/* * This file is part of the UCB release of Plan 9. It is subject to the license * terms in the LICENSE file found in the top-level directory of this * distribution and at http://akaros.cs.berkeley.edu/files/Plan9License. No * part of the UCB release of Plan 9, including this file, may be copied, * modified, propagated, or distributed except according to the terms contained * in the LICENSE file. */ /* * USB device driver framework. * * This is in charge of providing access to actual HCIs * and providing I/O to the various endpoints of devices. * A separate user program (usbd) is in charge of * enumerating the bus, setting up endpoints and * starting devices (also user programs). * * The interface provided is a violation of the standard: * you're welcome. * * The interface consists of a root directory with several files * plus a directory (epN.M) with two files per endpoint. * A device is represented by its first endpoint, which * is a control endpoint automatically allocated for each device. * Device control endpoints may be used to create new endpoints. * Devices corresponding to hubs may also allocate new devices, * perhaps also hubs. Initially, a hub device is allocated for * each controller present, to represent its root hub. Those can * never be removed. * * All endpoints refer to the first endpoint (epN.0) of the device, * which keeps per-device information, and also to the HCI used * to reach them. Although all endpoints cache that information. * * epN.M/data files permit I/O and are considered DMEXCL. * epN.M/ctl files provide status info and accept control requests. * * Endpoints may be given file names to be listed also at #u, * for those drivers that have nothing to do after configuring the * device and its endpoints. * * Drivers for different controllers are kept at usb[oue]hci.c * It's likely we could factor out much from controllers into * a generic controller driver, the problem is that details * regarding how to handle toggles, tokens, Tds, etc. will * get in the way. Thus, code is probably easier the way it is. */ #include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "io.h" #include "../port/error.h" #include "../port/usb.h" typedef struct Hcitype Hcitype; enum { /* Qid numbers */ Qdir = 0, /* #u */ Qusbdir, /* #u/usb */ Qctl, /* #u/usb/ctl - control requests */ Qep0dir, /* #u/usb/ep0.0 - endpoint 0 dir */ Qep0io, /* #u/usb/ep0.0/data - endpoint 0 I/O */ Qep0ctl, /* #u/usb/ep0.0/ctl - endpoint 0 ctl. */ Qep0dummy, /* give 4 qids to each endpoint */ Qepdir = 0, /* (qid-qep0dir)&3 is one of these */ Qepio, /* to identify which file for the endpoint */ Qepctl, /* ... */ /* Usb ctls. */ CMdebug = 0, /* debug on|off */ CMdump, /* dump (data structures for debug) */ /* Ep. ctls */ CMnew = 0, /* new nb ctl|bulk|intr|iso r|w|rw (endpoint) */ CMnewdev, /* newdev full|low|high portnb (allocate new devices) */ CMhub, /* hub (set the device as a hub) */ CMspeed, /* speed full|low|high|no */ CMmaxpkt, /* maxpkt size */ CMntds, /* ntds nb (max nb. of tds per µframe) */ CMclrhalt, /* clrhalt (halt was cleared on endpoint) */ CMpollival, /* pollival interval (interrupt/iso) */ CMhz, /* hz n (samples/sec; iso) */ CMsamplesz, /* samplesz n (sample size; iso) */ CMinfo, /* info infostr (ke.ep info for humans) */ CMdetach, /* detach (abort I/O forever on this ep). */ CMaddress, /* address (address is assigned) */ CMdebugep, /* debug n (set/clear debug for this ep) */ CMname, /* name str (show up as #u/name as well) */ CMtmout, /* timeout n (activate timeouts for ep) */ CMpreset, /* reset the port */ /* Hub feature selectors */ Rportenable = 1, Rportreset = 4, }; struct Hcitype { char* type; int (*reset)(Hci*); }; #define QID(q) ((int)(q).path) static char Edetach[] = "device is detached"; static char Enotconf[] = "endpoint not configured"; char Estalled[] = "endpoint stalled"; static Cmdtab usbctls[] = { {CMdebug, "debug", 2}, {CMdump, "dump", 1}, }; static Cmdtab epctls[] = { {CMnew, "new", 4}, {CMnewdev, "newdev", 3}, {CMhub, "hub", 1}, {CMspeed, "speed", 2}, {CMmaxpkt, "maxpkt", 2}, {CMntds, "ntds", 2}, {CMpollival, "pollival", 2}, {CMsamplesz, "samplesz", 2}, {CMhz, "hz", 2}, {CMinfo, "info", 0}, {CMdetach, "detach", 1}, {CMaddress, "address", 1}, {CMdebugep, "debug", 2}, {CMclrhalt, "clrhalt", 1}, {CMname, "name", 2}, {CMtmout, "timeout", 2}, {CMpreset, "reset", 1}, }; static Dirtab usbdir[] = { {"ctl", {Qctl}, 0, 0666}, }; char *usbmodename[] = { [OREAD] = "r", [OWRITE] = "w", [ORDWR] = "rw", }; static char *ttname[] = { [Tnone] = "none", [Tctl] = "control", [Tiso] = "iso", [Tintr] = "interrupt", [Tbulk] = "bulk", }; static char *spname[] = { [Fullspeed] = "full", [Lowspeed] = "low", [Highspeed] = "high", [Nospeed] = "no", }; static int debug; static Hcitype hcitypes[Nhcis]; static Hci* hcis[Nhcis]; static QLock epslck; /* add, del, lookup endpoints */ static Ep* eps[Neps]; /* all endpoints known */ static int epmax; /* 1 + last endpoint index used */ static int usbidgen; /* device address generator */ /* * Is there something like this in a library? should it be? */ char* seprintdata(char *s, char *se, unsigned char *d, int n) { int i, l; s = seprint(s, se, " %#p[%d]: ", d, n); l = n; if(l > 10) l = 10; for(i=0; i= epmax || eps[q] == nil) return -1; return q; } static int isqtype(int q, int type) { if(q < Qep0dir) return 0; q -= Qep0dir; return (q & 3) == type; } void addhcitype(char* t, int (*r)(Hci*)) { static int ntype; if(ntype == Nhcis) panic("too many USB host interface types"); hcitypes[ntype].type = t; hcitypes[ntype].reset = r; ntype++; } static char* seprintep(char *s, char *se, Ep *ep, int all) { Proc *up = externup(); static char* dsnames[] = { "config", "enabled", "detached", "reset" }; Udev *d; int i; int di; d = ep->dev; qlock(&ep->ql); if(waserror()){ qunlock(&ep->ql); nexterror(); } di = ep->dev->nb; if(all) s = seprint(s, se, "dev %d ep %d ", di, ep->nb); s = seprint(s, se, "%s", dsnames[ep->dev->state]); s = seprint(s, se, " %s", ttname[ep->ttype]); assert(ep->mode == OREAD || ep->mode == OWRITE || ep->mode == ORDWR); s = seprint(s, se, " %s", usbmodename[ep->mode]); s = seprint(s, se, " speed %s", spname[d->speed]); s = seprint(s, se, " maxpkt %ld", ep->maxpkt); s = seprint(s, se, " pollival %ld", ep->pollival); s = seprint(s, se, " samplesz %ld", ep->samplesz); s = seprint(s, se, " hz %ld", ep->hz); s = seprint(s, se, " hub %d", ep->dev->hub); s = seprint(s, se, " port %d", ep->dev->port); if(ep->inuse) s = seprint(s, se, " busy"); else s = seprint(s, se, " idle"); if(all){ s = seprint(s, se, " load %lu", ep->load); s = seprint(s, se, " ref %ld addr %#p", ep->r.ref, ep); s = seprint(s, se, " idx %d", ep->idx); if(ep->name != nil) s = seprint(s, se, " name '%s'", ep->name); if(ep->tmout != 0) s = seprint(s, se, " tmout"); if(ep == ep->ep0){ s = seprint(s, se, " ctlrno %#x", ep->hp->ctlrno); s = seprint(s, se, " eps:"); for(i = 0; i < nelem(d->eps); i++) if(d->eps[i] != nil) s = seprint(s, se, " ep%d.%d", di, i); } } if(ep->info != nil) s = seprint(s, se, "\n%s %s\n", ep->info, ep->hp->ISAConf.type); else s = seprint(s, se, "\n"); qunlock(&ep->ql); poperror(); return s; } static Ep* epalloc(Hci *hp) { Ep *ep; int i; ep = smalloc(sizeof(Ep)); ep->r.ref = 1; qlock(&epslck); for(i = 0; i < Neps; i++) if(eps[i] == nil) break; if(i == Neps){ qunlock(&epslck); free(ep); print("usb: bug: too few endpoints.\n"); return nil; } ep->idx = i; if(epmax <= i) epmax = i+1; eps[i] = ep; ep->hp = hp; ep->maxpkt = 8; ep->ntds = 1; ep->samplesz = ep->pollival = ep->hz = 0; /* make them void */ qunlock(&epslck); return ep; } static Ep* getep(int i) { Ep *ep; if(i < 0 || i >= epmax || eps[i] == nil) return nil; qlock(&epslck); ep = eps[i]; if(ep != nil) incref(&ep->r); qunlock(&epslck); return ep; } static void putep(Ep *ep) { Udev *d; if(ep != nil && decref(&ep->r) == 0){ d = ep->dev; deprint("usb: ep%d.%d %#p released\n", d->nb, ep->nb, ep); qlock(&epslck); eps[ep->idx] = nil; if(ep->idx == epmax-1) epmax--; if(ep == ep->ep0 && ep->dev != nil && ep->dev->nb == usbidgen) usbidgen--; qunlock(&epslck); if(d != nil){ qlock(&ep->ep0->ql); d->eps[ep->nb] = nil; qunlock(&ep->ep0->ql); } if(ep->ep0 != ep){ putep(ep->ep0); ep->ep0 = nil; } free(ep->info); free(ep->name); free(ep); } } static void dumpeps(void) { Proc *up = externup(); int i; static char buf[512]; char *s; char *e; Ep *ep; print("usb dump eps: epmax %d Neps %d (ref=1+ for dump):\n", epmax, Neps); for(i = 0; i < epmax; i++){ s = buf; e = buf+sizeof(buf); ep = getep(i); if(ep != nil){ if(waserror()){ putep(ep); nexterror(); } s = seprint(s, e, "ep%d.%d ", ep->dev->nb, ep->nb); seprintep(s, e, ep, 1); print("%s", buf); ep->hp->Hciimpl.seprintep(buf, e, ep); print("%s", buf); poperror(); putep(ep); } } print("usb dump hcis:\n"); for(i = 0; i < Nhcis; i++) if(hcis[i] != nil) hcis[i]->Hciimpl.dump(hcis[i]); } static int newusbid(Hci *hci) { int id; qlock(&epslck); id = ++usbidgen; if(id >= 0x7F) print("#u: too many device addresses; reuse them more\n"); qunlock(&epslck); return id; } /* * Create endpoint 0 for a new device */ static Ep* newdev(Hci *hp, int ishub, int isroot) { Ep *ep; Udev *d; ep = epalloc(hp); d = ep->dev = smalloc(sizeof(Udev)); d->nb = newusbid(hp); d->eps[0] = ep; ep->nb = 0; ep->toggle[0] = ep->toggle[1] = 0; d->ishub = ishub; d->isroot = isroot; if(hp->highspeed != 0) d->speed = Highspeed; else d->speed = Fullspeed; d->state = Dconfig; /* address not yet set */ ep->dev = d; ep->ep0 = ep; /* no ref counted here */ ep->ttype = Tctl; ep->tmout = Xfertmout; ep->mode = ORDWR; dprint("newdev %#p ep%d.%d %#p\n", d, d->nb, ep->nb, ep); return ep; } /* * Create a new endpoint for the device * accessed via the given endpoint 0. */ static Ep* newdevep(Ep *ep, int i, int tt, int mode) { Ep *nep; Udev *d; d = ep->dev; if(d->eps[i] != nil) error("endpoint already in use"); nep = epalloc(ep->hp); incref(&ep->r); d->eps[i] = nep; nep->nb = i; nep->toggle[0] = nep->toggle[1] = 0; nep->ep0 = ep; nep->dev = ep->dev; nep->mode = mode; nep->ttype = tt; nep->debug = ep->debug; /* set defaults */ switch(tt){ case Tctl: nep->tmout = Xfertmout; break; case Tintr: nep->pollival = 10; break; case Tiso: nep->tmout = Xfertmout; nep->pollival = 10; nep->samplesz = 4; nep->hz = 44100; break; } deprint("newdevep ep%d.%d %#p\n", d->nb, nep->nb, nep); return ep; } static int epdataperm(int mode) { switch(mode){ case OREAD: return 0440|DMEXCL; break; case OWRITE: return 0220|DMEXCL; break; default: return 0660|DMEXCL; } } static int usbgen(Chan *c, char *l, Dirtab *d, int n, int s, Dir *dp) { Proc *up = externup(); Qid q; Dirtab *dir; int perm; char *se; Ep *ep; int nb; int mode; if(0)ddprint("usbgen q %#x s %d...", QID(c->qid), s); if(s == DEVDOTDOT){ if(QID(c->qid) <= Qusbdir){ mkqid(&q, Qdir, 0, QTDIR); devdir(c, q, "#u", 0, eve, 0555, dp); }else{ mkqid(&q, Qusbdir, 0, QTDIR); devdir(c, q, "usb", 0, eve, 0555, dp); } if(0)ddprint("ok\n"); return 1; } switch(QID(c->qid)){ case Qdir: /* list #u */ if(s == 0){ mkqid(&q, Qusbdir, 0, QTDIR); devdir(c, q, "usb", 0, eve, 0555, dp); if(0)ddprint("ok\n"); return 1; } s--; if(s < 0 || s >= epmax) goto Fail; ep = getep(s); if(ep == nil || ep->name == nil){ if(ep != nil) putep(ep); if(0)ddprint("skip\n"); return 0; } if(waserror()){ putep(ep); nexterror(); } mkqid(&q, Qep0io+s*4, 0, QTFILE); devdir(c, q, ep->name, 0, eve, epdataperm(ep->mode), dp); putep(ep); poperror(); if(0)ddprint("ok\n"); return 1; case Qusbdir: /* list #u/usb */ Usbdir: if(s < nelem(usbdir)){ dir = &usbdir[s]; mkqid(&q, dir->qid.path, 0, QTFILE); devdir(c, q, dir->name, dir->length, eve, dir->perm, dp); if(0)ddprint("ok\n"); return 1; } s -= nelem(usbdir); if(s < 0 || s >= epmax) goto Fail; ep = getep(s); if(ep == nil){ if(0)ddprint("skip\n"); return 0; } if(waserror()){ putep(ep); nexterror(); } se = up->genbuf+sizeof(up->genbuf); seprint(up->genbuf, se, "ep%d.%d", ep->dev->nb, ep->nb); mkqid(&q, Qep0dir+4*s, 0, QTDIR); putep(ep); poperror(); devdir(c, q, up->genbuf, 0, eve, 0755, dp); if(0)ddprint("ok\n"); return 1; case Qctl: s = 0; goto Usbdir; default: /* list #u/usb/epN.M */ nb = qid2epidx(QID(c->qid)); ep = getep(nb); if(ep == nil) goto Fail; mode = ep->mode; putep(ep); if(isqtype(QID(c->qid), Qepdir)){ Epdir: switch(s){ case 0: mkqid(&q, Qep0io+nb*4, 0, QTFILE); perm = epdataperm(mode); devdir(c, q, "data", 0, eve, perm, dp); break; case 1: mkqid(&q, Qep0ctl+nb*4, 0, QTFILE); devdir(c, q, "ctl", 0, eve, 0664, dp); break; default: goto Fail; } }else if(isqtype(QID(c->qid), Qepctl)){ s = 1; goto Epdir; }else{ s = 0; goto Epdir; } if(0)ddprint("ok\n"); return 1; } Fail: if(0)ddprint("fail\n"); return -1; } static Hci* hciprobe(int cardno, int ctlrno) { Hci *hp; char *type; char name[64]; static int epnb = 1; /* guess the endpoint nb. for the controller */ ddprint("hciprobe %d %d\n", cardno, ctlrno); hp = smalloc(sizeof(Hci)); hp->ctlrno = ctlrno; hp->tbdf = BUSUNKNOWN; if(cardno < 0){ //if(isaconfig("usb", ctlrno, hp) == 0){ // free(hp); // return nil; //} for(cardno = 0; cardno < Nhcis; cardno++){ if(hcitypes[cardno].type == nil) break; type = hp->ISAConf.type; if(type==nil || *type==0) type = "uhci"; if(cistrcmp(hcitypes[cardno].type, type) == 0) break; } } if(cardno >= Nhcis || hcitypes[cardno].type == nil){ free(hp); return nil; } dprint("%s...", hcitypes[cardno].type); if(hcitypes[cardno].reset(hp) < 0){ free(hp); return nil; } /* * IRQ2 doesn't really exist, it's used to gang the interrupt * controllers together. A device set to IRQ2 will appear on * the second interrupt controller as IRQ9. */ if(hp->ISAConf.irq == 2) hp->ISAConf.irq = 9; snprint(name, sizeof(name), "usb%s", hcitypes[cardno].type); intrenable(hp->ISAConf.irq, hp->Hciimpl.interrupt, hp, hp->tbdf, name); /* * modern machines have too many usb controllers to list on * the console. */ dprint("#u/usb/ep%d.0: %s: port 0x%lX irq %d\n", epnb, hcitypes[cardno].type, hp->ISAConf.port, hp->ISAConf.irq); epnb++; return hp; } static void usbreset(void) { int cardno, ctlrno; Hci *hp; dprint("usbreset\n"); for(ctlrno = 0; ctlrno < Nhcis; ctlrno++) if((hp = hciprobe(-1, ctlrno)) != nil) hcis[ctlrno] = hp; cardno = ctlrno = 0; while(cardno < Nhcis && ctlrno < Nhcis && hcitypes[cardno].type != nil) if(hcis[ctlrno] != nil) ctlrno++; else{ hp = hciprobe(cardno, ctlrno); if(hp == nil) cardno++; hcis[ctlrno++] = hp; } if(hcis[Nhcis-1] != nil) print("usbreset: bug: Nhcis (%d) too small\n", Nhcis); } static void usbinit(void) { Hci *hp; int ctlrno; Ep *d; char info[40]; dprint("usbinit\n"); for(ctlrno = 0; ctlrno < Nhcis; ctlrno++){ hp = hcis[ctlrno]; if(hp != nil){ if(hp->Hciimpl.init != nil) hp->Hciimpl.init(hp); d = newdev(hp, 1, 1); /* new root hub */ d->dev->state = Denabled; /* although addr == 0 */ d->maxpkt = 64; snprint(info, sizeof(info), "ports %d", hp->nports); kstrdup(&d->info, info); } } } static Chan* usbattach(char *spec) { return devattach(L'u', spec); } static Walkqid* usbwalk(Chan *c, Chan *nc, char **name, int nname) { return devwalk(c, nc, name, nname, nil, 0, usbgen); } static int usbstat(Chan *c, unsigned char *db, int n) { return devstat(c, db, n, nil, 0, usbgen); } /* * µs for the given transfer, for bandwidth allocation. * This is a very rough worst case for what 5.11.3 * of the usb 2.0 spec says. * Also, we are using maxpkt and not actual transfer sizes. * Only when we are sure we * are not exceeding b/w might we consider adjusting it. */ static uint32_t usbload(int speed, int maxpkt) { enum{ Hostns = 1000, Hubns = 333 }; uint32_t l; uint32_t bs; l = 0; bs = 10UL * maxpkt; switch(speed){ case Highspeed: l = 55*8*2 + 2 * (3 + bs) + Hostns; break; case Fullspeed: l = 9107 + 84 * (4 + bs) + Hostns; break; case Lowspeed: l = 64107 + 2 * Hubns + 667 * (3 + bs) + Hostns; break; default: print("usbload: bad speed %d\n", speed); /* let it run */ } return l / 1000UL; /* in µs */ } static Chan* usbopen(Chan *c, int omode) { Proc *up = externup(); int q; Ep *ep; int mode; mode = openmode(omode); q = QID(c->qid); if(q >= Qep0dir && qid2epidx(q) < 0) error(Eio); if(q < Qep0dir || isqtype(q, Qepctl) || isqtype(q, Qepdir)) return devopen(c, omode, nil, 0, usbgen); ep = getep(qid2epidx(q)); if(ep == nil) error(Eio); deprint("usbopen q %#x fid %d omode %d\n", q, c->fid, mode); if(waserror()){ putep(ep); nexterror(); } qlock(&ep->ql); if(ep->inuse){ qunlock(&ep->ql); error(Einuse); } ep->inuse = 1; qunlock(&ep->ql); if(waserror()){ ep->inuse = 0; nexterror(); } if(mode != OREAD && ep->mode == OREAD) error(Eperm); if(mode != OWRITE && ep->mode == OWRITE) error(Eperm); if(ep->ttype == Tnone) error(Enotconf); ep->clrhalt = 0; ep->rhrepl = -1; if(ep->load == 0) ep->load = usbload(ep->dev->speed, ep->maxpkt); ep->hp->Hciimpl.epopen(ep); poperror(); /* ep->inuse */ poperror(); /* don't putep(): ref kept for fid using the ep. */ c->mode = mode; c->flag |= COPEN; c->offset = 0; c->aux = nil; /* paranoia */ return c; } static void epclose(Ep *ep) { Proc *up = externup(); qlock(&ep->ql); if(waserror()){ qunlock(&ep->ql); nexterror(); } if(ep->inuse){ ep->hp->Hciimpl.epclose(ep); ep->inuse = 0; } qunlock(&ep->ql); poperror(); } static void usbclose(Chan *c) { Proc *up = externup(); int q; Ep *ep; q = QID(c->qid); if(q < Qep0dir || isqtype(q, Qepctl) || isqtype(q, Qepdir)) return; ep = getep(qid2epidx(q)); if(ep == nil) return; deprint("usbclose q %#x fid %d ref %ld\n", q, c->fid, ep->r.ref); if(waserror()){ putep(ep); nexterror(); } if(c->flag & COPEN){ free(c->aux); c->aux = nil; epclose(ep); putep(ep); /* release ref kept since usbopen */ c->flag &= ~COPEN; } poperror(); putep(ep); } static int32_t ctlread(Chan *c, void *a, int32_t n, int64_t offset) { Proc *up = externup(); int q; char *s; char *us; char *se; Ep *ep; int i; q = QID(c->qid); us = s = smalloc(READSTR); se = s + READSTR; if(waserror()){ free(us); nexterror(); } if(q == Qctl) for(i = 0; i < epmax; i++){ ep = getep(i); if(ep != nil){ if(waserror()){ putep(ep); nexterror(); } s = seprint(s, se, "ep%d.%d ", ep->dev->nb, ep->nb); s = seprintep(s, se, ep, 0); poperror(); } putep(ep); } else{ ep = getep(qid2epidx(q)); if(ep == nil) error(Eio); if(waserror()){ putep(ep); nexterror(); } if(c->aux != nil){ /* After a new endpoint request we read * the new endpoint name back. */ strecpy(s, se, c->aux); free(c->aux); c->aux = nil; }else seprintep(s, se, ep, 0); poperror(); putep(ep); } n = readstr(offset, a, n, us); poperror(); free(us); return n; } /* * Fake root hub emulation. */ static int32_t rhubread(Ep *ep, void *a, int32_t n) { char *b; if(ep->dev->isroot == 0 || ep->nb != 0 || n < 2) return -1; if(ep->rhrepl < 0) return -1; b = a; memset(b, 0, n); PUT2(b, ep->rhrepl); ep->rhrepl = -1; return n; } static int32_t rhubwrite(Ep *ep, void *a, int32_t n) { unsigned char *s; int cmd; int feature; int port; Hci *hp; if(ep->dev == nil || ep->dev->isroot == 0 || ep->nb != 0) return -1; if(n != Rsetuplen) error("root hub is a toy hub"); ep->rhrepl = -1; s = a; if(s[Rtype] != (Rh2d|Rclass|Rother) && s[Rtype] != (Rd2h|Rclass|Rother)) error("root hub is a toy hub"); hp = ep->hp; cmd = s[Rreq]; feature = GET2(s+Rvalue); port = GET2(s+Rindex); if(port < 1 || port > hp->nports) error("bad hub port number"); switch(feature){ case Rportenable: ep->rhrepl = hp->Hciimpl.portenable(hp, port, cmd == Rsetfeature); break; case Rportreset: ep->rhrepl = hp->Hciimpl.portreset(hp, port, cmd == Rsetfeature); break; case Rgetstatus: ep->rhrepl = hp->Hciimpl.portstatus(hp, port); break; default: ep->rhrepl = 0; } return n; } static int32_t usbread(Chan *c, void *a, int32_t n, int64_t offset) { Proc *up = externup(); int q; Ep *ep; int nr; q = QID(c->qid); if(c->qid.type == QTDIR) return devdirread(c, a, n, nil, 0, usbgen); if(q == Qctl || isqtype(q, Qepctl)) return ctlread(c, a, n, offset); ep = getep(qid2epidx(q)); if(ep == nil) error(Eio); if(waserror()){ putep(ep); nexterror(); } if(ep->dev->state == Ddetach) error(Edetach); if(ep->mode == OWRITE || ep->inuse == 0) error(Ebadusefd); switch(ep->ttype){ case Tnone: error("endpoint not configured"); case Tctl: nr = rhubread(ep, a, n); if(nr >= 0){ n = nr; break; } /* else fall */ default: ddeprint("\nusbread q %#x fid %d cnt %ld off %lld\n",q,c->fid,n,offset); n = ep->hp->Hciimpl.epread(ep, a, n); break; } poperror(); putep(ep); return n; } static int32_t pow2(int n) { return 1 << n; } static void setmaxpkt(Ep *ep, char* s) { int32_t spp; /* samples per packet */ if(ep->dev->speed == Highspeed) spp = (ep->hz * ep->pollival * ep->ntds + 7999) / 8000; else spp = (ep->hz * ep->pollival + 999) / 1000; ep->maxpkt = spp * ep->samplesz; deprint("usb: %s: setmaxpkt: hz %ld poll %ld" " ntds %d %s speed -> spp %ld maxpkt %ld\n", s, ep->hz, ep->pollival, ep->ntds, spname[ep->dev->speed], spp, ep->maxpkt); if(ep->maxpkt > 1024){ print("usb: %s: maxpkt %ld > 1024. truncating\n", s, ep->maxpkt); ep->maxpkt = 1024; } } /* * Many endpoint ctls. simply update the portable representation * of the endpoint. The actual controller driver will look * at them to setup the endpoints as dictated. */ static int32_t epctl(Ep *ep, Chan *c, void *a, int32_t n) { Proc *up = externup(); int i, l, mode, nb, tt; char *b, *s; Cmdbuf *cb; Cmdtab *ct; Ep *nep; Udev *d; static char *Info = "info "; d = ep->dev; cb = parsecmd(a, n); if(waserror()){ free(cb); nexterror(); } ct = lookupcmd(cb, epctls, nelem(epctls)); if(ct == nil) error(Ebadctl); i = ct->index; if(i == CMnew || i == CMspeed || i == CMhub || i == CMpreset) if(ep != ep->ep0) error("allowed only on a setup endpoint"); if(i != CMclrhalt && i != CMdetach && i != CMdebugep && i != CMname) if(ep != ep->ep0 && ep->inuse != 0) error("must configure before using"); switch(i){ case CMnew: deprint("usb epctl %s\n", cb->f[0]); nb = strtol(cb->f[1], nil, 0); if(nb < 0 || nb >= Ndeveps) error("bad endpoint number"); tt = name2ttype(cb->f[2]); if(tt == Tnone) error("unknown endpoint type"); mode = name2mode(cb->f[3]); if(mode < 0) error("unknown i/o mode"); newdevep(ep, nb, tt, mode); break; case CMnewdev: deprint("usb epctl %s\n", cb->f[0]); if(ep != ep->ep0 || d->ishub == 0) error("not a hub setup endpoint"); l = name2speed(cb->f[1]); if(l == Nospeed) error("speed must be full|low|high"); nep = newdev(ep->hp, 0, 0); nep->dev->speed = l; if(nep->dev->speed != Lowspeed) nep->maxpkt = 64; /* assume full speed */ nep->dev->hub = d->nb; nep->dev->port = atoi(cb->f[2]); /* next read request will read * the name for the new endpoint */ l = sizeof(up->genbuf); snprint(up->genbuf, l, "ep%d.%d", nep->dev->nb, nep->nb); kstrdup((char**)&c->aux, up->genbuf); break; case CMhub: deprint("usb epctl %s\n", cb->f[0]); d->ishub = 1; break; case CMspeed: l = name2speed(cb->f[1]); deprint("usb epctl %s %d\n", cb->f[0], l); if(l == Nospeed) error("speed must be full|low|high"); qlock(&ep->ep0->ql); d->speed = l; qunlock(&ep->ep0->ql); break; case CMmaxpkt: l = strtoul(cb->f[1], nil, 0); deprint("usb epctl %s %d\n", cb->f[0], l); if(l < 1 || l > 1024) error("maxpkt not in [1:1024]"); qlock(&ep->ql); ep->maxpkt = l; qunlock(&ep->ql); break; case CMntds: l = strtoul(cb->f[1], nil, 0); deprint("usb epctl %s %d\n", cb->f[0], l); if(l < 1 || l > 3) error("ntds not in [1:3]"); qlock(&ep->ql); ep->ntds = l; qunlock(&ep->ql); break; case CMpollival: if(ep->ttype != Tintr && ep->ttype != Tiso) error("not an intr or iso endpoint"); l = strtoul(cb->f[1], nil, 0); deprint("usb epctl %s %d\n", cb->f[0], l); if(ep->ttype == Tiso || (ep->ttype == Tintr && ep->dev->speed == Highspeed)){ if(l < 1 || l > 16) error("pollival power not in [1:16]"); l = pow2(l-1); }else if(l < 1 || l > 255) error("pollival not in [1:255]"); qlock(&ep->ql); ep->pollival = l; if(ep->ttype == Tiso) setmaxpkt(ep, "pollival"); qunlock(&ep->ql); break; case CMsamplesz: if(ep->ttype != Tiso) error("not an iso endpoint"); l = strtoul(cb->f[1], nil, 0); deprint("usb epctl %s %d\n", cb->f[0], l); if(l <= 0 || l > 8) error("samplesz not in [1:8]"); qlock(&ep->ql); ep->samplesz = l; setmaxpkt(ep, "samplesz"); qunlock(&ep->ql); break; case CMhz: if(ep->ttype != Tiso) error("not an iso endpoint"); l = strtoul(cb->f[1], nil, 0); deprint("usb epctl %s %d\n", cb->f[0], l); if(l <= 0 || l > 100000) error("hz not in [1:100000]"); qlock(&ep->ql); ep->hz = l; setmaxpkt(ep, "hz"); qunlock(&ep->ql); break; case CMclrhalt: qlock(&ep->ql); deprint("usb epctl %s\n", cb->f[0]); ep->clrhalt = 1; qunlock(&ep->ql); break; case CMinfo: deprint("usb epctl %s\n", cb->f[0]); l = strlen(Info); s = a; if(n < l+2 || strncmp(Info, s, l) != 0) error(Ebadctl); if(n > 1024) n = 1024; b = smalloc(n); memmove(b, s+l, n-l); b[n-l] = 0; if(b[n-l-1] == '\n') b[n-l-1] = 0; qlock(&ep->ql); free(ep->info); ep->info = b; qunlock(&ep->ql); break; case CMaddress: deprint("usb epctl %s\n", cb->f[0]); ep->dev->state = Denabled; break; case CMdetach: if(ep->dev->isroot != 0) error("can't detach a root hub"); deprint("usb epctl %s ep%d.%d\n", cb->f[0], ep->dev->nb, ep->nb); ep->dev->state = Ddetach; /* Release file system ref. for its endpoints */ for(i = 0; i < nelem(ep->dev->eps); i++) putep(ep->dev->eps[i]); break; case CMdebugep: if(strcmp(cb->f[1], "on") == 0) ep->debug = 1; else if(strcmp(cb->f[1], "off") == 0) ep->debug = 0; else ep->debug = strtoul(cb->f[1], nil, 0); print("usb: ep%d.%d debug %d\n", ep->dev->nb, ep->nb, ep->debug); break; case CMname: deprint("usb epctl %s %s\n", cb->f[0], cb->f[1]); validname(cb->f[1], 0); kstrdup(&ep->name, cb->f[1]); break; case CMtmout: deprint("usb epctl %s\n", cb->f[0]); if(ep->ttype == Tiso || ep->ttype == Tctl) error("ctl ignored for this endpoint type"); ep->tmout = strtoul(cb->f[1], nil, 0); if(ep->tmout != 0 && ep->tmout < Xfertmout) ep->tmout = Xfertmout; break; case CMpreset: deprint("usb epctl %s\n", cb->f[0]); if(ep->ttype != Tctl) error("not a control endpoint"); if(ep->dev->state != Denabled) error("forbidden on devices not enabled"); ep->dev->state = Dreset; break; default: panic("usb: unknown epctl %d", ct->index); } free(cb); poperror(); return n; } static int32_t usbctl(void *a, int32_t n) { Proc *up = externup(); Cmdtab *ct; Cmdbuf *cb; Ep *ep; int i; cb = parsecmd(a, n); if(waserror()){ free(cb); nexterror(); } ct = lookupcmd(cb, usbctls, nelem(usbctls)); dprint("usb ctl %s\n", cb->f[0]); switch(ct->index){ case CMdebug: if(strcmp(cb->f[1], "on") == 0) debug = 1; else if(strcmp(cb->f[1], "off") == 0) debug = 0; else debug = strtol(cb->f[1], nil, 0); print("usb: debug %d\n", debug); for(i = 0; i < epmax; i++) if((ep = getep(i)) != nil){ ep->hp->Hciimpl.debug(ep->hp, debug); putep(ep); } break; case CMdump: dumpeps(); break; } free(cb); poperror(); return n; } static int32_t ctlwrite(Chan *c, void *a, int32_t n) { Proc *up = externup(); int q; Ep *ep; q = QID(c->qid); if(q == Qctl) return usbctl(a, n); ep = getep(qid2epidx(q)); if(ep == nil) error(Eio); if(waserror()){ putep(ep); nexterror(); } if(ep->dev->state == Ddetach) error(Edetach); if(isqtype(q, Qepctl) && c->aux != nil){ /* Be sure we don't keep a cloned ep name */ free(c->aux); c->aux = nil; error("read, not write, expected"); } n = epctl(ep, c, a, n); putep(ep); poperror(); return n; } static int32_t usbwrite(Chan *c, void *a, int32_t n, int64_t off) { Proc *up = externup(); int nr, q; Ep *ep; if(c->qid.type == QTDIR) error(Eisdir); q = QID(c->qid); if(q == Qctl || isqtype(q, Qepctl)) return ctlwrite(c, a, n); ep = getep(qid2epidx(q)); if(ep == nil) error(Eio); if(waserror()){ putep(ep); nexterror(); } if(ep->dev->state == Ddetach) error(Edetach); if(ep->mode == OREAD || ep->inuse == 0) error(Ebadusefd); switch(ep->ttype){ case Tnone: error("endpoint not configured"); case Tctl: nr = rhubwrite(ep, a, n); if(nr >= 0){ n = nr; break; } /* else fall */ default: ddeprint("\nusbwrite q %#x fid %d cnt %ld off %lld\n",q, c->fid, n, off); ep->hp->Hciimpl.epwrite(ep, a, n); } putep(ep); poperror(); return n; } void usbshutdown(void) { Hci *hp; int i; for(i = 0; i < Nhcis; i++){ hp = hcis[i]; if(hp == nil) continue; if(hp->Hciimpl.shutdown == nil) print("#u: no shutdown function for %s\n", hp->ISAConf.type); else hp->Hciimpl.shutdown(hp); } } Dev usbdevtab = { .dc = L'u', .name = "usb", .reset = usbreset, .init = usbinit, .shutdown = usbshutdown, .attach = usbattach, .walk = usbwalk, .stat = usbstat, .open = usbopen, .create = devcreate, .close = usbclose, .read = usbread, .bread = devbread, .write = usbwrite, .bwrite = devbwrite, .remove = devremove, .wstat = devwstat, };