/* $OpenBSD: bioctl.c,v 1.9 2005/04/12 20:49:19 marco Exp $ */ /* * Copyright (c) 2004, 2005 Marco Peereboom * All rights reserved. * * 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. * * THIS SOFTWARE IS PROVIDED BY THE AUTHORS 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 AUTHORS 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. * */ #include #include #include #include #include #include #include #include #include #include #include #include #include "bioctl.h" /* globals */ const char *bio_device = "/dev/bio"; SLIST_HEAD(dev_list, dev); /* RAID card device list */ struct dev_list devices = SLIST_HEAD_INITIALIZER(dev); /* User provided device list*/ struct dev_list ul = SLIST_HEAD_INITIALIZER(dev); int devh = -1; int debug = 0; struct bio_locate bl; int main(int argc, char *argv[]) { extern char *optarg; bioc_capabilities bc; bioc_alarm ba; int ch; int rv; unsigned char *pl; char *bioc_dev = NULL; char *al_arg = NULL; /* argument to alarm */ char *ss_arg = NULL; /* argument to start/stop */ char inq[INQSIZE]; struct dev *delm; u_int64_t func = 0, subfunc = 0; u_int32_t devlist = 0; if (argc < 2) usage(); atexit(cleanup); while ((ch = getopt(argc, argv, "a:b:Dd:ehl:pst:u:")) != -1) { switch (ch) { case 'a': /* alarm */ func |= BIOC_ALARM; al_arg = optarg; break; case 'b': /* LED blink/unblink */ func |= BIOC_BLINK; al_arg = optarg; break; case 'D': /* enable debug */ debug = 1; break; case 'd': /* device */ bioc_dev = optarg; break; case 'e': /* enumerate */ func |= BIOC_SCSICMD; subfunc |= F_ENUM; break; case 'l': /* device list, separated for now use one dev only*/ func |= PARSELIST; pl = optarg; break; case 'p': /* ping */ func |= BIOC_PING; break; case 's': /* status */ func |= BIOC_STATUS; break; case 't': func |= BIOC_SCSICMD; subfunc |= parse_passthru(optarg); break; case 'u': /* start/stop */ func |= BIOC_STARTSTOP; ss_arg = optarg; break; case 'h': /* help/usage */ /* FALLTHROUGH */ default: usage(); /* NOTREACHED */ } } devh = open(bio_device, O_RDWR); if (devh == -1) err(1, "Can't open %s", bio_device); bl.name = bioc_dev; rv = ioctl(devh, BIOCLOCATE, &bl); if (rv == -1) errx(1, "Can't locate %s device via %s", bl.name, bio_device); if (debug) warnx("cookie = %p", bl.cookie); if (func & PARSELIST) parse_devlist(pl); if (!bio_get_capabilities(&bc)) warnx("could not retrieve capabilities."); else { /* we should have everything setup by now so get to work */ if (func & BIOC_ALARM) if (bc.ioctls & BIOC_ALARM) bio_alarm(al_arg); else warnx("alarms are not supported."); if (func & BIOC_BLINK) if (bc.ioctls & BIOC_BLINK) SLIST_FOREACH(delm, &ul, next) { bio_blink(al_arg, delm->channel, delm->target); } else warnx("blink is not supported."); if (func & BIOC_PING) if (bc.ioctls & BIOC_PING) bio_ping(); else warnx("ping not supported."); if (func & BIOC_STATUS) { if (bc.ioctls & BIOC_STATUS) bio_status(); else warnx("status function not supported."); } if (func & BIOC_STARTSTOP) { if (bc.ioctls & BIOC_STARTSTOP) { SLIST_FOREACH(delm, &ul, next) { bio_startstop(ss_arg, delm->channel, delm->target); } } else warnx("start/stop unit not supported."); } if (func & BIOC_SCSICMD) { if (bc.ioctls & BIOC_SCSICMD) { if (subfunc & F_READCAP) { SLIST_FOREACH(delm, &ul, next) { bio_pt_readcap(delm->channel, delm->target, F_NOISY); } } if (subfunc & F_INQUIRY) { SLIST_FOREACH(delm, &ul, next) { bio_pt_inquire(delm->channel, delm->target, F_NOISY, &inq[0]); } } if (subfunc & F_TUR) { SLIST_FOREACH(delm, &ul, next) { bio_pt_tur(delm->channel, delm->target); } } if (subfunc & F_ENUM) bio_pt_enum(); } else warnx("passthrough not supported."); } } return (0); } void usage(void) { extern char *__progname; fprintf(stderr, "usage: %s [-Dehpt] " "[-a alarm function] " "[-b blink function] " "[-s get status] " "[-t passthrough] " "[-l device list] " "[-u go/stop function ] " "-d raid device\n", __progname); exit(1); } void cleanup(void) { struct dev *delm; if (debug) printf("atexit\n"); while (devices.slh_first != NULL) { delm = devices.slh_first; SLIST_REMOVE_HEAD(&devices, next); if (debug) printf("free device: %p\n", delm); free(delm); } while (ul.slh_first != NULL) { delm = ul.slh_first; SLIST_REMOVE_HEAD(&ul, next); if (debug) printf("free ul: %p\n", delm); free(delm); } if (devh != -1) close(devh); } u_int64_t parse_passthru(char *f) { if (debug) printf("get_subfunc: %s, ", f); switch (f[0]) { case 'i': /* INQUIRY */ if (debug) printf("inquiry\n"); return (F_INQUIRY); case 'e': /* ENUMERATE, not a pass through hmmm */ if (debug) printf("enumerate\n"); return (F_ENUM); case 'r': /* READ CAPACITY */ if (debug) printf("read cap\n"); return (F_READCAP); case 't': /* TUR */ if (debug) printf("TUR\n"); return (F_TUR); default: errx(1, "invalid pass through function"); } } void parse_devlist(char *dl) { u_int8_t c , t, done = 0; char *es, *s; struct dev *delm; es = NULL; s = dl; if (debug) printf("parse: %s\n", dl); while (!done) { c = strtol(s, &es, 10); if (debug) printf("%p %p %u %c\n", s, es, c, es[0]); s = es; if (es[0] == ':') { s++; t = strtol(s, &es, 10); if (debug) printf("%p %p %u %c\n", s, es, t, es[0]); s = es; if (c > 4) errx(1, "invalid channel number"); if (t > 16) errx(1, "invalid target number"); delm = malloc(sizeof(struct dev)); if (!delm) errx(1, "not enough memory"); delm->target = t; delm->channel = c; SLIST_INSERT_HEAD(&ul, delm, next); } if (es[0] == ',') { s++; continue; } if (es[0] == '\0') { done = 1; continue; } done = 2; } if (done == 2) { /* boink */ errx(1, "invalid device list."); } } int bio_get_capabilities(bioc_capabilities *bc) { int rv; bc->cookie = bl.cookie; rv = ioctl(devh, BIOCCAPABILITIES, bc); if (rv == -1) { warnx("Error calling bioc_ioctl() via bio_ioctl()"); return 0; } if (debug) { printf("ioctls = %016llx\n", bc->ioctls); printf("raid_types = %08lx\n", bc->raid_types); } return (1); } void bio_alarm(char *arg) { int rv; bioc_alarm ba; if (debug) printf("alarm in: %s, ", arg); ba.cookie = bl.cookie; switch (arg[0]) { case 'q': /* silence alarm */ /* FALLTHROUGH */ case 's': if (debug) printf("silence\n"); ba.opcode = BIOCSALARM_SILENCE; break; case 'e': /* enable alarm */ if (debug) printf("enable\n"); ba.opcode = BIOCSALARM_ENABLE; break; case 'd': /* disable alarm */ if (debug) printf("disable\n"); ba.opcode = BIOCSALARM_DISABLE; break; case 't': /* test alarm */ if (debug) printf("test\n"); ba.opcode = BIOCSALARM_TEST; break; case 'g': /* get alarm state */ if (debug) printf("get state\n"); ba.opcode = BIOCGALARM_STATE; break; default: warnx("invalid alarm function: %s", arg); return; } rv = ioctl(devh, BIOCALARM, &ba); if (rv == -1) { warnx("bioc_ioctl() call failed"); return; } if (arg[0] == 'g') { printf("alarm is currently %s\n", ba.state ? "enabled" : "disabled"); } } void ses_verbose(u_int8_t *rc, u_int8_t len) { struct ses_config_page *scp; struct ses_type_desc_hdr *tdh; char *str; u_int8_t i; scp = (struct ses_config_page *)rc; printf("element types: %d, id: %s\n", scp->nr_elem_typ, scp->enc_vendor_id); str = (char *) (&scp->enc_desc_len + scp->enc_desc_len + 1 + (scp->nr_elem_typ * sizeof(struct ses_type_desc_hdr))); for (i = 0; i < scp->nr_elem_typ; i++) { tdh = (struct ses_type_desc_hdr *) (&scp->enc_desc_len + scp->enc_desc_len + 1 + (i * sizeof(struct ses_type_desc_hdr))); printf("type: %d, count: %d, sub enclosure id: %d, " "len: %d, text: %s\n", tdh->elem_type, tdh->nr_elem, tdh->sub_enc_id, tdh->type_desc_len, str); str += tdh->type_desc_len; } } void bio_blink_userland(u_int8_t opc, u_int8_t c, u_int8_t t) { struct dev *delm; /* page 1 stuff */ struct ses_enc_ctrl_diag_page *cdp; struct ses_config_page *scp; struct ses_type_desc_hdr *tdh; /* page 2 stuff */ struct ses_enc_stat_diag_page *esdp; struct ses_dev_elmt_status_diag *desd; u_int8_t rc[SESSIZE]; u_int8_t rc2[SESSIZE]; u_int8_t i, elements, found = 0; /* FIXME if the raid controllers are clustered we might have more * than one proc device. */ bio_pt_enum(); SLIST_FOREACH(delm, &devices, next) { if (delm->channel != c) continue; if (delm->type != T_PROCESSOR) continue; if (debug) printf("proc at channel: %d target: %2d\n", delm->channel, delm->target); /* figure out what we have */ if (!get_ses_page(delm->channel, delm->target, SES_CFG_DIAG_PAGE, &rc[0], sizeof(rc))) { return; } if (debug) ses_verbose(&rc[0], sizeof(rc)); /* find first disk element */ elements = 0; scp = (struct ses_config_page *)rc; for (i = 0; i < scp->nr_elem_typ; i++) { tdh = (struct ses_type_desc_hdr *) (&scp->enc_desc_len + scp->enc_desc_len + 1 + (i * sizeof(struct ses_type_desc_hdr))); if (tdh->elem_type == STDH_DEVICE) { found = 1; break; } elements += tdh->nr_elem; } if (debug) { printf("tdh->elem_type: %d, tdh->nr_elem: %d, " "elements: %d\n", tdh->elem_type, tdh->nr_elem, elements); } if (!found) { if (debug) printf("no devices found\n"); return; } /* get ses page so that we can modify bits for blink */ if (!get_ses_page(delm->channel, delm->target, SES_CTRL_DIAG_PAGE, &rc2[0], sizeof(rc2))) { return; } esdp = (struct ses_enc_stat_diag_page *)rc2; desd = (struct ses_dev_elmt_status_diag *) (esdp->elmts + elements); /* FIXME do we need padding? */ /* loop through all slots to see if target is available */ found = 0; for (i = 0; i < tdh->nr_elem; i++) { if (debug) printf("stat: %d, addr: %d, b3: %d, b4: %d\n", desd->common_status, desd->slot_addr, desd->byte3, desd->byte4); if (t == desd->slot_addr) { found = 1; break; } desd += 1; /* next element */ } if (!found) { printf("target: %d not found\n", t); return; } cdp = (struct ses_enc_ctrl_diag_page *)rc2; cdp->elmts[i].common_ctrl = SDECD_SELECT; switch (opc) { case BIOCSBLINK_ALERT: cdp->elmts[i].byte4 = SDECD_RQST_FAULT; cdp->elmts[i].byte3 = 0x00; break; case BIOCSBLINK_BLINK: cdp->elmts[i].byte3 = SDECD_RQST_IDENT; cdp->elmts[i].byte4 = 0x00; break; case BIOCSBLINK_UNBLINK: cdp->elmts[i].byte3 = 0x00; cdp->elmts[i].byte4 = 0x00; break; default: return; } if (!set_ses_page(delm->channel, delm->target, &rc2[0], sizeof(rc2))) { return; } return; /* done */ } } void bio_blink(char * arg, u_int8_t c, u_int8_t t) { int rv; bioc_blink bb; if (debug) printf("blink in: %s, ", arg); bb.cookie = bl.cookie; switch (arg[0]) { case 'a': /* blink amber or alert led */ if (debug) printf("blink alert\n"); bb.opcode = BIOCSBLINK_ALERT; break; case 'b': /* blink hdd */ if (debug) printf("blink\n"); bb.opcode = BIOCSBLINK_BLINK; break; case 'u': /* unblink hdd */ if (debug) printf("unblink\n"); bb.opcode = BIOCSBLINK_UNBLINK; break; default: warnx("invalid blink function: %s", arg); return; } rv = ioctl(devh, BIOCBLINK, &bb); if (rv == -1) { if (errno == EOPNOTSUPP) { /* operation is not supported in kernel, do it here */ if (debug) printf("doing blink in userland\n"); bio_blink_userland(bb.opcode, c, t); } else warnx("bioc_ioctl() call failed"); } } void bio_ping(void) { int rv; bioc_ping bp; bp.cookie = bl.cookie; bp.x = 0; rv = ioctl(devh, BIOCPING, &bp); if (rv == -1) { warnx("Error calling bioc_ioctl() via bio_ioctl()"); return; } printf("x after ioctl() = %i\n", bp.x); } void bio_startstop(char *arg, u_int8_t c, u_int8_t t) { int rv; bioc_startstop bs; if (debug) printf("startstop in: %s, ", arg); bs.cookie = bl.cookie; switch (arg[0]) { case 's': /* stop unit */ if (debug) printf("stop\n"); bs.opcode = BIOCSUNIT_STOP; break; case 'g': /* start or go unit */ if (debug) printf("start\n"); bs.opcode = BIOCSUNIT_START; break; default: warnx("invalid start/stop function: %s", arg); return; } bs.channel = c; bs.target = t; rv = ioctl(devh, BIOCSTARTSTOP, &bs); if (rv == -1) { warnx("bioc_ioctl() call failed"); return; } if (debug) printf("startstop done\n"); } /* get status, for now only do all */ void bio_status(void) { int rv; bioc_status bs; if (debug) printf("status()\n"); bs.cookie = bl.cookie; bs.opcode = BIOCGSTAT_ALL; rv = ioctl(devh, BIOCSTATUS, &bs); if (rv == -1) { warnx("bioc_ioctl() call failed"); return; } if (debug) printf("status done\n"); } /* read capacity for disk c,t */ u_int64_t bio_pt_readcap(u_int8_t c, u_int8_t t, u_int8_t flags) { bioc_scsicmd bpt; struct read_cap rc; int rv; u_int64_t size; memset(&bpt, 0, sizeof(bpt)); bpt.cookie = bl.cookie; bpt.channel = c; bpt.target = t; bpt.cdblen = 10; bpt.cdb[0] = READ_CAPACITY; bpt.data = &rc; /* set up return data pointer */ bpt.datalen = sizeof(rc); bpt.direction = BIOC_DIRIN; bpt.senselen = 32; /* silly since the kernel overrides it */ rv = ioctl(devh, BIOCSCSICMD, &bpt); if (rv == -1) { warnx("READ CAPACITY failed %x", bpt.status); return (0); } else if (bpt.status) { if (bpt.sensebuf[0] == 0x70 || bpt.sensebuf[0] == 0x71) print_sense(&bpt.sensebuf[0], bpt.senselen); else printf("channel: %d target: %2d READ CAPACITY failed " "without sense data\n", c, t); return (0); } rc.maxlba = betoh32(rc.maxlba); rc.bsize = betoh32(rc.bsize); size = (u_int64_t)rc.maxlba * (u_int64_t)rc.bsize; if (debug) printf("\nREAD CAPACITY: %lu * %lu = %llu\n", rc.maxlba, rc.bsize, size); if (flags & F_NOISY) { printf("channel: %d target: %2d READ CAPACITY %llu", c, t, size); print_cap(size); printf("\n"); } return (size); } /* inquire device */ u_int32_t bio_pt_inquire(u_int8_t c, u_int8_t t, u_int8_t flags, u_int8_t *inq) { bioc_scsicmd bpt; int rv, i; memset(&bpt, 0, sizeof(bpt)); bpt.cookie = bl.cookie; bpt.channel = c; bpt.target = t; bpt.cdblen = 6; bpt.cdb[0] = INQUIRY; bpt.cdb[4] = INQSIZE; /* LENGTH */ bpt.data = inq; /* set up return data pointer */ bpt.datalen = INQSIZE; /* minimum INQ size */ bpt.direction = BIOC_DIRIN; bpt.senselen = 32; /* silly since the kernel overrides it */ rv = ioctl(devh, BIOCSCSICMD, &bpt); if (rv == -1) { warnx("INQUIRY failed %x", bpt.status); return 0; } else if (bpt.status) { if (bpt.sensebuf[0] == 0x70 || bpt.sensebuf[0] == 0x71) print_sense(&bpt.sensebuf[0], bpt.senselen); else if (flags & F_NOISY) printf("device %d:%d did not respond to " "INQUIRY command\n", c, t); return 0; } printf("channel: %u target: %2u ", c, t); print_inquiry(flags, inq, bpt.datalen); if (flags & F_NOISY) printf("\n"); return 1; } /* TUR for disk c,t */ u_int32_t bio_pt_tur(u_int8_t c, u_int8_t t) { bioc_scsicmd bpt; int rv; if (debug) printf("tur\n"); memset(&bpt, 0, sizeof(bpt)); bpt.cookie = bl.cookie; bpt.channel = c; bpt.target = t; bpt.cdblen = 6; bpt.cdb[0] = TEST_UNIT_READY; bpt.direction = BIOC_DIRNONE; rv = ioctl(devh, BIOCSCSICMD, &bpt); if (rv == -1) { warnx("passthrough failed"); return (0); } if (bpt.status) { if (bpt.sensebuf[0] == 0x70 || bpt.sensebuf[0] == 0x71) print_sense(&bpt.sensebuf[0], bpt.senselen); else printf("channel: %d target: %2d: TUR failed without " "sense data\n", c, t); return (0); } printf("channel: %d target: %2d: TUR completed\n", c, t); return (1); } /* enumerate all disks */ void bio_pt_enum(void) { bioc_scsicmd bpt; u_int32_t c, t, i, d; int rv; u_int8_t inq[INQSIZE]; struct dev *delm; d = 0; for (c = 0; c < 4 /* FIXME */; c++) { for (t = 0; t < 16 /* FIXME */; t++) { if (bio_pt_inquire(c, t, F_SILENCE, &inq[0])) { if (inq[0] & SID_QUAL) continue; /* invalid device */ delm = malloc(sizeof(struct dev)); if (delm == NULL) errx(1, "not enough memory"); delm->id = d++; delm->target = t; delm->channel = c; delm->type = inq[0]; if (delm->type == T_DIRECT) { /* FIXME check the return value */ delm->capacity = bio_pt_readcap( delm->channel, delm->target, F_SILENCE); print_cap(delm->capacity); } printf("\n"); SLIST_INSERT_HEAD(&devices, delm, next); } } /* for t */ } /* for c */ } /* printf sense data */ void print_sense(u_int8_t *sensebuf, u_int8_t sensebuflen) { u_int8_t i; if (debug) printf("print_sense() %p, %u\n", sensebuf, sensebuflen); for (i = 0; i < sensebuflen; i++) { printf("%02x ", sensebuf[i]); } printf("\n"); /* FIXME add some pretty decoding here */ } void print_inquiry(u_int8_t flags, u_int8_t *inq, u_int8_t inqlen) { u_int8_t i; if (inqlen < INQSIZE) { /* INQUIRY shall return at least 36 bytes */ printf("invalid INQUIRY buffer size\n"); return; } if (SID_QUAL & inq[0]) { printf("invalid device\n"); return; } switch (SID_TYPE & inq[0]) { case T_DIRECT: printf("disk "); break; case T_PROCESSOR: printf("proc "); break; default: printf("unsuported device type\n"); return; } for (i = 0; i < inqlen; i++) { if (i < 8) { if ((flags & F_NOISY) || debug) printf("%02x ", inq[i]); } else printf("%c", inq[i] < ' ' ? ' ' : inq[i]); } } void print_cap(u_int64_t cap) { if (cap / S_TERA > 1) { printf(" %3llu TB", cap / S_TERA); return; } if (cap / S_GIGA > 1) { printf(" %3llu GB", cap / S_GIGA); return; } if (cap / S_MEGA > 1) { printf(" %3llu MB", cap / S_MEGA); return; } if (cap / S_KILO > 1) { printf(" %3llu MB", cap / S_KILO); return; } printf(" %llu B", cap); } #if 0 /* in case we want to do SAFTE this is the format */ /* SAF-TE */ memset(&bpt, 0, sizeof(bpt)); bpt.cookie = bl.cookie; bpt.channel = delm->channel; bpt.target = delm->target; bpt.cdblen = 10; bpt.cdb[0] = 0x3c; /* READ BUFFER */ bpt.cdb[1] = 0x01; /* SAF-TE command */ bpt.cdb[8] = sizeof(rc); /* LSB size, FIXME */ bpt.data = &rc[0]; /* set up return data pointer */ bpt.datalen = sizeof(rc); bpt.direction = BIOC_DIRIN; bpt.senselen = 32; /* silly since the kernel overrides it */ #endif int get_ses_page(u_int8_t c, u_int8_t t, u_int8_t p, u_int8_t *buf, u_int8_t buflen) { bioc_scsicmd bpt; int rv; memset(&bpt, 0, sizeof(bpt)); bpt.cookie = bl.cookie; bpt.channel = c; bpt.target = t; bpt.cdblen = 6; bpt.cdb[0] = RECEIVE_DIAGNOSTIC; /* FIXME add this cdb struct + #defines to scsi_all.h */ bpt.cdb[1] = 0x01; /* set PCV bit for SES commands */ bpt.cdb[2] = p; /* SES page nr */ bpt.cdb[4] = buflen; bpt.data = buf; /* set up return data pointer */ bpt.datalen = buflen; bpt.direction = BIOC_DIRIN; bpt.senselen = 32; /* silly since the kernel overrides it */ rv = ioctl(devh, BIOCSCSICMD, &bpt); if (rv == -1) { warnx("RECEIVE_DIAGNOSTIC failed %x", bpt.status); return (0); } else if (bpt.status) { if (bpt.sensebuf[0] == 0x70 || bpt.sensebuf[0] == 0x71) print_sense(&bpt.sensebuf[0], bpt.senselen); else printf("channel: %d target: %2d RECEIVE_DIAGNOSTIC " "failed without sense data\n", c, t); return (0); } if (debug) { /* abuse print sense a little */ print_sense(buf, bpt.datalen); } return (1); } int set_ses_page(u_int8_t c, u_int8_t t, u_int8_t *buf, u_int8_t buflen) { bioc_scsicmd bpt; int rv; memset(&bpt, 0, sizeof(bpt)); bpt.cookie = bl.cookie; bpt.channel = c; bpt.target = t; bpt.cdblen = 6; bpt.cdb[0] = SEND_DIAGNOSTIC; bpt.cdb[1] = SSD_PF; bpt.cdb[4] = buflen; bpt.data = buf; /* set up return data pointer */ bpt.datalen = buflen; bpt.direction = BIOC_DIROUT; bpt.senselen = 32; /* silly since the kernel overrides it */ rv = ioctl(devh, BIOCSCSICMD, &bpt); if (rv == -1) { warnx("SEND_DIAGNOSTIC failed %x", bpt.status); return (0); } else if (bpt.status) { if (bpt.sensebuf[0] == 0x70 || bpt.sensebuf[0] == 0x71) print_sense(&bpt.sensebuf[0], bpt.senselen); else printf("channel: %d target: %2d SEND_DIAGNOSTIC " "failed without sense data\n", c, t); return (0); } if (debug) { /* abuse print sense a little */ print_sense(buf, bpt.datalen); } return (1); }