ref: e3aee39a389700ad821a1619f114e226c1bd42d0
dir: /sys/src/9/pc/etherx550.c/
/* * intel 10GB ethernet pci-express driver * 6.0.0: net 02.00.00 8086/15c8 11 0:dfc0000c 2097152 4:dfe0400c 16384 * Intel Corporation Ethernet Connection X553/X550-AT 10GBASE-T */ #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 "../port/etherif.h" enum { /* general */ Ctrl = 0x00000/4, /* Device Control */ Status = 0x00008/4, /* Device Status */ Ctrlext = 0x00018/4, /* Extended Device Control */ Tcptimer = 0x0004c/4, /* tcp timer */ /* nvm */ Eec = 0x10010/4, /* eeprom/flash control */ Eemngctl = 0x10110/4, /* Manageability EEPROM-Mode Control */ /* interrupt */ Icr = 0x00800/4, /* interrupt cause read */ Ics = 0x00808/4, /* " set */ Ims = 0x00880/4, /* " mask read/set */ Imc = 0x00888/4, /* " mask clear */ Iac = 0x00810/4, /* " auto clear */ Iam = 0x00890/4, /* " auto mask enable */ Itr = 0x00820/4, /* " throttling rate (0-19) */ Ivar = 0x00900/4, /* " vector allocation regs. */ /* rx dma */ Rdbal = 0x01000/4, /* rx desc base low (0-63) +0x40n */ Rdbah = 0x01004/4, /* " high */ Rdlen = 0x01008/4, /* " length */ Rdh = 0x01010/4, /* " head */ Rdt = 0x01018/4, /* " tail */ Rxdctl = 0x01028/4, /* " control */ Srrctl = 0x02100/4, /* split and replication rx ctl. */ Rdrxctl = 0x02f00/4, /* rx dma control */ Rxpbsize = 0x03c00/4, /* rx packet buffer size */ Rxctrl = 0x03000/4, /* rx control */ /* rx */ Rxcsum = 0x05000/4, /* rx checksum control */ Mcstctrl = 0x05090/4, /* multicast control register */ Mta = 0x05200/4, /* multicast table array (0-127) */ Ral = 0x05400/4, /* rx address low */ Rah = 0x05404/4, Vfta = 0x0a000/4, /* vlan filter table array. */ Fctrl = 0x05080/4, /* filter control */ /* tx */ Tdbal = 0x06000/4, /* tx desc base low +0x40n */ Tdbah = 0x06004/4, /* " high */ Tdlen = 0x06008/4, /* " len */ Tdh = 0x06010/4, /* " head */ Tdt = 0x06018/4, /* " tail */ Txdctl = 0x06028/4, /* " control */ Dmatxctl = 0x04a80/4, /* mac */ Hlreg0 = 0x04240/4, /* highlander control reg 0 */ Hlreg1 = 0x04244/4, /* highlander control reg 1 (ro) */ Maxfrs = 0x04268/4, /* max frame size */ Links = 0x042a4/4, /* link status */ }; enum { /* Ctrl */ Rst = 1<<26, /* full nic reset */ /* Ctrlext */ Drvload = 1<<28, /* Driver Load */ /* Eec */ AutoRd = 1<<9, /* NVM auto read done */ /* Eemngctl */ CfgDone0 = 1<<18, /* Configuration Done Port 0 */ CfgDone1 = 1<<19, /* Configuration Done Port 1 */ /* Txdctl */ Pthresh = 0, /* prefresh threshold shift in bits */ Hthresh = 8, /* host buffer minimum threshold */ Wthresh = 16, /* writeback threshold */ Ten = 1<<25, /* Fctrl */ Bam = 1<<10, /* broadcast accept mode */ Upe = 1<<9, /* unicast promiscuous */ Mpe = 1<<8, /* multicast promiscuous */ /* Rxdctl */ Renable = 1<<25, /* Dmatxctl */ Txen = 1<<0, /* Rxctl */ Rxen = 1<<0, /* Rdrxctl */ Dmaidone = 1<<3, /* Rxcsum */ Ippcse = 1<<12, /* ip payload checksum enable */ /* Mcstctrl */ Mo = 0, /* multicast offset 47:36 */ Mfe = 1<<2, /* multicast filter enable */ /* Rah */ Av = 1<<31, /* interrupts */ Irx0 = 1<<0, /* driver defined - rx interrupt */ Itx0 = 1<<1, /* driver defined - tx interrupt */ Lsc = 1<<20, /* link status change */ /* Ivar Interrupt Vector Allocation Register */ Intalloc0 = 0, /* Map the 0th queue Rx interrupt to the 0th bit of EICR register */ Intallocval0 = 1<<7, intalloc1 = 1<<8, /* Map the 0th queue Tx interrupt to the 1st bit of EICR register */ Intallocval1 = 1<<15, /* Links */ Lnkup = 1<<30, Lnkspd = 1<<29, /* Hlreg0 */ Jumboen = 1<<2, }; typedef struct { uint reg; char *name; } Stat; static Stat stattab[] = { 0x4000, "crc error", 0x4004, "illegal byte", 0x4008, "short packet", 0x3fa0, "missed pkt0", 0x4034, "mac local flt", 0x4038, "mac rmt flt", 0x4040, "rx length err", 0x405c, "rx 040", 0x4060, "rx 07f", 0x4064, "rx 100", 0x4068, "rx 200", 0x406c, "rx 3ff", 0x4070, "rx big", 0x4074, "rx ok", 0x4078, "rx bcast", 0x407c, "rx mcast", 0x4080, "tx ok", 0x40a4, "rx runt", 0x40a8, "rx frag", 0x40ac, "rx ovrsz", 0x40b0, "rx jab", 0x40d0, "rx pkt", 0x40d4, "tx pkt", 0x40d8, "tx 040", 0x40dc, "tx 07f", 0x40e0, "tx 100", 0x40e4, "tx 200", 0x40e8, "tx 3ff", 0x40ec, "tx big", 0x40f0, "tx mcast", 0x40f4, "tx bcast", 0x4120, "xsum err", }; /* status */ enum { Pif = 1<<7, /* past exact filter (sic) */ Ipcs = 1<<6, /* ip checksum calcuated */ L4cs = 1<<5, /* layer 2 */ Udpcs = 1<<4, /* udp checksum calcuated */ Vp = 1<<3, /* 802.1q packet matched vet */ Reop = 1<<1, /* end of packet */ Rdd = 1<<0, /* descriptor done */ }; typedef struct { u32int addr[2]; ushort length; ushort cksum; uchar status; uchar errors; ushort vlan; } Rd; enum { /* Td cmd */ Rs = 1<<3, Ic = 1<<2, Ifcs = 1<<1, Teop = 1<<0, /* Td status */ Tdd = 1<<0, }; typedef struct { u32int addr[2]; u16int length; uchar cso; uchar cmd; uchar status; uchar css; ushort vlan; } Td; enum { Factive = 1<<0, Fstarted = 1<<1, }; typedef struct { Pcidev *p; Ether *edev; uintptr io; u32int *reg; u32int *regmsi; uchar flag; int nrd; int ntd; int rbsz; Lock slock; Lock alock; QLock tlock; Rendez lrendez; Rendez trendez; Rendez rrendez; uint im; uint lim; uint rim; uint tim; Lock imlock; char *alloc; Rd *rdba; Block **rb; uint rdt; uint rdfree; Td *tdba; uint tdh; uint tdt; Block **tb; uchar ra[Eaddrlen]; u32int mta[128]; ulong stats[nelem(stattab)]; uint speeds[3]; } Ctlr; /* tweakable paramaters */ enum { Mtu = 12*1024, Nrd = 256, Ntd = 256, Nrb = 256, }; static Ctlr *ctlrtab[4]; static int nctlr; static void readstats(Ctlr *c) { int i; lock(&c->slock); for(i = 0; i < nelem(c->stats); i++) c->stats[i] += c->reg[stattab[i].reg >> 2]; unlock(&c->slock); } static int speedtab[] = { 0, 1000, 10000, }; static long ifstat(Ether *e, void *a, long n, ulong offset) { uint i, *t; char *s, *p, *q; Ctlr *c; p = s = smalloc(READSTR); q = p + READSTR; c = e->ctlr; readstats(c); for(i = 0; i < nelem(stattab); i++) if(c->stats[i] > 0) p = seprint(p, q, "%.10s %uld\n", stattab[i].name, c->stats[i]); t = c->speeds; p = seprint(p, q, "speeds: 0:%d 1000:%d 10000:%d\n", t[0], t[1], t[2]); seprint(p, q, "rdfree %d rdh %d rdt %d\n", c->rdfree, c->reg[Rdt], c->reg[Rdh]); n = readstr(offset, a, n, s); free(s); return n; } static void im(Ctlr *c, int i) { ilock(&c->imlock); c->im |= i; c->reg[Ims] = c->im; iunlock(&c->imlock); } static int lim(void *v) { return ((Ctlr*)v)->lim != 0; } static void lproc(void *v) { int r, i; Ctlr *c; Ether *e; e = v; c = e->ctlr; while(waserror()) ; for (;;) { r = c->reg[Links]; e->link = (r & Lnkup) != 0; i = 0; if(e->link) i = 1 + ((r & Lnkspd) != 0); c->speeds[i]++; e->mbps = speedtab[i]; c->lim = 0; im(c, Lsc); sleep(&c->lrendez, lim, c); c->lim = 0; } } static long ctl(Ether *, void *, long) { error(Ebadarg); return -1; } #define Next(x, m) (((x)+1) & (m)) static int cleanup(Ctlr *c, int tdh) { Block *b; uint m, n; m = c->ntd - 1; while(c->tdba[n = Next(tdh, m)].status & Tdd){ tdh = n; b = c->tb[tdh]; c->tb[tdh] = 0; freeb(b); c->tdba[tdh].status = 0; } return tdh; } static void transmit(Ether *e) { uint i, m, tdt, tdh; Ctlr *c; Block *b; Td *t; c = e->ctlr; if(!canqlock(&c->tlock)){ im(c, Itx0); return; } tdh = c->tdh = cleanup(c, c->tdh); tdt = c->tdt; m = c->ntd - 1; for(i = 0; i < 8; i++){ if(Next(tdt, m) == tdh){ im(c, Itx0); break; } if(!(b = qget(e->oq))) break; t = c->tdba + tdt; t->addr[0] = PCIWADDR(b->rp); t->length = BLEN(b); t->cmd = Rs | Ifcs | Teop; c->tb[tdt] = b; tdt = Next(tdt, m); } if(i){ c->tdt = tdt; c->reg[Tdt] = tdt; } qunlock(&c->tlock); } static int tim(void *c) { return ((Ctlr*)c)->tim != 0; } static void tproc(void *v) { Ctlr *c; Ether *e; e = v; c = e->ctlr; while(waserror()) ; for (;;) { sleep(&c->trendez, tim, c); /* transmit kicks us */ c->tim = 0; transmit(e); } } static void rxinit(Ctlr *c) { int i; Block *b; c->reg[Rxctrl] &= ~Rxen; /* Pg 144 Step 2 Receive buffers of appropriate size should be allocated and pointers to these buffers should be stored in the descriptor ring - replinish() does this? */ for(i = 0; i < c->nrd; i++){ b = c->rb[i]; c->rb[i] = 0; if(b) freeb(b); } c->rdfree = 0; c->reg[Fctrl] |= Bam; c->reg[Rxcsum] |= Ippcse; c->reg[Srrctl] = c->rbsz / 1024; c->reg[Maxfrs] = c->rbsz << 16; c->reg[Hlreg0] |= Jumboen; c->reg[Rdbal] = PCIWADDR(c->rdba); c->reg[Rdbah] = 0; c->reg[Rdlen] = c->nrd*sizeof(Rd); c->reg[Rdh] = 0; c->reg[Rdt] = c->rdt = 0; c->reg[Rxdctl] = Renable; while((c->reg[Rxdctl] & Renable) == 0) ; /* TODO? bump the tail pointer RDT to enable descriptors fetching by setting it to the ring length minus 1. Pg 145 */ c->reg[Rxctrl] |= Rxen; } static void replenish(Ctlr *c, uint rdh) { int rdt, m, i; Block *b; Rd *r; m = c->nrd - 1; i = 0; for(rdt = c->rdt; Next(rdt, m) != rdh; rdt = Next(rdt, m)){ b = allocb(c->rbsz+BY2PG); b->rp = (uchar*)PGROUND((uintptr)b->base); b->wp = b->rp; c->rb[rdt] = b; r = c->rdba + rdt; r->addr[0] = PCIWADDR(b->rp); r->status = 0; c->rdfree++; i++; } if(i) c->reg[Rdt] = c->rdt = rdt; } static int rim(void *v) { return ((Ctlr*)v)->rim != 0; } static uchar zeroea[Eaddrlen]; static void rproc(void *v) { uint m, rdh; Block *b; Ctlr *c; Ether *e; Rd *r; e = v; c = e->ctlr; m = c->nrd - 1; rdh = 0; while(waserror()) ; loop: replenish(c, rdh); im(c, Irx0); sleep(&c->rrendez, rim, c); loop1: c->rim = 0; if(c->nrd - c->rdfree >= 16) replenish(c, rdh); r = c->rdba + rdh; if(!(r->status & Rdd)) goto loop; /* UGH */ b = c->rb[rdh]; c->rb[rdh] = 0; b->wp += r->length; if((r->status & 1)){ if(r->status & Ipcs) b->flag |= Bipck; b->checksum = r->cksum; } // r->status = 0; etheriq(e, b); c->rdfree--; rdh = Next(rdh, m); goto loop1; /* UGH */ } static void promiscuous(void *a, int on) { Ctlr *c; Ether *e; e = a; c = e->ctlr; if(on) c->reg[Fctrl] |= Upe | Mpe; else c->reg[Fctrl] &= ~(Upe | Mpe); } static void multicast(void *a, uchar *ea, int on) { int b, i; Ctlr *c; Ether *e; e = a; c = e->ctlr; /* * 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. * * Extracts the 12 bits, from a multicast address, to determine which * bit-vector to set in the multicast table. The hardware uses 12 bits, from * incoming rx multicast addresses, to determine the bit-vector to check in * the MTA. Which of the 4 combination, of 12-bits, the hardware uses is set * by the MO field of the MCSTCTRL. The MO field is set during initialization * to mc_filter_type. * * The MTA is a register array of 128 32-bit registers. It is treated * like an array of 4096 bits. We want to set bit * BitArray[vector_value]. So we figure out what register the bit is * in, read it, OR in the new bit, then write back the new value. The * register is determined by the upper 7 bits of the vector value and * the bit within that register are determined by the lower 5 bits of * the value. * * when Mcstctrl.Mo == 0, use bits [47:36] of the address * register index = bits [47:41] * which bit in the above register = bits [40:36] */ i = ea[5] >> 1; /* register index = 47:41 (7 bits) */ b = (ea[5]&1)<<4 | ea[4]>>4; /* which bit in the above register = 40:36 (5 bits) */ b = 1 << b; if(on) c->mta[i] |= b; // else // c->mta[i] &= ~b; c->reg[Mta+i] = c->mta[i]; c->reg[Mcstctrl] = Mfe; /* for(i = 0; i < 128; i++) c->reg[Mta + i] = -1; brute force it to work for testing */ } static int detach(Ctlr *c) { int i; u32int l, h; l = c->reg[Ral]; h = c->reg[Rah]; if (h & Av) { c->ra[0] = l & 0xFF; c->ra[1] = l>>8 & 0xFF; c->ra[2] = l>>16 & 0xFF; c->ra[3] = l>>24 & 0xFF; c->ra[4] = h & 0xFF; c->ra[5] = h>>8 & 0xFF; } c->reg[Imc] = ~0; c->reg[Ctrl] |= Rst; for(i = 0; i < 100; i++){ delay(1); if((c->reg[Ctrl] & Rst) == 0) break; } if (i >= 100) return -1; delay(10); /* not cleared by reset; kill it manually. */ for(i = 1; i < 16; i++) c->reg[Rah + i] &= ~(1 << 31); for(i = 0; i < 128; i++) c->reg[Mta + i] = 0; for(i = 1; i < 640; i++) c->reg[Vfta + i] = 0; c->reg[Ctrlext] &= ~Drvload; /* driver works without this */ return 0; } static void shutdown(Ether *e) { detach(e->ctlr); } static int reset(Ctlr *c) { int i; while((c->reg[Eec] & AutoRd) == 0) ; while((c->reg[Eemngctl] & CfgDone0) == 0) ; while((c->reg[Eemngctl] & CfgDone1) == 0) ; while((c->reg[Rdrxctl] & Dmaidone) == 0) ; if(detach(c)){ print("iX550: reset timeout\n"); return -1; } while((c->reg[Eec] & AutoRd) == 0) ; while((c->reg[Eemngctl] & CfgDone0) == 0) ; while((c->reg[Eemngctl] & CfgDone1) == 0) ; while((c->reg[Rdrxctl] & Dmaidone) == 0) ; readstats(c); for(i = 0; i<nelem(c->stats); i++) c->stats[i] = 0; /* configure interrupt mapping */ c->reg[Ivar] = Intalloc0 | Intallocval0 | intalloc1 | Intallocval1; /* interrupt throttling goes here. */ for(i = Itr; i < Itr + 20; i++) c->reg[i] = 1<<3; /* 1 interval */ return 0; } static void txinit(Ctlr *c) { Block *b; int i; c->reg[Txdctl] = 16<<Wthresh | 16<<Pthresh; for(i = 0; i < c->ntd; i++){ b = c->tb[i]; c->tb[i] = 0; if(b) freeb(b); } memset(c->tdba, 0, c->ntd * sizeof(Td)); c->reg[Tdbal] = PCIWADDR(c->tdba); c->reg[Tdbah] = 0; c->reg[Tdlen] = c->ntd*sizeof(Td); c->reg[Tdh] = 0; c->reg[Tdt] = 0; c->tdh = c->ntd - 1; c->tdt = 0; c->reg[Txdctl] |= Ten; c->reg[Dmatxctl] |= Txen; } static void attach(Ether *e) { Ctlr *c; int t; char buf[KNAMELEN]; c = e->ctlr; c->edev = e; /* point back to Ether* */ lock(&c->alock); if(c->alloc){ unlock(&c->alock); return; } c->nrd = Nrd; c->ntd = Ntd; t = c->nrd * sizeof *c->rdba + 255; t += c->ntd * sizeof *c->tdba + 255; t += (c->ntd + c->nrd) * sizeof(Block*); c->alloc = malloc(t); unlock(&c->alock); if(c->alloc == nil) error(Enomem); c->rdba = (Rd*)ROUNDUP((uintptr)c->alloc, 256); c->tdba = (Td*)ROUNDUP((uintptr)(c->rdba + c->nrd), 256); c->rb = (Block**)(c->tdba + c->ntd); c->tb = (Block**)(c->rb + c->nrd); rxinit(c); txinit(c); c->reg[Ctrlext] |= Drvload; /* driver works without this */ snprint(buf, sizeof buf, "#l%dl", e->ctlrno); kproc(buf, lproc, e); snprint(buf, sizeof buf, "#l%dr", e->ctlrno); kproc(buf, rproc, e); snprint(buf, sizeof buf, "#l%dt", e->ctlrno); kproc(buf, tproc, e); } static void interrupt(Ureg*, void *v) { int icr, im; Ctlr *c; Ether *e; e = v; c = e->ctlr; ilock(&c->imlock); c->reg[Imc] = ~0; im = c->im; while((icr = c->reg[Icr] & c->im) != 0){ if(icr & Lsc){ im &= ~Lsc; c->lim = icr & Lsc; wakeup(&c->lrendez); } if(icr & Irx0){ im &= ~Irx0; c->rim = icr & Irx0; wakeup(&c->rrendez); } if(icr & Itx0){ im &= ~Itx0; c->tim = icr & Itx0; wakeup(&c->trendez); } } c->reg[Ims] = c->im = im; iunlock(&c->imlock); } extern void addvgaseg(char*, ulong, ulong); static void scan(void) { uintptr io, iomsi; void *mem, *memmsi; int pciregs, pcimsix; Ctlr *c; Pcidev *p; p = 0; while(p = pcimatch(p, 0x8086, 0x15c8)){ /* X553/X550-AT 10GBASE-T */ pcimsix = 4; pciregs = 0; if(nctlr == nelem(ctlrtab)){ print("iX550: too many controllers\n"); return; } c = malloc(sizeof *c); if(c == nil){ print("iX550: can't allocate memory\n"); continue; } io = p->mem[pciregs].bar & ~0xf; mem = vmap(io, p->mem[pciregs].size); if(mem == nil){ print("iX550: can't map regs %#p\n", io); free(c); continue; } if (nctlr == 0) addvgaseg("pci.ctlr0.bar0", p->mem[pciregs].bar & ~0xf, p->mem[pciregs].size); else if (nctlr == 1) addvgaseg("pci.ctlr1.bar0", p->mem[pciregs].bar & ~0xf, p->mem[pciregs].size); iomsi = p->mem[pcimsix].bar & ~0xf; memmsi = vmap(iomsi, p->mem[pcimsix].size); if(memmsi == nil){ print("iX550: can't map msi-x regs %#p\n", iomsi); vunmap(mem, p->mem[pciregs].size); free(c); continue; } pcienable(p); c->p = p; c->io = io; c->reg = (u32int*)mem; c->regmsi = (u32int*)memmsi; c->rbsz = ROUND(Mtu, 1024); if(reset(c)){ print("iX550: can't reset\n"); free(c); vunmap(mem, p->mem[pciregs].size); vunmap(memmsi, p->mem[pcimsix].size); continue; } pcisetbme(p); ctlrtab[nctlr++] = c; } } static int pnp(Ether *e) { static uchar zeros[Eaddrlen]; int i; Ctlr *c = nil; uchar *p; if(nctlr == 0) scan(); for(i = 0; i < nctlr; i++){ c = ctlrtab[i]; if(c == nil || c->flag & Factive) continue; if(e->port == 0 || e->port == c->io) break; } if (i >= nctlr) return -1; if(memcmp(c->ra, zeros, Eaddrlen) != 0) memmove(e->ea, c->ra, Eaddrlen); p = e->ea; c->reg[Ral] = p[3]<<24 | p[2]<<16 | p[1]<<8 | p[0]; c->reg[Rah] = p[5]<<8 | p[4] | 1<<31; c->flag |= Factive; e->ctlr = c; e->port = (uintptr)c->reg; e->irq = c->p->intl; e->tbdf = c->p->tbdf; e->mbps = 10000; e->maxmtu = Mtu; e->arg = e; e->attach = attach; e->ctl = ctl; e->ifstat = ifstat; e->multicast = multicast; e->promiscuous = promiscuous; e->shutdown = shutdown; e->transmit = transmit; intrenable(e->irq, interrupt, e, e->tbdf, e->name); return 0; } void etherx550link(void) { addethercard("iX550", pnp); }