last = bp; mi->mi_resq.sqh_last = &bp->b_actf; mscp_kickaway(mi); splx(s); } void mscp_kickaway(mi) struct mscp_softc *mi; { struct buf *bp; struct mscp *mp; int next; while ((bp = SIMPLEQ_FIRST(&mi->mi_resq))) { /* * Ok; we are ready to try to start a xfer. Get a MSCP packet * and try to start... */ if ((mp = mscp_getcp(mi, MSCP_DONTWAIT)) == NULL) { if (mi->mi_credits > MSCP_MINCREDITS) printf("%s: command ring too small\n", mi->mi_dev.dv_parent->dv_xname); /* * By some (strange) reason we didn't get a MSCP packet. * Just return and wait for free packets. */ return; } if ((next = (ffs(mi->mi_mxiuse) - 1)) < 0) panic("no mxi buffers"); mi->mi_mxiuse &= ~(1 << next); if (mi->mi_xi[next].mxi_inuse) panic("mxi inuse"); /* * Set up the MSCP packet and ask the ctlr to start. */ mp->mscp_opcode = (bp->b_flags & B_READ) ? M_OP_READ : M_OP_WRITE; mp->mscp_cmdref = next; mi->mi_xi[next].mxi_bp = bp; mi->mi_xi[next].mxi_mp = mp; mi->mi_xi[next].mxi_inuse = 1; bp->b_resid = next; (*mi->mi_me->me_fillin)(bp, mp); (*mi->mi_mc->mc_go)(mi->mi_dev.dv_parent, &mi->mi_xi[next]); if ((mi->mi_resq.sqh_first = bp->b_actf) == NULL) mi->mi_resq.sqh_last = &mi->mi_resq.sqh_first; #if 0 mi->mi_w = bp->b_actf; #endif } } void mscp_dgo(mi, mxi) struct mscp_softc *mi; struct mscp_xi *mxi; { volatile int i; struct mscp *mp; /* * Fill in the MSCP packet and move the buffer to the I/O wait queue. */ mp = mxi->mxi_mp; mp->mscp_seq.seq_buffer = mxi->mxi_dmam->dm_segs[0].ds_addr; *mp->mscp_addr |= MSCP_OWN | MSCP_INT; i = READ_IP; } #ifdef DIAGNOSTIC /* * Dump the entire contents of an MSCP packet in hex. Mainly useful * for debugging.... */ void mscp_hexdump(mp) struct mscp *mp; { long *p = (long *) mp; int i = mp->mscp_msglen; if (i > 256) /* sanity */ i = 256; i /= sizeof (*p); /* ASSUMES MULTIPLE OF sizeof(long) */ while (--i >= 0) printf("0x%x ", (int)*p++); printf("\n"); } #endif /* * MSCP error reporting */ /* * Messages for the various subcodes. */ static char unknown_msg[] = "unknown subcode"; /* * Subcodes for Success (0) */ static char *succ_msgs[] = { "normal", /* 0 */ "spin down ignored", /* 1 = Spin-Down Ignored */ "still connected", /* 2 = Still Connected */ unknown_msg, "dup. unit #", /* 4 = Duplicate Unit Number */ unknown_msg, unknown_msg, unknown_msg, "already online", /* 8 = Already Online */ unknown_msg, unknown_msg, unknown_msg, unknown_msg, unknown_msg, unknown_msg, unknown_msg, "still online", /* 16 = Still Online */ }; /* * Subcodes for Invalid Command (1) */ static char *icmd_msgs[] = { "invalid msg length", /* 0 = Invalid Message Length */ }; /* * Subcodes for Command Aborted (2) */ /* none known */ /* * Subcodes for Unit Offline (3) */ static char *offl_msgs[] = { "unknown drive", /* 0 = Unknown, or online to other ctlr */ "not mounted", /* 1 = Unmounted, or RUN/STOP at STOP */ "inoperative", /* 2 = Unit Inoperative */ unknown_msg, "duplicate", /* 4 = Duplicate Unit Number */ unknown_msg, unknown_msg, unknown_msg, "in diagnosis", /* 8 = Disabled by FS or diagnostic */ }; /* * Subcodes for Unit Available (4) */ /* none known */ /* * Subcodes for Media Format Error (5) */ static char *media_fmt_msgs[] = { "fct unread - edc", /* 0 = FCT unreadable */ "invalid sector header",/* 1 = Invalid Sector Header */ "not 512 sectors", /* 2 = Not 512 Byte Sectors */ "not formatted", /* 3 = Not Formatted */ "fct ecc", /* 4 = FCT ECC */ }; /* * Subcodes for Write Protected (6) * N.B.: Code 6 subcodes are 7 bits higher than other subcodes * (i.e., bits 12-15). */ static char *wrprot_msgs[] = { unknown_msg, "software", /* 1 = Software Write Protect */ "hardware", /* 2 = Hardware Write Protect */ }; /* * Subcodes for Compare Error (7) */ /* none known */ /* * Subcodes for Data Error (8) */ static char *data_msgs[] = { "forced error", /* 0 = Forced Error (software) */ unknown_msg, "header compare", /* 2 = Header Compare Error */ "sync timeout", /* 3 = Sync Timeout Error */ unknown_msg, unknown_msg, unknown_msg, "uncorrectable ecc", /* 7 = Uncorrectable ECC */ "1 symbol ecc", /* 8 = 1 bit ECC */ "2 symbol ecc", /* 9 = 2 bit ECC */ "3 symbol ecc", /* 10 = 3 bit ECC */ "4 symbol ecc", /* 11 = 4 bit ECC */ "5 symbol ecc", /* 12 = 5 bit ECC */ "6 symbol ecc", /* 13 = 6 bit ECC */ "7 symbol ecc", /* 14 = 7 bit ECC */ "8 symbol ecc", /* 15 = 8 bit ECC */ }; /* * Subcodes for Host Buffer Access Error (9) */ static char *host_buffer_msgs[] = { unknown_msg, "odd xfer addr", /* 1 = Odd Transfer Address */ "odd xfer count", /* 2 = Odd Transfer Count */ "non-exist. memory", /* 3 = Non-Existent Memory */ "memory parity", /* 4 = Memory Parity Error */ }; /* * Subcodes for Controller Error (10) */ static char *cntlr_msgs[] = { unknown_msg, "serdes overrun", /* 1 = Serialiser/Deserialiser Overrun */ "edc", /* 2 = Error Detection Code? */ "inconsistent internal data struct",/* 3 = Internal Error */ }; /* * Subcodes for Drive Error (11) */ static char *drive_msgs[] = { unknown_msg, "sdi command timeout", /* 1 = SDI Command Timeout */ "ctlr detected protocol",/* 2 = Controller Detected Protocol Error */ "positioner", /* 3 = Positioner Error */ "lost rd/wr ready", /* 4 = Lost R/W Ready Error */ "drive clock dropout", /* 5 = Lost Drive Clock */ "lost recvr ready", /* 6 = Lost Receiver Ready */ "drive detected error", /* 7 = Drive Error */ "ctlr detected pulse or parity",/* 8 = Pulse or Parity Error */ }; /* * The following table correlates message codes with the * decoding strings. */ struct code_decode { char *cdc_msg; int cdc_nsubcodes; char **cdc_submsgs; } code_decode[] = { #define SC(m) sizeof (m) / sizeof (m[0]), m {"success", SC(succ_msgs)}, {"invalid command", SC(icmd_msgs)}, {"command aborted", 0, 0}, {"unit offline", SC(offl_msgs)}, {"unit available", 0, 0}, {"media format error", SC(media_fmt_msgs)}, {"write protected", SC(wrprot_msgs)}, {"compare error", 0, 0}, {"data error", SC(data_msgs)}, {"host buffer access error", SC(host_buffer_msgs)}, {"controller error", SC(cntlr_msgs)}, {"drive error", SC(drive_msgs)}, #undef SC }; /* * Print the decoded error event from an MSCP error datagram. */ void mscp_printevent(mp) struct mscp *mp; { int event = mp->mscp_event; struct code_decode *cdc; int c, sc; char *cm, *scm; /* * The code is the lower six bits of the event number (aka * status). If that is 6 (write protect), the subcode is in * bits 12-15; otherwise, it is in bits 5-11. * I WONDER WHAT THE OTHER BITS ARE FOR. IT SURE WOULD BE * NICE IF DEC SOLD DOCUMENTATION FOR THEIR OWN CONTROLLERS. */ c = event & M_ST_MASK; sc = (c != 6 ? event >> 5 : event >> 12) & 0x7ff; if (c >= sizeof code_decode / sizeof code_decode[0]) cm = "- unknown code", scm = "??"; else { cdc = &code_decode[c]; cm = cdc->cdc_msg; if (sc >= cdc->cdc_nsubcodes) scm = unknown_msg; else scm = cdc->cdc_submsgs[sc]; } printf(" %s (%s) (code %d, subcode %d)\n", cm, scm, c, sc); } static char *codemsg[16] = { "lbn", "code 1", "code 2", "code 3", "code 4", "code 5", "rbn", "code 7", "code 8", "code 9", "code 10", "code 11", "code 12", "code 13", "code 14", "code 15" }; /* * Print the code and logical block number for an error packet. * THIS IS PROBABLY PECULIAR TO DISK DRIVES. IT SURE WOULD BE * NICE IF DEC SOLD DOCUMENTATION FOR THEIR OWN CONTROLLERS. */ int mscp_decodeerror(name, mp, mi) char *name; struct mscp *mp; struct mscp_softc *mi; { int issoft; /* * We will get three sdi errors of type 11 after autoconfig * is finished; depending of searching for non-existing units. * How can we avoid this??? */ if (((mp->mscp_event & M_ST_MASK) == 11) && (mi->mi_ierr++ < 3)) return 1; /* * For bad blocks, mp->mscp_erd.erd_hdr identifies a code and * the logical block number. Code 0 is a regular block; code 6 * is a replacement block. The remaining codes are currently * undefined. The code is in the upper four bits of the header * (bits 0-27 are the lbn). */ issoft = mp->mscp_flags & (M_LF_SUCC | M_LF_CONT); #define BADCODE(h) (codemsg[(unsigned)(h) >> 28]) #define BADLBN(h) ((h) & 0xfffffff) printf("%s: drive %d %s error datagram%s:", name, mp->mscp_unit, issoft ? "soft" : "hard", mp->mscp_flags & M_LF_CONT ? " (continuing)" : ""); switch (mp->mscp_format & 0377) { case M_FM_CTLRERR: /* controller error */ break; case M_FM_BUSADDR: /* host memory access error */ printf(" memory addr 0x%x:", (int)mp->mscp_erd.erd_busaddr); break; case M_FM_DISKTRN: printf(" unit %d: level %d retry %d, %s %d:", mp->mscp_unit, mp->mscp_erd.erd_level, mp->mscp_erd.erd_retry, BADCODE(mp->mscp_erd.erd_hdr), (int)BADLBN(mp->mscp_erd.erd_hdr)); break; case M_FM_SDI: printf(" unit %d: %s %d:", mp->mscp_unit, BADCODE(mp->mscp_erd.erd_hdr), (int)BADLBN(mp->mscp_erd.erd_hdr)); break; case M_FM_SMLDSK: printf(" unit %d: small disk error, cyl %d:", mp->mscp_unit, mp->mscp_erd.erd_sdecyl); break; case M_FM_TAPETRN: printf(" unit %d: tape transfer error, grp 0x%x event 0%o:", mp->mscp_unit, mp->mscp_erd.erd_sdecyl, mp->mscp_event); break; case M_FM_STIERR: printf(" unit %d: STI error, event 0%o:", mp->mscp_unit, mp->mscp_event); break; default: printf(" unit %d: unknown error, format 0x%x:", mp->mscp_unit, mp->mscp_format); } mscp_printevent(mp); return 0; #undef BADCODE #undef BADLBN }