ref: 7628681f83b663609eace87a50f8fbf68c31f40b
dir: /sys/src/9/pc/usbuhci.c/
/* * USB Universal Host Controller Interface (sic) driver. * * BUGS: * - Too many delays and ilocks. * - bandwidth admission control must be done per-frame. * - interrupt endpoints should go on a tree like [oe]hci. * - must warn of power overruns. */ #include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "io.h" #include "../port/pci.h" #include "../port/error.h" #include "../port/usb.h" typedef struct Ctlio Ctlio; typedef struct Ctlr Ctlr; typedef struct Isoio Isoio; typedef struct Qh Qh; typedef struct Qhpool Qhpool; typedef struct Qio Qio; typedef struct Td Td; typedef struct Tdpool Tdpool; enum { Resetdelay = 100, /* delay after a controller reset (ms) */ Enabledelay = 100, /* waiting for a port to enable */ Abortdelay = 10, /* delay after cancelling Tds (ms) */ Incr = 64, /* for Td and Qh pools */ Tdatomic = 8, /* max nb. of Tds per bulk I/O op. */ /* Queue states (software) */ Qidle = 0, Qinstall, Qrun, Qdone, Qclose, Qfree, /* * HW constants */ Nframes = 1024, /* 2ⁿ for xspanalloc; max 1024 */ Align = 16, /* for data structures */ /* Size of small buffer kept within Tds. (software) */ /* Keep as a multiple of Align to maintain alignment of Tds in pool */ Tdndata = 1*Align, /* i/o space * Some ports are short, some are long, some are byte. * We use ins[bsl] and not vmap. */ Cmd = 0, Crun = 0x01, Chcreset = 0x02, /* host controller reset */ Cgreset = 0x04, /* global reset */ Cegsm = 0x08, /* enter global suspend */ Cfgr = 0x10, /* forge global resume */ Cdbg = 0x20, /* single step, debug */ Cmaxp = 0x80, /* max packet */ Status = 2, Susbintr = 0x01, /* interrupt */ Seintr = 0x02, /* error interrupt */ Sresume = 0x04, /* resume detect */ Shserr = 0x08, /* host system error */ Shcerr = 0x10, /* host controller error */ Shalted = 0x20, /* controller halted */ Sall = 0x3F, Usbintr = 4, Itmout = 0x01, /* timeout or crc */ Iresume = 0x02, /* resume interrupt enable */ Ioc = 0x04, /* interrupt on complete */ Ishort = 0x08, /* short packet interrupt */ Iall = 0x0F, Frnum = 6, Flbaseadd = 8, SOFmod = 0xC, /* start of frame modifier register */ Portsc0 = 0x10, PSpresent = 0x0001, /* device present */ PSstatuschg = 0x0002, /* PSpresent changed */ PSenable = 0x0004, /* device enabled */ PSchange = 0x0008, /* PSenable changed */ PSresume = 0x0040, /* resume detected */ PSreserved1 = 0x0080, /* always read as 1; reserved */ PSslow = 0x0100, /* device has low speed */ PSreset = 0x0200, /* port reset */ PSsuspend = 0x1000, /* port suspended */ /* Transfer descriptor link */ Tdterm = 0x1, /* nil (terminate) */ Tdlinkqh = 0x2, /* link refers to a QH */ Tdvf = 0x4, /* run linked Tds first (depth-first)*/ /* Transfer status bits */ Tdbitstuff = 0x00020000, /* bit stuffing error */ Tdcrcto = 0x00040000, /* crc or timeout error */ Tdnak = 0x00080000, /* nak packet received */ Tdbabble = 0x00100000, /* babble detected */ Tddberr = 0x00200000, /* data buf. error */ Tdstalled = 0x00400000, /* serious error to ep. */ Tdactive = 0x00800000, /* enabled/in use by hw */ /* Transfer control bits */ Tdioc = 0x01000000, /* interrupt on complete */ Tdiso = 0x02000000, /* isochronous select */ Tdlow = 0x04000000, /* low speed device */ Tderr1 = 0x08000000, /* bit 0 of error counter */ Tderr2 = 0x10000000, /* bit 1 of error counter */ Tdspd = 0x20000000, /* short packet detect */ Tdlen = 0x000003FF, /* actual length field */ Tdfatalerr = Tdnak|Tdbabble|Tdstalled, /* hw retries others */ Tderrors = Tdfatalerr|Tdbitstuff|Tdcrcto|Tddberr, /* Transfer descriptor token bits */ Tddata0 = 0, Tddata1 = 0x80000, /* data toggle (1==DATA1) */ Tdtokin = 0x69, Tdtokout = 0xE1, Tdtoksetup = 0x2D, Tdmaxpkt = 0x800, /* max packet size */ /* Queue head bits */ QHterm = 1<<0, /* nil (terminate) */ QHlinkqh = 1<<1, /* link refers to a QH */ QHvf = 1<<2, /* vertical first (depth first) */ }; struct Ctlr { Lock; /* for ilock. qh lists and basic ctlr I/O */ QLock portlck; /* for port resets/enable... */ Pcidev* pcidev; Ctlr *next; int active; int port; /* I/O address */ Qh* qhs; /* list of Qhs for this controller */ Qh* qh[Tmax]; /* Dummy Qhs to insert Qhs after */ Isoio* iso; /* list of active iso I/O */ ulong* frames; /* frame list (used by hw) */ ulong load; /* max load for a single frame */ ulong isoload; /* max iso load for a single frame */ int nintr; /* number of interrupts attended */ int ntdintr; /* number of intrs. with something to do */ int nqhintr; /* number of intrs. for Qhs */ int nisointr; /* number of intrs. for iso transfers */ }; struct Qio { QLock; /* for the entire I/O process */ Rendez; /* wait for completion */ Qh* qh; /* Td list (field const after init) */ int usbid; /* usb address for endpoint/device */ int toggle; /* Tddata0/Tddata1 */ int tok; /* Tdtoksetup, Tdtokin, Tdtokout */ ulong iotime; /* time of last I/O */ int debug; /* debug flag from the endpoint */ char* err; /* error string */ }; struct Ctlio { Qio; /* a single Qio for each RPC */ uchar* data; /* read from last ctl req. */ int ndata; /* number of bytes read */ }; struct Isoio { QLock; Rendez; /* wait for space/completion/errors */ int usbid; /* address used for device/endpoint */ int tok; /* Tdtokin or Tdtokout */ int state; /* Qrun -> Qdone -> Qrun... -> Qclose */ int nframes; /* Nframes/ep->pollival */ uchar* data; /* iso data buffers if not embedded */ int td0frno; /* frame number for first Td */ Td* tdu; /* next td for user I/O in tdps */ Td* tdi; /* next td processed by interrupt */ char* err; /* error string */ int nerrs; /* nb of consecutive I/O errors */ long nleft; /* number of bytes left from last write */ int debug; /* debug flag from the endpoint */ Isoio* next; /* in list of active Isoios */ Td* tdps[Nframes]; /* pointer to Td used for i-th frame or nil */ int delay; /* maximum number of bytes to buffer */ }; struct Tdpool { Lock; Td* free; int nalloc; int ninuse; int nfree; }; struct Qhpool { Lock; Qh* free; int nalloc; int ninuse; int nfree; }; /* * HW data structures */ /* * Queue header (known by hw). * 16-byte aligned. first two words used by hw. * They are taken from the pool upon endpoint opening and * queued after the dummy queue header for the endpoint type * in the controller. Actual I/O happens as Tds are linked into it. * The driver does I/O in lock-step. * The user builds a list of Tds and links it into the Qh, * then the Qh goes from Qidle to Qrun and nobody touches it until * it becomes Qdone at interrupt time. * At that point the user collects the Tds and it goes Qidle. * A premature cancel may set the state to Qclose and abort I/O. * The Ctlr lock protects change of state for Qhs in use. */ struct Qh { ulong link; /* link to next horiz. item (eg. Qh) */ ulong elink; /* link to element (eg. Td; updated by hw) */ ulong state; /* Qidle -> Qinstall -> Qrun -> Qdone | Qclose */ Qio* io; /* for this queue */ Qh* next; /* in active or free list */ Td* tds; /* Td list in this Qh (initially, elink) */ char* tag; /* debug and align, mostly */ }; /* * Transfer descriptor. * 16-byte aligned. first two words used by hw. Next 4 by sw. * We keep an embedded buffer for small I/O transfers. * They are taken from the pool when buffers are needed for I/O * and linked at the Qh/Isoio for the endpoint and direction requiring it. * The block keeps actual data. They are protected from races by * the queue or the pool keeping it. The owner of the link to the Td * is free to use it and can be the only one using it. */ struct Td { ulong link; /* Link to next Td or Qh */ ulong csw; /* control and status word (updated by hw) */ ulong token; /* endpt, device, pid */ ulong buffer; /* buffer pointer */ Td* next; /* in qh or Isoio or free list */ ulong ndata; /* bytes available/used at data */ uchar* data; /* pointer to actual data */ void* buff; /* allocated data, for large transfers */ uchar sbuff[Tdndata]; /* embedded buffer, for small transfers */ }; #define INB(x) inb(ctlr->port+(x)) #define INS(x) ins(ctlr->port+(x)) #define INL(x) inl(ctlr->port+(x)) #define OUTB(x, v) outb(ctlr->port+(x), (v)) #define OUTS(x, v) outs(ctlr->port+(x), (v)) #define OUTL(x, v) outl(ctlr->port+(x), (v)) #define TRUNC(x, sz) ((x) & ((sz)-1)) #define PTR(q) ((void*)KADDR((ulong)(q) & ~ (0xF|PCIWINDOW))) #define QPTR(q) ((Qh*)PTR(q)) #define TPTR(q) ((Td*)PTR(q)) #define PORT(p) (Portsc0 + 2*(p)) #define diprint if(debug || iso->debug)print #define ddiprint if(debug>1 || iso->debug>1)print #define dqprint if(debug || (qh->io && qh->io->debug))print #define ddqprint if(debug>1 || (qh->io && qh->io->debug>1))print static Tdpool tdpool; static Qhpool qhpool; static int debug; static char* qhsname[] = { "idle", "install", "run", "done", "close", "FREE" }; static void uhcicmd(Ctlr *ctlr, int c) { OUTS(Cmd, c); } static void uhcirun(Ctlr *ctlr, int on) { int i; ddprint("uhci %#ux setting run to %d\n", ctlr->port, on); if(on) uhcicmd(ctlr, INS(Cmd)|Crun); else uhcicmd(ctlr, INS(Cmd) & ~Crun); for(i = 0; i < 100; i++) if(on == 0 && (INS(Status) & Shalted) != 0) break; else if(on != 0 && (INS(Status) & Shalted) == 0) break; else delay(1); if(i == 100) dprint("uhci %#x run cmd timed out\n", ctlr->port); ddprint("uhci %#ux cmd %#ux sts %#ux\n", ctlr->port, INS(Cmd), INS(Status)); } static int tdlen(Td *td) { return (td->csw+1) & Tdlen; } static int maxtdlen(Td *td) { return ((td->token>>21)+1) & (Tdmaxpkt-1); } static int tdtok(Td *td) { return td->token & 0xFF; } static char* seprinttd(char *s, char *se, Td *td) { s = seprint(s, se, "%#p link %#ulx", td, td->link); if((td->link & Tdvf) != 0) s = seprint(s, se, "V"); if((td->link & Tdterm) != 0) s = seprint(s, se, "T"); if((td->link & Tdlinkqh) != 0) s = seprint(s, se, "Q"); s = seprint(s, se, " csw %#ulx ", td->csw); if(td->csw & Tdactive) s = seprint(s, se, "a"); if(td->csw & Tdiso) s = seprint(s, se, "I"); if(td->csw & Tdioc) s = seprint(s, se, "i"); if(td->csw & Tdlow) s = seprint(s, se, "l"); if((td->csw & (Tderr1|Tderr2)) == 0) s = seprint(s, se, "z"); if(td->csw & Tderrors) s = seprint(s, se, " err %#ulx", td->csw & Tderrors); if(td->csw & Tdstalled) s = seprint(s, se, "s"); if(td->csw & Tddberr) s = seprint(s, se, "d"); if(td->csw & Tdbabble) s = seprint(s, se, "b"); if(td->csw & Tdnak) s = seprint(s, se, "n"); if(td->csw & Tdcrcto) s = seprint(s, se, "c"); if(td->csw & Tdbitstuff) s = seprint(s, se, "B"); s = seprint(s, se, " stslen %d", tdlen(td)); s = seprint(s, se, " token %#ulx", td->token); if(td->token == 0) /* the BWS loopback Td, ignore rest */ return s; s = seprint(s, se, " maxlen %d", maxtdlen(td)); if(td->token & Tddata1) s = seprint(s, se, " d1"); else s = seprint(s, se, " d0"); s = seprint(s, se, " id %#ulx:", (td->token>>15) & Epmax); s = seprint(s, se, "%#ulx", (td->token>>8) & Devmax); switch(tdtok(td)){ case Tdtokin: s = seprint(s, se, " in"); break; case Tdtokout: s = seprint(s, se, " out"); break; case Tdtoksetup: s = seprint(s, se, " setup"); break; default: s = seprint(s, se, " BADPID"); } s = seprint(s, se, "\n\t buffer %#ulx data %#p", td->buffer, td->data); s = seprint(s, se, " ndata %uld sbuff %#p buff %#p", td->ndata, td->sbuff, td->buff); if(td->ndata > 0) s = seprintdata(s, se, td->data, td->ndata); return s; } static void isodump(Isoio *iso, int all) { char buf[256]; Td *td; int i; print("iso %#p %s state %d nframes %d" " td0 %#p tdu %#p tdi %#p data %#p\n", iso, iso->tok == Tdtokin ? "in" : "out", iso->state, iso->nframes, iso->tdps[iso->td0frno], iso->tdu, iso->tdi, iso->data); if(iso->err != nil) print("\terr='%s'\n", iso->err); if(all == 0){ seprinttd(buf, buf+sizeof(buf), iso->tdu); print("\ttdu %s\n", buf); seprinttd(buf, buf+sizeof(buf), iso->tdi); print("\ttdi %s\n", buf); }else{ td = iso->tdps[iso->td0frno]; for(i = 0; i < iso->nframes; i++){ seprinttd(buf, buf+sizeof(buf), td); if(td == iso->tdi) print("i->"); if(td == iso->tdu) print("u->"); print("\t%s\n", buf); td = td->next; } } } static int sameptr(void *p, ulong l) { if(l & QHterm) return p == nil; return PTR(l) == p; } static void dumptd(Td *td, char *pref) { char buf[256]; char *s; char *se; int i; i = 0; se = buf+sizeof(buf); for(; td != nil; td = td->next){ s = seprinttd(buf, se, td); if(!sameptr(td->next, td->link)) seprint(s, se, " next %#p != link %#ulx %#p", td->next, td->link, TPTR(td->link)); print("%std %s\n", pref, buf); if(i++ > 20){ print("...more tds...\n"); break; } } } static void qhdump(Qh *qh, char *pref) { char buf[256]; char *s; char *se; ulong td; int i; s = buf; se = buf+sizeof(buf); s = seprint(s, se, "%sqh %s %#p state %s link %#ulx", pref, qh->tag, qh, qhsname[qh->state], qh->link); if(!sameptr(qh->tds, qh->elink)) s = seprint(s, se, " [tds %#p != elink %#ulx %#p]", qh->tds, qh->elink, TPTR(qh->elink)); if(!sameptr(qh->next, qh->link)) s = seprint(s, se, " [next %#p != link %#ulx %#p]", qh->next, qh->link, QPTR(qh->link)); if((qh->link & Tdterm) != 0) s = seprint(s, se, "T"); if((qh->link & Tdlinkqh) != 0) s = seprint(s, se, "Q"); s = seprint(s, se, " elink %#ulx", qh->elink); if((qh->elink & Tdterm) != 0) s = seprint(s, se, "T"); if((qh->elink & Tdlinkqh) != 0) s = seprint(s, se, "Q"); s = seprint(s, se, " io %#p", qh->io); if(qh->io != nil && qh->io->err != nil) seprint(s, se, " err='%s'", qh->io->err); print("%s\n", buf); dumptd(qh->tds, "\t"); if((qh->elink & QHterm) == 0){ print("\thw tds:"); i = 0; for(td = qh->elink; (td & Tdterm) == 0; td = TPTR(td)->link){ print(" %#ulx", td); if(td == TPTR(td)->link) /* BWS Td */ break; if(i++ > 40){ print("..."); break; } } print("\n"); } } static void xdump(Ctlr *ctlr, int doilock) { Isoio *iso; Qh *qh; int i; if(doilock) ilock(ctlr); print("uhci port %#x frames %#p nintr %d ntdintr %d", ctlr->port, ctlr->frames, ctlr->nintr, ctlr->ntdintr); print(" nqhintr %d nisointr %d\n", ctlr->nqhintr, ctlr->nisointr); print("cmd %#ux sts %#ux fl %#ulx ps1 %#ux ps2 %#ux frames[0] %#ulx\n", INS(Cmd), INS(Status), INL(Flbaseadd), INS(PORT(0)), INS(PORT(1)), ctlr->frames[0]); for(iso = ctlr->iso; iso != nil; iso = iso->next) isodump(iso, 1); i = 0; for(qh = ctlr->qhs; qh != nil; qh = qh->next){ qhdump(qh, ""); if(i++ > 20){ print("qhloop\n"); break; } } print("\n"); if(doilock){ iunlock(ctlr); if(ctlr->next == nil){ lock(&tdpool); print("tds: alloc %d = inuse %d + free %d\n", tdpool.nalloc, tdpool.ninuse, tdpool.nfree); unlock(&tdpool); lock(&qhpool); print("qhs: alloc %d = inuse %d + free %d\n", qhpool.nalloc, qhpool.ninuse, qhpool.nfree); unlock(&qhpool); } } } static void dump(Hci *hp) { xdump(hp->aux, 1); } static Td* tdalloc(void) { int i; Td *td; uchar *pool; lock(&tdpool); if(tdpool.free == nil){ ddprint("uhci: tdalloc %d Tds\n", Incr); pool = xspanalloc(Incr*ROUND(sizeof(Td), Align), Align, 0); if(pool == nil) panic("tdalloc"); for(i=Incr; --i>=0;){ td = (Td*)(pool + i*ROUND(sizeof(Td), Align)); td->next = tdpool.free; tdpool.free = td; } tdpool.nalloc += Incr; tdpool.nfree += Incr; } td = tdpool.free; tdpool.free = td->next; tdpool.ninuse++; tdpool.nfree--; unlock(&tdpool); memset(td, 0, sizeof(Td)); td->link = Tdterm; assert(((uintptr)td & 0xF) == 0); return td; } static void tdfree(Td *td) { if(td == nil) return; free(td->buff); td->buff = nil; lock(&tdpool); td->next = tdpool.free; tdpool.free = td; tdpool.ninuse--; tdpool.nfree++; unlock(&tdpool); } static void qhlinkqh(Qh* qh, Qh* next) { if(next == nil) qh->link = QHterm; else{ next->link = qh->link; next->next = qh->next; qh->link = PCIWADDR(next)|QHlinkqh; } qh->next = next; } static void qhlinktd(Qh *qh, Td *td) { qh->tds = td; if(td == nil) qh->elink = QHvf|QHterm; else qh->elink = PCIWADDR(td); } static void tdlinktd(Td *td, Td *next) { td->next = next; if(next == nil) td->link = Tdterm; else td->link = PCIWADDR(next)|Tdvf; } static Qh* qhalloc(Ctlr *ctlr, Qh *prev, Qio *io, char *tag) { int i; Qh *qh; uchar *pool; lock(&qhpool); if(qhpool.free == nil){ ddprint("uhci: qhalloc %d Qhs\n", Incr); pool = xspanalloc(Incr*ROUND(sizeof(Qh), Align), Align, 0); if(pool == nil) panic("qhalloc"); for(i=Incr; --i>=0;){ qh = (Qh*)(pool + i*ROUND(sizeof(Qh), Align)); qh->next = qhpool.free; qhpool.free = qh; } qhpool.nalloc += Incr; qhpool.nfree += Incr; } qh = qhpool.free; qhpool.free = qh->next; qh->next = nil; qh->link = QHterm; qhpool.ninuse++; qhpool.nfree--; unlock(&qhpool); qh->tds = nil; qh->elink = QHterm; qh->state = Qidle; qh->io = io; qh->tag = nil; kstrdup(&qh->tag, tag); if(prev != nil){ coherence(); ilock(ctlr); qhlinkqh(prev, qh); iunlock(ctlr); } assert(((uintptr)qh & 0xF) == 0); return qh; } static void qhfree(Ctlr *ctlr, Qh *qh) { Td *td; Qh *q; ilock(ctlr); for(q = ctlr->qhs; q != nil; q = q->next) if(q->next == qh) break; if(q == nil) panic("qhfree: nil q"); q->next = qh->next; q->link = qh->link; qh->state = Qfree; /* paranoia */ iunlock(ctlr); while((td = qh->tds) != nil){ qh->tds = td->next; tdfree(td); } lock(&qhpool); qh->next = qhpool.free; qh->tag = nil; qh->io = nil; qhpool.free = qh; qhpool.ninuse--; qhpool.nfree++; unlock(&qhpool); ddprint("qhfree: qh %#p\n", qh); } static char* errmsg(int err) { if(err == 0) return "ok"; if(err & Tdcrcto) return "crc/timeout error"; if(err & Tdbabble) return "babble detected"; if(err & Tddberr) return "db error"; if(err & Tdbitstuff) return "bit stuffing error"; if(err & Tdstalled) return Estalled; return Eio; } static int isocanread(void *a) { Isoio *iso; iso = a; return iso->state == Qclose || (iso->state == Qrun && iso->tok == Tdtokin && iso->tdi != iso->tdu); } static int isocanwrite(void *a) { Isoio *iso; iso = a; return iso->state == Qclose || (iso->state == Qrun && iso->tok == Tdtokout && iso->tdu->next != iso->tdi); } static int isodelay(void *a) { Isoio *iso; int delay; Td *tdi; iso = a; if(iso->state == Qclose || iso->err || iso->delay == 0) return 1; delay = 0; for(tdi = iso->tdi; tdi->next != iso->tdu; tdi = tdi->next){ if((tdi->csw & Tdactive) == 0) continue; delay += maxtdlen(tdi); if(delay > iso->delay) break; } return delay <= iso->delay; } static void tdisoinit(Isoio *iso, Td *td, long count) { td->ndata = count; td->token = ((count-1)<<21)| ((iso->usbid & 0x7FF)<<8) | iso->tok; td->csw = Tderr1|Tdiso|Tdactive|Tdioc; } /* * Process Iso i/o on interrupt. For writes update just error status. * For reads update tds to reflect data and also error status. * When tdi aproaches tdu, advance tdu; data may be lost. * (If nframes is << Nframes tdu might be far away but this avoids * races regarding frno.) * If we suffer errors for more than half the frames we stall. */ static void isointerrupt(Ctlr *ctlr, Isoio* iso) { Td *tdi; int err; int i; int nframes; tdi = iso->tdi; if((tdi->csw & Tdactive) != 0) /* nothing new done */ return; ctlr->nisointr++; ddiprint("isointr: iso %#p: tdi %#p tdu %#p\n", iso, tdi, iso->tdu); if(iso->state != Qrun && iso->state != Qdone) panic("isointr: iso state"); if(debug > 1 || iso->debug > 1) isodump(iso, 0); nframes = iso->nframes / 2; /* limit how many we look */ if(nframes > 64) nframes = 64; for(i = 0; i < nframes && (tdi->csw & Tdactive) == 0; i++){ tdi->csw &= ~Tdioc; err = tdi->csw & Tderrors; if(err == 0) iso->nerrs = 0; else if(iso->nerrs++ > iso->nframes/2) tdi->csw |= Tdstalled; if((tdi->csw & Tdstalled) != 0){ if(iso->err == nil){ iso->err = errmsg(err); diprint("isointerrupt: tdi %#p error %#ux %s\n", tdi, err, iso->err); diprint("ctlr load %uld\n", ctlr->load); } tdi->ndata = 0; }else tdi->ndata = tdlen(tdi); if(tdi->next == iso->tdu || tdi->next->next == iso->tdu){ memset(iso->tdu->data, 0, maxtdlen(iso->tdu)); tdisoinit(iso, iso->tdu, maxtdlen(iso->tdu)); iso->tdu = iso->tdu->next; iso->nleft = 0; } tdi = tdi->next; } ddiprint("isointr: %d frames processed\n", i); if(i == nframes) tdi->csw |= Tdioc; iso->tdi = tdi; if(isocanwrite(iso) || isocanread(iso)){ diprint("wakeup iso %#p tdi %#p tdu %#p\n", iso, iso->tdi, iso->tdu); wakeup(iso); } } /* * Process a Qh upon interrupt. There's one per ongoing user I/O. * User process releases resources later, that is not done here. * We may find in this order one or more Tds: * - none/many non active and completed Tds * - none/one (usually(!) not active) and failed Td * - none/many active Tds. * Upon errors the entire transfer is aborted and error reported. * Otherwise, the transfer is complete only when all Tds are done or * when a read with less than maxpkt is found. * Use the software list and not qh->elink to avoid races. * We could use qh->elink to see if there's something new or not. */ static void qhinterrupt(Ctlr *ctlr, Qh *qh) { Td *td; int err; ctlr->nqhintr++; if(qh->state != Qrun) panic("qhinterrupt: qh state"); if(qh->tds == nil) panic("qhinterrupt: no tds"); if((qh->tds->csw & Tdactive) == 0) ddqprint("qhinterrupt port %#ux qh %#p p0 %#x p1 %#x\n", ctlr->port, qh, INS(PORT(0)), INS(PORT(1))); for(td = qh->tds; td != nil; td = td->next){ if(td->csw & Tdactive) return; td->csw &= ~Tdioc; if((td->csw & Tdstalled) != 0){ err = td->csw & Tderrors; /* just stalled is end of xfer but not an error */ if(err != Tdstalled && qh->io->err == nil){ qh->io->err = errmsg(td->csw & Tderrors); dqprint("qhinterrupt: td %#p error %#ux %s\n", td, err, qh->io->err); dqprint("ctlr load %uld\n", ctlr->load); } break; } if((td->csw & Tdnak) != 0){ /* retransmit; not serious */ td->csw &= ~Tdnak; if(td->next == nil) td->csw |= Tdioc; } td->ndata = tdlen(td); if(td->ndata < maxtdlen(td)){ /* EOT */ td = td->next; break; } } /* * Done. Make void the Tds not used (errors or EOT) and wakeup epio. */ qh->elink = QHterm; for(; td != nil; td = td->next) td->ndata = 0; qh->state = Qdone; wakeup(qh->io); } static void interrupt(Ureg*, void *a) { Hci *hp; Ctlr *ctlr; int frptr; int frno; Qh *qh; Isoio *iso; int sts; int cmd; hp = a; ctlr = hp->aux; ilock(ctlr); ctlr->nintr++; sts = INS(Status); if((sts & Sall) == 0){ /* not for us; sharing irq */ iunlock(ctlr); return; } OUTS(Status, sts & Sall); cmd = INS(Cmd); if(debug > 1){ frptr = INL(Flbaseadd); frno = INL(Frnum); frno = TRUNC(frno, Nframes); iprint("cmd %#ux sts %#ux frptr %#ux frno %d\n", cmd, sts, frptr, frno); } ctlr->ntdintr++; /* * Will we know in USB 3.0 who the interrupt was for?. * Do they still teach indexing in CS? * This is Intel's doing. */ for(iso = ctlr->iso; iso != nil; iso = iso->next) if(iso->state == Qrun || iso->state == Qdone) isointerrupt(ctlr, iso); for(qh = ctlr->qhs; qh != nil; qh = qh->next) if(qh->state == Qrun) qhinterrupt(ctlr, qh); else if(qh->state == Qclose) qhlinktd(qh, nil); iunlock(ctlr); } /* * iso->tdu is the next place to put data. When it gets full * it is activated and tdu advanced. */ static long putsamples(Ctlr *ctlr, Isoio *iso, uchar *b, long count) { long n, tot, left; Td *tdu; for(tot = 0; isocanwrite(iso) && tot < count; tot += n){ n = count-tot; tdu = iso->tdu; left = iso->nleft; if(n > maxtdlen(tdu) - left) n = maxtdlen(tdu) - left; iunlock(ctlr); /* can pagefault here */ memmove(tdu->data+left, b+tot, n); ilock(ctlr); if(tdu != iso->tdu) continue; iso->nleft += n; if(iso->nleft == maxtdlen(tdu)){ tdisoinit(iso, tdu, iso->nleft); iso->tdu = tdu->next; iso->nleft = 0; } } return tot; } /* * Queue data for writing and return error status from * last writes done, to maintain buffered data. */ static long episowrite(Ep *ep, Isoio *iso, void *a, long count) { Ctlr *ctlr; uchar *b; int tot; int nw; char *err; iso->debug = ep->debug; iso->delay = ep->sampledelay * ep->samplesz; diprint("uhci: episowrite: %#p ep%d.%d\n", iso, ep->dev->nb, ep->nb); ctlr = ep->hp->aux; eqlock(iso); if(waserror()){ qunlock(iso); nexterror(); } ilock(ctlr); if(iso->state == Qclose){ iunlock(ctlr); error(iso->err ? iso->err : Eio); } iso->state = Qrun; b = a; for(tot = 0; tot < count; tot += nw){ while(isocanwrite(iso) == 0){ iunlock(ctlr); diprint("uhci: episowrite: %#p sleep\n", iso); if(waserror()){ if(iso->err == nil) iso->err = "I/O timed out"; ilock(ctlr); break; } tsleep(iso, isocanwrite, iso, ep->tmout); poperror(); ilock(ctlr); } err = iso->err; iso->err = nil; if(iso->state == Qclose || err != nil){ iunlock(ctlr); error(err ? err : Eio); } if(iso->state != Qrun) panic("episowrite: iso not running"); nw = putsamples(ctlr, iso, b+tot, count-tot); } while(isodelay(iso) == 0){ iunlock(ctlr); sleep(iso, isodelay, iso); ilock(ctlr); } if(iso->state != Qclose) iso->state = Qdone; iunlock(ctlr); err = iso->err; /* in case it failed early */ iso->err = nil; qunlock(iso); poperror(); if(err != nil) error(err); diprint("uhci: episowrite: %#p %d bytes\n", iso, tot); return tot; } /* * Available data is kept at tdu and following tds, up to tdi (excluded). */ static long episoread(Ep *ep, Isoio *iso, void *a, int count) { Ctlr *ctlr; uchar *b; int nr; int tot; Td *tdu; iso->debug = ep->debug; diprint("uhci: episoread: %#p ep%d.%d\n", iso, ep->dev->nb, ep->nb); b = a; ctlr = ep->hp->aux; eqlock(iso); if(waserror()){ qunlock(iso); nexterror(); } iso->err = nil; iso->nerrs = 0; ilock(ctlr); if(iso->state == Qclose){ iunlock(ctlr); error(iso->err ? iso->err : Eio); } iso->state = Qrun; while(isocanread(iso) == 0){ iunlock(ctlr); diprint("uhci: episoread: %#p sleep\n", iso); if(waserror()){ if(iso->err == nil) iso->err = "I/O timed out"; ilock(ctlr); break; } tsleep(iso, isocanread, iso, ep->tmout); poperror(); ilock(ctlr); } if(iso->state == Qclose){ iunlock(ctlr); error(iso->err ? iso->err : Eio); } iso->state = Qdone; for(tot = 0; iso->tdi != iso->tdu && tot < count; tot += nr){ tdu = iso->tdu; if(tdu->csw & Tdactive){ diprint("uhci: episoread: %#p tdu active\n", iso); break; } nr = tdu->ndata; if(tot + nr > count) nr = count - tot; if(nr == 0) print("uhci: ep%d.%d: too many polls\n", ep->dev->nb, ep->nb); else{ iunlock(ctlr); /* We could page fault here */ memmove(b+tot, tdu->data, nr); ilock(ctlr); if(iso->tdu != tdu) continue; if(nr < tdu->ndata) memmove(tdu->data, tdu->data+nr, tdu->ndata - nr); tdu->ndata -= nr; } if(tdu->ndata == 0){ tdisoinit(iso, tdu, ep->maxpkt); iso->tdu = tdu->next; } } iunlock(ctlr); qunlock(iso); poperror(); diprint("uhci: episoread: %#p %d bytes err '%s'\n", iso, tot, iso->err); if(iso->err != nil) error(iso->err); return tot; } static int nexttoggle(int tog) { if(tog == Tddata0) return Tddata1; else return Tddata0; } static Td* epgettd(Ep *ep, Qio *io, int flags, void *a, int count) { Td *td; int tok; if(ep->maxpkt < count) error("maxpkt too short"); td = tdalloc(); if(count <= Tdndata) td->data = td->sbuff; else td->data = td->buff = smalloc(ep->maxpkt); td->buffer = PCIWADDR(td->data); td->ndata = count; if(a != nil && count > 0) memmove(td->data, a, count); td->csw = Tderr2|Tderr1|flags; if(ep->dev->speed == Lowspeed) td->csw |= Tdlow; tok = io->tok | io->toggle; io->toggle = nexttoggle(io->toggle); td->token = ((count-1)<<21) | ((io->usbid&0x7FF)<<8) | tok; return td; } /* * Try to get them idle */ static void aborttds(Qh *qh) { Td *td; qh->elink = QHterm; coherence(); for(td = qh->tds; td != nil; td = td->next){ if(td->csw & Tdactive){ td->ndata = 0; td->csw &= ~(Tdactive|Tdioc); coherence(); } } } static int epiodone(void *a) { Qh *qh; qh = a; return qh->state != Qrun; } static void epiowait(Ctlr *ctlr, Qio *io, int tmout, ulong load) { Qh *qh; int timedout; qh = io->qh; ddqprint("uhci io %#p sleep on qh %#p state %uld\n", io, qh, qh->state); timedout = 0; if(waserror()){ dqprint("uhci io %#p qh %#p timed out\n", io, qh); timedout++; }else{ if(tmout == 0) sleep(io, epiodone, qh); else tsleep(io, epiodone, qh, tmout); poperror(); } ilock(ctlr); if(qh->state == Qrun) timedout = 1; else if(qh->state != Qdone && qh->state != Qclose) panic("epio: queue not done and not closed"); if(timedout){ aborttds(qh); qh->state = Qdone; if(io->err == nil) io->err = "request timed out"; iunlock(ctlr); while(waserror()) ; tsleep(&up->sleep, return0, 0, Abortdelay); poperror(); ilock(ctlr); } if(qh->state != Qclose) qh->state = Qidle; qhlinktd(qh, nil); ctlr->load -= load; iunlock(ctlr); } /* * Non iso I/O. * To make it work for control transfers, the caller may * lock the Qio for the entire control transfer. */ static long epio(Ep *ep, Qio *io, void *a, long count, int mustlock) { Td *td, *ltd, *td0, *ntd; Ctlr *ctlr; Qh* qh; long n, tot; char buf[128]; uchar *c; int saved, ntds, tmout; ulong load; char *err; ctlr = ep->hp->aux; io->debug = ep->debug; tmout = ep->tmout; ddeprint("epio: %s ep%d.%d io %#p count %ld load %uld\n", io->tok == Tdtokin ? "in" : "out", ep->dev->nb, ep->nb, io, count, ctlr->load); if((debug > 1 || ep->debug > 1) && io->tok != Tdtokin){ seprintdata(buf, buf+sizeof(buf), a, count); print("uchi epio: user data: %s\n", buf); } if(mustlock){ eqlock(io); if(waserror()){ qunlock(io); nexterror(); } } io->err = nil; ilock(ctlr); qh = io->qh; if(qh == nil || qh->state == Qclose){ /* Tds released by cancelio */ iunlock(ctlr); error(io->err ? io->err : Eio); } if(qh->state != Qidle) panic("epio: qh not idle"); qh->state = Qinstall; iunlock(ctlr); c = a; td0 = ltd = nil; load = tot = 0; do{ n = ep->maxpkt; if(count-tot < n) n = count-tot; if(c != nil && io->tok != Tdtokin) td = epgettd(ep, io, Tdactive, c+tot, n); else td = epgettd(ep, io, Tdactive|Tdspd, nil, n); if(td0 == nil) td0 = td; else tdlinktd(ltd, td); ltd = td; tot += n; load += ep->load; }while(tot < count); if(td0 == nil || ltd == nil) panic("epio: no td"); ltd->csw |= Tdioc; /* the last one interrupts */ ddeprint("uhci: load %uld ctlr load %uld\n", load, ctlr->load); ilock(ctlr); if(qh->state != Qclose){ io->iotime = TK2MS(MACHP(0)->ticks); qh->state = Qrun; coherence(); qhlinktd(qh, td0); ctlr->load += load; } iunlock(ctlr); epiowait(ctlr, io, tmout, load); if(debug > 1 || ep->debug > 1) dumptd(td0, "epio: got tds: "); err = io->err; tot = 0; c = a; saved = 0; ntds = 0; for(td = td0; td != nil; td = ntd){ ntds++; /* * Use td tok, not io tok, because of setup packets. * Also, if the Td was stalled or active (previous Td * was a short packet), we must save the toggle as it is. */ if(td->csw & (Tdstalled|Tdactive)){ if(saved++ == 0) io->toggle = td->token & Tddata1; }else{ n = td->ndata; if(err == nil && n < 0) err = Eio; if(err == nil && n > 0 && tot < count){ if((tot + n) > count) n = count - tot; if(c != nil && tdtok(td) == Tdtokin){ memmove(c, td->data, n); c += n; } tot += n; } } ntd = td->next; tdfree(td); } if(mustlock){ qunlock(io); poperror(); } ddeprint("epio: io %#p: %d tds: return %ld err '%s'\n", io, ntds, tot, err); if(err != nil) error(err); return tot; } /* * halt condition was cleared on the endpoint. update our toggles. */ static void clrhalt(Ep *ep) { Qio *io; ep->clrhalt = 0; switch(ep->ttype){ case Tbulk: case Tintr: io = ep->aux; if(ep->mode != OREAD){ qlock(&io[OWRITE]); io[OWRITE].toggle = Tddata0; deprint("ep clrhalt for io %#p\n", io+OWRITE); qunlock(&io[OWRITE]); } if(ep->mode != OWRITE){ qlock(&io[OREAD]); io[OREAD].toggle = Tddata0; deprint("ep clrhalt for io %#p\n", io+OREAD); qunlock(&io[OREAD]); } break; } } static long epread(Ep *ep, void *a, long count) { Ctlio *cio; Qio *io; Isoio *iso; char buf[160]; ulong delta; ddeprint("uhci: epread\n"); if(ep->aux == nil) panic("epread: not open"); switch(ep->ttype){ case Tctl: cio = ep->aux; eqlock(cio); if(waserror()){ qunlock(cio); nexterror(); } ddeprint("epread ctl ndata %d\n", cio->ndata); if(cio->ndata < 0) error("request expected"); else if(cio->ndata == 0){ cio->ndata = -1; count = 0; }else{ if(count > cio->ndata) count = cio->ndata; if(count > 0) memmove(a, cio->data, count); /* BUG for big transfers */ free(cio->data); cio->data = nil; cio->ndata = 0; /* signal EOF next time */ } qunlock(cio); poperror(); if(debug>1 || ep->debug){ seprintdata(buf, buf+sizeof(buf), a, count); print("epread: %s\n", buf); } return count; case Tbulk: io = ep->aux; if(ep->clrhalt) clrhalt(ep); return epio(ep, &io[OREAD], a, count, 1); case Tintr: io = ep->aux; delta = TK2MS(MACHP(0)->ticks) - io[OREAD].iotime + 1; if(delta < ep->pollival / 2) tsleep(&up->sleep, return0, 0, ep->pollival/2 - delta); if(ep->clrhalt) clrhalt(ep); return epio(ep, &io[OREAD], a, count, 1); case Tiso: iso = ep->aux; return episoread(ep, iso, a, count); default: panic("epread: bad ep ttype %d", ep->ttype); } } /* * Control transfers are one setup write (data0) * plus zero or more reads/writes (data1, data0, ...) * plus a final write/read with data1 to ack. * For both host to device and device to host we perform * the entire transfer when the user writes the request, * and keep any data read from the device for a later read. * We call epio three times instead of placing all Tds at * the same time because doing so leads to crc/tmout errors * for some devices. * Upon errors on the data phase we must still run the status * phase or the device may cease responding in the future. */ static long epctlio(Ep *ep, Ctlio *cio, void *a, long count) { uchar *c; long len; ddeprint("epctlio: cio %#p ep%d.%d count %ld\n", cio, ep->dev->nb, ep->nb, count); if(count < Rsetuplen) error("short usb comand"); eqlock(cio); free(cio->data); cio->data = nil; cio->ndata = 0; if(waserror()){ qunlock(cio); free(cio->data); cio->data = nil; cio->ndata = 0; nexterror(); } /* set the address if unset and out of configuration state */ if(ep->dev->state != Dconfig && ep->dev->state != Dreset) if(cio->usbid == 0) cio->usbid = ((ep->nb&Epmax)<<7)|(ep->dev->nb&Devmax); c = a; cio->tok = Tdtoksetup; cio->toggle = Tddata0; if(epio(ep, cio, a, Rsetuplen, 0) < Rsetuplen) error(Eio); a = c + Rsetuplen; count -= Rsetuplen; cio->toggle = Tddata1; if(c[Rtype] & Rd2h){ cio->tok = Tdtokin; len = GET2(c+Rcount); if(len <= 0) error("bad length in d2h request"); if(len > Maxctllen) error("d2h data too large to fit in uhci"); a = cio->data = smalloc(len+1); }else{ cio->tok = Tdtokout; len = count; } if(len > 0) if(waserror()) len = -1; else{ len = epio(ep, cio, a, len, 0); poperror(); } if(c[Rtype] & Rd2h){ count = Rsetuplen; cio->ndata = len; cio->tok = Tdtokout; }else{ if(len < 0) count = -1; else count = Rsetuplen + len; cio->tok = Tdtokin; } cio->toggle = Tddata1; epio(ep, cio, nil, 0, 0); qunlock(cio); poperror(); ddeprint("epctlio cio %#p return %ld\n", cio, count); return count; } static long epwrite(Ep *ep, void *a, long count) { Ctlio *cio; Isoio *iso; Qio *io; ulong delta; char *b; int tot; int nw; ddeprint("uhci: epwrite ep%d.%d\n", ep->dev->nb, ep->nb); if(ep->aux == nil) panic("uhci: epwrite: not open"); switch(ep->ttype){ case Tctl: cio = ep->aux; return epctlio(ep, cio, a, count); case Tbulk: io = ep->aux; if(ep->clrhalt) clrhalt(ep); /* * Put at most Tdatomic Tds (512 bytes) at a time. * Otherwise some devices produce babble errors. */ b = a; for(tot = 0; tot < count ; tot += nw){ nw = count - tot; if(nw > Tdatomic * ep->maxpkt) nw = Tdatomic * ep->maxpkt; nw = epio(ep, &io[OWRITE], b+tot, nw, 1); } return tot; case Tintr: io = ep->aux; delta = TK2MS(MACHP(0)->ticks) - io[OWRITE].iotime + 1; if(delta < ep->pollival) tsleep(&up->sleep, return0, 0, ep->pollival - delta); if(ep->clrhalt) clrhalt(ep); return epio(ep, &io[OWRITE], a, count, 1); case Tiso: iso = ep->aux; return episowrite(ep, iso, a, count); default: panic("uhci: epwrite: bad ep ttype %d", ep->ttype); } } static void isoopen(Ep *ep) { Ctlr *ctlr; Isoio *iso; int frno; int i; Td* td; Td* ltd; int size; int left; if(ep->mode == ORDWR) error("iso i/o is half-duplex"); ctlr = ep->hp->aux; iso = ep->aux; iso->debug = ep->debug; iso->next = nil; /* paranoia */ if(ep->mode == OREAD) iso->tok = Tdtokin; else iso->tok = Tdtokout; iso->usbid = ((ep->nb & Epmax)<<7)|(ep->dev->nb & Devmax); iso->state = Qidle; iso->nframes = Nframes/ep->pollival; if(iso->nframes < 3) error("uhci isoopen bug"); /* we need at least 3 tds */ ilock(ctlr); if(ctlr->load + ep->load > 800) print("usb: uhci: bandwidth may be exceeded\n"); ctlr->load += ep->load; ctlr->isoload += ep->load; dprint("uhci: load %uld isoload %uld\n", ctlr->load, ctlr->isoload); iunlock(ctlr); /* * From here on this cannot raise errors * unless we catch them and release here all memory allocated. */ if(ep->maxpkt > Tdndata) iso->data = smalloc(iso->nframes*ep->maxpkt); ilock(ctlr); frno = INS(Frnum) + 10; /* start 10ms ahead */ frno = TRUNC(frno, Nframes); iunlock(ctlr); iso->td0frno = frno; ltd = nil; left = 0; for(i = 0; i < iso->nframes; i++){ td = iso->tdps[frno] = tdalloc(); if(ep->mode == OREAD) size = ep->maxpkt; else{ size = (ep->hz+left) * ep->pollival / 1000; size *= ep->samplesz; left = (ep->hz+left) * ep->pollival % 1000; if(size > ep->maxpkt){ print("uhci: ep%d.%d: size > maxpkt\n", ep->dev->nb, ep->nb); print("size = %d max = %ld\n", size, ep->maxpkt); size = ep->maxpkt; } } if(size > Tdndata) td->data = iso->data + i * ep->maxpkt; else td->data = td->sbuff; td->buffer = PCIWADDR(td->data); tdisoinit(iso, td, size); if(ltd != nil) ltd->next = td; ltd = td; frno = TRUNC(frno+ep->pollival, Nframes); } ltd->next = iso->tdps[iso->td0frno]; iso->tdi = iso->tdps[iso->td0frno]; iso->tdu = iso->tdi; ilock(ctlr); frno = iso->td0frno; for(i = 0; i < iso->nframes; i++){ iso->tdps[frno]->link = ctlr->frames[frno]; frno = TRUNC(frno+ep->pollival, Nframes); } coherence(); frno = iso->td0frno; for(i = 0; i < iso->nframes; i++){ ctlr->frames[frno] = PCIWADDR(iso->tdps[frno]); frno = TRUNC(frno+ep->pollival, Nframes); } iso->next = ctlr->iso; ctlr->iso = iso; iso->state = Qdone; iunlock(ctlr); if(debug > 1 || iso->debug >1) isodump(iso, 0); } /* * Allocate the endpoint and set it up for I/O * in the controller. This must follow what's said * in Ep regarding configuration, including perhaps * the saved toggles (saved on a previous close of * the endpoint data file by epclose). */ static void epopen(Ep *ep) { Ctlr *ctlr; Qh *cqh; Qio *io; Ctlio *cio; int usbid; ctlr = ep->hp->aux; deprint("uhci: epopen ep%d.%d\n", ep->dev->nb, ep->nb); if(ep->aux != nil) panic("uhci: epopen called with open ep"); if(waserror()){ free(ep->aux); ep->aux = nil; nexterror(); } if(ep->maxpkt > Tdmaxpkt){ print("uhci: maxkpkt too large: using %d\n", Tdmaxpkt); ep->maxpkt = Tdmaxpkt; } cqh = ctlr->qh[ep->ttype]; switch(ep->ttype){ case Tnone: error("endpoint not configured"); case Tiso: ep->aux = smalloc(sizeof(Isoio)); isoopen(ep); break; case Tctl: cio = ep->aux = smalloc(sizeof(Ctlio)); cio->debug = ep->debug; cio->ndata = -1; cio->data = nil; if(ep->dev->isroot != 0 && ep->nb == 0) /* root hub */ break; cio->qh = qhalloc(ctlr, cqh, cio, "epc"); break; case Tbulk: case Tintr: io = ep->aux = smalloc(sizeof(Qio)*2); io[OREAD].debug = io[OWRITE].debug = ep->debug; usbid = ((ep->nb&Epmax)<<7)|(ep->dev->nb&Devmax); if(ep->mode != OREAD){ if(ep->toggle[OWRITE] != 0) io[OWRITE].toggle = Tddata1; else io[OWRITE].toggle = Tddata0; io[OWRITE].tok = Tdtokout; io[OWRITE].qh = qhalloc(ctlr, cqh, io+OWRITE, "epw"); io[OWRITE].usbid = usbid; } if(ep->mode != OWRITE){ if(ep->toggle[OREAD] != 0) io[OREAD].toggle = Tddata1; else io[OREAD].toggle = Tddata0; io[OREAD].tok = Tdtokin; io[OREAD].qh = qhalloc(ctlr, cqh, io+OREAD, "epr"); io[OREAD].usbid = usbid; } break; } if(debug>1 || ep->debug) dump(ep->hp); deprint("uhci: epopen done\n"); poperror(); } static void cancelio(Ctlr *ctlr, Qio *io) { Qh *qh; ilock(ctlr); qh = io->qh; if(qh == nil || qh->state == Qclose){ iunlock(ctlr); return; } dqprint("uhci: cancelio for qh %#p state %s\n", qh, qhsname[qh->state]); aborttds(qh); qh->state = Qclose; iunlock(ctlr); while(waserror()) ; tsleep(&up->sleep, return0, 0, Abortdelay); poperror(); wakeup(io); qlock(io); /* wait for epio if running */ if(io->qh == qh) io->qh = nil; qunlock(io); qhfree(ctlr, qh); } static void cancelisoio(Ctlr *ctlr, Isoio *iso, int pollival, ulong load) { Isoio **il; ulong *lp; int i; int frno; Td *td; ilock(ctlr); if(iso->state == Qclose){ iunlock(ctlr); return; } if(iso->state != Qrun && iso->state != Qdone) panic("bad iso state"); iso->state = Qclose; if(ctlr->isoload < load) panic("uhci: low isoload"); ctlr->isoload -= load; ctlr->load -= load; for(il = &ctlr->iso; *il != nil; il = &(*il)->next) if(*il == iso) break; if(*il == nil) panic("isocancel: not found"); *il = iso->next; frno = iso->td0frno; for(i = 0; i < iso->nframes; i++){ td = iso->tdps[frno]; td->csw &= ~(Tdioc|Tdactive); for(lp=&ctlr->frames[frno]; !(*lp & Tdterm); lp = &TPTR(*lp)->link) if(TPTR(*lp) == td) break; if(*lp & Tdterm) panic("cancelisoio: td not found"); *lp = td->link; frno = TRUNC(frno+pollival, Nframes); } iunlock(ctlr); /* * wakeup anyone waiting for I/O and * wait to be sure no I/O is in progress in the controller. * and then wait to be sure episo-io is no longer running. */ wakeup(iso); diprint("cancelisoio iso %#p waiting for I/O to cease\n", iso); tsleep(&up->sleep, return0, 0, 5); qlock(iso); qunlock(iso); diprint("cancelisoio iso %#p releasing iso\n", iso); frno = iso->td0frno; for(i = 0; i < iso->nframes; i++){ tdfree(iso->tdps[frno]); iso->tdps[frno] = nil; frno = TRUNC(frno+pollival, Nframes); } free(iso->data); iso->data = nil; } static void epclose(Ep *ep) { Ctlr *ctlr; Ctlio *cio; Isoio *iso; Qio *io; ctlr = ep->hp->aux; deprint("uhci: epclose ep%d.%d\n", ep->dev->nb, ep->nb); if(ep->aux == nil) panic("uhci: epclose called with closed ep"); switch(ep->ttype){ case Tctl: cio = ep->aux; cancelio(ctlr, cio); free(cio->data); cio->data = nil; break; case Tbulk: case Tintr: io = ep->aux; ep->toggle[OREAD] = ep->toggle[OWRITE] = 0; if(ep->mode != OWRITE){ cancelio(ctlr, &io[OREAD]); if(io[OREAD].toggle == Tddata1) ep->toggle[OREAD] = 1; } if(ep->mode != OREAD){ cancelio(ctlr, &io[OWRITE]); if(io[OWRITE].toggle == Tddata1) ep->toggle[OWRITE] = 1; } break; case Tiso: iso = ep->aux; cancelisoio(ctlr, iso, ep->pollival, ep->load); break; default: panic("epclose: bad ttype %d", ep->ttype); } free(ep->aux); ep->aux = nil; } static char* seprintep(char *s, char *e, Ep *ep) { Ctlio *cio; Qio *io; Isoio *iso; Ctlr *ctlr; ctlr = ep->hp->aux; ilock(ctlr); if(ep->aux == nil){ *s = 0; iunlock(ctlr); return s; } switch(ep->ttype){ case Tctl: cio = ep->aux; s = seprint(s,e,"cio %#p qh %#p" " id %#x tog %#x tok %#x err %s\n", cio, cio->qh, cio->usbid, cio->toggle, cio->tok, cio->err); break; case Tbulk: case Tintr: io = ep->aux; if(ep->mode != OWRITE) s = seprint(s,e,"r: qh %#p id %#x tog %#x tok %#x err %s\n", io[OREAD].qh, io[OREAD].usbid, io[OREAD].toggle, io[OREAD].tok, io[OREAD].err); if(ep->mode != OREAD) s = seprint(s,e,"w: qh %#p id %#x tog %#x tok %#x err %s\n", io[OWRITE].qh, io[OWRITE].usbid, io[OWRITE].toggle, io[OWRITE].tok, io[OWRITE].err); break; case Tiso: iso = ep->aux; s = seprint(s,e,"iso %#p id %#x tok %#x tdu %#p tdi %#p err %s\n", iso, iso->usbid, iso->tok, iso->tdu, iso->tdi, iso->err); break; } iunlock(ctlr); return s; } static int portenable(Hci *hp, int port, int on) { int s; int ioport; Ctlr *ctlr; ctlr = hp->aux; dprint("uhci: %#x port %d enable=%d\n", ctlr->port, port, on); ioport = PORT(port-1); eqlock(&ctlr->portlck); if(waserror()){ qunlock(&ctlr->portlck); nexterror(); } ilock(ctlr); s = INS(ioport); if(on) OUTS(ioport, s | PSenable); else OUTS(ioport, s & ~PSenable); microdelay(64); iunlock(ctlr); tsleep(&up->sleep, return0, 0, Enabledelay); dprint("uhci %#ux port %d enable=%d: sts %#x\n", ctlr->port, port, on, INS(ioport)); qunlock(&ctlr->portlck); poperror(); return 0; } static int portreset(Hci *hp, int port, int on) { int i, p; Ctlr *ctlr; if(on == 0) return 0; ctlr = hp->aux; dprint("uhci: %#ux port %d reset\n", ctlr->port, port); p = PORT(port-1); ilock(ctlr); OUTS(p, PSreset); delay(50); OUTS(p, INS(p) & ~PSreset); OUTS(p, INS(p) | PSenable); microdelay(64); for(i=0; i<1000 && (INS(p) & PSenable) == 0; i++) ; OUTS(p, (INS(p) & ~PSreset)|PSenable); iunlock(ctlr); dprint("uhci %#ux after port %d reset: sts %#x\n", ctlr->port, port, INS(p)); return 0; } static int portstatus(Hci *hp, int port) { int s; int r; int ioport; Ctlr *ctlr; ctlr = hp->aux; ioport = PORT(port-1); eqlock(&ctlr->portlck); if(waserror()){ iunlock(ctlr); qunlock(&ctlr->portlck); nexterror(); } ilock(ctlr); s = INS(ioport); if(s & (PSstatuschg | PSchange)){ OUTS(ioport, s); ddprint("uhci %#ux port %d status %#x\n", ctlr->port, port, s); } iunlock(ctlr); qunlock(&ctlr->portlck); poperror(); /* * We must return status bits as a * get port status hub request would do. */ r = 0; if(s & PSpresent) r |= HPpresent; if(s & PSenable) r |= HPenable; if(s & PSsuspend) r |= HPsuspend; if(s & PSreset) r |= HPreset; if(s & PSslow) r |= HPslow; if(s & PSstatuschg) r |= HPstatuschg; if(s & PSchange) r |= HPchange; return r; } static Ctlr* scanpci(void) { static Ctlr *first, **lastp; Ctlr *ctlr; Pcidev *p; int io; if(lastp != nil) return first; lastp = &first; p = nil; while(p = pcimatch(p, 0, 0)){ /* * Find UHCI controllers (Programming Interface = 0). */ if(p->ccrb != Pcibcserial || p->ccru != Pciscusb) continue; switch(p->ccrp){ case 0: if((p->mem[4].bar & 1) == 0) continue; io = p->mem[4].bar & ~3; break; default: continue; } if(io == 0){ print("usbuhci: %#x %#x: failed to map registers\n", p->vid, p->did); continue; } if(ioalloc(io, p->mem[4].size, 0, "usbuhci") < 0){ print("usbuhci: port %#ux in use\n", io); continue; } print("uhci: %#x %#x: port %#ux size %lld irq %d\n", p->vid, p->did, io, p->mem[4].size, p->intl); ctlr = malloc(sizeof(Ctlr)); if(ctlr == nil){ iofree(io); print("usbuhci: no memory\n"); continue; } ctlr->pcidev = p; ctlr->port = io; *lastp = ctlr; lastp = &ctlr->next; } return first; } static void uhcimeminit(Ctlr *ctlr) { Td* td; Qh *qh; int frsize; int i; ctlr->qhs = ctlr->qh[Tctl] = qhalloc(ctlr, nil, nil, "CTL"); ctlr->qh[Tintr] = qhalloc(ctlr, ctlr->qh[Tctl], nil, "INT"); ctlr->qh[Tbulk] = qhalloc(ctlr, ctlr->qh[Tintr], nil, "BLK"); /* idle Td from dummy Qh at the end. looped back to itself */ /* This is a workaround for PIIX4 errata 29773804.pdf */ qh = qhalloc(ctlr, ctlr->qh[Tbulk], nil, "BWS"); td = tdalloc(); td->link = PCIWADDR(td); qhlinktd(qh, td); /* loop (hw only) from the last qh back to control xfers. * this may be done only for some of them. Disable until ehci comes. */ if(0) qh->link = PCIWADDR(ctlr->qhs); frsize = Nframes*sizeof(ulong); ctlr->frames = xspanalloc(frsize, frsize, 0); if(ctlr->frames == nil) panic("uhci reset: no memory"); ctlr->iso = nil; for(i = 0; i < Nframes; i++) ctlr->frames[i] = PCIWADDR(ctlr->qhs)|QHlinkqh; OUTL(Flbaseadd, PCIWADDR(ctlr->frames)); OUTS(Frnum, 0); dprint("uhci %#ux flb %#ulx frno %#ux\n", ctlr->port, INL(Flbaseadd), INS(Frnum)); } static void init(Hci *hp) { Ctlr *ctlr; int sts; int i; ctlr = hp->aux; dprint("uhci %#ux init\n", ctlr->port); coherence(); ilock(ctlr); OUTS(Usbintr, Itmout|Iresume|Ioc|Ishort); uhcirun(ctlr, 1); dprint("uhci: init: cmd %#ux sts %#ux sof %#ux", INS(Cmd), INS(Status), INS(SOFmod)); dprint(" flb %#ulx frno %#ux psc0 %#ux psc1 %#ux", INL(Flbaseadd), INS(Frnum), INS(PORT(0)), INS(PORT(1))); /* guess other ports */ for(i = 2; i < 6; i++){ sts = INS(PORT(i)); if(sts != 0xFFFF && (sts & PSreserved1) == 1){ dprint(" psc%d %#ux", i, sts); hp->nports++; }else break; } for(i = 0; i < hp->nports; i++) OUTS(PORT(i), 0); iunlock(ctlr); } static void uhcireset(Ctlr *ctlr) { int i; int sof; ilock(ctlr); dprint("uhci %#ux reset\n", ctlr->port); /* * Turn off legacy mode. Some controllers won't * interrupt us as expected otherwise. */ uhcirun(ctlr, 0); pcicfgw16(ctlr->pcidev, 0xc0, 0x2000); OUTS(Usbintr, 0); sof = INB(SOFmod); uhcicmd(ctlr, Cgreset); /* global reset */ delay(Resetdelay); uhcicmd(ctlr, 0); /* all halt */ uhcicmd(ctlr, Chcreset); /* controller reset */ for(i = 0; i < 100; i++){ if((INS(Cmd) & Chcreset) == 0) break; delay(1); } if(i == 100) print("uhci %#x controller reset timed out\n", ctlr->port); OUTB(SOFmod, sof); iunlock(ctlr); } static void setdebug(Hci*, int d) { debug = d; } static void shutdown(Hci *hp) { Ctlr *ctlr; ctlr = hp->aux; ilock(ctlr); uhcirun(ctlr, 0); delay(100); iunlock(ctlr); } static int reset(Hci *hp) { Ctlr *ctlr; Pcidev *p; if(getconf("*nousbuhci")) return -1; /* * Any adapter matches if no hp->port is supplied, * otherwise the ports must match. */ for(ctlr = scanpci(); ctlr != nil; ctlr = ctlr->next){ if(ctlr->active == 0) if(hp->port == 0 || hp->port == ctlr->port){ ctlr->active = 1; break; } } if(ctlr == nil) return -1; p = ctlr->pcidev; pcienable(p); hp->aux = ctlr; hp->port = ctlr->port; hp->irq = p->intl; hp->tbdf = p->tbdf; hp->nports = 2; /* default */ uhcireset(ctlr); uhcimeminit(ctlr); pcisetbme(p); /* * Linkage to the generic HCI driver. */ hp->init = init; hp->dump = dump; hp->interrupt = interrupt; hp->epopen = epopen; hp->epclose = epclose; hp->epread = epread; hp->epwrite = epwrite; hp->seprintep = seprintep; hp->portenable = portenable; hp->portreset = portreset; hp->portstatus = portstatus; hp->shutdown = shutdown; hp->debug = setdebug; hp->type = "uhci"; intrenable(hp->irq, hp->interrupt, hp, hp->tbdf, hp->type); return 0; } void usbuhcilink(void) { addhcitype("uhci", reset); }