#include "all.h" #define SCSInone SCSIread #define MAXDRIVE 10 #define MAXSIDE 500 #define TWORM MINUTE(10) #define THYSTER SECOND(10) typedef struct Side Side; struct Side { QLock; /* protects loading/unloading */ int elem; /* element number */ int drive; /* if loaded, where */ uchar status; /* Sunload, etc */ uchar rot; /* if backside */ int ord; /* ordinal number for labeling */ Timet time; /* time since last access, to unspin */ Timet stime; /* time since last spinup, for hysteresis */ long nblock; /* number of native blocks */ long block; /* bytes per native block */ long mult; /* multiplier to get plan9 blocks */ long max; /* max size in plan9 blocks */ }; typedef struct Juke Juke; struct Juke { QLock; /* protects drive mechanism */ Side side[MAXSIDE]; int nside; /* how many storage elements (*2 if rev) */ int ndrive; /* number of transfer elements */ Device* juke; /* devworm of changer */ Device* drive[MAXDRIVE]; /* devworm for i/o */ uchar offline[MAXDRIVE]; /* drives removed from service */ long fixedsize; /* one size fits all */ int probeok; /* wait for init to probe */ /* * geometry returned by mode sense. * a *0 number (such as mt0) is the `element number' of the * first element of that type (e.g., mt, or motor transport). * an n* number is the quantity of them. */ int mt0, nmt; /* motor transports (robot pickers) */ int se0, nse; /* storage elements (discs, slots) */ int ie0, nie; /* interchange elements (mailbox slots) */ int dt0, ndt; /* drives (data transfer?) */ int rot; /* if true, discs are double-sided */ Juke* link; }; static Juke* jukelist; enum { Sempty = 0, /* does not exist */ Sunload, /* on the shelf */ Sstart, /* loaded and spinning */ }; extern int FIXEDSIZE; static int wormsense(Device*); static Side* wormunit(Device*); static void shelves(void); static int mmove(Juke*, int, int, int, int); static int bestdrive(Juke*, int); static void waitready(Device*); static void element(Juke*, int); /* * mounts and spins up the device * locks the structure */ static Side* wormunit(Device *d) { int p, s, drive; Side *v; Juke *w; uchar cmd[10], buf[8]; w = d->private; p = d->wren.targ; if(p < 0 || p >= w->nside) { // panic("wormunit partition %Z\n", d); return 0; } /* * if disk is unloaded, must load it * into next (circular) logical unit */ v = &w->side[p]; qlock(v); if(v->status == Sunload) { for(;;) { qlock(w); drive = bestdrive(w, p); if(drive >= 0) break; qunlock(w); waitsec(100); } print(" load r%ld drive %Z\n", v-w->side, w->drive[drive]); if(mmove(w, w->mt0, v->elem, w->dt0+drive, v->rot)) { qunlock(w); goto sbad; } v->drive = drive; v->status = Sstart; v->stime = toytime(); qunlock(w); waitready(w->drive[drive]); v->stime = toytime(); } if(v->status != Sstart) { if(v->status == Sempty) print("worm: unit empty %Z\n", d); else print("worm: not started %Z\n", d); goto sbad; } v->time = toytime(); if(v->block) return v; /* * capacity command */ memset(cmd, 0, sizeof(cmd)); memset(buf, 0, sizeof(buf)); cmd[0] = 0x25; /* read capacity */ s = scsiio(w->drive[v->drive], SCSIread, cmd, sizeof(cmd), buf, sizeof(buf)); if(s) goto sbad; v->nblock = (buf[0]<<24) | (buf[1]<<16) | (buf[2]<<8) | (buf[3]<<0); v->block = (buf[4]<<24) | (buf[5]<<16) | (buf[6]<<8) | (buf[7]<<0); v->mult = (RBUFSIZE + v->block - 1) / v->block; v->max = (v->nblock + 1) / v->mult; print(" worm %Z: drive %Z\n", d, w->drive[v->drive]); print(" %ld blocks at %ld bytes each\n", v->nblock, v->block); print(" %ld logical blocks at %d bytes each\n", v->max, RBUFSIZE); print(" %ld multiplier\n", v->mult); if(d->type != Devlworm) return v; /* check for label */ print("label %Z ordinal %d\n", d, v->ord); qunlock(v); return wormunit(d); sbad: qunlock(v); // panic("wormunit sbad"); return 0; } static void waitready(Device *d) { uchar cmd[6]; int s, e; for(e=0;e<100;e++) { memset(cmd, 0, sizeof(cmd)); s = scsiio(d, SCSInone, cmd, sizeof(cmd), cmd, 0); if(s == 0) break; waitsec(100); } } static int bestdrive(Juke *w, int side) { Side *v, *bv[MAXDRIVE]; int i, s, e, drive; Timet t, t0; loop: /* build table of what platters on what drives */ for(i=0; indt; i++) bv[i] = 0; v = &w->side[0]; for(i=0; inside; i++, v++) { s = v->status; if(s == Sstart) { drive = v->drive; if(drive >= 0 && drive < w->ndt) bv[drive] = v; } } /* * find oldest drive, but must be * at least THYSTER old. */ e = w->side[side].elem; t0 = toytime() - THYSTER; t = t0; drive = -1; for(i=0; indt; i++) { v = bv[i]; if(v == 0) { /* 2nd priority: empty drive */ if(w->offline[i]) continue; if(w->drive[i] != devnone) { drive = i; t = 0; } continue; } if(v->elem == e) { /* 1st priority: other side */ drive = -1; if(v->stime < t0) drive = i; break; } if(v->stime < t) { /* 3rd priority: by time */ drive = i; t = v->stime; } } if(drive >= 0) { v = bv[drive]; if(v) { qlock(v); if(v->status != Sstart) { qunlock(v); goto loop; } print(" unload r%ld drive %Z\n", v-w->side, w->drive[drive]); if(mmove(w, w->mt0, w->dt0+drive, v->elem, v->rot)) { qunlock(v); goto loop; } v->status = Sunload; qunlock(v); } } return drive; } Devsize wormsize(Device *d) { Side *v; Juke *w; Devsize size; w = d->private; if(w->fixedsize) size = w->fixedsize; else { v = wormunit(d); if(v == 0) return 0; size = v->max; qunlock(v); if(FIXEDSIZE) // TODO? push FIXEDSIZE into Device or Juke struct w->fixedsize = size; } if(d->type == Devlworm) return size-1; return size; } /* * return a Devjuke or an mcat (normally of sides) from within d (or nil). * if it's an mcat, the caller must walk it. */ static Device * devtojuke(Device *d, Device *top) { while (d != nil) switch(d->type) { default: print("devtojuke: type of device %Z of %Z unknown\n", d, top); return nil; case Devjuke: /* jackpot! d->private is a (Juke *) with nside, &c. */ /* FALL THROUGH */ case Devmcat: case Devmlev: case Devmirr: /* squint hard & call an mlev or a mirr an mcat */ return d; case Devworm: case Devlworm: /* * d->private is a (Juke *) with nside, etc., * but we're not supposed to get here. */ print("devtojuke: (l)worm %Z of %Z encountered\n", d, top); /* FALL THROUGH */ case Devwren: case Devide: return nil; case Devcw: d = d->cw.w; /* usually juke */ break; case Devro: d = d->ro.parent; /* cw */ break; case Devfworm: d = d->fw.fw; break; case Devpart: d = d->part.d; break; case Devswab: d = d->swab.d; break; } return d; } static int devisside(Device *d) { return d->type == Devworm || d->type == Devlworm; } static Device * findside(Device *juke, int side, Device *top) { int i = 0; Device *mcat = juke->j.m, *x; Juke *w = juke->private; for (x = mcat->cat.first; x != nil; x = x->link) { if (!devisside(x)) { print("wormsizeside: %Z of %Z of %Z type not (l)worm\n", x, mcat, top); return nil; } i = x->wren.targ; if (i < 0 || i >= w->nside) panic("wormsizeside: side %d in %Z out of range", i, mcat); if (i == side) break; } if (x == nil) return nil; if (w->side[i].time == 0) { print("wormsizeside: side %d not in jukebox %Z\n", i, juke); return nil; } return x; } typedef struct { int sleft; /* sides still to visit to reach desired side */ int starget; /* side of topdev we want */ Device *topdev; int sawjuke; /* passed by a jukebox */ int sized; /* flag: asked wormsize for size of starget */ } Visit; /* * walk the Device tree from d looking for Devjukes, counting sides. * the main complication is mcats and the like with Devjukes in them. * use Devjuke's d->private as Juke* and see sides. */ static Off visitsides(Device *d, Device *parentj, Visit *vp) { Off size = 0; Device *x; Juke *w; /* * find the first juke or mcat. * d==nil means we couldn't find one; typically harmless, due to a * mirror of dissimilar devices. */ d = devtojuke(d, vp->topdev); if (d == nil || vp->sleft < 0) return 0; if (d->type == Devjuke) { /* jackpot! d->private is a (Juke *) */ vp->sawjuke = 1; w = d->private; /* * if there aren't enough sides in this jukebox to reach * the desired one, subtract these sides and pass. */ if (vp->sleft >= w->nside) { vp->sleft -= w->nside; return 0; } /* else this is the right juke, paw through mcat of sides */ return visitsides(d->j.m, d, vp); } /* * d will usually be an mcat of sides, but it could be an mcat of * jukes, for example. in that case, we need to walk the mcat, * recursing as needed, until we find the right juke, then stop at * the right side within its mcat of sides, by comparing side * numbers, not just by counting (to allow for unused slots). */ x = d->cat.first; if (x == nil) { print("visitsides: %Z of %Z: empty mcat\n", d, vp->topdev); return 0; } if (!devisside(x)) { for (; x != nil && !vp->sized; x = x->link) size = visitsides(x, parentj, vp); return size; } /* the side we want is in this jukebox, thus this mcat (d) */ if (parentj == nil) { print("visitsides: no parent juke for sides mcat %Z\n", d); vp->sleft = -1; return 0; } if (d != parentj->j.m) panic("visitsides: mcat mismatch %Z vs %Z", d, parentj->j.m); x = findside(parentj, vp->sleft, vp->topdev); if (x == nil) { vp->sleft = -1; return 0; } /* we've turned vp->starget into the right Device* */ vp->sleft = 0; vp->sized = 1; return wormsize(x); } /* * d must be, or be within, a filesystem config that also contains * the jukebox that `side' resides on. * d is normally a Devcw, but could be Devwren, Devide, Devpart, Devfworm, * etc. if called from chk.c Ctouch code. Note too that the worm part of * the Devcw might be other than a Devjuke. */ Devsize wormsizeside(Device *d, int side) { Devsize size; Visit visit; memset(&visit, 0, sizeof visit); visit.starget = visit.sleft = side; visit.topdev = d; size = visitsides(d, nil, &visit); if (visit.sawjuke && (visit.sleft != 0 || !visit.sized)) { print("wormsizeside: fewer than %d sides in %Z\n", side, d); return 0; } return size; } /* * returns starts (in blocks) of side #side and #(side+1) of dev in *stp. * dev should be a Devcw. */ void wormsidestarts(Device *dev, int side, Sidestarts *stp) { int s; Devsize dstart; for (dstart = s = 0; s < side; s++) dstart += wormsizeside(dev, s); stp->sstart = dstart; stp->s1start = dstart + wormsizeside(dev, side); } static int wormiocmd(Device *d, int io, Off b, void *c) { Side *v; Juke *w; Off l; int s; long m; uchar cmd[10]; w = d->private; v = wormunit(d); if(v == 0) return 0x71; if(b >= v->max) { qunlock(v); print("worm: wormiocmd out of range %Z(%lld)\n", d, (Wideoff)b); return 0x071; } memset(cmd, 0, sizeof(cmd)); cmd[0] = 0x28; /* extended read */ if(io != SCSIread) cmd[0] = 0x2a; /* extended write */ m = v->mult; l = b * m; cmd[2] = l>>24; cmd[3] = l>>16; cmd[4] = l>>8; cmd[5] = l; cmd[7] = m>>8; cmd[8] = m; s = scsiio(w->drive[v->drive], io, cmd, sizeof(cmd), c, RBUFSIZE); qunlock(v); return s; } int wormread(Device *d, Off b, void *c) { int s; s = wormiocmd(d, SCSIread, b, c); if(s) { print("wormread: %Z(%lld) bad status #%x\n", d, (Wideoff)b, s); cons.nwormre++; return s; } return 0; } int wormwrite(Device *d, Off b, void *c) { int s; s = wormiocmd(d, SCSIwrite, b, c); if(s) { print("wormwrite: %Z(%lld) bad status #%x\n", d, (Wideoff)b, s); cons.nwormwe++; return s; } return 0; } static int mmove(Juke *w, int trans, int from, int to, int rot) { uchar cmd[12], buf[4]; int s; static recur = 0; memset(cmd, 0, sizeof(cmd)); cmd[0] = 0xa5; /* move medium */ cmd[2] = trans>>8; cmd[3] = trans; cmd[4] = from>>8; cmd[5] = from; cmd[6] = to>>8; cmd[7] = to; if(rot) cmd[10] = 1; s = scsiio(w->juke, SCSInone, cmd, sizeof(cmd), buf, 0); if(s) { print("scsio status #%x\n", s); print("move medium t=%d fr=%d to=%d rot=%d\n", trans, from, to, rot); // panic("mmove"); if(recur == 0) { recur = 1; print("element from=%d\n", from); element(w, from); print("element to=%d\n", to); element(w, to); print("element trans=%d\n", trans); element(w, trans); recur = 0; } return 1; } return 0; } static void geometry(Juke *w) { int s; uchar cmd[6], buf[4+20]; memset(cmd, 0, sizeof(cmd)); memset(buf, 0, sizeof(buf)); cmd[0] = 0x1a; /* mode sense */ cmd[2] = 0x1d; /* element address assignment */ cmd[4] = sizeof(buf); /* allocation length */ s = scsiio(w->juke, SCSIread, cmd, sizeof(cmd), buf, sizeof(buf)); if(s) panic("geometry #%x\n", s); w->mt0 = (buf[4+2]<<8) | buf[4+3]; w->nmt = (buf[4+4]<<8) | buf[4+5]; w->se0 = (buf[4+6]<<8) | buf[4+7]; w->nse = (buf[4+8]<<8) | buf[4+9]; w->ie0 = (buf[4+10]<<8) | buf[4+11]; w->nie = (buf[4+12]<<8) | buf[4+13]; w->dt0 = (buf[4+14]<<8) | buf[4+15]; w->ndt = (buf[4+16]<<8) | buf[4+17]; memset(cmd, 0, 6); memset(buf, 0, sizeof(buf)); cmd[0] = 0x1a; /* mode sense */ cmd[2] = 0x1e; /* transport geometry */ cmd[4] = sizeof(buf); /* allocation length */ s = scsiio(w->juke, SCSIread, cmd, sizeof(cmd), buf, sizeof(buf)); if(s) panic("geometry #%x\n", s); w->rot = buf[4+2] & 1; print(" mt %d %d\n", w->mt0, w->nmt); print(" se %d %d\n", w->se0, w->nse); print(" ie %d %d\n", w->ie0, w->nie); print(" dt %d %d\n", w->dt0, w->ndt); print(" rot %d\n", w->rot); prflush(); } static void element(Juke *w, int e) { uchar cmd[12], buf[8+8+88]; int s, t; memset(cmd, 0, sizeof(cmd)); memset(buf, 0, sizeof(buf)); cmd[0] = 0xb8; /* read element status */ cmd[2] = e>>8; /* starting element */ cmd[3] = e; cmd[5] = 1; /* number of elements */ cmd[9] = sizeof(buf); /* allocation length */ s = scsiio(w->juke, SCSIread, cmd, sizeof(cmd), buf, sizeof(buf)); if(s) { print("scsiio #%x\n", s); goto bad; } s = (buf[0]<<8) | buf[1]; if(s != e) { print("element = %d\n", s); goto bad; } if(buf[3] != 1) { print("number reported = %d\n", buf[3]); goto bad; } s = (buf[8+8+0]<<8) | buf[8+8+1]; if(s != e) { print("element1 = %d\n", s); goto bad; } switch(buf[8+0]) { /* element type */ default: print("unknown element %d: %d\n", e, buf[8+0]); goto bad; case 1: /* transport */ s = e - w->mt0; if(s < 0 || s >= w->nmt) goto bad; if(buf[8+8+2] & 1) print("transport %d full %d.%d\n", s, (buf[8+8+10]<<8) | buf[8+8+11], (buf[8+8+9]>>6) & 1); break; case 2: /* storage */ s = e - w->se0; if(s < 0 || s >= w->nse) goto bad; w->side[s].status = Sempty; if(buf[8+8+2] & 1) w->side[s].status = Sunload; if(w->rot) w->side[w->nse+s].status = w->side[s].status; break; case 3: /* import/export */ s = e - w->ie0; if(s < 0 || s >= w->nie) goto bad; print("import/export %d #%.2x %d.%d\n", s, buf[8+8+2], (buf[8+8+10]<<8) | buf[8+8+11], (buf[8+8+9]>>6) & 1); break; case 4: /* data transfer */ s = e - w->dt0; if(s < 0 || s >= w->ndt) goto bad; print("data transfer %d #%.2x %d.%d\n", s, buf[8+8+2], (buf[8+8+10]<<8) | buf[8+8+11], (buf[8+8+9]>>6) & 1); if(buf[8+8+2] & 1) { t = ((buf[8+8+10]<<8) | buf[8+8+11]) - w->se0; if (t < 0 || t >= w->nse || t >= MAXSIDE || s >= MAXDRIVE) { print( "element: juke %Z lies; claims side %d is in drive %d\n", w->juke, t, s); /* lying sack of ... */ /* * at minimum, we've avoided corrupting our * data structures. if we know that numbers * like w->nside are valid here, we could use * them in more stringent tests. * perhaps should whack the jukebox upside the * head here to knock some sense into it. */ goto bad; } print("r%d in drive %d\n", t, s); if(mmove(w, w->mt0, w->dt0+s, w->se0+t, (buf[8+8+9]>>6) & 1)) { print("mmove initial unload\n"); goto bad; } w->side[t].status = Sunload; if(w->rot) w->side[w->nse+t].status = Sunload; } if(buf[8+8+2] & 4) { print("drive w%d has exception #%.2x #%.2x\n", s, buf[8+8+4], buf[8+8+5]); goto bad; } break; } return; bad: /* panic("element") */ ; } static void positions(Juke *w) { int i, f; /* mark empty shelves */ for(i=0; inse; i++) element(w, w->se0+i); for(i=0; inmt; i++) element(w, w->mt0+i); for(i=0; inie; i++) element(w, w->ie0+i); for(i=0; indt; i++) element(w, w->dt0+i); f = 0; for(i=0; inse; i++) { if(w->side[i].status == Sempty) { if(f) { print("r%d\n", i-1); f = 0; } } else { if(!f) { print(" shelves r%d-", i); f = 1; } } } if(f) print("r%d\n", i-1); } static void jinit(Juke *w, Device *d, int o) { int p; Device *dev = d; switch(d->type) { default: print("juke platter not (devmcat of) dev(l)worm: %Z\n", d); panic("jinit: type"); case Devmcat: /* * we don't call mcatinit(d) here, so we have to set d->cat.ndev * ourselves. */ for(d=d->cat.first; d; d=d->link) jinit(w, d, o++); dev->cat.ndev = o; break; case Devlworm: p = d->wren.targ; if(p < 0 || p >= w->nside) panic("jinit partition %Z\n", d); w->side[p].ord = o; case Devworm: if(d->private) { print("juke platter private pointer set %p\n", d->private); panic("jinit: private"); } d->private = w; break; } } Side* wormi(char *arg) { int i, j; Juke *w; Side *v; i = number(arg, -1, 10) - 1; w = jukelist; if(i < 0 || i >= w->nside) { print("bad unit number %s (%d)\n", arg, i+1); return 0; } j = i; if(j >= w->nse) j -= w->nse; if(j < w->nside) { v = &w->side[j]; qlock(v); if(v->status == Sstart) { if(mmove(w, w->mt0, w->dt0+v->drive, v->elem, v->rot)) { qunlock(v); return 0; } v->status = Sunload; } qunlock(v); } j += w->nse; if(j < w->nside) { v = &w->side[j]; qlock(v); if(v->status == Sstart) { if(mmove(w, w->mt0, w->dt0+v->drive, v->elem, v->rot)) { qunlock(v); return 0; } v->status = Sunload; } qunlock(v); } v = &w->side[i]; qlock(v); return v; } static void cmd_wormoffline(int argc, char *argv[]) { int u, i; Juke *w; if(argc <= 1) { print("usage: wormoffline drive\n"); return; } u = number(argv[1], -1, 10); w = jukelist; if(u < 0 || u >= w->ndrive) { print("bad drive %s (0<=%d<%d)\n", argv[1], u, w->ndrive); return; } if(w->offline[u]) print("drive %d already offline\n", u); w->offline[u] = 1; for(i=0; indrive; i++) if(w->offline[i] == 0) return; print("that would take all drives offline\n"); w->offline[u] = 0; } static void cmd_wormonline(int argc, char *argv[]) { int u; Juke *w; if(argc <= 1) { print("usage: wormonline drive\n"); return; } u = number(argv[1], -1, 10); w = jukelist; if(u < 0 || u >= w->ndrive) { print("bad drive %s (0<=%d<%d)\n", argv[1], u, w->ndrive); return; } if(w->offline[u] == 0) print("drive %d already online\n", u); w->offline[u] = 0; } static void cmd_wormreset(int, char *[]) { Juke *w; for(w=jukelist; w; w=w->link) { qlock(w); positions(w); qunlock(w); } } static void cmd_wormeject(int argc, char *argv[]) { Juke *w; Side *v; if(argc <= 1) { print("usage: wormeject unit\n"); return; } v = wormi(argv[1]); if(v == 0) return; w = jukelist; mmove(w, w->mt0, v->elem, w->ie0, 0); qunlock(v); } static void cmd_wormingest(int argc, char *argv[]) { Juke *w; Side *v; if(argc <= 1) { print("usage: wormingest unit\n"); return; } v = wormi(argv[1]); if(v == 0) return; w = jukelist; mmove(w, w->mt0, w->ie0, v->elem, 0); qunlock(v); } void jukeinit(Device *d) { Juke *w; Device *xdev; Side *v; int i; /* j(ww...)(r) */ xdev = d->j.j; if(xdev->type != Devmcat) { print("juke union not mcat\n"); goto bad; } /* * pick up the changer device */ xdev = xdev->cat.first; if(xdev->type != Devwren) { print("juke changer not wren %Z\n", xdev); goto bad; } for(w=jukelist; w; w=w->link) if(xdev == w->juke) goto found; /* * allocate a juke structure * no locking problems. */ w = ialloc(sizeof(Juke), 0); w->link = jukelist; jukelist = w; print("alloc juke %Z\n", xdev); qlock(w); qunlock(w); w->name = "juke"; w->juke = xdev; geometry(w); /* * pick up each side */ w->nside = w->nse; if(w->rot) w->nside += w->nside; if(w->nside > MAXSIDE) { print("too many sides: %d max %d\n", w->nside, MAXSIDE); goto bad; } for(i=0; inse; i++) { v = &w->side[i]; qlock(v); qunlock(v); v->name = "shelf"; v->elem = w->se0 + i; v->rot = 0; v->status = Sempty; v->time = toytime(); if(w->rot) { v += w->nse; qlock(v); qunlock(v); v->name = "shelf"; v->elem = w->se0 + i; v->rot = 1; v->status = Sempty; v->time = toytime(); } } positions(w); w->ndrive = w->ndt; if(w->ndrive > MAXDRIVE) { print("ndrives truncated to %d\n", MAXDRIVE); w->ndrive = MAXDRIVE; } /* * pick up each drive */ for(i=0; indrive; i++) w->drive[i] = devnone; cmd_install("wormreset", "-- put drives back where jukebox thinks they belong", cmd_wormreset); cmd_install("wormeject", "unit -- shelf to outside", cmd_wormeject); cmd_install("wormingest", "unit -- outside to shelf", cmd_wormingest); cmd_install("wormoffline", "unit -- disable drive", cmd_wormoffline); cmd_install("wormonline", "unit -- enable drive", cmd_wormonline); found: i = 0; while(xdev = xdev->link) { if(xdev->type != Devwren) { print("drive not devwren: %Z\n", xdev); goto bad; } if(w->drive[i]->type != Devnone && xdev != w->drive[i]) { print("double init drive %d %Z %Z\n", i, w->drive[i], xdev); goto bad; } if(i >= w->ndrive) { print("too many drives %Z\n", xdev); goto bad; } w->drive[i++] = xdev; } if(i <= 0) { print("no drives\n"); goto bad; } /* * put w pointer in each platter */ d->private = w; jinit(w, d->j.m, 0); w->probeok = 1; return; bad: panic("juke init"); } /* * called periodically */ void wormprobe(void) { int i, drive; Timet t; Side *v; Juke *w; t = toytime() - TWORM; for(w=jukelist; w; w=w->link) { if(w->probeok == 0 || !canqlock(w)) continue; for(i=0; inside; i++) { v = &w->side[i]; if(!canqlock(v)) continue; if(v->status == Sstart && t > v->time) { drive = v->drive; print(" time r%ld drive %Z\n", v-w->side, w->drive[drive]); mmove(w, w->mt0, w->dt0+drive, v->elem, v->rot); v->status = Sunload; } qunlock(v); } qunlock(w); } }