ref: 2127b8c552390cdaeb848d0992d2923733936d09
dir: /sys/src/9/kw/ether1116.c/
/* * marvell kirkwood gigabit ethernet (88e1116 and 88e1121) driver * (as found in the sheevaplug, openrd and guruplug). * the main difference is the flavour of phy kludgery necessary. * * from /public/doc/marvell/88f61xx.kirkwood.pdf, * /public/doc/marvell/88e1116.pdf, and * /public/doc/marvell/88e1121r.pdf. */ #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/netif.h" #include "etherif.h" #include "ethermii.h" #include "../ip/ip.h" #define MIIDBG if(0)iprint #define WINATTR(v) (((v) & MASK(8)) << 8) #define WINSIZE(v) (((v)/(64*1024) - 1) << 16) enum { Nrx = 512, Ntx = 32, Nrxblks = 1024, Rxblklen = 2+1522, /* ifc. supplies first 2 bytes as padding */ Maxrxintrsec = 20*1000, /* max. rx intrs. / sec */ Etherstuck = 70, /* must send or receive a packet in this many sec.s */ Descralign = 16, Bufalign = 8, Pass = 1, /* accept packets */ Qno = 0, /* do everything on queue zero */ }; typedef struct Ctlr Ctlr; typedef struct Gbereg Gbereg; typedef struct Mibstats Mibstats; typedef struct Rx Rx; typedef struct Tx Tx; static struct { Lock; Block *head; } freeblocks; /* hardware receive buffer descriptor */ struct Rx { ulong cs; ulong countsize; /* bytes, buffer size */ ulong buf; /* phys. addr. of packet buffer */ ulong next; /* phys. addr. of next Rx */ }; /* hardware transmit buffer descriptor */ struct Tx { ulong cs; ulong countchk; /* bytes, checksum */ ulong buf; /* phys. addr. of packet buffer */ ulong next; /* phys. addr. of next Tx */ }; /* fixed by hw; part of Gberegs */ struct Mibstats { union { uvlong rxby; /* good bytes rcv'd */ struct { ulong rxbylo; ulong rxbyhi; }; }; ulong badrxby; /* bad bytes rcv'd */ ulong mactxerr; /* tx err pkts */ ulong rxpkt; /* good pkts rcv'd */ ulong badrxpkt; /* bad pkts rcv'd */ ulong rxbcastpkt; /* b'cast pkts rcv'd */ ulong rxmcastpkt; /* m'cast pkts rcv'd */ ulong rx64; /* pkts <= 64 bytes */ ulong rx65_127; /* pkts 65—127 bytes */ ulong rx128_255; /* pkts 128—255 bytes */ ulong rx256_511; /* pkts 256—511 bytes */ ulong rx512_1023; /* pkts 512—1023 bytes */ ulong rx1024_max; /* pkts >= 1024 bytes */ union { uvlong txby; /* good bytes sent */ struct { ulong txbylo; ulong txbyhi; }; }; ulong txpkt; /* good pkts sent */ /* half-duplex: pkts dropped due to excessive collisions */ ulong txcollpktdrop; ulong txmcastpkt; /* m'cast pkts sent */ ulong txbcastpkt; /* b'cast pkts sent */ ulong badmacctlpkts; /* bad mac ctl pkts */ ulong txflctl; /* flow-control pkts sent */ ulong rxflctl; /* good flow-control pkts rcv'd */ ulong badrxflctl; /* bad flow-control pkts rcv'd */ ulong rxundersized; /* runts */ ulong rxfrags; /* fragments rcv'd */ ulong rxtoobig; /* oversized pkts rcv'd */ ulong rxjabber; /* jabber pkts rcv'd */ ulong rxerr; /* rx error events */ ulong crcerr; /* crc error events */ ulong collisions; /* collision events */ ulong latecoll; /* late collisions */ }; struct Ctlr { Lock; Ether *ether; Gbereg *reg; Lock initlock; int init; Rx *rx; /* receive descriptors */ Block *rxb[Nrx]; /* blocks belonging to the descriptors */ int rxhead; /* descr ethernet will write to next */ int rxtail; /* next descr that might need a buffer */ Rendez rrendez; /* interrupt wakes up read process */ int haveinput; Tx *tx; Block *txb[Ntx]; int txhead; /* next descr we can use for new packet */ int txtail; /* next descr to reclaim on tx complete */ Mii *mii; int port; /* stats */ ulong intrs; ulong newintrs; ulong txunderrun; ulong txringfull; ulong rxdiscard; ulong rxoverrun; ulong nofirstlast; Mibstats; }; #define Rxqon(q) (1<<(q)) #define Txqon(q) (1<<(q)) enum { /* euc bits */ Portreset = 1 << 20, /* sdma config, sdc bits */ Burst1 = 0, Burst2, Burst4, Burst8, Burst16, SDCrifb = 1<<0, /* rx intr on pkt boundaries */ #define SDCrxburst(v) ((v)<<1) SDCrxnobyteswap = 1<<4, SDCtxnobyteswap = 1<<5, SDCswap64byte = 1<<6, #define SDCtxburst(v) ((v)<<22) /* rx intr ipg (inter packet gap) */ #define SDCipgintrx(v) ((((v)>>15) & 1)<<25) | (((v) & MASK(15))<<7) /* portcfg bits */ PCFGupromisc = 1<<0, /* unicast promiscuous mode */ #define Rxqdefault(q) ((q)<<1) #define Rxqarp(q) ((q)<<4) PCFGbcrejectnoiparp = 1<<7, PCFGbcrejectip = 1<<8, PCFGbcrejectarp = 1<<9, PCFGamnotxes = 1<<12, /* auto mode, no summary update on tx */ PCFGtcpq = 1<<14, /* capture tcp frames to tcpq */ PCFGudpq = 1<<15, /* capture udp frames to udpq */ #define Rxqtcp(q) ((q)<<16) #define Rxqudp(q) ((q)<<19) #define Rxqbpdu(q) ((q)<<22) PCFGrxcs = 1<<25, /* rx tcp checksum mode with header */ /* portcfgx bits */ PCFGXspanq = 1<<1, PCFGXcrcoff = 1<<2, /* no ethernet crc */ /* port serial control0, psc0 bits */ PSC0porton = 1<<0, PSC0forcelinkup = 1<<1, PSC0an_dplxoff = 1<<2, /* an_ = auto. negotiate */ PSC0an_flctloff = 1<<3, PSC0an_pauseadv = 1<<4, PSC0nofrclinkdown = 1<<10, PSC0an_spdoff = 1<<13, PSC0dteadv = 1<<14, /* dte advertise */ /* max. input pkt size */ #define PSC0mru(v) ((v)<<17) PSC0mrumask = PSC0mru(MASK(3)), PSC0mru1518 = 0, /* 1500+2* 6(addrs) +2 + 4(crc) */ PSC0mru1522, /* 1518 + 4(vlan tags) */ PSC0mru1552, /* `baby giant' */ PSC0mru9022, /* `jumbo' */ PSC0mru9192, /* bigger jumbo */ PSC0mru9700, /* still bigger jumbo */ PSC0fd_frc = 1<<21, /* force full duplex */ PSC0flctlfrc = 1<<22, PSC0gmiispd_gbfrc = 1<<23, PSC0miispdfrc100mbps = 1<<24, /* port status 0, ps0 bits */ PS0linkup = 1<<1, PS0fd = 1<<2, /* full duplex */ PS0flctl = 1<<3, PS0gmii_gb = 1<<4, PS0mii100mbps = 1<<5, PS0txbusy = 1<<7, PS0txfifoempty = 1<<10, PS0rxfifo1empty = 1<<11, PS0rxfifo2empty = 1<<12, /* port serial control 1, psc1 bits */ PSC1loopback = 1<<1, PSC1mii = 0<<2, PSC1rgmii = 1<<3, /* enable RGMII */ PSC1portreset = 1<<4, PSC1clockbypass = 1<<5, PSC1iban = 1<<6, PSC1iban_bypass = 1<<7, PSC1iban_restart= 1<<8, PSC1_gbonly = 1<<11, PSC1encolonbp = 1<<15, /* "collision during back-pressure mib counting" */ PSC1coldomlimmask= MASK(6)<<16, #define PSC1coldomlim(v) (((v) & MASK(6))<<16) PSC1miiallowoddpreamble = 1<<22, /* port status 1, ps1 bits */ PS1rxpause = 1<<0, PS1txpause = 1<<1, PS1pressure = 1<<2, PS1syncfail10ms = 1<<3, PS1an_done = 1<<4, PS1inbandan_bypassed = 1<<5, PS1serdesplllocked = 1<<6, PS1syncok = 1<<7, PS1nosquelch = 1<<8, /* irq bits */ /* rx buf returned to cpu ownership, or frame reception finished */ Irx = 1<<0, Iextend = 1<<1, /* IEsum of irqe set */ #define Irxbufferq(q) (1<<((q)+2)) /* rx buf returned to cpu ownership */ Irxerr = 1<<10, /* input ring full, usually */ #define Irxerrq(q) (1<<((q)+11)) #define Itxendq(q) (1<<((q)+19)) /* tx dma stopped for q */ Isum = 1<<31, /* irq extended, irqe bits */ #define IEtxbufferq(q) (1<<((q)+0)) /* tx buf returned to cpu ownership */ #define IEtxerrq(q) (1<<((q)+8)) IEphystschg = 1<<16, IEptp = 1<<17, IErxoverrun = 1<<18, IEtxunderrun = 1<<19, IElinkchg = 1<<20, IEintaddrerr = 1<<23, IEprbserr = 1<<25, IEsum = 1<<31, /* tx fifo urgent threshold (tx interrupt coalescing), pxtfut */ #define TFUTipginttx(v) (((v) & MASK(16))<<4); /* minimal frame size, mfs */ MFS40by = 10<<2, MFS44by = 11<<2, MFS48by = 12<<2, MFS52by = 13<<2, MFS56by = 14<<2, MFS60by = 15<<2, MFS64by = 16<<2, /* receive descriptor status */ RCSmacerr = 1<<0, RCSmacmask = 3<<1, RCSmacce = 0<<1, RCSmacor = 1<<1, RCSmacmf = 2<<1, RCSl4chkshift = 3, RCSl4chkmask = MASK(16), RCSvlan = 1<<17, RCSbpdu = 1<<18, RCSl4mask = 3<<21, RCSl4tcp4 = 0<<21, RCSl4udp4 = 1<<21, RCSl4other = 2<<21, RCSl4rsvd = 3<<21, RCSl2ev2 = 1<<23, RCSl3ip4 = 1<<24, RCSip4headok = 1<<25, RCSlast = 1<<26, RCSfirst = 1<<27, RCSunknownaddr = 1<<28, RCSenableintr = 1<<29, RCSl4chkok = 1<<30, RCSdmaown = 1<<31, /* transmit descriptor status */ TCSmacerr = 1<<0, TCSmacmask = 3<<1, TCSmaclc = 0<<1, TCSmacur = 1<<1, TCSmacrl = 2<<1, TCSllc = 1<<9, TCSl4chkmode = 1<<10, TCSipv4hdlenshift= 11, TCSvlan = 1<<15, TCSl4type = 1<<16, TCSgl4chk = 1<<17, TCSgip4chk = 1<<18, TCSpadding = 1<<19, TCSlast = 1<<20, TCSfirst = 1<<21, TCSenableintr = 1<<23, TCSautomode = 1<<30, TCSdmaown = 1<<31, }; enum { /* SMI regs */ PhysmiTimeout = 10000, /* what units? in ms. */ Physmidataoff = 0, /* Data */ Physmidatamask = 0xffff<<Physmidataoff, Physmiaddroff = 16, /* PHY device addr */ Physmiaddrmask = 0x1f << Physmiaddroff, Physmiop = 26, Physmiopmask = 3<<Physmiop, PhysmiopWr = 0<<Physmiop, PhysmiopRd = 1<<Physmiop, PhysmiReadok = 1<<27, PhysmiBusy = 1<<28, SmiRegaddroff = 21, /* PHY device register addr */ SmiRegaddrmask = 0x1f << SmiRegaddroff, }; struct Gbereg { ulong phy; /* PHY address */ ulong smi; /* serial mgmt. interface */ ulong euda; /* ether default address */ ulong eudid; /* ether default id */ uchar _pad0[0x80-0x10]; /* dma stuff */ ulong euirq; /* interrupt cause */ ulong euirqmask; /* interrupt mask */ uchar _pad1[0x94-0x88]; ulong euea; /* error address */ ulong euiae; /* internal error address */ uchar _pad2[0xb0-0x9c]; ulong euc; /* control */ uchar _pad3[0x200-0xb4]; struct { ulong base; /* window base */ ulong size; /* window size */ } base[6]; uchar _pad4[0x280-0x230]; ulong harr[4]; /* high address remap */ ulong bare; /* base address enable */ ulong epap; /* port access protect */ uchar _pad5[0x400-0x298]; ulong portcfg; /* port configuration */ ulong portcfgx; /* port config. extend */ ulong mii; /* mii serial parameters */ ulong _pad6; ulong evlane; /* vlan ether type */ ulong macal; /* mac address low */ ulong macah; /* mac address high */ ulong sdc; /* sdma config. */ ulong dscp[7]; /* ip diff. serv. code point -> pri */ ulong psc0; /* port serial control 0 */ ulong vpt2p; /* vlan priority tag -> pri */ ulong ps0; /* ether port status 0 */ ulong tqc; /* transmit queue command */ ulong psc1; /* port serial control 1 */ ulong ps1; /* ether port status 1 */ ulong mvhdr; /* marvell header */ ulong _pad8[2]; /* interrupts */ ulong irq; /* interrupt cause; some rw0c bits */ ulong irqe; /* " " extended; some rw0c bits */ ulong irqmask; /* interrupt mask (actually enable) */ ulong irqemask; /* " " extended */ ulong _pad9; ulong pxtfut; /* port tx fifo urgent threshold */ ulong _pad10; ulong pxmfs; /* port rx minimum frame size */ ulong _pad11; /* * # of input frames discarded by addr filtering or lack of resources; * zeroed upon read. */ ulong pxdfc; /* port rx discard frame counter */ ulong pxofc; /* port overrun frame counter */ ulong _pad12[2]; ulong piae; /* port internal address error */ uchar _pad13[0x4bc-0x498]; ulong etherprio; /* ether type priority */ uchar _pad14[0x4dc-0x4c0]; ulong tqfpc; /* tx queue fixed priority config. */ ulong pttbrc; /* port tx token-bucket rate config. */ ulong tqc1; /* tx queue command 1 */ ulong pmtu; /* port maximum transmit unit */ ulong pmtbs; /* port maximum token bucket size */ uchar _pad15[0x600-0x4f0]; struct { ulong _pad[3]; ulong r; /* phys. addr.: cur. rx desc. ptrs */ } crdp[8]; ulong rqc; /* rx queue command */ ulong tcsdp; /* phys. addr.: cur. tx desc. ptr */ uchar _pad16[0x6c0-0x688]; ulong tcqdp[8]; /* phys. addr.: cur. tx q. desc. ptr */ uchar _pad17[0x700-0x6e0]; struct { ulong tbctr; /* queue tx token-bucket counter */ ulong tbcfg; /* tx queue token-bucket config. */ ulong acfg; /* tx queue arbiter config. */ ulong _pad; } tq[8]; ulong pttbc; /* port tx token-bucket counter */ uchar _pad18[0x7a8-0x784]; ulong ipg2; /* tx queue ipg */ ulong _pad19[3]; ulong ipg3; ulong _pad20; ulong htlp; /* high token in low packet */ ulong htap; /* high token in async packet */ ulong ltap; /* low token in async packet */ ulong _pad21; ulong ts; /* tx speed */ uchar _pad22[0x1000-0x7d4]; /* mac mib counters: statistics */ Mibstats; uchar _pad23[0x1400-0x1080]; /* multicast filtering; each byte: Qno<<1 | Pass */ ulong dfsmt[64]; /* dest addr filter special m'cast table */ ulong dfomt[64]; /* dest addr filter other m'cast table */ /* unicast filtering */ ulong dfut[4]; /* dest addr filter unicast table */ }; static Ctlr *ctlrs[MaxEther]; static uchar zeroea[Eaddrlen]; static void getmibstats(Ctlr *); static void rxfreeb(Block *b) { b->wp = b->rp = (uchar*)((uintptr)(b->lim - Rxblklen) & ~(Bufalign - 1)); assert(((uintptr)b->rp & (Bufalign - 1)) == 0); b->free = rxfreeb; ilock(&freeblocks); b->next = freeblocks.head; freeblocks.head = b; iunlock(&freeblocks); } static Block * rxallocb(void) { Block *b; ilock(&freeblocks); b = freeblocks.head; if(b != nil) { freeblocks.head = b->next; b->next = nil; b->free = rxfreeb; } iunlock(&freeblocks); return b; } static void rxkick(Ctlr *ctlr) { Gbereg *reg = ctlr->reg; if (reg->crdp[Qno].r == 0) reg->crdp[Qno].r = PADDR(&ctlr->rx[ctlr->rxhead]); if ((reg->rqc & 0xff) == 0) /* all queues are stopped? */ reg->rqc = Rxqon(Qno); /* restart */ coherence(); } static void txkick(Ctlr *ctlr) { Gbereg *reg = ctlr->reg; if (reg->tcqdp[Qno] == 0) reg->tcqdp[Qno] = PADDR(&ctlr->tx[ctlr->txhead]); if ((reg->tqc & 0xff) == 0) /* all q's stopped? */ reg->tqc = Txqon(Qno); /* restart */ coherence(); } static void rxreplenish(Ctlr *ctlr) { Rx *r; Block *b; while(ctlr->rxb[ctlr->rxtail] == nil) { b = rxallocb(); if(b == nil) { iprint("#l%d: rxreplenish out of buffers\n", ctlr->ether->ctlrno); break; } ctlr->rxb[ctlr->rxtail] = b; /* set up uncached receive descriptor */ r = &ctlr->rx[ctlr->rxtail]; assert(((uintptr)r & (Descralign - 1)) == 0); r->countsize = ROUNDUP(Rxblklen, 8); r->buf = PADDR(b->rp); coherence(); /* and fire */ r->cs = RCSdmaown | RCSenableintr; coherence(); ctlr->rxtail = NEXT(ctlr->rxtail, Nrx); } } static void dump(uchar *bp, long max) { if (max > 64) max = 64; for (; max > 0; max--, bp++) iprint("%02.2ux ", *bp); print("...\n"); } static void etheractive(Ether *ether) { ether->starttime = TK2MS(MACHP(0)->ticks)/1000; } static void ethercheck(Ether *ether) { if (ether->starttime != 0 && TK2MS(MACHP(0)->ticks)/1000 - ether->starttime > Etherstuck) { etheractive(ether); if (ether->ctlrno == 0) /* only complain about main ether */ iprint("#l%d: ethernet stuck\n", ether->ctlrno); } } static void receive(Ether *ether) { int i; ulong n; Block *b; Ctlr *ctlr = ether->ctlr; Rx *r; ethercheck(ether); for (i = Nrx-2; i > 0; i--) { r = &ctlr->rx[ctlr->rxhead]; /* *r is uncached */ assert(((uintptr)r & (Descralign - 1)) == 0); if(r->cs & RCSdmaown) /* descriptor busy? */ break; b = ctlr->rxb[ctlr->rxhead]; /* got input buffer? */ if (b == nil) panic("ether1116: nil ctlr->rxb[ctlr->rxhead] " "in receive"); ctlr->rxb[ctlr->rxhead] = nil; ctlr->rxhead = NEXT(ctlr->rxhead, Nrx); if((r->cs & (RCSfirst|RCSlast)) != (RCSfirst|RCSlast)) { ctlr->nofirstlast++; /* partial packet */ freeb(b); continue; } if(r->cs & RCSmacerr) { freeb(b); continue; } n = r->countsize >> 16; /* TODO includes 2 pad bytes? */ assert(n >= 2 && n < 2048); /* clear any cached packet or part thereof */ l2cacheuinvse(b->rp, n+2); cachedinvse(b->rp, n+2); b->wp = b->rp + n; /* * skip hardware padding intended to align ipv4 address * in memory (mv-s104860-u0 §8.3.4.1) */ b->rp += 2; etheriq(ether, b, 1); etheractive(ether); if (i % (Nrx / 2) == 0) { rxreplenish(ctlr); rxkick(ctlr); } } rxreplenish(ctlr); rxkick(ctlr); } static void txreplenish(Ether *ether) /* free transmitted packets */ { Ctlr *ctlr; ctlr = ether->ctlr; while(ctlr->txtail != ctlr->txhead) { /* ctlr->tx is uncached */ if(ctlr->tx[ctlr->txtail].cs & TCSdmaown) break; if(ctlr->txb[ctlr->txtail] == nil) panic("no block for sent packet?!"); freeb(ctlr->txb[ctlr->txtail]); ctlr->txb[ctlr->txtail] = nil; ctlr->txtail = NEXT(ctlr->txtail, Ntx); etheractive(ether); } } /* * transmit strategy: fill the output ring as far as possible, * perhaps leaving a few spare; kick off the output and take * an interrupt only when the transmit queue is empty. */ static void transmit(Ether *ether) { int i, kick, len; Block *b; Ctlr *ctlr = ether->ctlr; Gbereg *reg = ctlr->reg; Tx *t; ethercheck(ether); ilock(ctlr); txreplenish(ether); /* reap old packets */ /* queue new packets; use at most half the tx descs to avoid livelock */ kick = 0; for (i = Ntx/2 - 2; i > 0; i--) { t = &ctlr->tx[ctlr->txhead]; /* *t is uncached */ assert(((uintptr)t & (Descralign - 1)) == 0); if(t->cs & TCSdmaown) { /* descriptor busy? */ ctlr->txringfull++; break; } b = qget(ether->oq); /* outgoing packet? */ if (b == nil) break; len = BLEN(b); if(len < ether->minmtu || len > ether->maxmtu) { freeb(b); continue; } ctlr->txb[ctlr->txhead] = b; /* make sure the whole packet is in memory */ cachedwbse(b->rp, len); l2cacheuwbse(b->rp, len); /* set up the transmit descriptor */ t->buf = PADDR(b->rp); t->countchk = len << 16; coherence(); /* and fire */ t->cs = TCSpadding | TCSfirst | TCSlast | TCSdmaown | TCSenableintr; coherence(); kick++; ctlr->txhead = NEXT(ctlr->txhead, Ntx); } if (kick) { txkick(ctlr); reg->irqmask |= Itxendq(Qno); reg->irqemask |= IEtxerrq(Qno) | IEtxunderrun; } iunlock(ctlr); } static void dumprxdescs(Ctlr *ctlr) { int i; Gbereg *reg = ctlr->reg; iprint("\nrxhead %d rxtail %d; txcdp %#p rxcdp %#p\n", ctlr->rxhead, ctlr->rxtail, reg->tcqdp[Qno], reg->crdp[Qno].r); for (i = 0; i < Nrx; i++) { iprint("rxb %d @ %#p: %#p\n", i, &ctlr->rxb[i], ctlr->rxb[i]); delay(50); } for (i = 0; i < Nrx; i++) { iprint("rx %d @ %#p: cs %#lux countsize %lud buf %#lux next %#lux\n", i, &ctlr->rx[i], ctlr->rx[i].cs, ctlr->rx[i].countsize >> 3, ctlr->rx[i].buf, ctlr->rx[i].next); delay(50); } delay(1000); } static int gotinput(void* ctlr) { return ((Ctlr*)ctlr)->haveinput != 0; } /* * process any packets in the input ring. * also sum mib stats frequently to avoid the overflow * mentioned in the errata. */ static void rcvproc(void* arg) { Ctlr *ctlr; Ether *ether; ether = arg; ctlr = ether->ctlr; while(waserror()) ; for(;;){ tsleep(&ctlr->rrendez, gotinput, ctlr, 10*1000); ilock(ctlr); getmibstats(ctlr); if (ctlr->haveinput) { ctlr->haveinput = 0; iunlock(ctlr); receive(ether); } else iunlock(ctlr); } } static void interrupt(Ureg*, void *arg) { ulong irq, irqe, handled; Ether *ether = arg; Ctlr *ctlr = ether->ctlr; Gbereg *reg = ctlr->reg; handled = 0; irq = reg->irq; irqe = reg->irqe; reg->irqe = 0; /* extinguish intr causes */ reg->irq = 0; /* extinguish intr causes */ ethercheck(ether); if(irq & (Irx | Irxbufferq(Qno))) { /* * letting a kproc process the input takes far less real time * than doing it all at interrupt level. */ ctlr->haveinput = 1; wakeup(&ctlr->rrendez); irq &= ~(Irx | Irxbufferq(Qno)); handled++; } else rxkick(ctlr); if(irq & Itxendq(Qno)) { /* transmit ring empty? */ reg->irqmask &= ~Itxendq(Qno); /* prevent more interrupts */ reg->irqemask &= ~(IEtxerrq(Qno) | IEtxunderrun); transmit(ether); irq &= ~Itxendq(Qno); handled++; } if(irqe & IEsum) { /* * IElinkchg appears to only be set when unplugging. * autonegotiation is likely not done yet, so linkup not valid, * thus we note the link change here, and check for * that and autonegotiation done below. */ if(irqe & IEphystschg) { ether->link = (reg->ps0 & PS0linkup) != 0; ether->linkchg = 1; } if(irqe & IEtxerrq(Qno)) ether->oerrs++; if(irqe & IErxoverrun) ether->overflows++; if(irqe & IEtxunderrun) ctlr->txunderrun++; if(irqe & (IEphystschg | IEtxerrq(Qno) | IErxoverrun | IEtxunderrun)) handled++; } if (irq & Isum) { if (irq & Irxerr) { /* nil desc. ptr. or desc. owned by cpu */ ether->buffs++; /* approx. error */ /* if the input ring is full, drain it */ ctlr->haveinput = 1; wakeup(&ctlr->rrendez); } if(irq & (Irxerr | Irxerrq(Qno))) handled++; irq &= ~(Irxerr | Irxerrq(Qno)); } if(ether->linkchg && (reg->ps1 & PS1an_done)) { handled++; ether->link = (reg->ps0 & PS0linkup) != 0; ether->linkchg = 0; } ctlr->newintrs++; if (!handled) { irq &= ~Isum; irqe &= ~IEtxbufferq(Qno); if (irq == 0 && irqe == 0) { /* seems to be triggered by continuous output */ // iprint("ether1116: spurious interrupt\n"); } else iprint("ether1116: interrupt cause unknown; " "irq %#lux irqe %#lux\n", irq, irqe); } intrclear(Irqlo, ether->irq); } void promiscuous(void *arg, int on) { Ether *ether = arg; Ctlr *ctlr = ether->ctlr; Gbereg *reg = ctlr->reg; ilock(ctlr); ether->prom = on; if(on) reg->portcfg |= PCFGupromisc; else reg->portcfg &= ~PCFGupromisc; iunlock(ctlr); } void multicast(void *, uchar *, int) { /* nothing to do; we always accept multicast */ } static void quiesce(Gbereg *reg); static void shutdown(Ether *ether) { int i; Ctlr *ctlr = ether->ctlr; Gbereg *reg = ctlr->reg; ilock(ctlr); quiesce(reg); reg->euc |= Portreset; coherence(); iunlock(ctlr); delay(100); ilock(ctlr); reg->euc &= ~Portreset; coherence(); delay(20); reg->psc0 = 0; /* no PSC0porton */ reg->psc1 |= PSC1portreset; coherence(); delay(50); reg->psc1 &= ~PSC1portreset; coherence(); for (i = 0; i < nelem(reg->tcqdp); i++) reg->tcqdp[i] = 0; for (i = 0; i < nelem(reg->crdp); i++) reg->crdp[i].r = 0; coherence(); iunlock(ctlr); } enum { CMjumbo, }; static Cmdtab ctlmsg[] = { CMjumbo, "jumbo", 2, }; long ctl(Ether *e, void *p, long n) { Cmdbuf *cb; Cmdtab *ct; Ctlr *ctlr = e->ctlr; Gbereg *reg = ctlr->reg; cb = parsecmd(p, n); if(waserror()) { free(cb); nexterror(); } ct = lookupcmd(cb, ctlmsg, nelem(ctlmsg)); switch(ct->index) { case CMjumbo: if(strcmp(cb->f[1], "on") == 0) { /* incoming packet queue doesn't expect jumbo frames */ error("jumbo disabled"); reg->psc0 = (reg->psc0 & ~PSC0mrumask) | PSC0mru(PSC0mru9022); e->maxmtu = 9022; } else if(strcmp(cb->f[1], "off") == 0) { reg->psc0 = (reg->psc0 & ~PSC0mrumask) | PSC0mru(PSC0mru1522); e->maxmtu = ETHERMAXTU; } else error(Ebadctl); break; default: error(Ebadctl); break; } free(cb); poperror(); return n; } /* * phy/mii goo */ static int smibusywait(Gbereg *reg, ulong waitbit) { ulong timeout, smi_reg; timeout = PhysmiTimeout; /* wait till the SMI is not busy */ do { /* read smi register */ smi_reg = reg->smi; if (timeout-- == 0) { MIIDBG("SMI busy timeout\n"); return -1; } // delay(1); } while (smi_reg & waitbit); return 0; } static int miird(Mii *mii, int pa, int ra) { ulong smi_reg, timeout; Gbereg *reg; reg = ((Ctlr*)mii->ctlr)->reg; /* check params */ if ((pa<<Physmiaddroff) & ~Physmiaddrmask || (ra<<SmiRegaddroff) & ~SmiRegaddrmask) return -1; smibusywait(reg, PhysmiBusy); /* fill the phy address and register offset and read opcode */ reg->smi = pa << Physmiaddroff | ra << SmiRegaddroff | PhysmiopRd; coherence(); /* wait til read value is ready */ timeout = PhysmiTimeout; do { smi_reg = reg->smi; if (timeout-- == 0) { MIIDBG("SMI read-valid timeout\n"); return -1; } } while (!(smi_reg & PhysmiReadok)); /* Wait for the data to update in the SMI register */ for (timeout = 0; timeout < PhysmiTimeout; timeout++) ; return reg->smi & Physmidatamask; } static int miiwr(Mii *mii, int pa, int ra, int v) { Gbereg *reg; ulong smi_reg; reg = ((Ctlr*)mii->ctlr)->reg; /* check params */ if (((pa<<Physmiaddroff) & ~Physmiaddrmask) || ((ra<<SmiRegaddroff) & ~SmiRegaddrmask)) return -1; smibusywait(reg, PhysmiBusy); /* fill the phy address and register offset and read opcode */ smi_reg = v << Physmidataoff | pa << Physmiaddroff | ra << SmiRegaddroff; reg->smi = smi_reg & ~PhysmiopRd; coherence(); return 0; } #define MIIMODEL(idr2) (((idr2) >> 4) & MASK(6)) enum { Hacknone, Hackdual, Ouimarvell = 0x005043, /* idr2 mii/phy model numbers */ Phy1000 = 0x00, /* 88E1000 Gb */ Phy1011 = 0x02, /* 88E1011 Gb */ Phy1000_3 = 0x03, /* 88E1000 Gb */ Phy1000s = 0x04, /* 88E1000S Gb */ Phy1000_5 = 0x05, /* 88E1000 Gb */ Phy1000_6 = 0x06, /* 88E1000 Gb */ Phy3082 = 0x08, /* 88E3082 10/100 */ Phy1112 = 0x09, /* 88E1112 Gb */ Phy1121r = 0x0b, /* says the 1121r manual */ Phy1149 = 0x0b, /* 88E1149 Gb */ Phy1111 = 0x0c, /* 88E1111 Gb */ Phy1116 = 0x21, /* 88E1116 Gb */ Phy1116r = 0x24, /* 88E1116R Gb */ Phy1118 = 0x22, /* 88E1118 Gb */ Phy3016 = 0x26, /* 88E3016 10/100 */ }; static int hackflavour; /* * on openrd, ether0's phy has address 8, ether1's is ether0's 24. * on guruplug, ether0's is phy 0 and ether1's is ether0's phy 1. */ int mymii(Mii* mii, int mask) { Ctlr *ctlr; MiiPhy *miiphy; int bit, ctlrno, oui, model, phyno, r, rmask; static int dualport, phyidx; static int phynos[NMiiPhy]; ctlr = mii->ctlr; ctlrno = ctlr->ether->ctlrno; /* first pass: figure out what kind of phy(s) we have. */ dualport = 0; if (ctlrno == 0) { for(phyno = 0; phyno < NMiiPhy; phyno++){ bit = 1<<phyno; if(!(mask & bit) || mii->mask & bit) continue; if(mii->mir(mii, phyno, Bmsr) == -1) continue; r = mii->mir(mii, phyno, Phyidr1); oui = (r & 0x3FFF)<<6; r = mii->mir(mii, phyno, Phyidr2); oui |= r>>10; model = MIIMODEL(r); if (oui == 0xfffff && model == 0x3f) continue; MIIDBG("ctlrno %d phy %d oui %#ux model %#ux\n", ctlrno, phyno, oui, model); if (oui == Ouimarvell && (model == Phy1121r || model == Phy1116r)) ++dualport; phynos[phyidx++] = phyno; } hackflavour = dualport == 2 && phyidx == 2? Hackdual: Hacknone; MIIDBG("ether1116: %s-port phy\n", hackflavour == Hackdual? "dual": "single"); } /* * Probe through mii for PHYs in mask; * return the mask of those found in the current probe. * If the PHY has not already been probed, update * the Mii information. */ rmask = 0; if (hackflavour == Hackdual && ctlrno < phyidx) { /* * openrd, guruplug or the like: use ether0's phys. * this is a nasty hack, but so is the hardware. */ MIIDBG("ctlrno %d using ctlrno 0's phyno %d\n", ctlrno, phynos[ctlrno]); ctlr->mii = mii = ctlrs[0]->mii; mask = 1 << phynos[ctlrno]; mii->mask = ~mask; } for(phyno = 0; phyno < NMiiPhy; phyno++){ bit = 1<<phyno; if(!(mask & bit)) continue; if(mii->mask & bit){ rmask |= bit; continue; } if(mii->mir(mii, phyno, Bmsr) == -1) continue; r = mii->mir(mii, phyno, Phyidr1); oui = (r & 0x3FFF)<<6; r = mii->mir(mii, phyno, Phyidr2); oui |= r>>10; if(oui == 0xFFFFF || oui == 0) continue; if((miiphy = malloc(sizeof(MiiPhy))) == nil) continue; miiphy->mii = mii; miiphy->oui = oui; miiphy->phyno = phyno; miiphy->anar = ~0; miiphy->fc = ~0; miiphy->mscr = ~0; mii->phy[phyno] = miiphy; if(ctlrno == 0 || hackflavour != Hackdual && mii->curphy == nil) mii->curphy = miiphy; mii->mask |= bit; mii->nphy++; rmask |= bit; } return rmask; } static int kirkwoodmii(Ether *ether) { int i; Ctlr *ctlr; MiiPhy *phy; MIIDBG("mii\n"); ctlr = ether->ctlr; if((ctlr->mii = malloc(sizeof(Mii))) == nil) return -1; ctlr->mii->ctlr = ctlr; ctlr->mii->mir = miird; ctlr->mii->miw = miiwr; if(mymii(ctlr->mii, ~0) == 0 || (phy = ctlr->mii->curphy) == nil){ print("#l%d: ether1116: init mii failure\n", ether->ctlrno); free(ctlr->mii); ctlr->mii = nil; return -1; } /* oui 005043 is marvell */ MIIDBG("oui %#X phyno %d\n", phy->oui, phy->phyno); // TODO: does this make sense? shouldn't each phy be initialised? if((ctlr->ether->ctlrno == 0 || hackflavour != Hackdual) && miistatus(ctlr->mii) < 0){ miireset(ctlr->mii); MIIDBG("miireset\n"); if(miiane(ctlr->mii, ~0, 0, ~0) < 0){ iprint("miiane failed\n"); return -1; } MIIDBG("miistatus\n"); miistatus(ctlr->mii); if(miird(ctlr->mii, phy->phyno, Bmsr) & BmsrLs){ for(i = 0; ; i++){ if(i > 600){ iprint("ether1116: autonegotiation failed\n"); break; } if(miird(ctlr->mii, phy->phyno, Bmsr) & BmsrAnc) break; delay(10); } if(miistatus(ctlr->mii) < 0) iprint("miistatus failed\n"); }else{ iprint("ether1116: no link\n"); phy->speed = 10; /* simple default */ } } ether->mbps = phy->speed; MIIDBG("#l%d: kirkwoodmii: fd %d speed %d tfc %d rfc %d\n", ctlr->port, phy->fd, phy->speed, phy->tfc, phy->rfc); MIIDBG("mii done\n"); return 0; } enum { /* PHY register pages */ Pagcopper, Pagfiber, Pagrgmii, Pagled, Pagrsvd1, Pagvct, Pagtest, Pagrsvd2, Pagfactest, }; static void miiregpage(Mii *mii, ulong dev, ulong page) { miiwr(mii, dev, Eadr, page); } static int miiphyinit(Mii *mii) { ulong dev; Ctlr *ctlr; Gbereg *reg; ctlr = (Ctlr*)mii->ctlr; reg = ctlr->reg; dev = reg->phy; MIIDBG("phy dev addr %lux\n", dev); /* leds link & activity */ miiregpage(mii, dev, Pagled); /* low 4 bits == 1: on - link, blink - activity, off - no link */ miiwr(mii, dev, Scr, (miird(mii, dev, Scr) & ~0xf) | 1); miiregpage(mii, dev, Pagrgmii); miiwr(mii, dev, Scr, miird(mii, dev, Scr) | Rgmiipwrup); /* must now do a software reset, says the manual */ miireset(ctlr->mii); /* enable RGMII delay on Tx and Rx for CPU port */ miiwr(mii, dev, Recr, miird(mii, dev, Recr) | Rxtiming | Rxtiming); /* must now do a software reset, says the manual */ miireset(ctlr->mii); miiregpage(mii, dev, Pagcopper); miiwr(mii, dev, Scr, (miird(mii, dev, Scr) & ~(Pwrdown|Endetect)) | Mdix); return 0; } /* * initialisation */ static void quiesce(Gbereg *reg) { ulong v; v = reg->tqc; if (v & 0xFF) reg->tqc = v << 8; /* stop active channels */ v = reg->rqc; if (v & 0xFF) reg->rqc = v << 8; /* stop active channels */ /* wait for all queues to stop */ while (reg->tqc & 0xFF || reg->rqc & 0xFF) ; } static void p16(uchar *p, ulong v) /* convert big-endian short to bytes */ { *p++ = v>>8; *p = v; } static void p32(uchar *p, ulong v) /* convert big-endian long to bytes */ { *p++ = v>>24; *p++ = v>>16; *p++ = v>>8; *p = v; } /* * set ether->ea from hw mac address, * configure unicast filtering to accept it. */ void archetheraddr(Ether *ether, Gbereg *reg, int rxqno) { uchar *ea; ulong nibble, ucreg, tbloff, regoff; ea = ether->ea; p32(ea, reg->macah); p16(ea+4, reg->macal); if (memcmp(ea, zeroea, sizeof zeroea) == 0 && ether->ctlrno > 0) { /* hack: use ctlr[0]'s + ctlrno */ memmove(ea, ctlrs[0]->ether->ea, Eaddrlen); ea[Eaddrlen-1] += ether->ctlrno; reg->macah = ea[0] << 24 | ea[1] << 16 | ea[2] << 8 | ea[3]; reg->macal = ea[4] << 8 | ea[5]; coherence(); } /* accept frames on ea */ nibble = ea[5] & 0xf; tbloff = nibble / 4; regoff = nibble % 4; regoff *= 8; ucreg = reg->dfut[tbloff] & (0xff << regoff); ucreg |= (rxqno << 1 | Pass) << regoff; reg->dfut[tbloff] = ucreg; /* accept all multicast too. set up special & other tables. */ memset(reg->dfsmt, Qno<<1 | Pass, sizeof reg->dfsmt); memset(reg->dfomt, Qno<<1 | Pass, sizeof reg->dfomt); coherence(); } static void cfgdramacc(Gbereg *reg) { memset(reg->harr, 0, sizeof reg->harr); memset(reg->base, 0, sizeof reg->base); reg->bare = MASK(6) - MASK(2); /* disable wins 2-5 */ /* this doesn't make any sense, but it's required */ reg->epap = 3 << 2 | 3; /* full access for wins 0 & 1 */ // reg->epap = 0; /* no access on access violation for all wins */ coherence(); reg->base[0].base = PHYSDRAM | WINATTR(Attrcs0) | Targdram; reg->base[0].size = WINSIZE(256*MB); reg->base[1].base = (PHYSDRAM + 256*MB) | WINATTR(Attrcs1) | Targdram; reg->base[1].size = WINSIZE(256*MB); coherence(); } static void ctlralloc(Ctlr *ctlr) { int i; Block *b; Rx *r; Tx *t; ilock(&freeblocks); for(i = 0; i < Nrxblks; i++) { b = iallocb(Rxblklen+Bufalign-1); if(b == nil) { iprint("ether1116: no memory for rx buffers\n"); break; } b->wp = b->rp = (uchar*) ((uintptr)(b->lim - Rxblklen) & ~(Bufalign - 1)); assert(((uintptr)b->rp & (Bufalign - 1)) == 0); b->free = rxfreeb; b->next = freeblocks.head; freeblocks.head = b; } iunlock(&freeblocks); /* * allocate uncached rx ring descriptors because rings are shared * with the ethernet controller and more than one fits in a cache line. */ ctlr->rx = ucallocalign(Nrx * sizeof(Rx), Descralign, 0); if(ctlr->rx == nil) panic("ether1116: no memory for rx ring"); for(i = 0; i < Nrx; i++) { r = &ctlr->rx[i]; assert(((uintptr)r & (Descralign - 1)) == 0); r->cs = 0; /* owned by software until r->buf is non-nil */ r->buf = 0; r->next = PADDR(&ctlr->rx[NEXT(i, Nrx)]); ctlr->rxb[i] = nil; } ctlr->rxtail = ctlr->rxhead = 0; rxreplenish(ctlr); /* allocate uncached tx ring descriptors */ ctlr->tx = ucallocalign(Ntx * sizeof(Tx), Descralign, 0); if(ctlr->tx == nil) panic("ether1116: no memory for tx ring"); for(i = 0; i < Ntx; i++) { t = &ctlr->tx[i]; assert(((uintptr)t & (Descralign - 1)) == 0); t->cs = 0; t->buf = 0; t->next = PADDR(&ctlr->tx[NEXT(i, Ntx)]); ctlr->txb[i] = nil; } ctlr->txtail = ctlr->txhead = 0; } static void ctlrinit(Ether *ether) { int i; Ctlr *ctlr = ether->ctlr; Gbereg *reg = ctlr->reg; static char name[KNAMELEN]; static Ctlr fakectlr; /* bigger than 4K; keep off the stack */ for (i = 0; i < nelem(reg->tcqdp); i++) reg->tcqdp[i] = 0; for (i = 0; i < nelem(reg->crdp); i++) reg->crdp[i].r = 0; coherence(); cfgdramacc(reg); ctlralloc(ctlr); reg->tcqdp[Qno] = PADDR(&ctlr->tx[ctlr->txhead]); reg->crdp[Qno].r = PADDR(&ctlr->rx[ctlr->rxhead]); coherence(); // dumprxdescs(ctlr); /* clear stats by reading them into fake ctlr */ getmibstats(&fakectlr); reg->pxmfs = MFS40by; /* allow runts in */ /* * ipg's (inter packet gaps) for interrupt coalescing, * values in units of 64 clock cycles. A full-sized * packet (1514 bytes) takes just over 12µs to transmit. */ if (CLOCKFREQ/(Maxrxintrsec*64) >= (1<<16)) panic("rx coalescing value %d too big for short", CLOCKFREQ/(Maxrxintrsec*64)); reg->sdc = SDCrifb | SDCrxburst(Burst16) | SDCtxburst(Burst16) | SDCrxnobyteswap | SDCtxnobyteswap | SDCipgintrx(CLOCKFREQ/(Maxrxintrsec*64)); reg->pxtfut = 0; /* TFUTipginttx(CLOCKFREQ/(Maxrxintrsec*64)) */ /* allow just these interrupts */ /* guruplug generates Irxerr interrupts continually */ reg->irqmask = Isum | Irx | Irxbufferq(Qno) | Irxerr | Itxendq(Qno); reg->irqemask = IEsum | IEtxerrq(Qno) | IEphystschg | IErxoverrun | IEtxunderrun; reg->irqe = 0; reg->euirqmask = 0; coherence(); reg->irq = 0; reg->euirq = 0; /* send errors to end of memory */ // reg->euda = PHYSDRAM + 512*MB - 8*1024; reg->euda = 0; reg->eudid = Attrcs1 << 4 | Targdram; // archetheraddr(ether, ctlr->reg, Qno); /* 2nd location */ reg->portcfg = Rxqdefault(Qno) | Rxqarp(Qno); reg->portcfgx = 0; coherence(); /* * start the controller running. * turn the port on, kick the receiver. */ reg->psc1 = PSC1rgmii | PSC1encolonbp | PSC1coldomlim(0x23); /* do this only when the controller is quiescent */ reg->psc0 = PSC0porton | PSC0an_flctloff | PSC0an_pauseadv | PSC0nofrclinkdown | PSC0mru(PSC0mru1522); coherence(); for (i = 0; i < 4000; i++) /* magic delay */ ; ether->link = (reg->ps0 & PS0linkup) != 0; /* set ethernet MTU for leaky bucket mechanism to 0 (disabled) */ reg->pmtu = 0; etheractive(ether); snprint(name, sizeof name, "#l%drproc", ether->ctlrno); kproc(name, rcvproc, ether); reg->rqc = Rxqon(Qno); coherence(); } static void attach(Ether* ether) { Ctlr *ctlr = ether->ctlr; lock(&ctlr->initlock); if(ctlr->init == 0) { ctlrinit(ether); ctlr->init = 1; } unlock(&ctlr->initlock); } /* * statistics goo. * mib registers clear on read. */ static void getmibstats(Ctlr *ctlr) { Gbereg *reg = ctlr->reg; /* * Marvell 88f6281 errata FE-ETH-120: high long of rxby and txby * can't be read correctly, so read the low long frequently * (every 30 seconds or less), thus avoiding overflow into high long. */ ctlr->rxby += reg->rxbylo; ctlr->txby += reg->txbylo; ctlr->badrxby += reg->badrxby; ctlr->mactxerr += reg->mactxerr; ctlr->rxpkt += reg->rxpkt; ctlr->badrxpkt += reg->badrxpkt; ctlr->rxbcastpkt+= reg->rxbcastpkt; ctlr->rxmcastpkt+= reg->rxmcastpkt; ctlr->rx64 += reg->rx64; ctlr->rx65_127 += reg->rx65_127; ctlr->rx128_255 += reg->rx128_255; ctlr->rx256_511 += reg->rx256_511; ctlr->rx512_1023+= reg->rx512_1023; ctlr->rx1024_max+= reg->rx1024_max; ctlr->txpkt += reg->txpkt; ctlr->txcollpktdrop+= reg->txcollpktdrop; ctlr->txmcastpkt+= reg->txmcastpkt; ctlr->txbcastpkt+= reg->txbcastpkt; ctlr->badmacctlpkts+= reg->badmacctlpkts; ctlr->txflctl += reg->txflctl; ctlr->rxflctl += reg->rxflctl; ctlr->badrxflctl+= reg->badrxflctl; ctlr->rxundersized+= reg->rxundersized; ctlr->rxfrags += reg->rxfrags; ctlr->rxtoobig += reg->rxtoobig; ctlr->rxjabber += reg->rxjabber; ctlr->rxerr += reg->rxerr; ctlr->crcerr += reg->crcerr; ctlr->collisions+= reg->collisions; ctlr->latecoll += reg->latecoll; } long ifstat(Ether *ether, void *a, long n, ulong off) { Ctlr *ctlr = ether->ctlr; Gbereg *reg = ctlr->reg; char *buf, *p, *e; buf = p = malloc(READSTR); e = p + READSTR; ilock(ctlr); getmibstats(ctlr); ctlr->intrs += ctlr->newintrs; p = seprint(p, e, "interrupts: %lud\n", ctlr->intrs); p = seprint(p, e, "new interrupts: %lud\n", ctlr->newintrs); ctlr->newintrs = 0; p = seprint(p, e, "tx underrun: %lud\n", ctlr->txunderrun); p = seprint(p, e, "tx ring full: %lud\n", ctlr->txringfull); ctlr->rxdiscard += reg->pxdfc; ctlr->rxoverrun += reg->pxofc; p = seprint(p, e, "rx discarded frames: %lud\n", ctlr->rxdiscard); p = seprint(p, e, "rx overrun frames: %lud\n", ctlr->rxoverrun); p = seprint(p, e, "no first+last flag: %lud\n", ctlr->nofirstlast); p = seprint(p, e, "duplex: %s\n", (reg->ps0 & PS0fd)? "full": "half"); p = seprint(p, e, "flow control: %s\n", (reg->ps0 & PS0flctl)? "on": "off"); /* p = seprint(p, e, "speed: %d mbps\n", ); */ p = seprint(p, e, "received bytes: %llud\n", ctlr->rxby); p = seprint(p, e, "bad received bytes: %lud\n", ctlr->badrxby); p = seprint(p, e, "internal mac transmit errors: %lud\n", ctlr->mactxerr); p = seprint(p, e, "total received frames: %lud\n", ctlr->rxpkt); p = seprint(p, e, "received broadcast frames: %lud\n", ctlr->rxbcastpkt); p = seprint(p, e, "received multicast frames: %lud\n", ctlr->rxmcastpkt); p = seprint(p, e, "bad received frames: %lud\n", ctlr->badrxpkt); p = seprint(p, e, "received frames 0-64: %lud\n", ctlr->rx64); p = seprint(p, e, "received frames 65-127: %lud\n", ctlr->rx65_127); p = seprint(p, e, "received frames 128-255: %lud\n", ctlr->rx128_255); p = seprint(p, e, "received frames 256-511: %lud\n", ctlr->rx256_511); p = seprint(p, e, "received frames 512-1023: %lud\n", ctlr->rx512_1023); p = seprint(p, e, "received frames 1024-max: %lud\n", ctlr->rx1024_max); p = seprint(p, e, "transmitted bytes: %llud\n", ctlr->txby); p = seprint(p, e, "total transmitted frames: %lud\n", ctlr->txpkt); p = seprint(p, e, "transmitted broadcast frames: %lud\n", ctlr->txbcastpkt); p = seprint(p, e, "transmitted multicast frames: %lud\n", ctlr->txmcastpkt); p = seprint(p, e, "transmit frames dropped by collision: %lud\n", ctlr->txcollpktdrop); p = seprint(p, e, "misaligned buffers: %lud\n", ether->pktsmisaligned); p = seprint(p, e, "bad mac control frames: %lud\n", ctlr->badmacctlpkts); p = seprint(p, e, "transmitted flow control messages: %lud\n", ctlr->txflctl); p = seprint(p, e, "received flow control messages: %lud\n", ctlr->rxflctl); p = seprint(p, e, "bad received flow control messages: %lud\n", ctlr->badrxflctl); p = seprint(p, e, "received undersized packets: %lud\n", ctlr->rxundersized); p = seprint(p, e, "received fragments: %lud\n", ctlr->rxfrags); p = seprint(p, e, "received oversized packets: %lud\n", ctlr->rxtoobig); p = seprint(p, e, "received jabber packets: %lud\n", ctlr->rxjabber); p = seprint(p, e, "mac receive errors: %lud\n", ctlr->rxerr); p = seprint(p, e, "crc errors: %lud\n", ctlr->crcerr); p = seprint(p, e, "collisions: %lud\n", ctlr->collisions); p = seprint(p, e, "late collisions: %lud\n", ctlr->latecoll); USED(p); iunlock(ctlr); n = readstr(off, a, n, buf); free(buf); return n; } static int reset(Ether *ether) { Ctlr *ctlr; ether->ctlr = ctlr = malloc(sizeof *ctlr); switch(ether->ctlrno) { case 0: ether->irq = IRQ0gbe0sum; break; case 1: ether->irq = IRQ0gbe1sum; break; default: panic("ether1116: bad ether ctlr #%d", ether->ctlrno); } ctlr->reg = (Gbereg*)soc.ether[ether->ctlrno]; /* need this for guruplug, at least */ *(ulong *)soc.iocfg |= 1 << 7 | 1 << 15; /* io cfg 0: 1.8v gbe */ coherence(); ctlr->ether = ether; ctlrs[ether->ctlrno] = ctlr; shutdown(ether); /* ensure that both interfaces are set to RGMII before calling mii */ ((Gbereg*)soc.ether[0])->psc1 |= PSC1rgmii; ((Gbereg*)soc.ether[1])->psc1 |= PSC1rgmii; coherence(); /* Set phy address of the port */ ctlr->port = ether->ctlrno; ctlr->reg->phy = ether->ctlrno; coherence(); ether->port = (uintptr)ctlr->reg; if(kirkwoodmii(ether) < 0){ free(ctlr); ether->ctlr = nil; return -1; } miiphyinit(ctlr->mii); archetheraddr(ether, ctlr->reg, Qno); /* original location */ if (memcmp(ether->ea, zeroea, sizeof zeroea) == 0){ iprint("ether1116: reset: zero ether->ea\n"); free(ctlr); ether->ctlr = nil; return -1; /* no rj45 for this ether */ } ether->attach = attach; ether->transmit = transmit; ether->interrupt = interrupt; ether->ifstat = ifstat; ether->shutdown = shutdown; ether->ctl = ctl; ether->arg = ether; ether->promiscuous = promiscuous; ether->multicast = multicast; return 0; } void ether1116link(void) { addethercard("88e1116", reset); }