#include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "io.h" #include "../port/netif.h" #include "../port/etherif.h" #include "../port/ethermii.h" enum { Rbsz = 2048, Maxtu = 1536, DmaOWN = 0x8000, DmaSOP = 0x2000, DmaEOP = 0x4000, DmaRxLg = 0x10, DmaRxNo = 0x08, DmaRxErr = 0x04, DmaRxCrc = 0x02, DmaRxOv = 0x01, DmaRxErrors = DmaRxLg|DmaRxNo|DmaRxErr|DmaRxCrc|DmaRxOv, DmaTxQtag = 0x1F80, DmaTxUnderrun = 0x0200, DmaTxAppendCrc = 0x0040, DmaTxOwCrc = 0x0020, DmaTxDoCsum = 0x0010, /* Ctlr->regs */ SysRevision = 0x00/4, SysPortCtrl = 0x04/4, PortModeIntEphy = 0, PortModeIntGphy = 1, PortModeExtEphy = 2, PortModeExtGphy = 3, PortModeExtRvmii50 = 4, PortModeExtRvmii25 = 16 | 4, LedActSourceMac = 1 << 9, SysRbufFlushCtrl = 0x08/4, SysTbufFlushCtrl = 0x0C/4, ExtRgmiiOobCtrl = 0x8C/4, RgmiiLink = 1 << 4, OobDisable = 1 << 5, RgmiiModeEn = 1 << 6, IdModeDis = 1 << 16, Intrl0 = 0x200/4, IrqScb = 1 << 0, IrqEphy = 1 << 1, IrqPhyDetR = 1 << 2, IrqPhyDetF = 1 << 3, IrqLinkUp = 1 << 4, IrqLinkDown = 1 << 5, IrqUmac = 1 << 6, IrqUmacTsv = 1 << 7, IrqTbufUnderrun = 1 << 8, IrqRbufOverflow = 1 << 9, IrqHfbSm = 1 << 10, IrqHfbMm = 1 << 11, IrqMpdR = 1 << 12, IrqRxDmaDone = 1 << 13, IrqRxDmaPDone = 1 << 14, IrqRxDmaBDone = 1 << 15, IrqTxDmaDone = 1 << 16, IrqTxDmaPDone = 1 << 17, IrqTxDmaBDone = 1 << 18, IrqMdioDone = 1 << 23, IrqMdioError = 1 << 24, Intrl1 = 0x240/4, /* Intrl0/1 + ... */ IntrSts = 0x00/4, IntrSet = 0x04/4, IntrClr = 0x08/4, IntrMaskSts = 0x0C/4, IntrMaskSet = 0x10/4, IntrMaskClr = 0x14/4, RbufCtrl = 0x300/4, Rbuf64En = 1 << 0, RbufAlign2B = 1 << 1, RbufBadDis = 1 << 2, RbufChkCtrl = 0x314/4, RbufChkRxChkEn = 1 << 0, RbufChkSkipFcs = 1 << 4, RbufOvflCnt = 0x394/4, RbufErrCnt = 0x398/4, RbufEnergyCtrl = 0x39c/4, RbufEeeEn = 1 << 0, RbufPmEn = 1 << 1, RbufTbufSizeCtrl= 0x3b4/4, TbufCtrl = 0x600/4, TbufBpMc = 0x60C/4, TbufEnergyCtrl = 0x614/4, UmacCmd = 0x808/4, CmdTxEn = 1 << 0, CmdRxEn = 1 << 1, CmdSpeed10 = 0 << 2, CmdSpeed100 = 1 << 2, CmdSpeed1000 = 2 << 2, CmdSpeedMask = 3 << 2, CmdProm = 1 << 4, CmdPadEn = 1 << 5, CmdCrcFwd = 1 << 6, CmdPauseFwd = 1 << 7, CmdRxPauseIgn = 1 << 8, CmdTxAddrIn = 1 << 9, CmdHdEn = 1 << 10, CmdSwReset = 1 << 13, CmdLclLoopEn = 1 << 15, CmdAutoConfig = 1 << 22, CmdCntlFrmEn = 1 << 23, CmdNoLenChk = 1 << 24, CmdRmtLoopEn = 1 << 25, CmdPrblEn = 1 << 27, CmdTxPauseIgn = 1 << 28, CmdTxRxEn = 1 << 29, CmdRuntFilterDis= 1 << 30, UmacMac0 = 0x80C/4, UmacMac1 = 0x810/4, UmacMaxFrameLen = 0x814/4, UmacEeeCtrl = 0x864/4, UmacEeeEn = 1<<3, UmacEeeLpiTimer = 0x868/4, UmacEeeWakeTimer= 0x86C/4, UmacEeeRefCount = 0x870/4, EeeRefCountMask = 0xFFFF, UmacTxFlush = 0xb34/4, UmacMibCtrl = 0xd80/4, MibResetRx = 1 << 0, MibResetRunt = 1 << 1, MibResetTx = 1 << 2, MdioCmd = 0xe14/4, MdioStartBusy = 1 << 29, MdioReadFail = 1 << 28, MdioRead = 2 << 26, MdioWrite = 1 << 26, MdioPhyShift = 21, MdioPhyMask = 0x1F, MdioAddrShift = 16, MdioAddrMask = 0x1F, UmacMpdCtrl = 0xe20/4, MpdEn = 1 << 0, MpdPwEn = 1 << 27, UmacMdfCtrl = 0xe50/4, UmacMdfAddr0 = 0xe54/4, RdmaOffset = 0x2000/4, TdmaOffset = 0x4000/4, HfbOffset = 0x8000/4, HfbCtlr = 0xFC00/4, HfbFltEnable = 0xFC04/4, HfbFltLen = 0xFC1C/4, /* common Ring->regs */ RdmaWP = 0x00/4, TdmaRP = 0x00/4, RxWP = 0x08/4, TxRP = 0x08/4, TxWP = 0x0C/4, RxRP = 0x0C/4, DmaRingBufSize = 0x10/4, DmaStart = 0x14/4, DmaEnd = 0x1C/4, DmaDoneThresh = 0x24/4, TdmaFlowPeriod = 0x28/4, RdmaXonXoffThresh=0x28/4, TdmaWP = 0x2C/4, RdmaRP = 0x2C/4, /* * reg offsets only for RING16 * ctlr->rx->regs / ctlr->tx->regs */ RingCfg = 0x40/4, RxRingCfgMask = 0x10000, TxRingCfgMask = 0x1000F, DmaCtrl = 0x44/4, DmaCtrlEn = 1 << 0, DmaStatus = 0x48/4, DmaStatusDis = 1 << 0, DmaScbBurstSize = 0x4C/4, TdmaArbCtrl = 0x6C/4, TdmaPriority0 = 0x70/4, TdmaPriority1 = 0x74/4, TdmaPriority2 = 0x78/4, RdmaTimeout0 = 0x6C/4, RdmaIndex2Ring0 = 0xB0/4, }; typedef struct Desc Desc; typedef struct Ring Ring; typedef struct Ctlr Ctlr; struct Desc { u32int *d; /* hw descriptor */ Block *b; }; struct Ring { Rendez; u32int *regs; u32int *intregs; u32int intmask; Desc *d; u32int m; u32int cp; u32int rp; u32int wp; int num; }; struct Ctlr { Lock; u32int *regs; Desc rd[256]; Desc td[256]; Ring rx[1+0]; Ring tx[1+0]; Rendez avail[1]; Rendez link[1]; struct { Mii; Rendez; } mii[1]; QLock; char attached; }; static Block *scratch; #define REG(x) (x) static void interrupt0(Ureg*, void *arg) { Ether *edev = arg; Ctlr *ctlr = edev->ctlr; u32int sts; sts = REG(ctlr->regs[Intrl0 + IntrSts]) & ~REG(ctlr->regs[Intrl0 + IntrMaskSts]); REG(ctlr->regs[Intrl0 + IntrClr]) = sts; REG(ctlr->regs[Intrl0 + IntrMaskSet]) = sts; if(sts & ctlr->rx->intmask) wakeup(ctlr->rx); if(sts & ctlr->tx->intmask) wakeup(ctlr->tx); if(sts & (IrqMdioDone|IrqMdioError)) wakeup(ctlr->mii); if(sts & (IrqLinkUp|IrqLinkDown)) wakeup(ctlr->link); } static void interrupt1(Ureg*, void *arg) { Ether *edev = arg; Ctlr *ctlr = edev->ctlr; u32int sts; int i; sts = REG(ctlr->regs[Intrl1 + IntrSts]) & ~REG(ctlr->regs[Intrl1 + IntrMaskSts]); REG(ctlr->regs[Intrl1 + IntrClr]) = sts; REG(ctlr->regs[Intrl1 + IntrMaskSet]) = sts; for(i = 1; i < nelem(ctlr->rx); i++) if(sts & ctlr->rx[i].intmask) wakeup(&ctlr->rx[i]); for(i = 1; i < nelem(ctlr->tx); i++) if(sts & ctlr->tx[i].intmask) wakeup(&ctlr->tx[i]); } static void setdma(Desc *d, void *v) { u64int pa = PADDR(v); REG(d->d[1]) = pa; REG(d->d[2]) = pa >> 32; } static void replenish(Desc *d) { d->b = allocb(Rbsz); dmaflush(1, d->b->rp, Rbsz); setdma(d, d->b->rp); } static int rxdone(void *arg) { Ring *r = arg; r->wp = REG(r->regs[RxWP]) & 0xFFFF; if(r->rp != r->wp) return 1; REG(r->intregs[IntrMaskClr]) = r->intmask; return 0; } static void recvproc(void *arg) { Ether *edev = arg; Ctlr *ctlr = edev->ctlr; Desc *d; Block *b; u32int s; while(waserror()) ; for(;;){ if(ctlr->rx->rp == ctlr->rx->wp){ sleep(ctlr->rx, rxdone, ctlr->rx); continue; } d = &ctlr->rx->d[ctlr->rx->rp & ctlr->rx->m]; b = d->b; dmaflush(0, b->rp, Rbsz); s = REG(d->d[0]); replenish(d); coherence(); ctlr->rx->rp = (ctlr->rx->rp + 1) & 0xFFFF; REG(ctlr->rx->regs[RxRP]) = ctlr->rx->rp; if((s & (DmaSOP|DmaEOP|DmaRxErrors)) != (DmaSOP|DmaEOP)){ freeb(b); continue; } b->wp += (s & 0x0FFF0000) >> 16; etheriq(edev, b); } } static int txavail(void *arg) { Ring *r = arg; return ((r->wp+1) & r->m) != (r->cp & r->m); } static void sendproc(void *arg) { Ether *edev = arg; Ctlr *ctlr = edev->ctlr; Desc *d; Block *b; while(waserror()) ; for(;;){ if(!txavail(ctlr->tx)){ sleep(ctlr->avail, txavail, ctlr->tx); continue; } if((b = qbread(edev->oq, 100000)) == nil) break; d = &ctlr->tx->d[ctlr->tx->wp & ctlr->tx->m]; assert(d->b == nil); d->b = b; dmaflush(1, b->rp, BLEN(b)); setdma(d, b->rp); REG(d->d[0]) = BLEN(b)<<16 | DmaTxQtag | DmaSOP | DmaEOP | DmaTxAppendCrc; coherence(); ctlr->tx->wp = (ctlr->tx->wp+1) & 0xFFFF; REG(ctlr->tx->regs[TxWP]) = ctlr->tx->wp; } } static int txdone(void *arg) { Ring *r = arg; if(r->cp != r->wp){ r->rp = REG(r->regs[TxRP]) & 0xFFFF; if(r->cp != r->rp) return 1; } REG(r->intregs[IntrMaskClr]) = r->intmask; return 0; } static void freeproc(void *arg) { Ether *edev = arg; Ctlr *ctlr = edev->ctlr; Desc *d; while(waserror()) ; for(;;){ if(ctlr->tx->cp == ctlr->tx->rp){ wakeup(ctlr->avail); sleep(ctlr->tx, txdone, ctlr->tx); continue; } d = &ctlr->tx->d[ctlr->tx->cp & ctlr->tx->m]; assert(d->b != nil); freeb(d->b); d->b = nil; coherence(); ctlr->tx->cp = (ctlr->tx->cp+1) & 0xFFFF; } } static void initring(Ring *ring, Desc *desc, int start, int size) { ring->d = &desc[start]; ring->m = size - 1; ring->cp = ring->rp = ring->wp = 0; REG(ring->regs[RxWP]) = 0; REG(ring->regs[RxRP]) = 0; REG(ring->regs[DmaStart]) = start*3; REG(ring->regs[DmaEnd]) = (start+size)*3 - 1; REG(ring->regs[RdmaWP]) = start*3; REG(ring->regs[RdmaRP]) = start*3; REG(ring->regs[DmaRingBufSize]) = (size << 16) | Rbsz; REG(ring->regs[DmaDoneThresh]) = 1; } static void introff(Ctlr *ctlr) { REG(ctlr->regs[Intrl0 + IntrMaskSet]) = -1; REG(ctlr->regs[Intrl0 + IntrClr]) = -1; REG(ctlr->regs[Intrl1 + IntrMaskSet]) = -1; REG(ctlr->regs[Intrl1 + IntrClr]) = -1; } static void dmaoff(Ctlr *ctlr) { REG(ctlr->rx->regs[DmaCtrl]) &= ~(RxRingCfgMask<<1 | DmaCtrlEn); REG(ctlr->tx->regs[DmaCtrl]) &= ~(TxRingCfgMask<<1 | DmaCtrlEn); REG(ctlr->regs[UmacTxFlush]) = 1; microdelay(10); REG(ctlr->regs[UmacTxFlush]) = 0; while((REG(ctlr->rx->regs[DmaStatus]) & DmaStatusDis) == 0) microdelay(10); while((REG(ctlr->tx->regs[DmaStatus]) & DmaStatusDis) == 0) microdelay(10); } static void dmaon(Ctlr *ctlr) { REG(ctlr->rx->regs[DmaCtrl]) |= DmaCtrlEn; REG(ctlr->tx->regs[DmaCtrl]) |= DmaCtrlEn; while(REG(ctlr->rx->regs[DmaStatus]) & DmaStatusDis) microdelay(10); while(REG(ctlr->tx->regs[DmaStatus]) & DmaStatusDis) microdelay(10); } static void allocbufs(Ctlr *ctlr) { int i; if(scratch == nil){ scratch = allocb(Rbsz); memset(scratch->rp, 0xFF, Rbsz); dmaflush(1, scratch->rp, Rbsz); } for(i = 0; i < nelem(ctlr->rd); i++){ ctlr->rd[i].d = &ctlr->regs[RdmaOffset + i*3]; replenish(&ctlr->rd[i]); } for(i = 0; i < nelem(ctlr->td); i++){ ctlr->td[i].d = &ctlr->regs[TdmaOffset + i*3]; setdma(&ctlr->td[i], scratch->rp); REG(ctlr->td[i].d[0]) = DmaTxUnderrun; } } static void freebufs(Ctlr *ctlr) { int i; for(i = 0; i < nelem(ctlr->rd); i++){ if(ctlr->rd[i].b != nil){ freeb(ctlr->rd[i].b); ctlr->rd[i].b = nil; } } for(i = 0; i < nelem(ctlr->td); i++){ if(ctlr->td[i].b != nil){ freeb(ctlr->td[i].b); ctlr->td[i].b = nil; } } } static void initrings(Ctlr *ctlr) { u32int rcfg, tcfg, dmapri[3]; int i; ctlr->rx->intregs = &ctlr->regs[Intrl0]; ctlr->rx->intmask = IrqRxDmaDone; ctlr->rx->num = 16; rcfg = 1<<16; for(i = 1; i < nelem(ctlr->rx); i++){ ctlr->rx[i].regs = &ctlr->regs[RdmaOffset + nelem(ctlr->rd)*3 + (i-1)*RingCfg]; ctlr->rx[i].intregs = &ctlr->regs[Intrl1]; ctlr->rx[i].intmask = 0x10000 << (i - 1); ctlr->rx[i].num = i - 1; rcfg |= 1<<(i-1); } assert(rcfg && (rcfg & ~RxRingCfgMask) == 0); ctlr->tx->intregs = &ctlr->regs[Intrl0]; ctlr->tx->intmask = IrqTxDmaDone; ctlr->tx->num = 16; tcfg = 1<<16; for(i = 1; i < nelem(ctlr->tx); i++){ ctlr->tx[i].regs = &ctlr->regs[TdmaOffset + nelem(ctlr->td)*3 + (i-1)*RingCfg]; ctlr->tx[i].intregs = &ctlr->regs[Intrl1]; ctlr->tx[i].intmask = 1 << (i - 1); ctlr->tx[i].num = i - 1; tcfg |= 1<<(i-1); } assert(tcfg && (tcfg & ~TxRingCfgMask) == 0); REG(ctlr->rx->regs[DmaScbBurstSize]) = 0x08; for(i = 1; i < nelem(ctlr->rx); i++) initring(&ctlr->rx[i], ctlr->rd, (i-1)*32, 32); initring(ctlr->rx, ctlr->rd, (i-1)*32, nelem(ctlr->rd) - (i-1)*32); for(i = 0; i < nelem(ctlr->rx); i++){ REG(ctlr->rx[i].regs[DmaDoneThresh]) = 1; REG(ctlr->rx[i].regs[RdmaXonXoffThresh]) = (5 << 16) | ((ctlr->rx[i].m+1) >> 4); // set dma timeout to 50µs REG(ctlr->rx->regs[RdmaTimeout0 + ctlr->rx[i].num]) = ((50*1000 + 8191)/8192); } REG(ctlr->tx->regs[DmaScbBurstSize]) = 0x08; for(i = 1; i < nelem(ctlr->tx); i++) initring(&ctlr->tx[i], ctlr->td, (i-1)*32, 32); initring(ctlr->tx, ctlr->td, (i-1)*32, nelem(ctlr->td) - (i-1)*32); dmapri[0] = dmapri[1] = dmapri[2] = 0; for(i = 0; i < nelem(ctlr->tx); i++){ REG(ctlr->tx[i].regs[DmaDoneThresh]) = 10; REG(ctlr->tx[i].regs[TdmaFlowPeriod]) = i ? 0 : Maxtu << 16; dmapri[ctlr->tx[i].num/6] |= i << ((ctlr->tx[i].num%6)*5); } REG(ctlr->tx->regs[TdmaArbCtrl]) = 2; REG(ctlr->tx->regs[TdmaPriority0]) = dmapri[0]; REG(ctlr->tx->regs[TdmaPriority1]) = dmapri[1]; REG(ctlr->tx->regs[TdmaPriority2]) = dmapri[2]; REG(ctlr->rx->regs[RingCfg]) = rcfg; REG(ctlr->tx->regs[RingCfg]) = tcfg; REG(ctlr->rx->regs[DmaCtrl]) |= rcfg<<1; REG(ctlr->tx->regs[DmaCtrl]) |= tcfg<<1; } static void umaccmd(Ctlr *ctlr, u32int set, u32int clr) { ilock(ctlr); REG(ctlr->regs[UmacCmd]) = (REG(ctlr->regs[UmacCmd]) & ~clr) | set; iunlock(ctlr); } static void reset(Ctlr *ctlr) { u32int r; // reset umac r = REG(ctlr->regs[SysRbufFlushCtrl]); REG(ctlr->regs[SysRbufFlushCtrl]) = r | 2; microdelay(10); REG(ctlr->regs[SysRbufFlushCtrl]) = r & ~2; microdelay(10); // umac reset REG(ctlr->regs[SysRbufFlushCtrl]) = 0; microdelay(10); REG(ctlr->regs[UmacCmd]) = 0; REG(ctlr->regs[UmacCmd]) = CmdSwReset | CmdLclLoopEn; microdelay(2); REG(ctlr->regs[UmacCmd]) = 0; } static void setmac(Ctlr *ctlr, uchar *ea) { REG(ctlr->regs[UmacMac0]) = ea[0]<<24 | ea[1]<<16 | ea[2]<<8 | ea[3]; REG(ctlr->regs[UmacMac1]) = ea[4]<<8 | ea[5]; } static void sethfb(Ctlr *ctlr) { int i; REG(ctlr->regs[HfbCtlr]) = 0; REG(ctlr->regs[HfbFltEnable]) = 0; REG(ctlr->regs[HfbFltEnable+1]) = 0; for(i = 0; i < 8; i++) REG(ctlr->rx->regs[RdmaIndex2Ring0+i]) = 0; for(i = 0; i < 48/4; i++) REG(ctlr->regs[HfbFltLen + i]) = 0; for(i = 0; i < 48*128; i++) REG(ctlr->regs[HfbOffset + i]) = 0; } static int mdiodone(void *arg) { Ctlr *ctlr = arg; REG(ctlr->regs[Intrl0 + IntrMaskClr]) = (IrqMdioDone|IrqMdioError); return (REG(ctlr->regs[MdioCmd]) & MdioStartBusy) == 0; } static int mdiowait(Ctlr *ctlr) { REG(ctlr->regs[MdioCmd]) |= MdioStartBusy; while(REG(ctlr->regs[MdioCmd]) & MdioStartBusy) tsleep(ctlr->mii, mdiodone, ctlr, 10); return 0; } static int mdiow(Mii* mii, int phy, int addr, int data) { Ctlr *ctlr = mii->ctlr; if(phy > MdioPhyMask) return -1; addr &= MdioAddrMask; REG(ctlr->regs[MdioCmd]) = MdioWrite | (phy << MdioPhyShift) | (addr << MdioAddrShift) | (data & 0xFFFF); return mdiowait(ctlr); } static int mdior(Mii* mii, int phy, int addr) { Ctlr *ctlr = mii->ctlr; if(phy > MdioPhyMask) return -1; addr &= MdioAddrMask; REG(ctlr->regs[MdioCmd]) = MdioRead | (phy << MdioPhyShift) | (addr << MdioAddrShift); if(mdiowait(ctlr) < 0) return -1; if(REG(ctlr->regs[MdioCmd]) & MdioReadFail) return -1; return REG(ctlr->regs[MdioCmd]) & 0xFFFF; } static int bcmshdr(Mii *mii, int reg) { miimiw(mii, 0x1C, (reg & 0x1F) << 10); return miimir(mii, 0x1C) & 0x3FF; } static int bcmshdw(Mii *mii, int reg, int dat) { return miimiw(mii, 0x1C, 0x8000 | (reg & 0x1F) << 10 | (dat & 0x3FF)); } static int linkevent(void *arg) { Ctlr *ctlr = arg; REG(ctlr->regs[Intrl0 + IntrMaskClr]) = IrqLinkUp|IrqLinkDown; return 0; } static void linkproc(void *arg) { Ether *edev = arg; Ctlr *ctlr = edev->ctlr; MiiPhy *phy; int link = -1; while(waserror()) ; for(;;){ tsleep(ctlr->link, linkevent, ctlr, 1000); miistatus(ctlr->mii); phy = ctlr->mii->curphy; if(phy == nil || phy->link == link) continue; link = phy->link; if(link){ u32int cmd = CmdRxEn|CmdTxEn; switch(phy->speed){ case 1000: cmd |= CmdSpeed1000; break; case 100: cmd |= CmdSpeed100; break; case 10: cmd |= CmdSpeed10; break; } if(!phy->fd) cmd |= CmdHdEn; if(!phy->rfc) cmd |= CmdRxPauseIgn; if(!phy->tfc) cmd |= CmdTxPauseIgn; REG(ctlr->regs[ExtRgmiiOobCtrl]) = (REG(ctlr->regs[ExtRgmiiOobCtrl]) & ~OobDisable) | RgmiiLink; umaccmd(ctlr, cmd, CmdSpeedMask|CmdHdEn|CmdRxPauseIgn|CmdTxPauseIgn); edev->mbps = phy->speed; } edev->link = link; // print("#l%d: link %d speed %d\n", edev->ctlrno, edev->link, edev->mbps); } } static void setmdfaddr(Ctlr *ctlr, int i, uchar *ea) { REG(ctlr->regs[UmacMdfAddr0 + i*2 + 0]) = ea[0] << 8 | ea[1]; REG(ctlr->regs[UmacMdfAddr0 + i*2 + 1]) = ea[2] << 24 | ea[3] << 16 | ea[4] << 8 | ea[5]; } static void rxmode(Ether *edev, int prom) { Ctlr *ctlr = edev->ctlr; Netaddr *na; int i; if(prom || edev->nmaddr > 16-2){ REG(ctlr->regs[UmacMdfCtrl]) = 0; umaccmd(ctlr, CmdProm, 0); return; } setmdfaddr(ctlr, 0, edev->bcast); setmdfaddr(ctlr, 1, edev->ea); for(i = 2, na = edev->maddr; na != nil; na = na->next, i++) setmdfaddr(ctlr, i, na->addr); REG(ctlr->regs[UmacMdfCtrl]) = (-0x10000 >> i) & 0x1FFFF; umaccmd(ctlr, 0, CmdProm); } static void shutdown(Ether *edev) { Ctlr *ctlr = edev->ctlr; dmaoff(ctlr); introff(ctlr); } static void attach(Ether *edev) { Ctlr *ctlr = edev->ctlr; eqlock(ctlr); if(ctlr->attached){ qunlock(ctlr); return; } if(waserror()){ print("#l%d: %s\n", edev->ctlrno, up->errstr); shutdown(edev); freebufs(ctlr); qunlock(ctlr); nexterror(); } // statistics REG(ctlr->regs[UmacMibCtrl]) = MibResetRx | MibResetTx | MibResetRunt; REG(ctlr->regs[UmacMibCtrl]) = 0; // wol REG(ctlr->regs[UmacMpdCtrl]) &= ~(MpdPwEn|MpdEn); // power REG(ctlr->regs[UmacEeeCtrl]) &= ~UmacEeeEn; REG(ctlr->regs[RbufEnergyCtrl]) &= ~(RbufEeeEn|RbufPmEn); REG(ctlr->regs[TbufEnergyCtrl]) &= ~(RbufEeeEn|RbufPmEn); REG(ctlr->regs[TbufBpMc]) = 0; REG(ctlr->regs[UmacMaxFrameLen]) = Maxtu; REG(ctlr->regs[RbufTbufSizeCtrl]) = 1; REG(ctlr->regs[TbufCtrl]) &= ~(Rbuf64En); REG(ctlr->regs[RbufCtrl]) &= ~(Rbuf64En|RbufAlign2B); REG(ctlr->regs[RbufChkCtrl]) &= ~(RbufChkRxChkEn|RbufChkSkipFcs); allocbufs(ctlr); initrings(ctlr); dmaon(ctlr); setmac(ctlr, edev->ea); sethfb(ctlr); rxmode(edev, 0); REG(ctlr->regs[SysPortCtrl]) = PortModeExtGphy; REG(ctlr->regs[ExtRgmiiOobCtrl]) |= RgmiiModeEn | IdModeDis; ctlr->mii->ctlr = ctlr; ctlr->mii->mir = mdior; ctlr->mii->miw = mdiow; mii(ctlr->mii, ~0); if(ctlr->mii->curphy == nil) error("no phy"); print("#l%d: phy%d id %.8ux oui %x\n", edev->ctlrno, ctlr->mii->curphy->phyno, ctlr->mii->curphy->id, ctlr->mii->curphy->oui); miireset(ctlr->mii); switch(ctlr->mii->curphy->id){ case 0x600d84a2: /* BCM54312PE */ /* mask interrupts */ miimiw(ctlr->mii, 0x10, miimir(ctlr->mii, 0x10) | 0x1000); /* SCR3: clear DLLAPD_DIS */ bcmshdw(ctlr->mii, 0x05, bcmshdr(ctlr->mii, 0x05) &~0x0002); /* APD: set APD_EN */ bcmshdw(ctlr->mii, 0x0a, bcmshdr(ctlr->mii, 0x0a) | 0x0020); /* blinkenlights */ bcmshdw(ctlr->mii, 0x09, bcmshdr(ctlr->mii, 0x09) | 0x0010); bcmshdw(ctlr->mii, 0x0d, 3<<0 | 0<<4); break; } /* don't advertise EEE */ miimmdw(ctlr->mii, 7, 60, 0); miiane(ctlr->mii, ~0, AnaAP|AnaP, ~0); ctlr->attached = 1; kproc("genet-recv", recvproc, edev); kproc("genet-send", sendproc, edev); kproc("genet-free", freeproc, edev); kproc("genet-link", linkproc, edev); qunlock(ctlr); poperror(); } static void prom(void *arg, int on) { Ether *edev = arg; rxmode(edev, on); } static void multi(void *arg, uchar*, int) { Ether *edev = arg; rxmode(edev, edev->prom > 0); } static int pnp(Ether *edev) { static Ctlr ctlr[1]; if(ctlr->regs != nil) return -1; ctlr->regs = (u32int*)(VIRTIO1 + 0x580000); ctlr->rx->regs = &ctlr->regs[RdmaOffset + nelem(ctlr->rd)*3 + 16*RingCfg]; ctlr->tx->regs = &ctlr->regs[TdmaOffset + nelem(ctlr->td)*3 + 16*RingCfg]; edev->port = (uintptr)ctlr->regs; edev->irq = IRQether; edev->ctlr = ctlr; edev->attach = attach; edev->shutdown = shutdown; edev->promiscuous = prom; edev->multicast = multi; edev->arg = edev; edev->mbps = 1000; edev->maxmtu = Maxtu; parseether(edev->ea, getethermac()); reset(ctlr); dmaoff(ctlr); introff(ctlr); intrenable(edev->irq+0, interrupt0, edev, BUSUNKNOWN, edev->name); intrenable(edev->irq+1, interrupt1, edev, BUSUNKNOWN, edev->name); return 0; } void ethergenetlink(void) { addethercard("genet", pnp); }