ref: df18213ce319be83502a281cdbc590bcf59ab6e7
dir: /sys/src/9/pc/ether83815.c/
/* * National Semiconductor DP83815 * * Supports only internal PHY and has been tested on: * Netgear FA311TX (using Netgear DS108 10/100 hub) * SiS 900 within SiS 630 * To do: * check Ethernet address; * test autonegotiation on 10 Mbit, and 100 Mbit full duplex; * external PHY via MII (should be common code for MII); * thresholds; * ring sizing; * physical link changes/disconnect; * push initialisation back to attach. * * C H Forsyth, forsyth@vitanuova.com, 18th June 2001. */ #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/netif.h" #include "../port/etherif.h" #define DEBUG 0 #define debug if(DEBUG)print enum { Nrde = 64, Ntde = 64, }; #define Rbsz ROUNDUP(sizeof(Etherpkt)+4, 4) typedef struct Des { ulong next; int cmdsts; ulong addr; Block* bp; } Des; enum { /* cmdsts */ Own = 1<<31, /* set by data producer to hand to consumer */ More = 1<<30, /* more of packet in next descriptor */ Intr = 1<<29, /* interrupt when device is done with it */ Supcrc = 1<<28, /* suppress crc on transmit */ Inccrc = 1<<28, /* crc included on receive (always) */ Ok = 1<<27, /* packet ok */ Size = 0xFFF, /* packet size in bytes */ /* transmit */ Txa = 1<<26, /* transmission aborted */ Tfu = 1<<25, /* transmit fifo underrun */ Crs = 1<<24, /* carrier sense lost */ Td = 1<<23, /* transmission deferred */ Ed = 1<<22, /* excessive deferral */ Owc = 1<<21, /* out of window collision */ Ec = 1<<20, /* excessive collisions */ /* 19-16 collision count */ /* receive */ Rxa = 1<<26, /* receive aborted (same as Rxo) */ Rxo = 1<<25, /* receive overrun */ Dest = 3<<23, /* destination class */ Drej= 0<<23, /* packet was rejected */ Duni= 1<<23, /* unicast */ Dmulti= 2<<23, /* multicast */ Dbroad= 3<<23, /* broadcast */ Long = 1<<22, /* too long packet received */ Runt = 1<<21, /* packet less than 64 bytes */ Ise = 1<<20, /* invalid symbol */ Crce = 1<<19, /* invalid crc */ Fae = 1<<18, /* frame alignment error */ Lbp = 1<<17, /* loopback packet */ Col = 1<<16, /* collision during receive */ }; enum { /* PCI vendor & device IDs */ Nat83815 = (0x0020<<16)|0x100B, SiS = 0x1039, SiS900 = (0x0900<<16)|SiS, SiS7016 = (0x7016<<16)|SiS, SiS630bridge = 0x0008, /* SiS 900 PCI revision codes */ SiSrev630s = 0x81, SiSrev630e = 0x82, SiSrev630ea1 = 0x83, SiSrev635 = 0x90, SiSeenodeaddr = 8, /* short addr of SiS eeprom mac addr */ SiS630eenodeaddr = 9, /* likewise for the 630 */ Nseenodeaddr = 6, /* " for NS eeprom */ Nat83815avng = 0x403, Nat83816avng = 0x505, /* 83816 acts like submodel of 83815 */ /* using reg. 0x58 to disambiguate. */ }; typedef struct Ctlr Ctlr; typedef struct Ctlr { int port; Pcidev* pcidev; Ctlr* next; int active; int id; /* (pcidev->did<<16)|pcidev->vid */ ushort srom[0xB+1]; uchar sromea[Eaddrlen]; /* MAC address */ uchar fd; /* option or auto negotiation */ int mbps; Lock lock; Des* rdr; /* receive descriptor ring */ int nrdr; /* size of rdr */ int rdrx; /* index into rdr */ Lock tlock; Des* tdr; /* transmit descriptor ring */ int ntdr; /* size of tdr */ int tdrh; /* host index into tdr */ int tdri; /* interface index into tdr */ int ntq; /* descriptors active */ int ntqmax; ulong rxa; /* receive statistics */ ulong rxo; ulong rlong; ulong runt; ulong ise; ulong crce; ulong fae; ulong lbp; ulong col; ulong rxsovr; ulong rxorn; ulong txa; /* transmit statistics */ ulong tfu; ulong crs; ulong td; ulong ed; ulong owc; ulong ec; ulong txurn; ulong dperr; /* system errors */ ulong rmabt; ulong rtabt; ulong sserr; ulong rxsover; ulong version; /* silicon version; register 0x58h */ } Ctlr; static Ctlr* ctlrhead; static Ctlr* ctlrtail; enum { /* registers (could memory map) */ Rcr= 0x00, /* command register */ Rld= 1<<10, /* reload */ Rst= 1<<8, Rxr= 1<<5, /* receiver reset */ Txr= 1<<4, /* transmitter reset */ Rxd= 1<<3, /* receiver disable */ Rxe= 1<<2, /* receiver enable */ Txd= 1<<1, /* transmitter disable */ Txe= 1<<0, /* transmitter enable */ Rcfg= 0x04, /* configuration */ Lnksts= 1<<31, /* link good */ Speed100= 1<<30, /* 100 Mb/s link */ Fdup= 1<<29, /* full duplex */ Pol= 1<<28, /* polarity reversal (10baseT) */ Aneg_dn= 1<<27, /* autonegotiation done */ Pint_acen= 1<<17, /* PHY interrupt auto clear enable */ Pause_adv= 1<<16, /* advertise pause during auto neg */ Paneg_ena= 1<<13, /* auto negotiation enable */ Paneg_all= 7<<13, /* auto negotiation enable 10/100 half & full */ Ext_phy= 1<<12, /* enable MII for external PHY */ Phy_rst= 1<<10, /* reset internal PHY */ Phy_dis= 1<<9, /* disable internal PHY (eg, low power) */ Req_alg= 1<<7, /* PCI bus request: set means less aggressive */ Sb= 1<<6, /* single slot back-off not random */ Pow= 1<<5, /* out of window timer selection */ Exd= 1<<4, /* disable excessive deferral timer */ Pesel= 1<<3, /* parity error algorithm selection */ Brom_dis= 1<<2, /* disable boot rom interface */ Bem= 1<<0, /* big-endian mode */ Rmear= 0x08, /* eeprom access */ Mdc= 1<<6, /* MII mangement check */ Mddir= 1<<5, /* MII management direction */ Mdio= 1<<4, /* MII mangement data */ Eesel= 1<<3, /* EEPROM chip select */ Eeclk= 1<<2, /* EEPROM clock */ Eedo= 1<<1, /* EEPROM data out (from chip) */ Eedi= 1<<0, /* EEPROM data in (to chip) */ Rptscr= 0x0C, /* pci test control */ Risr= 0x10, /* interrupt status */ Txrcmp= 1<<25, /* transmit reset complete */ Rxrcmp= 1<<24, /* receiver reset complete */ Dperr= 1<<23, /* detected parity error */ Sserr= 1<<22, /* signalled system error */ Rmabt= 1<<21, /* received master abort */ Rtabt= 1<<20, /* received target abort */ Rxsovr= 1<<16, /* RX status FIFO overrun */ Hiberr= 1<<15, /* high bits error set (OR of 25-16) */ Phy= 1<<14, /* PHY interrupt */ Pme= 1<<13, /* power management event (wake online) */ Swi= 1<<12, /* software interrupt */ Mib= 1<<11, /* MIB service */ Txurn= 1<<10, /* TX underrun */ Txidle= 1<<9, /* TX idle */ Txerr= 1<<8, /* TX packet error */ Txdesc= 1<<7, /* TX descriptor (with Intr bit done) */ Txok= 1<<6, /* TX ok */ Rxorn= 1<<5, /* RX overrun */ Rxidle= 1<<4, /* RX idle */ Rxearly= 1<<3, /* RX early threshold */ Rxerr= 1<<2, /* RX packet error */ Rxdesc= 1<<1, /* RX descriptor (with Intr bit done) */ Rxok= 1<<0, /* RX ok */ Rimr= 0x14, /* interrupt mask */ Rier= 0x18, /* interrupt enable */ Ie= 1<<0, /* interrupt enable */ Rtxdp= 0x20, /* transmit descriptor pointer */ Rtxcfg= 0x24, /* transmit configuration */ Csi= 1<<31, /* carrier sense ignore (needed for full duplex) */ Hbi= 1<<30, /* heartbeat ignore (needed for full duplex) */ Atp= 1<<28, /* automatic padding of runt packets */ Mxdma= 7<<20, /* maximum dma transfer field */ Mxdma32= 4<<20, /* 4x32-bit words (32 bytes) */ Mxdma64= 5<<20, /* 8x32-bit words (64 bytes) */ Flth= 0x3F<<8,/* Tx fill threshold, units of 32 bytes (must be > Mxdma) */ Drth= 0x3F<<0,/* Tx drain threshold (units of 32 bytes) */ Flth128= 4<<8, /* fill at 128 bytes */ Drth512= 16<<0, /* drain at 512 bytes */ Rrxdp= 0x30, /* receive descriptor pointer */ Rrxcfg= 0x34, /* receive configuration */ Atx= 1<<28, /* accept transmit packets (needed for full duplex) */ Rdrth= 0x1F<<1,/* Rx drain threshold (units of 32 bytes) */ Rdrth64= 2<<1, /* drain at 64 bytes */ Rccsr= 0x3C, /* CLKRUN control/status */ Pmests= 1<<15, /* PME status */ Rwcsr= 0x40, /* wake on lan control/status */ Rpcr= 0x44, /* pause control/status */ Rrfcr= 0x48, /* receive filter/match control */ Rfen= 1<<31, /* receive filter enable */ Aab= 1<<30, /* accept all broadcast */ Aam= 1<<29, /* accept all multicast */ Aau= 1<<28, /* accept all unicast */ Apm= 1<<27, /* accept on perfect match */ Apat= 0xF<<23,/* accept on pattern match */ Aarp= 1<<22, /* accept ARP */ Mhen= 1<<21, /* multicast hash enable */ Uhen= 1<<20, /* unicast hash enable */ Ulm= 1<<19, /* U/L bit mask */ /* bits 0-9 are rfaddr */ Rrfdr= 0x4C, /* receive filter/match data */ Rbrar= 0x50, /* boot rom address */ Rbrdr= 0x54, /* boot rom data */ Rsrr= 0x58, /* silicon revision */ Rmibc= 0x5C, /* MIB control */ /* 60-78 MIB data */ /* PHY registers */ Rbmcr= 0x80, /* basic mode configuration */ Reset= 1<<15, Sel100= 1<<13, /* select 100Mb/sec if no auto neg */ Anena= 1<<12, /* auto negotiation enable */ Anrestart= 1<<9, /* restart auto negotiation */ Selfdx= 1<<8, /* select full duplex if no auto neg */ Rbmsr= 0x84, /* basic mode status */ Ancomp= 1<<5, /* autonegotiation complete */ Rphyidr1= 0x88, Rphyidr2= 0x8C, Ranar= 0x90, /* autonegotiation advertisement */ Ranlpar= 0x94, /* autonegotiation link partner ability */ Raner= 0x98, /* autonegotiation expansion */ Rannptr= 0x9C, /* autonegotiation next page TX */ Rphysts= 0xC0, /* PHY status */ Rmicr= 0xC4, /* MII control */ Inten= 1<<1, /* PHY interrupt enable */ Rmisr= 0xC8, /* MII status */ Rfcscr= 0xD0, /* false carrier sense counter */ Rrecr= 0xD4, /* receive error counter */ Rpcsr= 0xD8, /* 100Mb config/status */ Rphycr= 0xE4, /* PHY control */ Rtbscr= 0xE8, /* 10BaseT status/control */ }; /* * eeprom addresses * 7 to 9 (16 bit words): mac address, shifted and reversed */ #define csr32r(c, r) (inl((c)->port+(r))) #define csr32w(c, r, l) (outl((c)->port+(r), (ulong)(l))) #define csr16r(c, r) (ins((c)->port+(r))) #define csr16w(c, r, l) (outs((c)->port+(r), (ulong)(l))) static void dumpcregs(Ctlr *ctlr) { int i; for(i=0; i<=0x5C; i+=4) print("%2.2ux %8.8lux\n", i, csr32r(ctlr, i)); } static void promiscuous(void* arg, int on) { Ctlr *ctlr; ulong w; ctlr = ((Ether*)arg)->ctlr; ilock(&ctlr->lock); w = csr32r(ctlr, Rrfcr); if(on != ((w&Aau)!=0)){ csr32w(ctlr, Rrfcr, w & ~Rfen); csr32w(ctlr, Rrfcr, Rfen | (w ^ Aau)); } iunlock(&ctlr->lock); } static void attach(Ether* ether) { Ctlr *ctlr; ctlr = ether->ctlr; ilock(&ctlr->lock); if(0) dumpcregs(ctlr); csr32w(ctlr, Rcr, Rxe); iunlock(&ctlr->lock); } static long ifstat(Ether* ether, void* a, long n, ulong offset) { Ctlr *ctlr; char *buf, *p; int i, l, len; ctlr = ether->ctlr; ether->crcs = ctlr->crce; ether->frames = ctlr->runt+ctlr->ise+ctlr->rlong+ctlr->fae; ether->buffs = ctlr->rxorn+ctlr->tfu; ether->overflows = ctlr->rxsovr; if(n == 0) return 0; p = smalloc(READSTR); l = snprint(p, READSTR, "Rxa: %lud\n", ctlr->rxa); l += snprint(p+l, READSTR-l, "Rxo: %lud\n", ctlr->rxo); l += snprint(p+l, READSTR-l, "Rlong: %lud\n", ctlr->rlong); l += snprint(p+l, READSTR-l, "Runt: %lud\n", ctlr->runt); l += snprint(p+l, READSTR-l, "Ise: %lud\n", ctlr->ise); l += snprint(p+l, READSTR-l, "Fae: %lud\n", ctlr->fae); l += snprint(p+l, READSTR-l, "Lbp: %lud\n", ctlr->lbp); l += snprint(p+l, READSTR-l, "Tfu: %lud\n", ctlr->tfu); l += snprint(p+l, READSTR-l, "Txa: %lud\n", ctlr->txa); l += snprint(p+l, READSTR-l, "CRC Error: %lud\n", ctlr->crce); l += snprint(p+l, READSTR-l, "Collision Seen: %lud\n", ctlr->col); l += snprint(p+l, READSTR-l, "Frame Too Long: %lud\n", ctlr->rlong); l += snprint(p+l, READSTR-l, "Runt Frame: %lud\n", ctlr->runt); l += snprint(p+l, READSTR-l, "Rx Underflow Error: %lud\n", ctlr->rxorn); l += snprint(p+l, READSTR-l, "Tx Underrun: %lud\n", ctlr->txurn); l += snprint(p+l, READSTR-l, "Excessive Collisions: %lud\n", ctlr->ec); l += snprint(p+l, READSTR-l, "Late Collision: %lud\n", ctlr->owc); l += snprint(p+l, READSTR-l, "Loss of Carrier: %lud\n", ctlr->crs); l += snprint(p+l, READSTR-l, "Parity: %lud\n", ctlr->dperr); l += snprint(p+l, READSTR-l, "Aborts: %lud\n", ctlr->rmabt+ctlr->rtabt); l += snprint(p+l, READSTR-l, "RX Status overrun: %lud\n", ctlr->rxsover); snprint(p+l, READSTR-l, "ntqmax: %d\n", ctlr->ntqmax); ctlr->ntqmax = 0; buf = a; len = readstr(offset, buf, n, p); if(offset > l) offset -= l; else offset = 0; buf += len; n -= len; l = snprint(p, READSTR, "srom:"); for(i = 0; i < nelem(ctlr->srom); i++){ if(i && ((i & 0x0F) == 0)) l += snprint(p+l, READSTR-l, "\n "); l += snprint(p+l, READSTR-l, " %4.4uX", ctlr->srom[i]); } snprint(p+l, READSTR-l, "\n"); len += readstr(offset, buf, n, p); free(p); return len; } static void txstart(Ether* ether) { Ctlr *ctlr; Block *bp; Des *des; int started; ctlr = ether->ctlr; started = 0; while(ctlr->ntq < ctlr->ntdr-1){ bp = qget(ether->oq); if(bp == nil) break; des = &ctlr->tdr[ctlr->tdrh]; des->bp = bp; des->addr = PADDR(bp->rp); ctlr->ntq++; coherence(); des->cmdsts = Own | BLEN(bp); ctlr->tdrh = NEXT(ctlr->tdrh, ctlr->ntdr); started = 1; } if(started){ coherence(); csr32w(ctlr, Rcr, Txe); /* prompt */ } if(ctlr->ntq > ctlr->ntqmax) ctlr->ntqmax = ctlr->ntq; } static void transmit(Ether* ether) { Ctlr *ctlr; ctlr = ether->ctlr; ilock(&ctlr->tlock); txstart(ether); iunlock(&ctlr->tlock); } static void txrxcfg(Ctlr *ctlr, int txdrth) { ulong rx, tx; rx = csr32r(ctlr, Rrxcfg); tx = csr32r(ctlr, Rtxcfg); if(ctlr->fd){ rx |= Atx; tx |= Csi | Hbi; }else{ rx &= ~Atx; tx &= ~(Csi | Hbi); } tx &= ~(Mxdma|Drth|Flth); tx |= Mxdma64 | Flth128 | txdrth; csr32w(ctlr, Rtxcfg, tx); rx &= ~(Mxdma|Rdrth); rx |= Mxdma64 | Rdrth64; csr32w(ctlr, Rrxcfg, rx); } static void interrupt(Ureg*, void* arg) { int len, status, cmdsts, n; Ctlr *ctlr; Ether *ether; Des *des; Block *bp; ether = arg; ctlr = ether->ctlr; while((status = csr32r(ctlr, Risr)) != 0){ status &= ~(Pme|Mib); if(status & Hiberr){ if(status & Rxsovr) ctlr->rxsover++; if(status & Sserr) ctlr->sserr++; if(status & Dperr) ctlr->dperr++; if(status & Rmabt) ctlr->rmabt++; if(status & Rtabt) ctlr->rtabt++; status &= ~(Hiberr|Txrcmp|Rxrcmp|Rxsovr|Dperr|Sserr|Rmabt|Rtabt); } /* update link state */ if(status&Phy){ status &= ~Phy; csr32r(ctlr, Rcfg); n = csr32r(ctlr, Rcfg); // iprint("83815 phy %x %x\n", n, n&Lnksts); ether->link = (n&Lnksts) != 0; } /* * Received packets. */ if(status & (Rxdesc|Rxok|Rxerr|Rxearly|Rxorn)){ des = &ctlr->rdr[ctlr->rdrx]; while((cmdsts = des->cmdsts) & Own){ if((cmdsts&Ok) == 0){ if(cmdsts & Rxa) ctlr->rxa++; if(cmdsts & Rxo) ctlr->rxo++; if(cmdsts & Long) ctlr->rlong++; if(cmdsts & Runt) ctlr->runt++; if(cmdsts & Ise) ctlr->ise++; if(cmdsts & Crce) ctlr->crce++; if(cmdsts & Fae) ctlr->fae++; if(cmdsts & Lbp) ctlr->lbp++; if(cmdsts & Col) ctlr->col++; } else if(bp = iallocb(Rbsz)){ len = (cmdsts&Size)-4; if(len <= 0){ debug("ns83815: packet len %d <=0\n", len); freeb(des->bp); }else{ des->bp->wp = des->bp->rp+len; etheriq(ether, des->bp); } des->bp = bp; des->addr = PADDR(bp->rp); coherence(); }else{ debug("ns83815: interrupt: iallocb for input buffer failed\n"); des->bp->next = 0; } des->cmdsts = Rbsz; coherence(); ctlr->rdrx = NEXT(ctlr->rdrx, ctlr->nrdr); des = &ctlr->rdr[ctlr->rdrx]; } status &= ~(Rxdesc|Rxok|Rxerr|Rxearly|Rxorn); } /* * Check the transmit side: * check for Transmit Underflow and Adjust * the threshold upwards; * free any transmitted buffers and try to * top-up the ring. */ if(status & Txurn){ ctlr->txurn++; ilock(&ctlr->lock); /* change threshold */ iunlock(&ctlr->lock); status &= ~(Txurn); } ilock(&ctlr->tlock); while(ctlr->ntq){ des = &ctlr->tdr[ctlr->tdri]; cmdsts = des->cmdsts; if(cmdsts & Own) break; if((cmdsts & Ok) == 0){ if(cmdsts & Txa) ctlr->txa++; if(cmdsts & Tfu) ctlr->tfu++; if(cmdsts & Td) ctlr->td++; if(cmdsts & Ed) ctlr->ed++; if(cmdsts & Owc) ctlr->owc++; if(cmdsts & Ec) ctlr->ec++; ether->oerrs++; } freeb(des->bp); des->bp = nil; des->cmdsts = 0; ctlr->ntq--; ctlr->tdri = NEXT(ctlr->tdri, ctlr->ntdr); } txstart(ether); iunlock(&ctlr->tlock); status &= ~(Txurn|Txidle|Txerr|Txdesc|Txok); /* * Anything left not catered for? */ if(status) print("#l%d: status %8.8uX\n", ether->ctlrno, status); } } static void ctlrinit(Ether* ether) { Ctlr *ctlr; Des *des, *last; ctlr = ether->ctlr; /* * Allocate suitable aligned descriptors * for the transmit and receive rings; * initialise the receive ring; * initialise the transmit ring; * unmask interrupts and start the transmit side. */ des = xspanalloc((ctlr->nrdr+ctlr->ntdr)*sizeof(Des), 32, 0); ctlr->tdr = des; ctlr->rdr = des+ctlr->ntdr; last = nil; for(des = ctlr->rdr; des < &ctlr->rdr[ctlr->nrdr]; des++){ des->bp = iallocb(Rbsz); if(des->bp == nil) panic("ether83815: can't allocate receive buffer"); des->cmdsts = Rbsz; des->addr = PADDR(des->bp->rp); if(last != nil) last->next = PADDR(des); last = des; } ctlr->rdr[ctlr->nrdr-1].next = PADDR(ctlr->rdr); ctlr->rdrx = 0; csr32w(ctlr, Rrxdp, PADDR(ctlr->rdr)); last = nil; for(des = ctlr->tdr; des < &ctlr->tdr[ctlr->ntdr]; des++){ des->cmdsts = 0; des->bp = nil; des->addr = ~0; if(last != nil) last->next = PADDR(des); last = des; } ctlr->tdr[ctlr->ntdr-1].next = PADDR(ctlr->tdr); ctlr->tdrh = 0; ctlr->tdri = 0; csr32w(ctlr, Rtxdp, PADDR(ctlr->tdr)); txrxcfg(ctlr, Drth512); csr32w(ctlr, Rimr, Dperr|Sserr|Rmabt|Rtabt|Rxsovr|Hiberr|Txurn|Txerr| Txdesc|Txok|Rxorn|Rxerr|Rxdesc|Rxok); /* Phy|Pme|Mib */ csr32w(ctlr, Rmicr, Inten); /* enable phy interrupts */ csr32r(ctlr, Risr); /* clear status */ csr32w(ctlr, Rier, Ie); } static void eeclk(Ctlr *ctlr, int clk) { csr32w(ctlr, Rmear, Eesel | clk); microdelay(2); } static void eeidle(Ctlr *ctlr) { int i; eeclk(ctlr, 0); eeclk(ctlr, Eeclk); for(i=0; i<25; i++){ eeclk(ctlr, 0); eeclk(ctlr, Eeclk); } eeclk(ctlr, 0); csr32w(ctlr, Rmear, 0); microdelay(2); } static ushort eegetw(Ctlr *ctlr, int a) { int d, i, w; eeidle(ctlr); eeclk(ctlr, 0); eeclk(ctlr, Eeclk); d = 0x180 | a; for(i=0x400; i; i>>=1){ if(d & i) csr32w(ctlr, Rmear, Eesel|Eedi); else csr32w(ctlr, Rmear, Eesel); eeclk(ctlr, Eeclk); eeclk(ctlr, 0); microdelay(2); } w = 0; for(i=0x8000; i; i >>= 1){ eeclk(ctlr, Eeclk); if(csr32r(ctlr, Rmear) & Eedo) w |= i; microdelay(2); eeclk(ctlr, 0); } eeidle(ctlr); return w; } static int resetctlr(Ctlr *ctlr) { int i; /* * Soft-reset the controller */ csr32w(ctlr, Rcr, Rst); for(i=0;; i++){ if(i > 100){ print("ns83815: soft reset did not complete\n"); return -1; } microdelay(250); if((csr32r(ctlr, Rcr) & Rst) == 0) break; delay(1); } return 0; } static void shutdown(Ether* ether) { Ctlr *ctlr = ether->ctlr; print("ether83815 shutting down\n"); csr32w(ctlr, Rcr, Rxd|Txd); /* disable transceiver */ resetctlr(ctlr); } static int softreset(Ctlr* ctlr, int resetphys) { int i, w; /* * Soft-reset the controller */ resetctlr(ctlr); if(ctlr->id != Nat83815) return 0; csr32w(ctlr, Rccsr, Pmests); csr32w(ctlr, Rccsr, 0); csr32w(ctlr, Rcfg, csr32r(ctlr, Rcfg) | Pint_acen); ctlr->version = csr32r(ctlr, Rsrr); if(resetphys){ /* * Soft-reset the PHY */ csr32w(ctlr, Rbmcr, Reset); for(i=0;; i++){ if(i > 100){ print("ns83815: PHY soft reset time out\n"); return -1; } if((csr32r(ctlr, Rbmcr) & Reset) == 0) break; delay(1); } } /* * Initialisation values, in sequence (see 4.4 Recommended Registers Configuration) */ csr16w(ctlr, 0xCC, 0x0001); /* PGSEL */ csr16w(ctlr, 0xE4, 0x189C); /* PMCCSR */ csr16w(ctlr, 0xFC, 0x0000); /* TSTDAT */ csr16w(ctlr, 0xF4, 0x5040); /* DSPCFG */ csr16w(ctlr, 0xF8, 0x008C); /* SDCFG */ /* * Auto negotiate */ csr16r(ctlr, Rbmsr); /* clear latched bits */ debug("anar: %4.4ux\n", csr16r(ctlr, Ranar)); csr16w(ctlr, Rbmcr, Anena); if(csr16r(ctlr, Ranar) == 0 || (csr32r(ctlr, Rcfg) & Aneg_dn) == 0){ csr16w(ctlr, Rbmcr, Anena|Anrestart); for(i=0;; i++){ if(i > 3000){ print("ns83815: auto neg timed out\n"); return -1; } if((w = csr16r(ctlr, Rbmsr)) & Ancomp) break; delay(1); } debug("%d ms\n", i); w &= 0xFFFF; debug("bmsr: %4.4ux\n", w); USED(w); } debug("anar: %4.4ux\n", csr16r(ctlr, Ranar)); debug("anlpar: %4.4ux\n", csr16r(ctlr, Ranlpar)); debug("aner: %4.4ux\n", csr16r(ctlr, Raner)); debug("physts: %4.4ux\n", csr16r(ctlr, Rphysts)); debug("tbscr: %4.4ux\n", csr16r(ctlr, Rtbscr)); return 0; } static int media(Ether* ether) { Ctlr* ctlr; ulong cfg; ctlr = ether->ctlr; cfg = csr32r(ctlr, Rcfg); ctlr->fd = (cfg & Fdup) != 0; ether->link = (cfg&Lnksts) != 0; return (cfg&(Lnksts|Speed100)) == Lnksts? 10: 100; } static char* mediatable[9] = { "10BASE-T", /* TP */ "10BASE-2", /* BNC */ "10BASE-5", /* AUI */ "100BASE-TX", "10BASE-TFD", "100BASE-TXFD", "100BASE-T4", "100BASE-FX", "100BASE-FXFD", }; static int is630(ulong id, Pcidev *p) { if(id == SiS900) switch (p->rid) { case SiSrev630s: case SiSrev630e: case SiSrev630ea1: return 1; } return 0; } enum { MagicReg = 0x48, MagicRegSz = 1, Magicrden = 0x40, /* read enable, apparently */ Paddr= 0x70, /* address port */ Pdata= 0x71, /* data port */ }; /* rcmos() originally from LANL's SiS 900 driver's rcmos() */ static int sisrdcmos(Ctlr *ctlr) { int i; unsigned reg; ulong port; Pcidev *p; debug("ns83815: SiS 630 rev. %ux reading mac address from cmos\n", ctlr->pcidev->rid); p = pcimatch(nil, SiS, SiS630bridge); if(p == nil) { print("ns83815: no SiS 630 rev. %ux bridge for mac addr\n", ctlr->pcidev->rid); return 0; } port = p->mem[0].bar & ~0x01; debug("ns83815: SiS 630 rev. %ux reading mac addr from cmos via bridge at port 0x%lux\n", ctlr->pcidev->rid, port); reg = pcicfgr8(p, MagicReg); pcicfgw8(p, MagicReg, reg|Magicrden); for (i = 0; i < Eaddrlen; i++) { outb(port+Paddr, SiS630eenodeaddr + i); ctlr->sromea[i] = inb(port+Pdata); } pcicfgw8(p, MagicReg, reg & ~Magicrden); return 1; } /* * If this is a SiS 630E chipset with an embedded SiS 900 controller, * we have to read the MAC address from the APC CMOS RAM. - sez freebsd. * However, CMOS *is* NVRAM normally. See devrtc.c:440, memory.c:88. */ static void sissrom(Ctlr *ctlr) { union { uchar eaddr[Eaddrlen]; ushort alignment; } ee; int i, off = SiSeenodeaddr, cnt = sizeof ee.eaddr / sizeof(short); ushort *shp = (ushort *)ee.eaddr; if(ctlr->id == SiS900 && ctlr->pcidev->rid == SiSrev635) { csr32w(ctlr, Rcr, csr32r(ctlr, Rcr) | Rld); csr32w(ctlr, Rcr, csr32r(ctlr, Rcr) & ~Rld); csr32w(ctlr, Rrfcr, csr32r(ctlr, Rrfcr) & ~Rfen); csr32w(ctlr, Rrfcr, 0); *shp++ = csr32r(ctlr, Rrfdr); csr32w(ctlr, Rrfcr, 1<<16); *shp++ = csr32r(ctlr, Rrfdr); csr32w(ctlr, Rrfcr, 1<<17); *shp = csr32r(ctlr, Rrfdr); csr32w(ctlr, Rrfcr, csr32r(ctlr, Rrfcr) | Rfen); memmove(ctlr->sromea, ee.eaddr, sizeof ctlr->sromea); } else if(!is630(ctlr->id, ctlr->pcidev) || !sisrdcmos(ctlr)) { for (i = 0; i < cnt; i++) *shp++ = eegetw(ctlr, off++); memmove(ctlr->sromea, ee.eaddr, sizeof ctlr->sromea); } } ushort søkrisee(Ctlr *c, int n) { int i; uint cmd; ushort r; csr32w(c, Rmear, Eesel); cmd = 0x180|n; for(i = 10; i >= 0; i--){ n = 1<<3; if(cmd&(1<<i)) n |= 1; csr32w(c, Rmear, n); csr32r(c, Rmear); csr32w(c, Rmear, n|4); csr32r(c, Rmear); } csr32w(c, Rmear, 1<<3); csr32r(c, Rmear); r = 0; for(i = 0; i < 16; i++){ csr32w(c, Rmear, 1<<3 | 1<<2); csr32r(c, Rmear); if(csr32r(c, Rmear) & 2) r |= 1<<i; csr32w(c, Rmear, 1<<3); csr32r(c, Rmear); } csr32w(c, Rmear, 1<<3); csr32w(c, Rmear, 0); return r; } static void nsnormalea(Ctlr *ctlr) { int i, j; /* * the MAC address is reversed, straddling word boundaries */ j = Nseenodeaddr*16 + 15; for(i = 0; i < 48; i++){ ctlr->sromea[i>>3] |= ((ctlr->srom[j>>4] >> (15-(j&0xF))) & 1) << (i&7); j++; } } static void ns403ea(Ctlr *ctlr) { int i; ushort s, t; s = ctlr->srom[6]; for(i = 0; i < 3; i++){ t = ctlr->srom[i+7]; ctlr->sromea[i*2] = t<<1 | s>>15; ctlr->sromea[i*2+1] = t>>7; s = t; } } static void nssrom(Ctlr* ctlr) { int i, ns403; ulong vers; ushort (*ee)(Ctlr*, int); vers = ctlr->version; ns403 = vers == Nat83815avng || vers == Nat83816avng; if(ns403){ ee = søkrisee; print("soekris %lx\n", vers); }else ee = eegetw; for(i = 0; i < nelem(ctlr->srom); i++) ctlr->srom[i] = ee(ctlr, i); if(ns403) ns403ea(ctlr); else nsnormalea(ctlr); } static void srom(Ctlr* ctlr) { memset(ctlr->sromea, 0, sizeof(ctlr->sromea)); switch (ctlr->id) { case SiS900: case SiS7016: sissrom(ctlr); break; case Nat83815: nssrom(ctlr); break; default: print("ns83815: srom: unknown id 0x%ux\n", ctlr->id); break; } } static void scanpci83815(void) { Ctlr *ctlr; Pcidev *p; ulong id; p = nil; while(p = pcimatch(p, 0, 0)){ if(p->ccrb != Pcibcnet || p->ccru != 0) continue; id = (p->did<<16)|p->vid; switch(id){ default: continue; case Nat83815: break; case SiS900: break; } /* * bar[0] is the I/O port register address and * bar[1] is the memory-mapped register address. */ ctlr = malloc(sizeof(Ctlr)); if(ctlr == nil){ print("ns83815: can't allocate memory\n"); continue; } ctlr->port = p->mem[0].bar & ~3; ctlr->pcidev = p; ctlr->id = id; if(ioalloc(ctlr->port, p->mem[0].size, 0, "ns83815") < 0){ print("ns83815: port 0x%uX in use\n", ctlr->port); free(ctlr); continue; } if(ctlrhead != nil) ctlrtail->next = ctlr; else ctlrhead = ctlr; ctlrtail = ctlr; } } /* multicast already on, don't need to do anything */ static void multicast(void*, uchar*, int) { } static int reset(Ether* ether) { Ctlr *ctlr; int i, x; ulong ctladdr; uchar ea[Eaddrlen]; static int scandone; if(scandone == 0){ scanpci83815(); scandone = 1; } /* * Any adapter matches if no ether->port is supplied, * otherwise the ports must match. */ for(ctlr = ctlrhead; ctlr != nil; ctlr = ctlr->next){ if(ctlr->active) continue; if(ether->port == 0 || ether->port == ctlr->port){ ctlr->active = 1; break; } } if(ctlr == nil) return -1; pcienable(ctlr->pcidev); softreset(ctlr, 0); srom(ctlr); ether->ctlr = ctlr; ether->port = ctlr->port; ether->irq = ctlr->pcidev->intl; ether->tbdf = ctlr->pcidev->tbdf; /* * Check if the adapter's station address is to be overridden. * If not, read it from the EEPROM and set in ether->ea prior to * loading the station address in the hardware. */ memset(ea, 0, Eaddrlen); if(memcmp(ea, ether->ea, Eaddrlen) == 0) memmove(ether->ea, ctlr->sromea, Eaddrlen); for(i=0; i<Eaddrlen; i+=2){ x = ether->ea[i] | (ether->ea[i+1]<<8); ctladdr = (ctlr->id == Nat83815? i: i<<15); csr32w(ctlr, Rrfcr, ctladdr); csr32w(ctlr, Rrfdr, x); } csr32w(ctlr, Rrfcr, Rfen|Apm|Aab|Aam); ether->mbps = media(ether); /* * Look for a medium override in case there's no autonegotiation * the autonegotiation fails. */ for(i = 0; i < ether->nopt; i++){ if(cistrcmp(ether->opt[i], "FD") == 0){ ctlr->fd = 1; continue; } for(x = 0; x < nelem(mediatable); x++){ debug("compare <%s> <%s>\n", mediatable[x], ether->opt[i]); if(cistrcmp(mediatable[x], ether->opt[i]) == 0){ if(x != 4 && x >= 3) ether->mbps = 100; else ether->mbps = 10; switch(x){ default: ctlr->fd = 0; break; case 0x04: /* 10BASE-TFD */ case 0x05: /* 100BASE-TXFD */ case 0x08: /* 100BASE-FXFD */ ctlr->fd = 1; break; } break; } } } /* * Initialise descriptor rings, ethernet address. */ ctlr->nrdr = Nrde; ctlr->ntdr = Ntde; pcisetbme(ctlr->pcidev); ctlrinit(ether); /* * Linkage to the generic ethernet driver. */ ether->attach = attach; ether->transmit = transmit; ether->ifstat = ifstat; ether->arg = ether; ether->promiscuous = promiscuous; ether->multicast = multicast; ether->shutdown = shutdown; intrenable(ether->irq, interrupt, ether, ether->tbdf, ether->name); return 0; } void ether83815link(void) { addethercard("83815", reset); }