ref: 2127b8c552390cdaeb848d0992d2923733936d09
dir: /sys/src/9/pc/sdmv50xx.c/
/* * Marvell 88SX[56]0[48][01] Serial ATA (SATA) driver * * See MV-S101357-00 Rev B Marvell PCI/PCI-X to 8-Port/4-Port * SATA Host Controller, ATA-5 ANSI NCITS 340-2000. * * This is a heavily-modified version (by Coraid) of a heavily-modified * version (from The Labs) of a driver written by Coraid, Inc. * The original copyright notice appears at the end of this file. */ #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/sd.h" #include <fis.h> #define dprint(...) // print(__VA_ARGS__) #define idprint(...) print(__VA_ARGS__) #define Ticks MACHP(0)->ticks enum { NCtlr = 4, NCtlrdrv = 8, NDrive = NCtlr*NCtlrdrv, SrbRing = 32, /* Addresses of ATA register */ ARcmd = 027, ARdev = 026, ARerr = 021, ARfea = 021, ARlba2 = 025, ARlba1 = 024, ARlba0 = 023, ARseccnt = 022, ARstat = 027, ATAerr = 1<<0, ATAdrq = 1<<3, ATAdf = 1<<5, ATAdrdy = 1<<6, ATAbusy = 1<<7, ATAabort = 1<<2, ATAobs = 1<<1 | 1<<2 | 1<<4, ATAeIEN = 1<<1, ATAbad = ATAbusy|ATAdf|ATAdrq|ATAerr, SFdone = 1<<0, SFerror = 1<<1, PRDeot = 1<<15, /* EDMA interrupt error cause register */ ePrtDataErr = 1<<0, ePrtPRDErr = 1<<1, eDevErr = 1<<2, eDevDis = 1<<3, eDevCon = 1<<4, eOverrun = 1<<5, eUnderrun = 1<<6, eSelfDis = 1<<8, ePrtCRQBErr = 1<<9, ePrtCRPBErr = 1<<10, ePrtIntErr = 1<<11, eIORdyErr = 1<<12, /* flags for sata 2 version */ eSelfDis2 = 1<<7, SerrInt = 1<<5, /* EDMA Command Register */ eEnEDMA = 1<<0, eDsEDMA = 1<<1, eAtaRst = 1<<2, /* Interrupt mask for errors we care about */ IEM = eDevDis | eDevCon | eSelfDis, IEM2 = eDevDis | eDevCon | eSelfDis2, /* phyerrata magic */ Mpreamp = 0x7e0, Dpreamp = 0x720, REV60X1B2 = 0x7, REV60X1C0 = 0x9, /* general mmio registers */ Portswtch = 0x1d64/4, /* drive states */ Dnull = 0, Dnew, Dready, Derror, Dmissing, Dreset, Dlast, /* sata mode */ DMautoneg = 0, DMsatai, DMsataii, }; typedef struct Arb Arb; typedef struct Bridge Bridge; typedef struct Chip Chip; typedef struct Ctlr Ctlr; typedef struct Drive Drive; typedef struct Edma Edma; typedef struct Prd Prd; typedef struct Rx Rx; typedef struct Srb Srb; typedef struct Tx Tx; /* * there are 4 drives per chip. thus an 8-port * card has two chips. */ struct Chip { Arb *arb; Edma *edma; }; struct Drive { Lock; Ctlr *ctlr; SDunit *unit; char name[10]; Sfis; Bridge *bridge; Edma *edma; Chip *chip; int chipx; int drivechange; int state; uvlong sectors; uint secsize; ulong pm2; /* phymode 2 init state */ ulong intick; /* check for hung drives. */ int wait; int mode; /* DMautoneg, satai or sataii. */ char serial[20+1]; char firmware[8+1]; char model[40+1]; uvlong wwn; ushort info[256]; Srb *srb[SrbRing-1]; int nsrb; Prd *prd; Tx *tx; Rx *rx; Srb *srbhead; Srb *srbtail; int driveno; /* ctlr*NCtlrdrv + unit */ }; struct Ctlr { Lock; int irq; int tbdf; int rid; ulong magic; int enabled; int type; SDev *sdev; Pcidev *pcidev; uchar *mmio; ulong *lmmio; Chip chip[2]; int nchip; Drive drive[NCtlrdrv]; int ndrive; }; struct Srb /* request buffer */ { Lock; Rendez; Srb *next; Drive *drive; uvlong blockno; int count; int req; int flag; uchar *data; uchar cmd; uchar lba[6]; uchar sectors; int sta; int err; }; /* * Memory-mapped I/O registers in many forms. */ struct Bridge /* memory-mapped per-drive registers */ { ulong status; ulong serror; ulong sctrl; ulong phyctrl; ulong phymode3; ulong phymode4; uchar fill0[0x14]; ulong phymode1; ulong phymode2; char fill1[8]; ulong ctrl; char fill2[0x34]; ulong phymode; char fill3[0x88]; }; /* must be 0x100 hex in length */ struct Arb /* memory-mapped per-chip registers */ { ulong config; /* satahc configuration register (sata2 only) */ ulong rqop; /* request queue out-pointer */ ulong rqip; /* response queue in pointer */ ulong ict; /* inerrupt caolescing threshold */ ulong itt; /* interrupt timer threshold */ ulong ic; /* interrupt cause */ ulong btc; /* bridges test control */ ulong bts; /* bridges test status */ ulong bpc; /* bridges pin configuration */ char fill1[0xdc]; Bridge bridge[4]; }; struct Edma /* memory-mapped per-drive DMA-related registers */ { ulong config; /* configuration register */ ulong timer; ulong iec; /* interrupt error cause */ ulong iem; /* interrupt error mask */ ulong txbasehi; /* request queue base address high */ ulong txi; /* request queue in pointer */ ulong txo; /* request queue out pointer */ ulong rxbasehi; /* response queue base address high */ ulong rxi; /* response queue in pointer */ ulong rxo; /* response queue out pointer */ ulong ctl; /* command register */ ulong testctl; /* test control */ ulong status; ulong iordyto; /* IORDY timeout */ char fill[0x18]; ulong sataconfig; /* sata 2 */ char fill[0xac]; ushort pio; /* data register */ char pad0[2]; uchar err; /* features and error */ char pad1[3]; uchar seccnt; /* sector count */ char pad2[3]; uchar lba0; char pad3[3]; uchar lba1; char pad4[3]; uchar lba2; char pad5[3]; uchar lba3; char pad6[3]; uchar cmdstat; /* cmd/status */ char pad7[3]; uchar altstat; /* alternate status */ uchar fill2[0x1df]; Bridge port; char fill3[0x1c00]; /* pad to 0x2000 bytes */ }; /* * Memory structures shared with card. */ struct Prd /* physical region descriptor */ { ulong pa; /* byte address of physical memory */ ushort count; /* byte count (bit0 must be 0) */ ushort flag; ulong zero; /* high long of 64 bit address */ ulong reserved; }; struct Tx /* command request block */ { ulong prdpa; /* physical region descriptor table structures */ ulong zero; /* must be zero (high long of prd address) */ ushort flag; /* control flags */ ushort regs[11]; }; struct Rx /* command response block */ { ushort cid; /* cID of response */ uchar cEdmaSts; /* EDMA status */ uchar cDevSts; /* status from disk */ ulong ts; /* time stamp */ }; static Ctlr *mvsatactlr[NCtlr]; static Drive *mvsatadrive[NDrive]; static int nmvsatadrive; static char *diskstates[Dlast] = { "null", "new", "ready", "error", "missing", "reset", }; extern SDifc sdmv50xxifc; /* * Request buffers. */ static struct { Lock; Srb *freechain; int nalloc; } srblist; static Srb* allocsrb(void) { Srb *p; ilock(&srblist); if((p = srblist.freechain) == nil){ srblist.nalloc++; iunlock(&srblist); p = smalloc(sizeof *p); }else{ srblist.freechain = p->next; iunlock(&srblist); } return p; } static void freesrb(Srb *p) { ilock(&srblist); p->next = srblist.freechain; srblist.freechain = p; iunlock(&srblist); } static int satawait(uchar *p, uchar mask, uchar v, int ms) { int i; for(i=0; i<ms && (*p & mask) != v; i++) microdelay(1000); return (*p & mask) == v; } /* unmask in the pci registers err done */ static void portswitch(ulong *mmio, int port, uint coal, uint on) { ulong m; m = 3<<(port&3)*2 | coal<<8; if((port&7) >= 4) m <<= 9; if(on) mmio[Portswtch] |= m; else mmio[Portswtch] &= m; } static char* dnam(Drive *d) { if(d->unit) return d->unit->name; return d->name; } /* I give up, marvell. You win. */ static void phyerrata(Drive *d) { ulong n, m; enum { BadAutoCal = 0xf << 26, }; if(d->ctlr->type == 1){ /* set phyctrl bits [0:1] to 01 per MV-S102013-00 Rev C. */ n = d->bridge->phyctrl; n &= ~3; d->bridge->phyctrl = n | 1; return; } microdelay(200); n = d->bridge->phymode2; while ((n & BadAutoCal) == BadAutoCal) { dprint("%s: badautocal\n", dnam(d)); n &= ~(1<<16); n |= 1<<31; d->bridge->phymode2 = n; microdelay(200); d->bridge->phymode2 &= ~(1<<16 | 1<<31); microdelay(200); n = d->bridge->phymode2; } n &= ~(1<<31); d->bridge->phymode2 = n; microdelay(200); /* abra cadabra! (random magic) */ m = d->bridge->phymode3; m &= ~0x7f800000; m |= 0x2a800000; d->bridge->phymode3 = m; /* fix phy mode 4 */ m = d->bridge->phymode3; n = d->bridge->phymode4; n &= ~(1<<1); n |= 1; switch(d->ctlr->rid){ case REV60X1B2: default: d->bridge->phymode4 = n; d->bridge->phymode3 = m; break; case REV60X1C0: d->bridge->phymode4 = n; break; } /* revert values of pre-emphasis and signal amps to the saved ones */ n = d->bridge->phymode2; n &= ~Mpreamp; n |= d->pm2; n &= ~(1<<16); d->bridge->phymode2 = n; } static void edmacleanout(Drive *d) { int i; Srb *srb; for(i=0; i<nelem(d->srb); i++){ if(srb = d->srb[i]){ d->srb[i] = nil; d->nsrb--; srb->flag |= SFerror|SFdone; wakeup(srb); } } while(srb = d->srbhead){ d->srbhead = srb->next; srb->flag |= SFerror|SFdone; wakeup(srb); } } static int edmadisable(Drive *d, int reset) { Edma *e; e = d->edma; if(!reset && (e->ctl & eEnEDMA) == 0) return 0; e->ctl = eDsEDMA; microdelay(1); if(reset) e->ctl = eAtaRst; microdelay(25); e->ctl = 0; if (satawait((uchar *)&e->ctl, eEnEDMA, 0, 3*1000) == 0){ print("%s: eEnEDMA never cleared on reset\n", dnam(d)); return -1; } edmacleanout(d); return 0; } static void resetdisk(Drive *d) { ulong n; d->sectors = 0; d->unit->sectors = 0; if (d->ctlr->type == 2) { /* * without bit 8 we can boot without disks, but * inserted disks will never appear. :-X */ n = d->edma->sataconfig; n &= 0xff; n |= 0x9b1100; d->edma->sataconfig = n; n = d->edma->sataconfig; /* flush */ USED(n); } if(edmadisable(d, 1) == -1){ } phyerrata(d); d->bridge->sctrl = 0x301 | d->mode<<4; d->state = Dmissing; } static void edmainit(Drive *d) { int i; if(d->tx != nil) return; d->tx = xspanalloc(32*sizeof(Tx), 1024, 0); d->rx = xspanalloc(32*sizeof(Rx), 256, 0); d->prd = xspanalloc(32*sizeof(Prd), 32, 0); for(i = 0; i < 32; i++) d->tx[i].prdpa = PCIWADDR(&d->prd[i]); coherence(); } static int configdrive(Ctlr *ctlr, Drive *d, SDunit *unit) { dprint("%s: configdrive\n", unit->name); d->unit = unit; resetdisk(d); portswitch(ctlr->lmmio, d->driveno, 0, 1); delay(100); if(d->bridge->status){ dprint("%s: configdrive: found drive %lux\n", unit->name, d->bridge->status); return 0; } return -1; } static int edmaenable(Drive *d) { Edma *edma; dprint("%s: enabledrive..", dnam(d)); if((d->bridge->status & 0xf) != 3){ dprint("%s: not present\n", dnam(d)); return -1; } edma = d->edma; if(satawait(&edma->cmdstat, ATAbusy, 0, 5*1000) == 0){ dprint("%s: busy timeout\n", dnam(d)); return -1; } edma->iec = 0; d->chip->arb->ic &= ~(0x101 << d->chipx); edma->config = 0x51f; if (d->ctlr->type == 2) edma->config |= 7<<11; edma->txi = PCIWADDR(d->tx); edma->txo = (ulong)d->tx & 0x3e0; edma->rxi = (ulong)d->rx & 0xf8; edma->rxo = PCIWADDR(d->rx); edma->ctl |= 1; /* enable dma */ return 0; } static int enabledrive(Drive *d) { dprint("%s: enabledrive..", dnam(d)); if(edmaenable(d) == 0){ switch(d->bridge->status){ case 0x113: case 0x123: d->state = Dnew; break; } return 0; } print("mv50: enable reset\n"); d->state = Dreset; return -1; } static void disabledrive(Drive *d) { if(d->tx == nil) /* never enabled */ return; d->edma->ctl = 0; d->edma->iem = 0; portswitch(d->ctlr->lmmio, d->driveno, 0, 0); } static int setudmamode(Drive *d, uchar mode) { Edma *edma; dprint("%s: setudmamode %d\n", dnam(d), mode); edma = d->edma; if(edma == nil) { iprint("setudamode(m%d): zero d->edma\m", d->driveno); return 0; } if(satawait(&edma->cmdstat, ~ATAobs, ATAdrdy, 250) == 0){ iprint("%s: cmdstat 0x%.2ux ready timeout\n", dnam(d), edma->cmdstat); return 0; } edma->altstat = ATAeIEN; edma->err = 3; edma->seccnt = 0x40 | mode; edma->cmdstat = 0xef; microdelay(1); if(satawait(&edma->cmdstat, ATAbusy, 0, 5*1000) == 0){ iprint("%s: cmdstat 0x%.2ux busy timeout\n", dnam(d), edma->cmdstat); return 0; } return 1; } static int identifydrive(Drive *d) { char *s; int i; ushort *id; Edma *edma; SDunit *u; dprint("%s: identifydrive\n", dnam(d)); setfissig(d, 0); /* BOTCH; need to find and set signature */ if(setudmamode(d, 5) == 0) /* BOTCH; run after identify */ goto Error; id = d->info; memset(d->info, 0, sizeof d->info); edma = d->edma; if(satawait(&edma->cmdstat, ~ATAobs, ATAdrdy, 5*1000) == 0) goto Error; edma->altstat = ATAeIEN; /* no interrupts */ edma->cmdstat = 0xec; microdelay(1); if(satawait(&edma->cmdstat, ATAbusy, 0, 5*1000) == 0) goto Error; for(i = 0; i < 256; i++) id[i] = edma->pio; if(edma->cmdstat & ATAbad) goto Error; d->sectors = idfeat(d, id); d->secsize = idss(d, id); idmove(d->serial, id+10, 20); idmove(d->firmware, id+23, 8); idmove(d->model, id+27, 40); d->wwn = idwwn(d, id); u = d->unit; memset(u->inquiry, 0, sizeof u->inquiry); u->inquiry[2] = 2; u->inquiry[3] = 2; u->inquiry[4] = sizeof u->inquiry - 4; idmove((char*)u->inquiry+8, id+27, 40); if(enabledrive(d) == 0) { d->state = Dready; d->drivechange = 1; s = nil; if(d->feat & Dllba) s = "L"; idprint("%s: %sLBA %llud sectors\n", dnam(d), s, d->sectors); } else d->state = Derror; if(d->state == Dready) return 0; return -1; Error: dprint("error..."); d->state = Derror; return -1; } /* * p. 163: * M recovered error * P protocol error * N PhyRdy change * W CommWake * B 8-to-10 encoding error * D disparity error * C crc error * H handshake error * S link sequence error * T transport state transition error * F unrecognized fis type * X device changed */ static char stab[] = { [1] 'M', [10] 'P', [16] 'N', [18] 'W', 'B', 'D', 'C', 'H', 'S', 'T', 'F', 'X' }; static ulong sbad = 7<<20 | 3<<23; static void serrdecode(ulong r, char *s, char *e) { int i; e -= 3; for(i = 0; i < nelem(stab) && s < e; i++) if(r & 1<<i && stab[i]){ *s++ = stab[i]; if(sbad & 1<<i) *s++ = '*'; } *s = 0; } static char *iectab[] = { "ePrtDataErr", "ePrtPRDErr", "eDevErr", "eDevDis", "eDevCon", "SerrInt", "eUnderrun", "eSelfDis2", "eSelfDis", "ePrtCRQBErr", "ePrtCRPBErr", "ePrtIntErr", "eIORdyErr", }; static char* iecdecode(ulong cause) { int i; for(i = 0; i < nelem(iectab); i++) if(cause&(1<<i)) return iectab[i]; return ""; } enum{ Cerror1 = ePrtDataErr|ePrtPRDErr|eOverrun|ePrtCRQBErr|ePrtCRPBErr|ePrtIntErr, Cerror2 = ePrtDataErr|ePrtPRDErr|ePrtCRQBErr| ePrtCRPBErr|ePrtIntErr|eDevErr|eSelfDis2, }; static void updatedrive(Drive *d) { int x; ulong cause; Edma *edma; char buf[32+4+1]; edma = d->edma; if((edma->ctl & eEnEDMA) == 0){ /* FEr SATA#4 40xx */ x = d->edma->cmdstat; USED(x); } cause = edma->iec; if(cause == 0) return; dprint("%s: cause %.8lux [%s]\n", dnam(d), cause, iecdecode(cause)); if(cause & eDevCon) d->state = Dnew; if(cause & eDevDis && d->state == Dready) iprint("%s: pulled: st=%.8lux\n", dnam(d), cause); switch(d->ctlr->type){ case 1: if(cause & eUnderrun){ /* FEr SATA#5 50xx for revs A0, B0 */ if(d->ctlr->rid < 2) d->state = Dreset; else{ d->state = Derror; dprint("%s: underrun\n", dnam(d)); } } if(cause & (eDevErr | eSelfDis)){ /* * FEr SATA#7 60xx for refs A0, B0 * check for IRC error. we only check the * ABORT flag as we don't get the upper nibble */ if(d->ctlr->rid < 2) if(edma->altstat & ATAerr && edma->err & ATAabort) d->state = Dreset; else d->state = Derror; } if(cause & Cerror1) d->state = Dreset; break; case 2: if(cause & Cerror2) d->state = Dreset; if(cause & SerrInt){ serrdecode(d->bridge->serror, buf, buf+sizeof buf); dprint("%s: serror %.8lux [%s]\n", dnam(d), d->bridge->serror, buf); d->bridge->serror = ~0; /*d->bridge->serror;*/ } break; } edma->iec = ~cause; } /* * Requests */ static Srb* srbrw(int rw, Drive *d, uchar *data, uint sectors, uvlong lba) { int i; Srb *srb; static uchar cmd[2][2] = { 0xC8, 0x25, 0xCA, 0x35 }; srb = allocsrb(); srb->req = rw; srb->drive = d; srb->blockno = lba; srb->sectors = sectors; srb->count = sectors * d->secsize; srb->flag = 0; srb->data = data; for(i=0; i<6; i++) srb->lba[i] = lba >> 8*i; srb->cmd = cmd[srb->req!=SDread][(d->feat&Dllba)!=0]; return srb; } #define CMD(r, v) (((r)<<8) | (v)) static void mvsatarequest(ushort *cmd, Srb *srb, int llba) { *cmd++ = CMD(ARseccnt, 0); *cmd++ = CMD(ARseccnt, srb->sectors); *cmd++ = CMD(ARfea, 0); if(llba){ *cmd++ = CMD(ARlba0, srb->lba[3]); *cmd++ = CMD(ARlba0, srb->lba[0]); *cmd++ = CMD(ARlba1, srb->lba[4]); *cmd++ = CMD(ARlba1, srb->lba[1]); *cmd++ = CMD(ARlba2, srb->lba[5]); *cmd++ = CMD(ARlba2, srb->lba[2]); *cmd++ = CMD(ARdev, 0xe0); }else{ *cmd++ = CMD(ARlba0, srb->lba[0]); *cmd++ = CMD(ARlba1, srb->lba[1]); *cmd++ = CMD(ARlba2, srb->lba[2]); *cmd++ = CMD(ARdev, srb->lba[3] | 0xe0); } *cmd = CMD(ARcmd, srb->cmd) | 1<<15; } static uintptr advance(uintptr pa, int shift) { int n, mask; mask = 0x1F<<shift; n = (pa & mask) + (1<<shift); return (pa & ~mask) | (n & mask); } static void startsrb(Drive *d, Srb *srb) { int i; Edma *edma; Prd *prd; Tx *tx; if(d->nsrb >= nelem(d->srb)){ srb->next = nil; if(d->srbhead) d->srbtail->next = srb; else d->srbhead = srb; d->srbtail = srb; return; } d->nsrb++; for(i=0; i<nelem(d->srb); i++) if(d->srb[i] == nil) break; if(i == nelem(d->srb)) panic("sdmv50xx: no free srbs"); d->intick = Ticks; d->srb[i] = srb; edma = d->edma; tx = (Tx*)KADDR(edma->txi); tx->flag = i<<1 | (srb->req == SDread); prd = KADDR(tx->prdpa); prd->pa = PCIWADDR(srb->data); prd->count = srb->count; prd->flag = PRDeot; mvsatarequest(tx->regs, srb, d->feat&Dllba); coherence(); edma->txi = advance(edma->txi, 5); d->intick = Ticks; } enum{ Rpidx = 0x1f<<3, }; static void completesrb(Drive *d) { Edma *edma; Rx *rx; Srb *srb; edma = d->edma; if((edma->ctl & eEnEDMA) == 0) return; while((edma->rxo&Rpidx) != (edma->rxi&Rpidx)){ rx = (Rx*)KADDR(edma->rxo); if(srb = d->srb[rx->cid]){ d->srb[rx->cid] = nil; d->nsrb--; if(rx->cDevSts & ATAbad) srb->flag |= SFerror; if (rx->cEdmaSts) iprint("cEdmaSts: %02ux\n", rx->cEdmaSts); srb->sta = rx->cDevSts; srb->flag |= SFdone; wakeup(srb); }else iprint("srb missing\n"); edma->rxo = advance(edma->rxo, 3); if(srb = d->srbhead){ d->srbhead = srb->next; startsrb(d, srb); } } } static int srbdone(void *v) { Srb *srb; srb = v; return srb->flag & SFdone; } /* * Interrupts */ static void mv50interrupt(Ureg*, void *v) { int i; ulong cause, tk0, m; Arb *a; Ctlr *ctlr; Drive *drive; static uint st; ctlr = v; ilock(ctlr); cause = ctlr->lmmio[0x1d60/4]; // dprint("sd%c: mv50interrupt: %.8lux\n", ctlr->sdev->idno, cause); for(i=0; cause && i<ctlr->ndrive; i++) if(cause & (3<<(i*2+i/4))){ drive = &ctlr->drive[i]; if(drive->edma == 0) continue; /* not ready yet. */ ilock(drive); updatedrive(drive); tk0 = Ticks; a = ctlr->chip[i/4].arb; m = 0x0101 << i%4; while(a->ic & m){ a->ic = ~m; completesrb(drive); if(TK2MS(Ticks - tk0) > 3000){ print("%s: irq wedge\n", dnam(drive)); drive->state = Dreset; break; } } iunlock(drive); } iunlock(ctlr); } enum{ Nms = 256, Midwait = 16*1024/Nms - 1, Mphywait = 512/Nms - 1, }; static void hangck(Drive *d) { Edma *e; e = d->edma; if(d->nsrb > 0 && TK2MS(Ticks - d->intick) > 5*1000 && (e->rxo&Rpidx) == (e->rxi&Rpidx)){ print("%s: drive hung; resetting\n", dnam(d)); d->state = Dreset; } } static void checkdrive(Drive *d, int i) { static ulong s, olds[NCtlr*NCtlrdrv]; ilock(d); s = d->bridge->status; if(s != olds[i]){ dprint("%s: status: %.8lux -> %.8lux: %s\n", dnam(d), olds[i], s, diskstates[d->state]); olds[i] = s; } hangck(d); switch(d->state){ case Dnew: case Dmissing: switch(s){ case 0x000: break; default: dprint("%s: unknown state %.8lux\n", dnam(d), s); case 0x100: if(++d->wait&Mphywait) break; reset: d->mode ^= 1; dprint("%s: reset; new mode %d\n", dnam(d), d->mode); resetdisk(d); break; case 0x123: case 0x113: s = d->edma->cmdstat; if(s == 0x7f || (s&~ATAobs) != ATAdrdy){ if((++d->wait&Midwait) == 0) goto reset; }else if(identifydrive(d) == -1) goto reset; } break; case Dready: if(s != 0) break; iprint("%s: pulled: st=%.8lux\n", dnam(d), s); /* never happens */ case Dreset: case Derror: dprint("%s reset: mode %d\n", dnam(d), d->mode); resetdisk(d); break; } iunlock(d); } static void satakproc(void*) { int i; while(waserror()) ; for(;;){ tsleep(&up->sleep, return0, 0, Nms); for(i = 0; i < nmvsatadrive; i++) checkdrive(mvsatadrive[i], i); } } static void initdrive(Drive *d) { edmainit(d); d->mode = DMsatai; if(d->ctlr->type == 1){ d->edma->iem = IEM; d->bridge = &d->chip->arb->bridge[d->chipx]; }else{ d->edma->iem = IEM2; d->bridge = &d->chip->edma[d->chipx].port; // d->edma->iem = ~(1<<6); d->pm2 = Dpreamp; if(d->ctlr->lmmio[0x180d8/4] & 1) d->pm2 = d->bridge->phymode2 & Mpreamp; } } static SDev* mv50pnp(void) { int i, nunit; uchar *base; ulong io, n, *mem; Ctlr *ctlr; Drive *d; Pcidev *p; SDev *head, *tail, *sdev; static int ctlrno, done; if(done++) return nil; p = nil; head = nil; tail = nil; while((p = pcimatch(p, 0x11ab, 0)) != nil){ if(p->ccrb != Pcibcstore || p->ccru + p->ccrp || p->did&0x0f00) continue; switch(p->did){ case 0x5040: case 0x5041: case 0x5080: case 0x5081: case 0x6041: case 0x6081: break; default: print("mv50pnp: unknown did %ux ignored\n", (ushort)p->did); continue; } if (ctlrno >= NCtlr) { print("mv50pnp: too many controllers\n"); break; } nunit = (p->did&0xf0) >> 4; print("#S/sd%c: Marvell 88sx%ux: %d sata-%s ports with%s flash\n", 'E' + ctlrno, (ushort)p->did, nunit, ((p->did&0xf000)==0x6000? "II": "I"), (p->did&1? "": "out")); if((sdev = malloc(sizeof *sdev)) == nil) continue; if((ctlr = malloc(sizeof *ctlr)) == nil){ free(sdev); continue; } io = p->mem[0].bar & ~0x0F; mem = (ulong*)vmap(io, p->mem[0].size); if(mem == 0){ print("sdmv50xx: address 0x%luX in use\n", io); free(sdev); free(ctlr); continue; } ctlr->rid = p->rid; /* avert thine eyes! (what does this do?) */ mem[0x104f0/4] = 0; ctlr->type = (p->did >> 12) & 3; if(ctlr->type == 1){ n = mem[0xc00/4]; n &= ~(3<<4); mem[0xc00/4] = n; } sdev->ifc = &sdmv50xxifc; sdev->ctlr = ctlr; sdev->nunit = nunit; sdev->idno = 'E'; ctlr->sdev = sdev; ctlr->irq = p->intl; ctlr->tbdf = p->tbdf; ctlr->pcidev = p; ctlr->lmmio = mem; ctlr->mmio = (uchar*)mem; ctlr->nchip = (nunit+3)/4; ctlr->ndrive = nunit; ctlr->enabled = 0; for(i = 0; i < ctlr->nchip; i++){ base = ctlr->mmio+0x20000+0x10000*i; ctlr->chip[i].arb = (Arb*)base; ctlr->chip[i].edma = (Edma*)(base + 0x2000); } for (i = 0; i < nunit; i++) { d = &ctlr->drive[i]; snprint(d->name, sizeof d->name, "mv50%d.%d", ctlrno, i); d->sectors = 0; d->ctlr = ctlr; d->driveno = ctlrno*NCtlrdrv + i; d->chipx = i%4; d->chip = &ctlr->chip[i/4]; d->edma = &d->chip->edma[d->chipx]; mvsatadrive[d->driveno] = d; initdrive(d); } mvsatactlr[ctlrno] = ctlr; nmvsatadrive += nunit; ctlrno++; if(head) tail->next = sdev; else head = sdev; tail = sdev; } return head; } static int mv50enable(SDev *sdev) { char name[32]; Ctlr *ctlr; dprint("sd%c: enable\n", sdev->idno); ctlr = sdev->ctlr; if (ctlr->enabled) return 1; ctlr->enabled = 1; kproc("mvsata", satakproc, 0); snprint(name, sizeof name, "%s (%s)", sdev->name, sdev->ifc->name); intrenable(ctlr->irq, mv50interrupt, ctlr, ctlr->tbdf, name); return 1; } static int mv50disable(SDev *sdev) { char name[32]; int i; Ctlr *ctlr; Drive *drive; dprint("sd%c: disable\n", sdev->idno); ctlr = sdev->ctlr; ilock(ctlr); for(i=0; i<ctlr->sdev->nunit; i++){ drive = &ctlr->drive[i]; ilock(drive); disabledrive(drive); iunlock(drive); } iunlock(ctlr); snprint(name, sizeof name, "%s (%s)", sdev->name, sdev->ifc->name); intrdisable(ctlr->irq, mv50interrupt, ctlr, ctlr->tbdf, name); return 0; } /* * Check that there is a disk or at least a hot swap bay in the drive. */ static int mv50verify(SDunit *unit) { Ctlr *ctlr; Drive *drive; int i; dprint("%s: verify\n", unit->name); ctlr = unit->dev->ctlr; drive = &ctlr->drive[unit->subno]; ilock(ctlr); ilock(drive); i = configdrive(ctlr, drive, unit); iunlock(drive); iunlock(ctlr); /* * If ctlr->type == 1, then the drives spin up whenever * the controller feels like it; if ctlr->type == 2, then * they spin up as a result of configdrive. * * If there is a drive in the slot, give it 1.4s to spin up * before returning. There is a noticeable drag on the * power supply when spinning up fifteen drives * all at once (like in the Coraid enclosures). */ if(ctlr->type == 2 && i == 0) if(!waserror()){ tsleep(&up->sleep, return0, 0, 1400); poperror(); } return 1; } /* * Check whether the disk is online. */ static int mv50online(SDunit *unit) { Ctlr *ctlr; Drive *d; int r, s0; static int once; ctlr = unit->dev->ctlr; d = &ctlr->drive[unit->subno]; r = 0; ilock(d); s0 = d->state; USED(s0); if(d->state == Dnew) identifydrive(d); if(d->drivechange){ idprint("%s: online: %s -> %s\n", unit->name, diskstates[s0], diskstates[d->state]); r = 2; unit->sectors = d->sectors; unit->secsize = d->secsize; d->drivechange = 0; } else if(d->state == Dready) r = 1; iunlock(d); return r; } /* * Register dumps */ typedef struct Regs Regs; struct Regs { ulong offset; char *name; }; static Regs regsctlr[] = { 0x0C28, "pci serr# mask", 0x1D40, "pci err addr low", 0x1D44, "pci err addr hi", 0x1D48, "pci err attr", 0x1D50, "pci err cmd", 0x1D58, "pci intr cause", 0x1D5C, "pci mask cause", 0x1D60, "device micr", 0x1D64, "device mimr", }; static Regs regsarb[] = { 0x0004, "arb rqop", 0x0008, "arb rqip", 0x000C, "arb ict", 0x0010, "arb itt", 0x0014, "arb ic", 0x0018, "arb btc", 0x001C, "arb bts", 0x0020, "arb bpc", }; static Regs regsbridge[] = { 0x0000, "bridge status", 0x0004, "bridge serror", 0x0008, "bridge sctrl", 0x000C, "bridge phyctrl", 0x003C, "bridge ctrl", 0x0074, "bridge phymode", }; static Regs regsedma[] = { 0x0000, "edma config", 0x0004, "edma timer", 0x0008, "edma iec", 0x000C, "edma iem", 0x0010, "edma txbasehi", 0x0014, "edma txi", 0x0018, "edma txo", 0x001C, "edma rxbasehi", 0x0020, "edma rxi", 0x0024, "edma rxo", 0x0028, "edma c", 0x002C, "edma tc", 0x0030, "edma status", 0x0034, "edma iordyto", /* 0x0100, "edma pio", 0x0104, "edma err", 0x0108, "edma sectors", 0x010C, "edma lba0", 0x0110, "edma lba1", 0x0114, "edma lba2", 0x0118, "edma lba3", 0x011C, "edma cmdstat", 0x0120, "edma altstat", */ }; static char* rdregs(char *p, char *e, void *base, Regs *r, int n, char *prefix) { int i; for(i=0; i<n; i++) p = seprint(p, e, "%s%s%-19s %.8ux\n", prefix ? prefix : "", prefix ? ": " : "", r[i].name, *(u32int*)((uchar*)base+r[i].offset)); return p; } static int mv50rctl(SDunit *unit, char *p, int l) { char *e, *op; Ctlr *ctlr; Drive *drive; if((ctlr = unit->dev->ctlr) == nil) return 0; drive = &ctlr->drive[unit->subno]; e = p+l; op = p; if(drive->state == Dready){ p = seprint(p, e, "model %s\n", drive->model); p = seprint(p, e, "serial %s\n", drive->serial); p = seprint(p, e, "firmware %s\n", drive->firmware); p = seprint(p, e, "wwn\t%llux\n", drive->wwn); p = seprint(p, e, "flag\t"); p = pflag(p, e, drive); }else p = seprint(p, e, "no disk present\n"); p = seprint(p, e, "geometry %llud %ud\n", drive->sectors, drive->secsize); p = rdregs(p, e, drive->bridge, regsbridge, nelem(regsbridge), nil); if(0){ p = rdregs(p, e, drive->chip->arb, regsarb, nelem(regsarb), nil); p = rdregs(p, e, drive->bridge, regsbridge, nelem(regsbridge), nil); p = rdregs(p, e, drive->edma, regsedma, nelem(regsedma), nil); } return p-op; } static int mv50wctl(SDunit *unit, Cmdbuf *cb) { Ctlr *ctlr; Drive *drive; if(strcmp(cb->f[0], "reset") == 0){ ctlr = unit->dev->ctlr; drive = &ctlr->drive[unit->subno]; ilock(drive); drive->state = Dreset; iunlock(drive); return 0; } cmderror(cb, Ebadctl); return -1; } static int waitready(Drive *d) { ulong s, i; for(i = 0; i < 120; i++){ ilock(d); s = d->bridge->status; iunlock(d); if(s == 0) return SDeio; if(d->state == Dready) return SDok; if((i+1)%60 == 0){ ilock(d); resetdisk(d); iunlock(d); } if(!waserror()){ tsleep(&up->sleep, return0, 0, 1000); poperror(); } } print("%s: not responding; error\n", dnam(d)); return SDeio; } static long mv50bio(SDunit *u, int /*lun*/, int write, void *a, long count, uvlong lba) { int n, try, flag; uchar *data; Ctlr *ctlr; Drive *d; Srb *srb; ctlr = u->dev->ctlr; d = ctlr->drive + u->subno; try = 0; data = a; retry: if(waitready(d) != SDok) return -1; while(count > 0){ /* * Max is 128 sectors (64kB) because prd->count is 16 bits. */ n = count; if(n > 128) n = 128; ilock(d); if((d->edma->ctl&eEnEDMA) == 0 && edmaenable(d) == -1){ iunlock(d); goto tryagain; } srb = srbrw(write, d, data, n, lba); startsrb(d, srb); iunlock(d); while(waserror()) ; sleep(srb, srbdone, srb); poperror(); flag = srb->flag; freesrb(srb); if(flag == 0){ tryagain: if(++try == 10){ print("%s: bad disk\n", dnam(d)); return -1; } dprint("%s: retry\n", dnam(d)); goto retry; } if(flag & SFerror){ print("%s: i/o error\n", dnam(d)); return -1; } count -= n; lba += n; data += n*u->secsize; } return data - (uchar*)a; } static int mv50rio(SDreq *r) { int count, n, status, rw; uvlong lba; Ctlr *ctlr; Drive *d; SDunit *unit; unit = r->unit; ctlr = unit->dev->ctlr; d = &ctlr->drive[unit->subno]; if((status = sdfakescsi(r)) != SDnostatus) return r->status = status; if((status = sdfakescsirw(r, &lba, &count, &rw)) == SDcheck) return status; n = mv50bio(r->unit, r->lun, rw, r->data, count, lba); if(n == -1) return SDeio; r->rlen = n; return SDok; } static void mkrfis(SDreq *r, Drive *d, Edma *e) { uchar *u; u = r->cmd; u[Ftype] = 0x34; u[Fioport] = 0; if((d->feat & Dllba) && (r->ataproto & P28) == 0){ u[Frerror] = e->err; u[Fsc8] = e->seccnt; u[Fsc] = e->seccnt; u[Flba24] = e->lba0; u[Flba0] = e->lba0; u[Flba32] = e->lba1; u[Flba8] = e->lba1; u[Flba40] = e->lba2; u[Flba16] = e->lba2; u[Fdev] = e->lba3; u[Fstatus] = e->cmdstat; }else{ u[Frerror] = e->err; u[Fsc] = e->seccnt; u[Flba0] = e->lba0; u[Flba8] = e->lba1; u[Flba16] = e->lba2; u[Fdev] = e->lba3; u[Fstatus] = e->cmdstat; } } static int piocmd(SDreq *r, Drive *d) { uchar *p, *c; int n, nsec, i, err; Edma *e; SDunit *u; u = r->unit; if(waitready(d) != SDok) return SDeio; nsec = 0; if(u->secsize != 0) nsec = r->dlen / u->secsize; if(r->dlen < nsec*u->secsize) nsec = r->dlen/u->secsize; if(nsec > 256) error("can't do more than 256 sectors"); ilock(d); e = d->edma; if(edmadisable(d, 0) == -1) { iunlock(d); error("can't disable edma"); } n = satawait(&e->cmdstat, ATAdrdy|ATAbusy, ATAdrdy, 3*1000); if(n == 0) { print("piocmd: notready %.2ux\n", e->cmdstat); iunlock(d); return sdsetsense(r, SDcheck, 4, 8, 0); } c = r->cmd; if(r->ataproto & P28){ e->altstat = ATAeIEN; e->seccnt = c[Fsc]; e->err = c[Ffeat]; e->lba0 = c[Flba0]; e->lba1 = c[Flba8]; e->lba2 = c[Flba16]; e->lba3 = c[Fdev]; e->cmdstat = c[Fcmd]; }else{ e->altstat = ATAeIEN; e->seccnt = c[Fsc8]; e->seccnt = c[Fsc]; e->err = c[Ffeat]; e->lba0 = c[Flba24]; e->lba0 = c[Flba0]; e->lba1 = c[Flba32]; e->lba1 = c[Flba8]; e->lba1 = c[Flba40]; e->lba2 = c[Flba16]; e->lba3 = c[Fdev]; e->cmdstat = c[Fcmd]; } err = 0; if((r->ataproto & Pdatam) == Pnd) n = satawait(&e->cmdstat, ATAbusy, 0, 3*1000); else n = satawait(&e->cmdstat, ATAbusy|ATAdrq, ATAdrq, 3*1000); if(n == 0 || e->cmdstat & ATAerr){ err = 1; goto lose; } p = r->data; for(; nsec > 0; nsec--) for (i = 0; i < u->secsize; i += 2) { n = satawait(&e->cmdstat, ATAbusy|ATAdrq, ATAdrq, 300); if (n == 0) { d->state = Dreset; err = 1; goto lose; } if(r->ataproto & Pout){ n = (ushort)p[i + 1] << 8; e->pio = n | p[i]; } else { n = e->pio; p[i] = n; p[i + 1] = n >> 8; } microdelay(1); } lose: if(nsec == 0) r->rlen = r->dlen; mkrfis(r, d, e); iunlock(d); if(err) return sdsetsense(r, SDcheck, 4, 8, 0); else return sdsetsense(r, SDok, 0, 0, 0); } /* * hack to allow udma mode to be set or unset * via direct ata command. it would be better * to move the assumptions about dma mode out * of some of the helper functions. */ static int isudm(SDreq *r) { uchar *c; c = r->cmd; if(c[Fcmd] == 0xef && c[Ffeat] == 0x03){ if(c[Fsc]&0x40) return 1; return -1; } return 0; } static int fisreqchk(Sfis *f, SDreq *r) { if((r->ataproto & Pprotom) == Ppkt) return SDnostatus; /* * handle oob requests; * restrict & sanitize commands */ if(r->clen != 16) error(Eio); if(r->cmd[0] == 0xf0){ sigtofis(f, r->cmd); r->status = SDok; return SDok; } r->cmd[0] = 0x27; r->cmd[1] = 0x80; r->cmd[7] |= 0xa0; return SDnostatus; } static int badf(SDreq *r, Drive*) { print("badf %.2ux %2ux\n", r->cmd[2], r->ataproto); return sdsetsense(r, SDcheck, 2, 24, 0); } static int ataio0(SDreq *r, Drive *d) { int (*f)(SDreq*, Drive*); f = badf; switch(r->ataproto & Pprotom){ default: break; case Ppio: case Pnd: f = piocmd; break; } return f(r, d); } static int mv50ata(SDreq *r) { int status, udm; Ctlr *c; Drive *d; SDunit *u; u = r->unit; c = u->dev->ctlr; d = c->drive + u->subno; if((status = fisreqchk(d, r)) != SDnostatus) return status; udm = isudm(r); USED(udm); /* botch */ // qlock(d); if(waserror()){ // qunlock(d); nexterror(); } retry: switch(status = ataio0(r, d)){ default: dprint("%s: status %d\n", dnam(d), status); break; case SDretry: dprint("%s: retry\n", dnam(d)); goto retry; case SDok: sdsetsense(r, SDok, 0, 0, 0); break; } poperror(); // qunlock(d); return r->status = status; } SDifc sdmv50xxifc = { "mv50xx", /* name */ mv50pnp, /* pnp */ nil, /* legacy */ mv50enable, /* enable */ mv50disable, /* disable */ mv50verify, /* verify */ mv50online, /* online */ mv50rio, /* rio */ mv50rctl, /* rctl */ mv50wctl, /* wctl */ mv50bio, /* bio */ nil, /* probe */ nil, /* clear */ nil, /* rtopctl */ nil, mv50ata, }; /* * The original driver on which this one is based came with the * following notice: * * Copyright 2005 * Coraid, Inc. * * This software is provided `as-is,' without any express or implied * warranty. In no event will the author be held liable for any damages * arising from the use of this software. * * Permission is granted to anyone to use this software for any purpose, * including commercial applications, and to alter it and redistribute it * freely, subject to the following restrictions: * * 1. The origin of this software must not be misrepresented; you must * not claim that you wrote the original software. If you use this * software in a product, an acknowledgment in the product documentation * would be appreciated but is not required. * * 2. Altered source versions must be plainly marked as such, and must * not be misrepresented as being the original software. * * 3. This notice may not be removed or altered from any source * distribution. */