/* * Intel 8254[340]NN Gigabit Ethernet PCI Controllers * as found on the Intel PRO/1000 series of adapters: * 82543GC Intel PRO/1000 T * 82544EI Intel PRO/1000 XT * 82540EM Intel PRO/1000 MT * 82541[GP]I * 82547GI * 82546GB * 82546EB * To Do: * finish autonegotiation code; * integrate fiber stuff back in (this ONLY handles * the CAT5 cards at the moment); * add checksum-offload; * add tuning control via ctl file; * this driver is little-endian specific. */ #include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "../port/error.h" #include "../port/ethermii.h" #include "../port/netif.h" #include "etherif.h" #include "io.h" enum { i82542 = (0x1000<<16)|0x8086, i82543gc = (0x1004<<16)|0x8086, i82544ei = (0x1008<<16)|0x8086, i82544eif = (0x1009<<16)|0x8086, i82544gc = (0x100d<<16)|0x8086, i82540em = (0x100E<<16)|0x8086, i82540eplp = (0x101E<<16)|0x8086, i82545em = (0x100F<<16)|0x8086, i82545gmc = (0x1026<<16)|0x8086, i82547ei = (0x1019<<16)|0x8086, i82547gi = (0x1075<<16)|0x8086, i82541ei = (0x1013<<16)|0x8086, i82541gi = (0x1076<<16)|0x8086, i82541gi2 = (0x1077<<16)|0x8086, i82541pi = (0x107c<<16)|0x8086, i82546gb = (0x1079<<16)|0x8086, i82546eb = (0x1010<<16)|0x8086, }; enum { Ctrl = 0x00000000, /* Device Control */ Ctrldup = 0x00000004, /* Device Control Duplicate */ Status = 0x00000008, /* Device Status */ Eecd = 0x00000010, /* EEPROM/Flash Control/Data */ Ctrlext = 0x00000018, /* Extended Device Control */ Mdic = 0x00000020, /* MDI Control */ Fcal = 0x00000028, /* Flow Control Address Low */ Fcah = 0x0000002C, /* Flow Control Address High */ Fct = 0x00000030, /* Flow Control Type */ Icr = 0x000000C0, /* Interrupt Cause Read */ Ics = 0x000000C8, /* Interrupt Cause Set */ Ims = 0x000000D0, /* Interrupt Mask Set/Read */ Imc = 0x000000D8, /* Interrupt mask Clear */ Rctl = 0x00000100, /* Receive Control */ Fcttv = 0x00000170, /* Flow Control Transmit Timer Value */ Txcw = 0x00000178, /* Transmit Configuration Word */ Rxcw = 0x00000180, /* Receive Configuration Word */ /* on the oldest cards (8254[23]), the Mta register is at 0x200 */ Tctl = 0x00000400, /* Transmit Control */ Tipg = 0x00000410, /* Transmit IPG */ Tbt = 0x00000448, /* Transmit Burst Timer */ Ait = 0x00000458, /* Adaptive IFS Throttle */ Fcrtl = 0x00002160, /* Flow Control RX Threshold Low */ Fcrth = 0x00002168, /* Flow Control Rx Threshold High */ Rdfh = 0x00002410, /* Receive data fifo head */ Rdft = 0x00002418, /* Receive data fifo tail */ Rdfhs = 0x00002420, /* Receive data fifo head saved */ Rdfts = 0x00002428, /* Receive data fifo tail saved */ Rdfpc = 0x00002430, /* Receive data fifo packet count */ Rdbal = 0x00002800, /* Rd Base Address Low */ Rdbah = 0x00002804, /* Rd Base Address High */ Rdlen = 0x00002808, /* Receive Descriptor Length */ Rdh = 0x00002810, /* Receive Descriptor Head */ Rdt = 0x00002818, /* Receive Descriptor Tail */ Rdtr = 0x00002820, /* Receive Descriptor Timer Ring */ Rxdctl = 0x00002828, /* Receive Descriptor Control */ Radv = 0x0000282C, /* Receive Interrupt Absolute Delay Timer */ Txdmac = 0x00003000, /* Transfer DMA Control */ Ett = 0x00003008, /* Early Transmit Control */ Tdfh = 0x00003410, /* Transmit data fifo head */ Tdft = 0x00003418, /* Transmit data fifo tail */ Tdfhs = 0x00003420, /* Transmit data Fifo Head saved */ Tdfts = 0x00003428, /* Transmit data fifo tail saved */ Tdfpc = 0x00003430, /* Trasnmit data Fifo packet count */ Tdbal = 0x00003800, /* Td Base Address Low */ Tdbah = 0x00003804, /* Td Base Address High */ Tdlen = 0x00003808, /* Transmit Descriptor Length */ Tdh = 0x00003810, /* Transmit Descriptor Head */ Tdt = 0x00003818, /* Transmit Descriptor Tail */ Tidv = 0x00003820, /* Transmit Interrupt Delay Value */ Txdctl = 0x00003828, /* Transmit Descriptor Control */ Tadv = 0x0000382C, /* Transmit Interrupt Absolute Delay Timer */ Statistics = 0x00004000, /* Start of Statistics Area */ Gorcl = 0x88/4, /* Good Octets Received Count */ Gotcl = 0x90/4, /* Good Octets Transmitted Count */ Torl = 0xC0/4, /* Total Octets Received */ Totl = 0xC8/4, /* Total Octets Transmitted */ Nstatistics = 64, Rxcsum = 0x00005000, /* Receive Checksum Control */ Mta = 0x00005200, /* Multicast Table Array */ Ral = 0x00005400, /* Receive Address Low */ Rah = 0x00005404, /* Receive Address High */ Manc = 0x00005820, /* Management Control */ }; enum { /* Ctrl */ Bem = 0x00000002, /* Big Endian Mode */ Prior = 0x00000004, /* Priority on the PCI bus */ Lrst = 0x00000008, /* Link Reset */ Asde = 0x00000020, /* Auto-Speed Detection Enable */ Slu = 0x00000040, /* Set Link Up */ Ilos = 0x00000080, /* Invert Loss of Signal (LOS) */ SspeedMASK = 0x00000300, /* Speed Selection */ SspeedSHIFT = 8, Sspeed10 = 0x00000000, /* 10Mb/s */ Sspeed100 = 0x00000100, /* 100Mb/s */ Sspeed1000 = 0x00000200, /* 1000Mb/s */ Frcspd = 0x00000800, /* Force Speed */ Frcdplx = 0x00001000, /* Force Duplex */ SwdpinsloMASK = 0x003C0000, /* Software Defined Pins - lo nibble */ SwdpinsloSHIFT = 18, SwdpioloMASK = 0x03C00000, /* Software Defined Pins - I or O */ SwdpioloSHIFT = 22, Devrst = 0x04000000, /* Device Reset */ Rfce = 0x08000000, /* Receive Flow Control Enable */ Tfce = 0x10000000, /* Transmit Flow Control Enable */ Vme = 0x40000000, /* VLAN Mode Enable */ }; enum { /* Status */ Lu = 0x00000002, /* Link Up */ Lanid = 0x0000000C, /* mask for Lan ID. (function id) */ Txoff = 0x00000010, /* Transmission Paused */ Tbimode = 0x00000020, /* TBI Mode Indication */ LspeedMASK = 0x000000C0, /* Link Speed Setting */ LspeedSHIFT = 6, Lspeed10 = 0x00000000, /* 10Mb/s */ Lspeed100 = 0x00000040, /* 100Mb/s */ Lspeed1000 = 0x00000080, /* 1000Mb/s */ Mtxckok = 0x00000400, /* MTX clock is running */ Pci66 = 0x00000800, /* PCI Bus speed indication */ Bus64 = 0x00001000, /* PCI Bus width indication */ Pcixmode = 0x00002000, /* PCI-X mode */ PcixspeedMASK = 0x0000C000, /* PCI-X bus speed */ PcixspeedSHIFT = 14, Pcix66 = 0x00000000, /* 50-66MHz */ Pcix100 = 0x00004000, /* 66-100MHz */ Pcix133 = 0x00008000, /* 100-133MHz */ }; enum { /* Ctrl and Status */ Fd = 0x00000001, /* Full-Duplex */ AsdvMASK = 0x00000300, AsdvSHIFT = 8, Asdv10 = 0x00000000, /* 10Mb/s */ Asdv100 = 0x00000100, /* 100Mb/s */ Asdv1000 = 0x00000200, /* 1000Mb/s */ }; enum { /* Eecd */ Sk = 0x00000001, /* Clock input to the EEPROM */ Cs = 0x00000002, /* Chip Select */ Di = 0x00000004, /* Data Input to the EEPROM */ Do = 0x00000008, /* Data Output from the EEPROM */ Areq = 0x00000040, /* EEPROM Access Request */ Agnt = 0x00000080, /* EEPROM Access Grant */ Eepresent = 0x00000100, /* EEPROM Present */ Eesz256 = 0x00000200, /* EEPROM is 256 words not 64 */ Eeszaddr = 0x00000400, /* EEPROM size for 8254[17] */ Spi = 0x00002000, /* EEPROM is SPI not Microwire */ }; enum { /* Ctrlext */ Gpien = 0x0000000F, /* General Purpose Interrupt Enables */ SwdpinshiMASK = 0x000000F0, /* Software Defined Pins - hi nibble */ SwdpinshiSHIFT = 4, SwdpiohiMASK = 0x00000F00, /* Software Defined Pins - I or O */ SwdpiohiSHIFT = 8, Asdchk = 0x00001000, /* ASD Check */ Eerst = 0x00002000, /* EEPROM Reset */ Ips = 0x00004000, /* Invert Power State */ Spdbyps = 0x00008000, /* Speed Select Bypass */ }; enum { /* EEPROM content offsets */ Ea = 0x00, /* Ethernet Address */ Cf = 0x03, /* Compatibility Field */ Pba = 0x08, /* Printed Board Assembly number */ Icw1 = 0x0A, /* Initialization Control Word 1 */ Sid = 0x0B, /* Subsystem ID */ Svid = 0x0C, /* Subsystem Vendor ID */ Did = 0x0D, /* Device ID */ Vid = 0x0E, /* Vendor ID */ Icw2 = 0x0F, /* Initialization Control Word 2 */ }; enum { /* Mdic */ MDIdMASK = 0x0000FFFF, /* Data */ MDIdSHIFT = 0, MDIrMASK = 0x001F0000, /* PHY Register Address */ MDIrSHIFT = 16, MDIpMASK = 0x03E00000, /* PHY Address */ MDIpSHIFT = 21, MDIwop = 0x04000000, /* Write Operation */ MDIrop = 0x08000000, /* Read Operation */ MDIready = 0x10000000, /* End of Transaction */ MDIie = 0x20000000, /* Interrupt Enable */ MDIe = 0x40000000, /* Error */ }; enum { /* Icr, Ics, Ims, Imc */ Txdw = 0x00000001, /* Transmit Descriptor Written Back */ Txqe = 0x00000002, /* Transmit Queue Empty */ Lsc = 0x00000004, /* Link Status Change */ Rxseq = 0x00000008, /* Receive Sequence Error */ Rxdmt0 = 0x00000010, /* Rd Minimum Threshold Reached */ Rxo = 0x00000040, /* Receiver Overrun */ Rxt0 = 0x00000080, /* Receiver Timer Interrupt */ Mdac = 0x00000200, /* MDIO Access Completed */ Rxcfg = 0x00000400, /* Receiving /C/ ordered sets */ Gpi0 = 0x00000800, /* General Purpose Interrupts */ Gpi1 = 0x00001000, Gpi2 = 0x00002000, Gpi3 = 0x00004000, }; /* * The Mdic register isn't implemented on the 82543GC, * the software defined pins are used instead. * These definitions work for the Intel PRO/1000 T Server Adapter. * The direction pin bits are read from the EEPROM. */ enum { Mdd = ((1<<2)<nic+((r)/4))) #define csr32w(c, r, v) (*((c)->nic+((r)/4)) = (v)) static Ctlr* igbectlrhead; static Ctlr* igbectlrtail; static Lock igberblock; /* free receive Blocks */ static Block* igberbpool; /* receive Blocks for all igbe controllers */ static char* statistics[Nstatistics] = { "CRC Error", "Alignment Error", "Symbol Error", "RX Error", "Missed Packets", "Single Collision", "Excessive Collisions", "Multiple Collision", "Late Collisions", nil, "Collision", "Transmit Underrun", "Defer", "Transmit - No CRS", "Sequence Error", "Carrier Extension Error", "Receive Error Length", nil, "XON Received", "XON Transmitted", "XOFF Received", "XOFF Transmitted", "FC Received Unsupported", "Packets Received (64 Bytes)", "Packets Received (65-127 Bytes)", "Packets Received (128-255 Bytes)", "Packets Received (256-511 Bytes)", "Packets Received (512-1023 Bytes)", "Packets Received (1024-1522 Bytes)", "Good Packets Received", "Broadcast Packets Received", "Multicast Packets Received", "Good Packets Transmitted", nil, "Good Octets Received", nil, "Good Octets Transmitted", nil, nil, nil, "Receive No Buffers", "Receive Undersize", "Receive Fragment", "Receive Oversize", "Receive Jabber", nil, nil, nil, "Total Octets Received", nil, "Total Octets Transmitted", nil, "Total Packets Received", "Total Packets Transmitted", "Packets Transmitted (64 Bytes)", "Packets Transmitted (65-127 Bytes)", "Packets Transmitted (128-255 Bytes)", "Packets Transmitted (256-511 Bytes)", "Packets Transmitted (512-1023 Bytes)", "Packets Transmitted (1024-1522 Bytes)", "Multicast Packets Transmitted", "Broadcast Packets Transmitted", "TCP Segmentation Context Transmitted", "TCP Segmentation Context Fail", }; static long igbeifstat(Ether* edev, void* a, long n, usize offset) { Ctlr *ctlr; char *p0, *p, *e, *s; int i, r; uvlong tuvl, ruvl; ctlr = edev->ctlr; p0 = p = malloc(READSTR); if(p == nil) error(Enomem); e = p + READSTR; qlock(&ctlr->slock); for(i = 0; i < Nstatistics; i++){ r = csr32r(ctlr, Statistics+i*4); if((s = statistics[i]) == nil) continue; switch(i){ case Gorcl: case Gotcl: case Torl: case Totl: ruvl = r; ruvl += ((uvlong)csr32r(ctlr, Statistics+(i+1)*4))<<32; tuvl = ruvl; tuvl += ctlr->statistics[i]; tuvl += ((uvlong)ctlr->statistics[i+1])<<32; if(tuvl == 0) continue; ctlr->statistics[i] = tuvl; ctlr->statistics[i+1] = tuvl>>32; p = seprint(p, e, "%s: %llud %llud\n", s, tuvl, ruvl); i++; break; default: ctlr->statistics[i] += r; if(ctlr->statistics[i] == 0) continue; p = seprint(p, e, "%s: %ud %ud\n", s, ctlr->statistics[i], r); break; } } p = seprint(p, e, "lintr: %ud %ud\n", ctlr->lintr, ctlr->lsleep); p = seprint(p, e, "rintr: %ud %ud\n", ctlr->rintr, ctlr->rsleep); p = seprint(p, e, "tintr: %ud %ud\n", ctlr->tintr, ctlr->txdw); p = seprint(p, e, "ixcs: %ud %ud %ud\n", ctlr->ixsm, ctlr->ipcs, ctlr->tcpcs); p = seprint(p, e, "rdtr: %ud\n", ctlr->rdtr); p = seprint(p, e, "ctrlext: %.8ux\n", csr32r(ctlr, Ctrlext)); p = seprint(p, e, "pba: %#ux\n", ctlr->pba); // p = seprint(p, e, "eeprom:"); // for(i = 0; i < 0x40; i++){ // if(i && ((i & 0x07) == 0)) // p = seprint(p, e, "\n "); // p = seprint(p, e, " %.4ux", ctlr->eeprom[i]); // } // p = seprint(p, e, "\n"); miidumpphy(ctlr->mii, p, e); qunlock(&ctlr->slock); n = readstr(offset, a, n, p0); free(p0); return n; } enum { CMrdtr, }; static Cmdtab igbectlmsg[] = { CMrdtr, "rdtr", 2, }; static long igbectl(Ether* edev, void* buf, long n) { int v; char *p; Ctlr *ctlr; Cmdbuf *cb; Cmdtab *ct; if((ctlr = edev->ctlr) == nil) error(Enonexist); cb = parsecmd(buf, n); if(waserror()){ free(cb); nexterror(); } ct = lookupcmd(cb, igbectlmsg, nelem(igbectlmsg)); switch(ct->index){ case CMrdtr: v = strtol(cb->f[1], &p, 0); if(v < 0 || p == cb->f[1] || v > 0xFFFF) error(Ebadarg); ctlr->rdtr = v; csr32w(ctlr, Rdtr, Fpd|v); break; } free(cb); poperror(); return n; } static void igbepromiscuous(void* arg, int on) { u32int rctl; Ctlr *ctlr; Ether *edev; edev = arg; ctlr = edev->ctlr; rctl = csr32r(ctlr, Rctl); rctl &= ~MoMASK; rctl |= Mo47b36; if(on) rctl |= Upe|Mpe; else rctl &= ~(Upe|Mpe); csr32w(ctlr, Rctl, rctl); } static void igbemulticast(void* arg, uchar* addr, int add) { u32int bit, x; Ctlr *ctlr; Ether *edev; edev = arg; ctlr = edev->ctlr; x = addr[5]>>1; bit = ((addr[5] & 1)<<4)|(addr[4]>>4); /* * multiple ether addresses can hash to the same filter bit, * so it's never safe to clear a filter bit. * if we want to clear filter bits, we need to keep track of * all the multicast addresses in use, clear all the filter bits, * then set the ones corresponding to in-use addresses. */ if(add) ctlr->mta[x] |= 1<mta[x] &= ~(1<mta[x]); } static Block* igberballoc(void) { Block *bp; ilock(&igberblock); if((bp = igberbpool) != nil){ igberbpool = bp->next; bp->next = nil; } iunlock(&igberblock); return bp; } static void igberbfree(Block* b) { b->rp = b->wp = (uchar*)ROUNDUP((uintptr)b->base, PGSZ); b->flag &= ~(Bipck | Budpck | Btcpck | Bpktck); ilock(&igberblock); b->next = igberbpool; igberbpool = b; iunlock(&igberblock); } static void igbeim(Ctlr* ctlr, int im) { ilock(&ctlr->imlock); ctlr->im |= im; csr32w(ctlr, Ims, ctlr->im); iunlock(&ctlr->imlock); } static int igbelim(void* ctlr) { return ((Ctlr*)ctlr)->lim != 0; } static void igbelproc(void* arg) { Ctlr *ctlr; Ether *edev; MiiPhy *phy; u32int ctrl, r; edev = arg; ctlr = edev->ctlr; for(;;){ if(ctlr->mii == nil || ctlr->mii->curphy == nil) { sched(); continue; } /* * To do: * logic to manage status change, * this is incomplete but should work * one time to set up the hardware. * * MiiPhy.speed, etc. should be in Mii. */ if(miistatus(ctlr->mii) < 0){ edev->link = 0; goto enable; } edev->link = 1; phy = ctlr->mii->curphy; ctrl = csr32r(ctlr, Ctrl); switch(ctlr->id){ case i82543gc: case i82544ei: case i82544eif: default: if(!(ctrl & Asde)){ ctrl &= ~(SspeedMASK|Ilos|Fd); ctrl |= Frcdplx|Frcspd; if(phy->speed == 1000) ctrl |= Sspeed1000; else if(phy->speed == 100) ctrl |= Sspeed100; if(phy->fd) ctrl |= Fd; } break; case i82540em: case i82540eplp: case i82547gi: case i82541gi: case i82541gi2: case i82541pi: break; } /* * Collision Distance. */ r = csr32r(ctlr, Tctl); r &= ~ColdMASK; if(phy->fd) r |= 64<rfc) ctrl |= Rfce; if(phy->tfc) ctrl |= Tfce; csr32w(ctlr, Ctrl, ctrl); enable: ctlr->lim = 0; igbeim(ctlr, Lsc); ctlr->lsleep++; sleep(&ctlr->lrendez, igbelim, ctlr); } } static void igbetxinit(Ctlr* ctlr) { int i, r; Block *bp; csr32w(ctlr, Tctl, (0x0F<id){ default: r = 6; break; case i82543gc: case i82544ei: case i82544eif: case i82544gc: case i82540em: case i82540eplp: case i82541ei: case i82541gi: case i82541gi2: case i82541pi: case i82545em: case i82545gmc: case i82546gb: case i82546eb: case i82547ei: case i82547gi: r = 8; break; } csr32w(ctlr, Tipg, (6<<20)|(8<<10)|r); csr32w(ctlr, Ait, 0); csr32w(ctlr, Txdmac, 0); csr32w(ctlr, Tdbal, Pciwaddrl(ctlr->tdba)); csr32w(ctlr, Tdbah, Pciwaddrh(ctlr->tdba)); csr32w(ctlr, Tdlen, ctlr->ntd*sizeof(Td)); ctlr->tdh = PREV(0, ctlr->ntd); csr32w(ctlr, Tdh, 0); ctlr->tdt = 0; csr32w(ctlr, Tdt, 0); for(i = 0; i < ctlr->ntd; i++){ if((bp = ctlr->tb[i]) != nil){ ctlr->tb[i] = nil; freeb(bp); } memset(&ctlr->tdba[i], 0, sizeof(Td)); } ctlr->tdfree = ctlr->ntd; csr32w(ctlr, Tidv, 128); r = (4<id){ default: break; case i82540em: case i82540eplp: case i82547gi: case i82545em: case i82545gmc: case i82546gb: case i82546eb: case i82541gi: case i82541gi2: case i82541pi: r = csr32r(ctlr, Txdctl); r &= ~WthreshMASK; r |= Gran|(4<tdh; m = c->ntd-1; while(c->tdba[n = Next(tdh, m)].status&Tdd){ tdh = n; if((b = c->tb[tdh]) != nil){ c->tb[tdh] = nil; freeb(b); } c->tdba[tdh].status = 0; c->cleaned++; } return c->tdh = tdh; } static void igbetransmit(Ether* edev) { Td *td; Block *b; Ctlr *c; int tdh, tdt, m; c = edev->ctlr; qlock(&c->tlock); tdh = igbecleanup(c); /* * Try to fill the ring back up. */ tdt = c->tdt; m = c->ntd-1; if(Next(tdt, m) != tdh) for(;;){ if((b = qget(edev->oq)) == nil) break; td = &c->tdba[tdt]; td->addr[0] = Pciwaddrl(b->rp); td->addr[1] = Pciwaddrh(b->rp); td->control = Ifcs|Teop|DtypeDD|Rs|BLEN(b); c->tb[tdt] = b; c->sent++; tdt = Next(tdt, m); if(Next(tdt, m) == tdh){ c->txdw++; c->tdt = tdt; coherence(); csr32w(c, Tdt, tdt); igbeim(c, Txdw); break; } c->tdt = tdt; coherence(); csr32w(c, Tdt, tdt); } qunlock(&c->tlock); } static void igbereplenish(Ctlr* ctlr) { Rd *rd; int rdt, m; Block *bp; rdt = ctlr->rdt; m = ctlr->nrd-1; while(Next(rdt, m) != ctlr->rdh){ rd = &ctlr->rdba[rdt]; if(ctlr->rb[rdt] == nil){ bp = igberballoc(); if(bp == nil){ iprint("#l%d: igbereplenish: no available buffers\n", ctlr->edev->ctlrno); break; } ctlr->rb[rdt] = bp; rd->addr[0] = Pciwaddrl(bp->rp); rd->addr[1] = Pciwaddrh(bp->rp); } rd->status = 0; rdt = Next(rdt, m); ctlr->rdfree++; } ctlr->rdt = rdt; coherence(); csr32w(ctlr, Rdt, rdt); } static void igberxinit(Ctlr* ctlr) { int i; Block *bp; csr32w(ctlr, Rctl, Dpf|Rbsize|Bam|RdtmsHALF); csr32w(ctlr, Rdbal, Pciwaddrl(ctlr->rdba)); csr32w(ctlr, Rdbah, Pciwaddrh(ctlr->rdba)); csr32w(ctlr, Rdlen, ctlr->nrd*sizeof(Rd)); ctlr->rdh = 0; csr32w(ctlr, Rdh, 0); ctlr->rdt = 0; csr32w(ctlr, Rdt, 0); ctlr->rdtr = 0; csr32w(ctlr, Rdtr, Fpd|0); for(i = 0; i < ctlr->nrd; i++){ if((bp = ctlr->rb[i]) != nil){ ctlr->rb[i] = nil; freeb(bp); } } igbereplenish(ctlr); switch(ctlr->id){ case i82540em: case i82540eplp: case i82541gi: case i82541gi2: case i82541pi: case i82545em: case i82545gmc: case i82546gb: case i82546eb: case i82547gi: csr32w(ctlr, Radv, 64); break; } csr32w(ctlr, Rxdctl, (8<rim != 0; } static void igberproc(void* arg) { Rd *rd; Block *bp; Ctlr *ctlr; int rdh; Ether *edev; edev = arg; ctlr = edev->ctlr; igberxinit(ctlr); csr32w(ctlr, Rctl, csr32r(ctlr, Rctl) | Ren); for(;;){ ctlr->rim = 0; igbeim(ctlr, Rxt0|Rxo|Rxdmt0|Rxseq); ctlr->rsleep++; sleep(&ctlr->rrendez, igberim, ctlr); rdh = ctlr->rdh; for(;;){ rd = &ctlr->rdba[rdh]; if(!(rd->status & Rdd)) break; /* * Accept eop packets with no errors. * With no errors and the Ixsm bit set, * the descriptor status Tpcs and Ipcs bits give * an indication of whether the checksums were * calculated and valid. */ if((rd->status & Reop) && rd->errors == 0){ bp = ctlr->rb[rdh]; ctlr->rb[rdh] = nil; bp->wp += rd->length; bp->next = nil; if(!(rd->status & Ixsm)){ ctlr->ixsm++; if(rd->status & Ipcs){ /* * IP checksum calculated * (and valid as errors == 0). */ ctlr->ipcs++; bp->flag |= Bipck; } if(rd->status & Tcpcs){ /* * TCP/UDP checksum calculated * (and valid as errors == 0). */ ctlr->tcpcs++; bp->flag |= Btcpck|Budpck; } bp->checksum = rd->checksum; bp->flag |= Bpktck; } bp->lim = bp->wp; // lie like a dog. etheriq(edev, bp, 1); } else if(ctlr->rb[rdh] != nil){ freeb(ctlr->rb[rdh]); ctlr->rb[rdh] = nil; } // memset(rd, 0, sizeof(Rd)); // coherence(); ctlr->rdfree--; rdh = NEXT(rdh, ctlr->nrd); } ctlr->rdh = rdh; if(ctlr->rdfree < ctlr->nrd/2 || (ctlr->rim & Rxdmt0)) igbereplenish(ctlr); } } static int txcansleep(void *v) { Ctlr *c; c = v; return NEXT(c->tdh, c->ntd) != csr32r(c, Tdh); } static void igbetproc(void *v) { Ether *e; Ctlr *c; e = v; c = e->ctlr; for(;;){ sleep(&c->trendez, txcansleep, c); igbetransmit(e); } } static void igbeattach(Ether* edev) { char name[KNAMELEN]; int i; Block *bp; Ctlr *ctlr; ctlr = edev->ctlr; qlock(&ctlr->alock); if(ctlr->alloc != nil){ qunlock(&ctlr->alock); return; } ctlr->nrd = ROUNDUP(Nrd, 8); ctlr->ntd = ROUNDUP(Ntd, 8); ctlr->alloc = malloc(ctlr->nrd*sizeof(Rd)+ctlr->ntd*sizeof(Td) + 127); if(ctlr->alloc == nil){ print("igbe: can't allocate ctlr->alloc\n"); qunlock(&ctlr->alock); return; } ctlr->rdba = (Rd*)ROUNDUP((uintptr)ctlr->alloc, 128); ctlr->tdba = (Td*)(ctlr->rdba+ctlr->nrd); ctlr->rb = malloc(ctlr->nrd*sizeof(Block*)); ctlr->tb = malloc(ctlr->ntd*sizeof(Block*)); if(waserror()){ while(bp = igberballoc()){ bp->free = nil; freeb(bp); } free(ctlr->tb); ctlr->tb = nil; free(ctlr->rb); ctlr->rb = nil; free(ctlr->alloc); ctlr->alloc = nil; qunlock(&ctlr->alock); nexterror(); } for(i = 0; i < Nrb; i++){ bp = allocb(Rbsz+PGSZ); bp->free = igberbfree; freeb(bp); } edev->maxmtu = Rbsz; snprint(name, KNAMELEN, "#l%dlproc", edev->ctlrno); kproc(name, igbelproc, edev); snprint(name, KNAMELEN, "#l%drproc", edev->ctlrno); kproc(name, igberproc, edev); snprint(name, KNAMELEN, "#l%dtproc", edev->ctlrno); kproc(name, igbetproc, edev); igbetxinit(ctlr); qunlock(&ctlr->alock); poperror(); } static void igbeinterrupt(Ureg*, void* arg) { Ctlr *ctlr; Ether *edev; u32int icr, im; edev = arg; ctlr = edev->ctlr; ilock(&ctlr->imlock); csr32w(ctlr, Imc, ~0); im = ctlr->im; while((icr = csr32r(ctlr, Icr) & ctlr->im) != 0){ if(icr & Lsc){ im &= ~Lsc; ctlr->lim = icr & Lsc; wakeup(&ctlr->lrendez); ctlr->lintr++; } if(icr & (Rxt0|Rxo|Rxdmt0|Rxseq)){ im &= ~(Rxt0|Rxo|Rxdmt0|Rxseq); ctlr->rim = icr & (Rxt0|Rxo|Rxdmt0|Rxseq); wakeup(&ctlr->rrendez); ctlr->rintr++; } if(icr & Txdw){ im &= ~Txdw; wakeup(&ctlr->trendez); ctlr->tintr++; } } ctlr->im = im; csr32w(ctlr, Ims, im); iunlock(&ctlr->imlock); } static int i82543mdior(Ctlr* ctlr, int n) { int i; u32int ctrl, r, data; /* * Read n bits from the Management Data I/O Interface. */ ctrl = csr32r(ctlr, Ctrl); r = (ctrl & ~Mddo)|Mdco; data = 0; for(i = n-1; i >= 0; i--){ if(csr32r(ctlr, Ctrl) & Mdd) data |= (1<= 0; i--){ if(bits & (1<ctlr; /* * MII Management Interface Read. * * Preamble; * ST+OP+PHYAD+REGAD; * TA + 16 data bits. */ i82543mdiow(ctlr, 0xFFFFFFFF, 32); i82543mdiow(ctlr, 0x1800|(pa<<5)|ra, 14); data = i82543mdior(ctlr, 18); if(data & 0x10000) return -1; return data & 0xFFFF; } static int i82543miimiw(Mii* mii, int pa, int ra, int data) { Ctlr *ctlr; ctlr = mii->ctlr; /* * MII Management Interface Write. * * Preamble; * ST+OP+PHYAD+REGAD+TA + 16 data bits; * Z. */ i82543mdiow(ctlr, 0xFFFFFFFF, 32); data &= 0xFFFF; data |= (0x05<<(5+5+2+16))|(pa<<(5+2+16))|(ra<<(2+16))|(0x02<<16); i82543mdiow(ctlr, data, 32); return 0; } static int igbemiimir(Mii* mii, int pa, int ra) { Ctlr *ctlr; u32int mdic, timo; ctlr = mii->ctlr; csr32w(ctlr, Mdic, MDIrop|(pa<ctlr; data &= MDIdMASK; csr32w(ctlr, Mdic, MDIwop|(pa<id){ case i82543gc: ctrl |= Frcdplx|Frcspd; csr32w(ctlr, Ctrl, ctrl); /* * The reset pin direction (Mdro) should already * be set from the EEPROM load. * If it's not set this configuration is unexpected * so bail. */ r = csr32r(ctlr, Ctrlext); if(!(r & Mdro)) return -1; csr32w(ctlr, Ctrlext, r); delay(20); r = csr32r(ctlr, Ctrlext); r &= ~Mdr; csr32w(ctlr, Ctrlext, r); delay(20); r = csr32r(ctlr, Ctrlext); r |= Mdr; csr32w(ctlr, Ctrlext, r); delay(20); read = i82543miimir; write = i82543miimiw; break; case i82544ei: case i82544eif: case i82544gc: case i82540em: case i82540eplp: case i82547ei: case i82547gi: case i82541ei: case i82541gi: case i82541gi2: case i82541pi: case i82545em: case i82545gmc: case i82546gb: case i82546eb: ctrl &= ~(Frcdplx|Frcspd); csr32w(ctlr, Ctrl, ctrl); read = igbemiimir; write = igbemiimiw; break; default: return -1; } if((ctlr->mii = miiattach(ctlr, ~0, read, write)) == nil) return -1; // print("oui %X phyno %d\n", ctlr->mii->curphy->oui, ctlr->mii->curphy->phyno); /* * 8254X-specific PHY registers not in 802.3: * 0x10 PHY specific control * 0x14 extended PHY specific control * Set appropriate values then reset the PHY to have * changes noted. */ switch(ctlr->id){ case i82547gi: case i82541gi: case i82541gi2: case i82541pi: case i82545em: case i82545gmc: case i82546gb: case i82546eb: break; default: r = miimir(ctlr->mii, 16); r |= 0x0800; /* assert CRS on Tx */ r |= 0x0060; /* auto-crossover all speeds */ r |= 0x0002; /* polarity reversal enabled */ miimiw(ctlr->mii, 16, r); r = miimir(ctlr->mii, 20); r |= 0x0070; /* +25MHz clock */ r &= ~0x0F00; r |= 0x0100; /* 1x downshift */ miimiw(ctlr->mii, 20, r); miireset(ctlr->mii); p = 0; if(ctlr->txcw & TxcwPs) p |= AnaP; if(ctlr->txcw & TxcwAs) p |= AnaAP; miiane(ctlr->mii, ~0, p, ~0); break; } return 0; } static int at93c46io(Ctlr* ctlr, char* op, int data) { char *lp, *p; int loop; u32int eecd, i, r; eecd = csr32r(ctlr, Eecd); r = 0; loop = -1; lp = nil; for(p = op; *p != '\0'; p++){ switch(*p){ default: return -1; case ' ': continue; case ':': /* start of loop */ loop = strtol(p+1, &lp, 0)-1; lp--; if(p == lp) loop = 7; p = lp; continue; case ';': /* end of loop */ if(lp == nil) return -1; loop--; if(loop >= 0) p = lp; else lp = nil; continue; case 'C': /* assert clock */ eecd |= Sk; break; case 'c': /* deassert clock */ eecd &= ~Sk; break; case 'D': /* next bit in 'data' byte */ if(loop < 0) return -1; if(data & (1<= 0) r |= (i<= 0) return -1; return r; } static int at93c46r(Ctlr* ctlr) { u16int sum; char rop[20]; int addr, areq, bits, data, i; u32int eecd; eecd = csr32r(ctlr, Eecd); if(eecd & Spi){ print("igbe: SPI EEPROM access not implemented\n"); return 0; } if(eecd & (Eeszaddr|Eesz256)) bits = 8; else bits = 6; sum = 0; switch(ctlr->id){ default: areq = 0; break; case i82540em: case i82540eplp: case i82541ei: case i82541gi: case i82541gi2: case i82541pi: case i82545em: case i82545gmc: case i82546gb: case i82546eb: case i82547ei: case i82547gi: areq = 1; csr32w(ctlr, Eecd, eecd|Areq); for(i = 0; i < 1000; i++){ if((eecd = csr32r(ctlr, Eecd)) & Agnt) break; microdelay(5); } if(!(eecd & Agnt)){ print("igbe: not granted EEPROM access\n"); goto release; } break; } // snprint(rop, sizeof(rop), "S :%dDCc;", bits+3); snprint(rop, sizeof(rop), "CcS :%dDCc;", bits+3); for(addr = 0; addr < 0x40; addr++){ /* * Read a word at address 'addr' from the Atmel AT93C46 * 3-Wire Serial EEPROM or compatible. The EEPROM access is * controlled by 4 bits in Eecd. See the AT93C46 datasheet * for protocol details. */ if(at93c46io(ctlr, rop, (0x06<eeprom[addr] = data; sum += data; } release: if(areq) csr32w(ctlr, Eecd, eecd & ~Areq); return sum; } static int igbedetach(Ctlr* ctlr) { int timeo; u32int r; /* rebalance rx/tx packet buffers for >8k jumbos. */ switch(ctlr->id){ case i82546eb: if(Rbsz <= 8192) break; ctlr->pba = csr32r(ctlr, 0x1000); ctlr->pba &= ~0xffff|0x20; csr32w(ctlr, 0x1000, ctlr->pba); ctlr->pba = csr32r(ctlr, 0x1000); break; } /* * Perform a device reset to get the chip back to the * power-on state, followed by an EEPROM reset to read * the defaults for some internal registers. */ csr32w(ctlr, Imc, ~0); csr32w(ctlr, Rctl, 0); csr32w(ctlr, Tctl, 0); delay(10); csr32w(ctlr, Ctrl, Devrst); delay(1); for(timeo = 0; timeo < 1000; timeo++){ if(!(csr32r(ctlr, Ctrl) & Devrst)) break; delay(1); } if(csr32r(ctlr, Ctrl) & Devrst) return -1; r = csr32r(ctlr, Ctrlext); csr32w(ctlr, Ctrlext, r|Eerst); delay(1); for(timeo = 0; timeo < 1000; timeo++){ if(!(csr32r(ctlr, Ctrlext) & Eerst)) break; delay(1); } if(csr32r(ctlr, Ctrlext) & Eerst) return -1; switch(ctlr->id){ default: break; case i82540em: case i82540eplp: case i82541gi: case i82541gi2: case i82541pi: case i82545em: case i82545gmc: case i82547gi: case i82546gb: case i82546eb: r = csr32r(ctlr, Manc); r &= ~Arpen; csr32w(ctlr, Manc, r); break; } csr32w(ctlr, Imc, ~0); delay(1); for(timeo = 0; timeo < 1000; timeo++){ if(!csr32r(ctlr, Icr)) break; delay(1); } if(csr32r(ctlr, Icr)) return -1; return 0; } static void igbeshutdown(Ether* ether) { igbedetach(ether->ctlr); } static int igbereset(Ctlr* ctlr) { int i; u32int ctrl, r, pause, swdpio, txcw; if(igbedetach(ctlr)) return -1; /* * Read the EEPROM, validate the checksum * then get the device back to a power-on state. */ if((r = at93c46r(ctlr)) != 0xBABA){ print("igbe: bad EEPROM checksum - %#.4ux\n", r); return -1; } /* * Snarf and set up the receive addresses. * There are 16 addresses. The first should be the MAC address. * The others are cleared and not marked valid (MS bit of Rah). */ if(ctlr->eeprom[Ea] == 0xFFFF) ctlr->eeprom[Ea] = 0xD000; for(i = 0; i < Eaddrlen/2; i++){ ctlr->ra[2*i] = ctlr->eeprom[Ea+i]; ctlr->ra[2*i+1] = ctlr->eeprom[Ea+i]>>8; } /* lan id seems to vary on 82543gc; don't use it */ if (ctlr->id != i82543gc) { r = (csr32r(ctlr, Status) & Lanid) >> 2; ctlr->ra[5] += r; /* ea ctlr[1] = ea ctlr[0]+1 */ } r = ctlr->ra[3]<<24 | ctlr->ra[2]<<16 | ctlr->ra[1]<<8 | ctlr->ra[0]; csr32w(ctlr, Ral, r); r = 0x80000000| ctlr->ra[5]<<8 | ctlr->ra[4]; csr32w(ctlr, Rah, r); for(i = 1; i < 16; i++){ csr32w(ctlr, Ral+i*8, 0); csr32w(ctlr, Rah+i*8, 0); } /* * Clear the Multicast Table Array. * It's a 4096 bit vector accessed as 128 32-bit registers. */ memset(ctlr->mta, 0, sizeof(ctlr->mta)); for(i = 0; i < 128; i++) csr32w(ctlr, Mta+i*4, 0); /* * Just in case the Eerst didn't load the defaults * (doesn't appear to fully on the 82543GC), do it manually. */ if (ctlr->id == i82543gc) { txcw = csr32r(ctlr, Txcw); txcw &= ~(TxcwAne|TxcwPauseMASK|TxcwFd); ctrl = csr32r(ctlr, Ctrl); ctrl &= ~(SwdpioloMASK|Frcspd|Ilos|Lrst|Fd); if(ctlr->eeprom[Icw1] & 0x0400){ ctrl |= Fd; txcw |= TxcwFd; } if(ctlr->eeprom[Icw1] & 0x0200) ctrl |= Lrst; if(ctlr->eeprom[Icw1] & 0x0010) ctrl |= Ilos; if(ctlr->eeprom[Icw1] & 0x0800) ctrl |= Frcspd; swdpio = (ctlr->eeprom[Icw1] & 0x01E0)>>5; ctrl |= swdpio<eeprom[Icw2] & 0x00F0)>>4; if(ctlr->eeprom[Icw1] & 0x1000) ctrl |= Ips; ctrl |= swdpio<eeprom[Icw2] & 0x0800) txcw |= TxcwAne; pause = (ctlr->eeprom[Icw2] & 0x3000)>>12; txcw |= pause<fcrtl = 0x00002000; ctlr->fcrth = 0x00004000; txcw |= TxcwAs|TxcwPs; break; case 0: ctlr->fcrtl = 0x00002000; ctlr->fcrth = 0x00004000; break; case 2: ctlr->fcrtl = 0; ctlr->fcrth = 0; txcw |= TxcwAs; break; } ctlr->txcw = txcw; csr32w(ctlr, Txcw, txcw); } /* * Flow control - values from the datasheet. */ csr32w(ctlr, Fcal, 0x00C28001); csr32w(ctlr, Fcah, 0x00000100); csr32w(ctlr, Fct, 0x00008808); csr32w(ctlr, Fcttv, 0x00000100); csr32w(ctlr, Fcrtl, ctlr->fcrtl); csr32w(ctlr, Fcrth, ctlr->fcrth); if(!(csr32r(ctlr, Status) & Tbimode) && igbemii(ctlr) < 0) return -1; return 0; } static void igbepci(void) { int cls; Pcidev *p; Ctlr *ctlr; void *mem; p = nil; while(p = pcimatch(p, 0, 0)){ if(p->ccrb != 0x02 || p->ccru != 0) continue; switch((p->did<<16)|p->vid){ default: continue; case i82543gc: case i82544ei: case i82544eif: case i82544gc: case i82547ei: case i82547gi: case i82540em: case i82540eplp: case i82541ei: case i82541gi: case i82541gi2: case i82541pi: case i82545em: case i82545gmc: case i82546gb: case i82546eb: break; } mem = vmap(p->mem[0].bar & ~0x0F, p->mem[0].size); if(mem == nil){ print("igbe: can't map %#.8ux\n", p->mem[0].bar); continue; } cls = pcicfgr8(p, PciCLS); switch(cls){ default: print("igbe: unexpected CLS - %d\n", cls*4); break; case 0x00: case 0xFF: print("igbe: unusable CLS; using 32 bytes\n"); pcicfgw8(p, PciCLS, 32/4); continue; case 0x08: case 0x10: break; } ctlr = malloc(sizeof(Ctlr)); if(ctlr == nil) { vunmap(mem, p->mem[0].size); continue; } ctlr->port = p->mem[0].bar & ~0x0F; ctlr->pcidev = p; ctlr->id = (p->did<<16)|p->vid; ctlr->cls = cls*4; ctlr->nic = mem; if(igbereset(ctlr)){ free(ctlr); vunmap(mem, p->mem[0].size); continue; } pcisetbme(p); if(igbectlrhead != nil) igbectlrtail->next = ctlr; else igbectlrhead = ctlr; igbectlrtail = ctlr; } } static int igbepnp(Ether* edev) { Ctlr *ctlr; if(igbectlrhead == nil) igbepci(); /* * Any adapter matches if no edev->port is supplied, * otherwise the ports must match. */ for(ctlr = igbectlrhead; ctlr != nil; ctlr = ctlr->next){ if(ctlr->active) continue; if(ethercfgmatch(edev, ctlr->pcidev, ctlr->port) == 0){ ctlr->active = 1; break; } } if(ctlr == nil) return -1; ctlr->edev = edev; /* point back to Ether* */ edev->ctlr = ctlr; edev->port = ctlr->port; edev->irq = ctlr->pcidev->intl; edev->tbdf = ctlr->pcidev->tbdf; edev->mbps = 1000; memmove(edev->ea, ctlr->ra, Eaddrlen); /* * Linkage to the generic ethernet driver. */ edev->attach = igbeattach; edev->transmit = igbetransmit; edev->interrupt = igbeinterrupt; edev->ifstat = igbeifstat; edev->ctl = igbectl; edev->arg = edev; edev->promiscuous = igbepromiscuous; edev->shutdown = igbeshutdown; edev->multicast = igbemulticast; return 0; } void etherigbelink(void) { addethercard("i82543", igbepnp); addethercard("igbe", igbepnp); }