ref: c07ad86666257eb54db8723b330d289b13036d44
dir: /os/pc/etherrhine.c/
/* Via Rhine driver, written for VT6102. Uses the ethermii to control PHY. Currently always copies on both, tx and rx. rx side could be copy-free, and tx-side might be made (almost) copy-free by using (possibly) two descriptors (if it allows arbitrary tx lengths, which it should..): first for alignment and second for rest of the frame. Rx-part should be worth doing. */ #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" typedef struct Desc Desc; typedef struct Ctlr Ctlr; enum { Ntxd = 16, Nrxd = 64, Nwait = 50, Ntxstats = 9, Nrxstats = 8, BIGSTR = 8192, }; struct Desc { ulong stat; ulong size; ulong addr; ulong next; char *buf; ulong pad[3]; }; struct Ctlr { Pcidev *pci; int attached; int txused; int txhead; int txtail; int rxtail; ulong port; Mii mii; ulong txstats[Ntxstats]; ulong rxstats[Nrxstats]; Desc *txd; /* wants to be aligned on 16-byte boundary */ Desc *rxd; QLock attachlck; Lock lock; }; #define ior8(c, r) (inb((c)->port+(r))) #define ior16(c, r) (ins((c)->port+(r))) #define ior32(c, r) (inl((c)->port+(r))) #define iow8(c, r, b) (outb((c)->port+(r), (int)(b))) #define iow16(c, r, w) (outs((c)->port+(r), (ushort)(w))) #define iow32(c, r, l) (outl((c)->port+(r), (ulong)(l))) enum Regs { Eaddr = 0x0, Rcr = 0x6, Tcr = 0x7, Cr = 0x8, Isr = 0xc, Imr = 0xe, McastAddr = 0x10, RxdAddr = 0x18, TxdAddr = 0x1C, Bcr = 0x6e, RhineMiiPhy = 0x6C, RhineMiiSr = 0x6D, RhineMiiCr = 0x70, RhineMiiAddr = 0x71, RhineMiiData = 0x72, Eecsr = 0x74, ConfigB = 0x79, ConfigD = 0x7B, MiscCr = 0x80, HwSticky = 0x83, MiscIsr = 0x84, MiscImr = 0x86, WolCrSet = 0xA0, WolCfgSet = 0xA1, WolCgSet = 0xA3, WolCrClr = 0xA4, PwrCfgClr = 0xA5, WolCgClr = 0xA7, }; enum Rcrbits { RxErrX = 1<<0, RxSmall = 1<<1, RxMcast = 1<<2, RxBcast = 1<<3, RxProm = 1<<4, RxFifo64 = 0<<5, RxFifo32 = 1<<5, RxFifo128 = 2<<5, RxFifo256 = 3<<5, RxFifo512 = 4<<5, RxFifo768 = 5<<5, RxFifo1024 = 6<<5, RxFifoStoreForward = 7<<5, }; enum Tcrbits { TxLoopback0 = 1<<1, TxLoopback1 = 1<<2, TxBackoff = 1<<3, TxFifo128 = 0<<5, TxFifo256 = 1<<5, TxFifo512 = 2<<5, TxFifo1024 = 3<<5, TxFifoStoreForward = 7<<5, }; enum Crbits { Init = 1<<0, Start = 1<<1, Stop = 1<<2, RxOn = 1<<3, TxOn = 1<<4, Tdmd = 1<<5, Rdmd = 1<<6, EarlyRx = 1<<8, Reserved0 = 1<<9, FullDuplex = 1<<10, NoAutoPoll = 1<<11, Reserved1 = 1<<12, Tdmd1 = 1<<13, Rdmd1 = 1<<14, Reset = 1<<15, }; enum Isrbits { RxOk = 1<<0, TxOk = 1<<1, RxErr = 1<<2, TxErr = 1<<3, TxBufUdf = 1<<4, RxBufLinkErr = 1<<5, BusErr = 1<<6, CrcOvf = 1<<7, EarlyRxInt = 1<<8, TxFifoUdf = 1<<9, RxFifoOvf = 1<<10, TxPktRace = 1<<11, NoRxbuf = 1<<12, TxCollision = 1<<13, PortCh = 1<<14, GPInt = 1<<15 }; enum Bcrbits { Dma32 = 0<<0, Dma64 = 1<<0, Dma128 = 2<<0, Dma256 = 3<<0, Dma512 = 4<<0, Dma1024 = 5<<0, DmaStoreForward = 7<<0, DupRxFifo0 = 1<<3, DupRxFifo1 = 1<<4, DupRxFifo2 = 1<<5, ExtraLed = 1<<6, MediumSelect = 1<<7, PollTimer0 = 1<<8, PollTimer1 = 1<<9, PollTimer2 = 1<<10, DupTxFifo0 = 1<<11, DupTxFifo1 = 1<<12, DupTxFifo2 = 1<<13, }; enum Eecsrbits { EeAutoLoad = 1<<5, }; enum MiscCrbits { Timer0Enable= 1<<0, Timer0Suspend = 1<<1, HalfDuplexFlowControl = 1<<2, FullDuplexFlowControl = 1<<3, Timer1Enable = 1<<8, ForceSoftReset = 1<<14, }; enum HwStickybits { StickyDS0 = 1<<0, StickyDS1 = 1<<1, WOLEna = 1<<2, WOLStat = 1<<3, }; enum WolCgbits { PmeOvr = 1<<7, }; enum Descbits { OwnNic = 1<<31, /* stat */ TxAbort = 1<<8, /* stat */ TxError = 1<<15, /* stat */ RxChainbuf = 1<<10, /* stat */ RxChainStart = 1<<9, /* stat */ RxChainEnd = 1<<8, /* stat */ Chainbuf = 1<<15, /* size rx & tx*/ TxDisableCrc = 1<<16, /* size */ TxChainStart = 1<<21, /* size */ TxChainEnd = 1<<22, /* size */ TxInt = 1<<23, /* size */ }; enum ConfigDbits { BackoffOptional = 1<<0, BackoffAMD = 1<<1, BackoffDEC = 1<<2, BackoffRandom = 1<<3, PmccTestMode = 1<<4, PciReadlineCap = 1<<5, DiagMode = 1<<6, MmioEnable = 1<<7, }; enum ConfigBbits { LatencyTimer = 1<<0, WriteWaitState = 1<<1, ReadWaitState = 1<<2, RxArbit = 1<<3, TxArbit = 1<<4, NoMemReadline = 1<<5, NoParity = 1<<6, NoTxQueuing = 1<<7, }; enum RhineMiiCrbits { Mdc = 1<<0, Mdi = 1<<1, Mdo = 1<<2, Mdout = 1<<3, Mdpm = 1<<4, Wcmd = 1<<5, Rcmd = 1<<6, Mauto = 1<<7, }; enum RhineMiiSrbits { Speed10M = 1<<0, LinkFail = 1<<1, PhyError = 1<<3, DefaultPhy = 1<<4, ResetPhy = 1<<7, }; enum RhineMiiAddrbits { Mdone = 1<<5, Msrcen = 1<<6, Midle = 1<<7, }; static char * txstatnames[Ntxstats] = { "aborts (excess collisions)", "out of window collisions", "carrier sense losses", "fifo underflows", "invalid descriptor format or underflows", "system errors", "reserved", "transmit errors", "collisions", }; static char * rxstatnames[Nrxstats] = { "receiver errors", "crc errors", "frame alignment errors", "fifo overflows", "long packets", "run packets", "system errors", "buffer underflows", }; static void attach(Ether *edev) { Ctlr *ctlr; Desc *txd, *rxd, *td, *rd; Mii *mi; MiiPhy *phy; int i, s; ctlr = edev->ctlr; qlock(&ctlr->attachlck); if (ctlr->attached == 0) { txd = ctlr->txd; rxd = ctlr->rxd; for (i = 0; i < Ntxd; ++i) { td = &txd[i]; td->next = PCIWADDR(&txd[(i+1) % Ntxd]); td->buf = xspanalloc(sizeof(Etherpkt)+4, 4, 0); td->addr = PCIWADDR(td->buf); td->size = 0; coherence(); td->stat = 0; } for (i = 0; i < Nrxd; ++i) { rd = &rxd[i]; rd->next = PCIWADDR(&rxd[(i+1) % Nrxd]); rd->buf = xspanalloc(sizeof(Etherpkt)+4, 4, 0); rd->addr = PCIWADDR(rd->buf); rd->size = sizeof(Etherpkt)+4; coherence(); rd->stat = OwnNic; } ctlr->txhead = ctlr->txtail = ctlr->rxtail = 0; mi = &ctlr->mii; miistatus(mi); phy = mi->curphy; s = splhi(); iow32(ctlr, TxdAddr, PCIWADDR(&txd[0])); iow32(ctlr, RxdAddr, PCIWADDR(&rxd[0])); iow16(ctlr, Cr, (phy->fd ? FullDuplex : 0) | NoAutoPoll | TxOn | RxOn | Start | Rdmd); iow16(ctlr, Isr, 0xFFFF); iow16(ctlr, Imr, 0xFFFF); iow8(ctlr, MiscIsr, 0xFF); iow8(ctlr, MiscImr, ~(3<<5)); splx(s); } ctlr->attached++; qunlock(&ctlr->attachlck); } static void txstart(Ether *edev) { Ctlr *ctlr; Desc *txd, *td; Block *b; int i, txused, n; ulong size; ctlr = edev->ctlr; txd = ctlr->txd; i = ctlr->txhead; txused = ctlr->txused; n = 0; while (txused < Ntxd) { if ((b = qget(edev->oq)) == nil) break; td = &txd[i]; size = BLEN(b); memmove(td->buf, b->rp, size); freeb(b); td->size = size | TxChainStart | TxChainEnd | TxInt; /* could reduce number of ints here */ coherence(); td->stat = OwnNic; i = (i + 1) % Ntxd; txused++; n++; } if (n) iow16(ctlr, Cr, ior16(ctlr, Cr) | Tdmd); ctlr->txhead = i; ctlr->txused = txused; } static void transmit(Ether *edev) { Ctlr *ctlr; ctlr = edev->ctlr; ilock(&ctlr->lock); txstart(edev); iunlock(&ctlr->lock); } static void txcomplete(Ether *edev) { Ctlr *ctlr; Desc *txd, *td; int i, txused, j; ulong stat; ctlr = edev->ctlr; txd = ctlr->txd; txused = ctlr->txused; i = ctlr->txtail; while (txused > 0) { td = &txd[i]; stat = td->stat; if (stat & OwnNic) break; ctlr->txstats[Ntxstats-1] += stat & 0xF; for (j = 0; j < Ntxstats-1; ++j) if (stat & (1<<(j+8))) ctlr->txstats[j]++; i = (i + 1) % Ntxd; txused--; } ctlr->txused = txused; ctlr->txtail = i; if (txused <= Ntxd/2) txstart(edev); } static void interrupt(Ureg *, void *arg) { Ether *edev; Ctlr *ctlr; ushort isr, misr; ulong stat; Desc *rxd, *rd; int i, n, j; edev = (Ether*)arg; ctlr = edev->ctlr; iow16(ctlr, Imr, 0); isr = ior16(ctlr, Isr); iow16(ctlr, Isr, 0xFFFF); misr = ior16(ctlr, MiscIsr) & ~(3<<5); /* don't care about used defined ints */ if (isr & RxOk) { Block *b; int size; rxd = ctlr->rxd; i = ctlr->rxtail; n = 0; while ((rxd[i].stat & OwnNic) == 0) { rd = &rxd[i]; stat = rd->stat; for (j = 0; j < Nrxstats; ++j) if (stat & (1<<j)) ctlr->rxstats[j]++; if (stat & 0xFF) iprint("rx: %lux\n", stat & 0xFF); size = ((rd->stat>>16) & 2047) - 4; b = iallocb(sizeof(Etherpkt)); memmove(b->wp, rd->buf, size); b->wp += size; etheriq(edev, b, 1); rd->size = sizeof(Etherpkt)+4; coherence(); rd->stat = OwnNic; i = (i + 1) % Nrxd; n++; } if (n) iow16(ctlr, Cr, ior16(ctlr, Cr) | Rdmd); ctlr->rxtail = i; isr &= ~RxOk; } if (isr & TxOk) { txcomplete(edev); isr &= ~TxOk; } if (isr | misr) iprint("etherrhine: unhandled irq(s). isr:%x misr:%x\n", isr, misr); iow16(ctlr, Imr, 0xFFFF); } static void promiscuous(void *arg, int enable) { Ether *edev; Ctlr *ctlr; edev = arg; ctlr = edev->ctlr; ilock(&ctlr->lock); iow8(ctlr, Rcr, (ior8(ctlr, Rcr) & ~(RxProm|RxBcast)) | (enable ? RxProm : RxBcast)); iunlock(&ctlr->lock); } static int miiread(Mii *mii, int phy, int reg) { Ctlr *ctlr; int n; ctlr = mii->ctlr; n = Nwait; while (n-- && ior8(ctlr, RhineMiiCr) & (Rcmd | Wcmd)) microdelay(1); if (n == Nwait) iprint("etherrhine: miiread: timeout\n"); iow8(ctlr, RhineMiiCr, 0); iow8(ctlr, RhineMiiPhy, phy); iow8(ctlr, RhineMiiAddr, reg); iow8(ctlr, RhineMiiCr, Rcmd); n = Nwait; while (n-- && ior8(ctlr, RhineMiiCr) & Rcmd) microdelay(1); if (n == Nwait) iprint("etherrhine: miiread: timeout\n"); n = ior16(ctlr, RhineMiiData); return n; } static int miiwrite(Mii *mii, int phy, int reg, int data) { int n; Ctlr *ctlr; ctlr = mii->ctlr; n = Nwait; while (n-- && ior8(ctlr, RhineMiiCr) & (Rcmd | Wcmd)) microdelay(1); if (n == Nwait) iprint("etherrhine: miiwrite: timeout\n"); iow8(ctlr, RhineMiiCr, 0); iow8(ctlr, RhineMiiPhy, phy); iow8(ctlr, RhineMiiAddr, reg); iow16(ctlr, RhineMiiData, data); iow8(ctlr, RhineMiiCr, Wcmd); n = Nwait; while (n-- && ior8(ctlr, RhineMiiCr) & Wcmd) microdelay(1); if (n == Nwait) iprint("etherrhine: miiwrite: timeout\n"); return 0; } /* multicast already on, don't need to do anything */ static void multicast(void*, uchar*, int) { } static void shutdown(Ether *edev) { int i; Ctlr *ctlr = edev->ctlr; ilock(&ctlr->lock); pcisetbme(ctlr->pci); iow16(ctlr, Cr, ior16(ctlr, Cr) | Stop); iow16(ctlr, Cr, ior16(ctlr, Cr) | Reset); for (i = 0; i < Nwait; ++i) { if ((ior16(ctlr, Cr) & Reset) == 0) break; delay(5); } if (i == Nwait) iprint("etherrhine: reset timeout\n"); iunlock(&ctlr->lock); } static void init(Ether *edev) { Ctlr *ctlr; MiiPhy *phy; int i; shutdown(edev); ctlr = edev->ctlr; ilock(&ctlr->lock); iow8(ctlr, Eecsr, ior8(ctlr, Eecsr) | EeAutoLoad); for (i = 0; i < Nwait; ++i) { if ((ior8(ctlr, Eecsr) & EeAutoLoad) == 0) break; delay(5); } if (i == Nwait) iprint("etherrhine: eeprom autoload timeout\n"); for (i = 0; i < Eaddrlen; ++i) edev->ea[i] = ior8(ctlr, Eaddr + i); ctlr->mii.mir = miiread; ctlr->mii.miw = miiwrite; ctlr->mii.ctlr = ctlr; if(mii(&ctlr->mii, ~0) == 0 || ctlr->mii.curphy == nil){ iprint("etherrhine: init mii failure\n"); return; } for (i = 0; i < NMiiPhy; ++i) if (ctlr->mii.phy[i]) if (ctlr->mii.phy[i]->oui != 0xFFFFF) ctlr->mii.curphy = ctlr->mii.phy[i]; miistatus(&ctlr->mii); phy = ctlr->mii.curphy; edev->mbps = phy->speed; iow16(ctlr, Imr, 0); iow16(ctlr, Cr, ior16(ctlr, Cr) | Stop); iow8(ctlr, Rcr, ior8(ctlr, Rcr) | RxMcast); iunlock(&ctlr->lock); } static Pcidev * rhinematch(ulong) { static int nrhines = 0; int nfound = 0; Pcidev *p = nil; while (p = pcimatch(p, 0x1106, 0)) if (p->did == 0x3065) if (++nfound > nrhines) { nrhines++; break; } return p; } static long ifstat(Ether* edev, void* a, long n, ulong offset) { int l = 0, i; char *p; Ctlr *ctlr; ctlr = edev->ctlr; p = malloc(BIGSTR); for (i = 0; i < Ntxstats; ++i) if (txstatnames[i]) l += snprint(p+l, BIGSTR - l, "tx: %s: %lud\n", txstatnames[i], ctlr->txstats[i]); for (i = 0; i < Nrxstats; ++i) if (rxstatnames[i]) l += snprint(p+l, BIGSTR - l, "rx: %s: %lud\n", rxstatnames[i], ctlr->rxstats[i]); /* for (i = 0; i < NMiiPhyr; ++i) { if ((i % 8) == 0) l += snprint(p + l, BIGSTR - l, "\nmii 0x%02x:", i); reg=miimir(&ctlr->mii, i); reg=miimir(&ctlr->mii, i); l += snprint(p + l, BIGSTR - l, " %4ux", reg); } for (i = 0; i < 0x100; i+=1) { if ((i % 16) == 0) l += snprint(p + l, BIGSTR - l, "\nreg 0x%02x:", i); else if ((i % 2) == 0) l += snprint(p + l, BIGSTR - l, " "); reg=ior8(ctlr, i); l += snprint(p + l, BIGSTR - l, "%02x", reg); } l += snprint(p + l, BIGSTR - l, " \n"); */ n = readstr(offset, a, n, p); free(p); return n; } static int pnp(Ether *edev) { Pcidev *p; Ctlr *ctlr; ulong port; ulong size; p = rhinematch(edev->port); if (p == nil) return -1; port = p->mem[0].bar & ~1; size = p->mem[0].size; if (ioalloc(port, size, 0, "rhine") < 0) { print("etherrhine: couldn't allocate port %lud\n", port); return -1; } if ((ctlr = malloc(sizeof(Ctlr))) == nil) { print("etherrhine: couldn't allocate memory for ctlr\n"); return -1; } memset(ctlr, 0, sizeof(Ctlr)); ctlr->txd = xspanalloc(sizeof(Desc) * Ntxd, 16, 0); ctlr->rxd = xspanalloc(sizeof(Desc) * Nrxd, 16, 0); ctlr->pci = p; ctlr->port = port; edev->ctlr = ctlr; edev->port = ctlr->port; edev->irq = p->intl; edev->tbdf = p->tbdf; init(edev); edev->interrupt = interrupt; edev->arg = edev; edev->attach = attach; edev->transmit = transmit; edev->ifstat = ifstat; edev->promiscuous = promiscuous; edev->multicast = multicast; edev->shutdown = shutdown; return 0; } void etherrhinelink(void) { addethercard("rhine", pnp); }