ref: 37e65b331bdf98f409be1bd2fbb55aec158c7877
dir: /sys/src/9/pc/sd53c8xx.c/
/* * NCR/Symbios/LSI Logic 53c8xx driver for Plan 9 * Nigel Roles (nigel@9fs.org) * * 27/5/02 Fixed problems with transfers >= 256 * 512 * * 13/3/01 Fixed microcode to support targets > 7 * * 01/12/00 Removed previous comments. Fixed a small problem in * mismatch recovery for targets with synchronous offsets of >=16 * connected to >=875s. Thanks, Jean. * * Known problems * * Read/write mismatch recovery may fail on 53c1010s. Really need to get a manual. */ #define MAXTARGET 16 /* can be 8 or 16 */ #include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "io.h" #include "../port/pci.h" #include "../port/sd.h" extern SDifc sd53c8xxifc; /**********************************/ /* Portable configuration macros */ /**********************************/ #define WMR_DEBUG /**********************************/ /* CPU specific macros */ /**********************************/ #define PRINTPREFIX "sd53c8xx: " static int idebug = 0; #define KPRINT if(0) iprint #define IPRINT if(idebug) iprint #define DEBUG(n) (0) #define IFLUSH() /*******************************/ /* General */ /*******************************/ #define DMASEG(x) PCIWADDR(x) #define legetl(x) (*(ulong*)(x)) #define lesetl(x,v) (*(ulong*)(x) = (v)) #define swabl(a,b,c) #define DMASEG_TO_PADDR(x) ((uintptr)(x)-PCIWINDOW) #define DMASEG_TO_KADDR(x) KADDR(DMASEG_TO_PADDR(x)) #define KPTR(x) (((x) == 0) ? nil : DMASEG_TO_KADDR(x)) #define MEGA 1000000L #ifdef INTERNAL_SCLK #define SCLK (33 * MEGA) #else #define SCLK (40 * MEGA) #endif /* INTERNAL_SCLK */ #define ULTRA_NOCLOCKDOUBLE_SCLK (80 * MEGA) #define MAXSYNCSCSIRATE (5 * MEGA) #define MAXFASTSYNCSCSIRATE (10 * MEGA) #define MAXULTRASYNCSCSIRATE (20 * MEGA) #define MAXULTRA2SYNCSCSIRATE (40 * MEGA) #define MAXASYNCCORERATE (25 * MEGA) #define MAXSYNCCORERATE (25 * MEGA) #define MAXFASTSYNCCORERATE (50 * MEGA) #define MAXULTRASYNCCORERATE (80 * MEGA) #define MAXULTRA2SYNCCORERATE (160 * MEGA) #define X_MSG 1 #define X_MSG_SDTR 1 #define X_MSG_WDTR 3 struct na_patch { unsigned lwoff; unsigned char type; }; typedef struct Ncr { uchar scntl0; /* 00 */ uchar scntl1; uchar scntl2; uchar scntl3; uchar scid; /* 04 */ uchar sxfer; uchar sdid; uchar gpreg; uchar sfbr; /* 08 */ uchar socl; uchar ssid; uchar sbcl; uchar dstat; /* 0c */ uchar sstat0; uchar sstat1; uchar sstat2; uchar dsa[4]; /* 10 */ uchar istat; /* 14 */ uchar istatpad[3]; uchar ctest0; /* 18 */ uchar ctest1; uchar ctest2; uchar ctest3; uchar temp[4]; /* 1c */ uchar dfifo; /* 20 */ uchar ctest4; uchar ctest5; uchar ctest6; uchar dbc[3]; /* 24 */ uchar dcmd; /* 27 */ uchar dnad[4]; /* 28 */ uchar dsp[4]; /* 2c */ uchar dsps[4]; /* 30 */ uchar scratcha[4]; /* 34 */ uchar dmode; /* 38 */ uchar dien; uchar dwt; uchar dcntl; uchar adder[4]; /* 3c */ uchar sien0; /* 40 */ uchar sien1; uchar sist0; uchar sist1; uchar slpar; /* 44 */ uchar slparpad0; uchar macntl; uchar gpcntl; uchar stime0; /* 48 */ uchar stime1; uchar respid; uchar respidpad0; uchar stest0; /* 4c */ uchar stest1; uchar stest2; uchar stest3; uchar sidl; /* 50 */ uchar sidlpad[3]; uchar sodl; /* 54 */ uchar sodlpad[3]; uchar sbdl; /* 58 */ uchar sbdlpad[3]; uchar scratchb[4]; /* 5c */ } Ncr; typedef struct Movedata { uchar dbc[4]; uchar pa[4]; } Movedata; typedef enum NegoState { NeitherDone, WideInit, WideResponse, WideDone, SyncInit, SyncResponse, BothDone } NegoState; typedef enum State { Allocated, Queued, Active, Done } State; typedef struct Dsa Dsa; struct Dsa { uchar stateb; uchar result; uchar dmablks; uchar flag; /* setbyte(state,3,...) */ uchar dmaaddr[4]; /* For block transfer: NCR order (little-endian) */ uchar target; /* Target */ uchar pad0[3]; uchar lun; /* Logical Unit Number */ uchar pad1[3]; uchar scntl3; /* Sync */ uchar sxfer; uchar pad2[2]; uchar next[4]; /* chaining for SCRIPT (NCR byte order) */ Dsa *freechain; /* chaining for freelist */ Rendez; uchar scsi_id_buf[4]; Movedata msg_out_buf; Movedata cmd_buf; Movedata data_buf; Movedata status_buf; uchar msg_out[10]; /* enough to include SDTR */ uchar status; int p9status; uchar parityerror; }; typedef enum Feature { BigFifo = 1, /* 536 byte fifo */ BurstOpCodeFetch = 2, /* burst fetch opcodes */ Prefetch = 4, /* prefetch 8 longwords */ LocalRAM = 8, /* 4K longwords of local RAM */ Differential = 16, /* Differential support */ Wide = 32, /* Wide capable */ Ultra = 64, /* Ultra capable */ ClockDouble = 128, /* Has clock doubler */ ClockQuad = 256, /* Has clock quadrupler (same as Ultra2) */ Ultra2 = 256, } Feature; typedef enum Burst { Burst2 = 0, Burst4 = 1, Burst8 = 2, Burst16 = 3, Burst32 = 4, Burst64 = 5, Burst128 = 6 } Burst; typedef struct Variant { ushort did; uchar maxrid; /* maximum allowed revision ID */ char *name; Burst burst; /* codings for max burst */ uchar maxsyncoff; /* max synchronous offset */ uchar registers; /* number of 32 bit registers */ unsigned feature; } Variant; static unsigned char cf2[] = { 6, 2, 3, 4, 6, 8, 12, 16 }; #define NULTRA2SCF (sizeof(cf2)/sizeof(cf2[0])) #define NULTRASCF (NULTRA2SCF - 2) #define NSCF (NULTRASCF - 1) typedef struct Controller { Lock; struct { uchar scntl3; uchar stest2; } bios; uchar synctab[NULTRA2SCF - 1][8];/* table of legal tpfs */ NegoState s[MAXTARGET]; uchar scntl3[MAXTARGET]; uchar sxfer[MAXTARGET]; uchar cap[MAXTARGET]; /* capabilities byte from Identify */ ushort capvalid; /* bit per target for validity of cap[] */ ushort wide; /* bit per target set if wide negotiated */ ulong sclk; /* clock speed of controller */ uchar clockmult; /* set by synctabinit */ uchar ccf; /* CCF bits */ uchar tpf; /* best tpf value for this controller */ uchar feature; /* requested features */ int running; /* is the script processor running? */ int ssm; /* single step mode */ Ncr *n; /* pointer to registers */ Variant *v; /* pointer to variant type */ ulong *script; /* where the real script is */ ulong scriptpa; /* where the real script is */ Pcidev* pcidev; SDev* sdev; struct { Lock; uchar head[4]; /* head of free list (NCR byte order) */ Dsa *freechain; } dsalist; QLock q[MAXTARGET]; /* queues for each target */ } Controller; #define SYNCOFFMASK(c) (((c)->v->maxsyncoff * 2) - 1) #define SSIDMASK(c) (((c)->v->feature & Wide) ? 15 : 7) /* ISTAT */ enum { Abrt = 0x80, Srst = 0x40, Sigp = 0x20, Sem = 0x10, Con = 0x08, Intf = 0x04, Sip = 0x02, Dip = 0x01 }; /* DSTAT */ enum { Dfe = 0x80, Mdpe = 0x40, Bf = 0x20, Abrted = 0x10, Ssi = 0x08, Sir = 0x04, Iid = 0x01 }; /* SSTAT */ enum { DataOut, DataIn, Cmd, Status, ReservedOut, ReservedIn, MessageOut, MessageIn }; static void setmovedata(Movedata*, ulong, ulong); static void advancedata(Movedata*, long); static int bios_set_differential(Controller *c); static char *phase[] = { "data out", "data in", "command", "status", "reserved out", "reserved in", "message out", "message in" }; #ifdef BOOTDEBUG #define DEBUGSIZE 10240 char debugbuf[DEBUGSIZE]; char *debuglast; static void intrprint(char *format, ...) { if (debuglast == 0) debuglast = debugbuf; debuglast = vseprint(debuglast, debugbuf + (DEBUGSIZE - 1), format, (&format + 1)); } static void iflush() { int s; char *endp; s = splhi(); if (debuglast == 0) debuglast = debugbuf; if (debuglast == debugbuf) { splx(s); return; } endp = debuglast; splx(s); screenputs(debugbuf, endp - debugbuf); s = splhi(); memmove(debugbuf, endp, debuglast - endp); debuglast -= endp - debugbuf; splx(s); } static void oprint(char *format, ...) { int s; iflush(); s = splhi(); if (debuglast == 0) debuglast = debugbuf; debuglast = vseprint(debuglast, debugbuf + (DEBUGSIZE - 1), format, (&format + 1)); splx(s); iflush(); } #endif #include "../pc/sd53c8xx.i" /* * We used to use a linked list of Dsas with nil as the terminator, * but occasionally the 896 card seems not to notice that the 0 * is really a 0, and then it tries to reference the Dsa at address 0. * To address this, we use a sentinel dsa that links back to itself * and has state A_STATE_END. If the card takes an iteration or * two to notice that the state says A_STATE_END, that's no big * deal. Clearly this isn't the right approach, but I'm just * stumped. Even with this, we occasionally get prints about * "WSR set", usually with about the same frequency that the * card used to walk past 0. */ static Dsa *dsaend; static Dsa * dsaalloc(Controller *c, int target, int lun) { Dsa *d; ilock(&c->dsalist); if ((d = c->dsalist.freechain) != nil) { c->dsalist.freechain = d->freechain; d->freechain = nil; if (DEBUG(1)) IPRINT(PRINTPREFIX "%d/%d: reused dsa %#p\n", target, lun, d); } else { /* c->dsalist must be ilocked */ d = xalloc(sizeof *d); if (d == nil) panic("sd53c8xx dsaallocnew: no memory"); d->freechain = nil; lesetl(d->next, legetl(c->dsalist.head)); lesetl(&d->stateb, A_STATE_FREE); coherence(); lesetl(c->dsalist.head, DMASEG(d)); coherence(); if (DEBUG(1)) IPRINT(PRINTPREFIX "%d/%d: allocated dsa %#p\n", target, lun, d); } lesetl(&d->stateb, A_STATE_ALLOCATED); iunlock(&c->dsalist); d->target = target; d->lun = lun; return d; } static void dsafree(Controller *c, Dsa *d) { ilock(&c->dsalist); d->freechain = c->dsalist.freechain; c->dsalist.freechain = d; lesetl(&d->stateb, A_STATE_FREE); iunlock(&c->dsalist); } static void dsadump(Controller *c) { Dsa *d; u32int *a; iprint("dsa controller list: c=%p head=%.8lux\n", c, legetl(c->dsalist.head)); for(d=KPTR(legetl(c->dsalist.head)); d != nil && d != dsaend; d=KPTR(legetl(d->next))){ a = (u32int*)d; iprint("\tdsa %p %.8ux %.8ux %.8ux %.8ux %.8ux %.8ux\n", a, a[0], a[1], a[2], a[3], a[4], a[5]); } /* a = KPTR(c->scriptpa+E_dsa_addr); iprint("dsa_addr: %.8ux %.8ux %.8ux %.8ux %.8ux\n", a[0], a[1], a[2], a[3], a[4]); a = KPTR(c->scriptpa+E_issue_addr); iprint("issue_addr: %.8ux %.8ux %.8ux %.8ux %.8ux\n", a[0], a[1], a[2], a[3], a[4]); a = KPTR(c->scriptpa+E_issue_test_begin); e = KPTR(c->scriptpa+E_issue_test_end); iprint("issue_test code (at offset %.8ux):\n", E_issue_test_begin); i = 0; for(; a<e; a++){ iprint(" %.8ux", *a); if(++i%8 == 0) iprint("\n"); } if(i%8) iprint("\n"); */ } static Dsa * dsafind(Controller *c, uchar target, uchar lun, uchar state) { Dsa *d; for (d = KPTR(legetl(c->dsalist.head)); d != nil && d != dsaend; d = KPTR(legetl(d->next))) { if (d->target != 0xff && d->target != target) continue; if (lun != 0xff && d->lun != lun) continue; if (state != 0xff && d->stateb != state) continue; break; } return d; } static void dumpncrregs(Controller *c, int intr) { int i; Ncr *n = c->n; int depth = c->v->registers / 4; if (intr) { IPRINT("sa = %.8lux\n", c->scriptpa); } else { KPRINT("sa = %.8lux\n", c->scriptpa); } for (i = 0; i < depth; i++) { int j; for (j = 0; j < 4; j++) { int k = j * depth + i; uchar *p; /* display little-endian to make 32-bit values readable */ p = (uchar*)n+k*4; if (intr) { IPRINT(" %.2x%.2x%.2x%.2x %.2x %.2x", p[3], p[2], p[1], p[0], k * 4, (k * 4) + 0x80); } else { KPRINT(" %.2x%.2x%.2x%.2x %.2x %.2x", p[3], p[2], p[1], p[0], k * 4, (k * 4) + 0x80); } USED(p); } if (intr) { IPRINT("\n"); } else { KPRINT("\n"); } } } static int chooserate(Controller *c, int tpf, int *scfp, int *xferpp) { /* find lowest entry >= tpf */ int besttpf = 1000; int bestscfi = 0; int bestxferp = 0; int scf, xferp; int maxscf; if (c->v->feature & Ultra2) maxscf = NULTRA2SCF; else if (c->v->feature & Ultra) maxscf = NULTRASCF; else maxscf = NSCF; /* * search large clock factors first since this should * result in more reliable transfers */ for (scf = maxscf; scf >= 1; scf--) { for (xferp = 0; xferp < 8; xferp++) { unsigned char v = c->synctab[scf - 1][xferp]; if (v == 0) continue; if (v >= tpf && v < besttpf) { besttpf = v; bestscfi = scf; bestxferp = xferp; } } } if (besttpf == 1000) return 0; if (scfp) *scfp = bestscfi; if (xferpp) *xferpp = bestxferp; return besttpf; } static void synctabinit(Controller *c) { int scf; unsigned long scsilimit; int xferp; unsigned long cr, sr; int tpf; int fast; int maxscf; if (c->v->feature & Ultra2) maxscf = NULTRA2SCF; else if (c->v->feature & Ultra) maxscf = NULTRASCF; else maxscf = NSCF; /* * for chips with no clock doubler, but Ultra capable (e.g. 860, or interestingly the * first spin of the 875), assume 80MHz * otherwise use the internal (33 Mhz) or external (40MHz) default */ if ((c->v->feature & Ultra) != 0 && (c->v->feature & (ClockDouble | ClockQuad)) == 0) c->sclk = ULTRA_NOCLOCKDOUBLE_SCLK; else c->sclk = SCLK; /* * otherwise, if the chip is Ultra capable, but has a slow(ish) clock, * invoke the doubler */ if (SCLK <= 40000000) { if (c->v->feature & ClockDouble) { c->sclk *= 2; c->clockmult = 1; } else if (c->v->feature & ClockQuad) { c->sclk *= 4; c->clockmult = 1; } else c->clockmult = 0; } else c->clockmult = 0; /* derive CCF from sclk */ /* woebetide anyone with SCLK < 16.7 or > 80MHz */ if (c->sclk <= 25 * MEGA) c->ccf = 1; else if (c->sclk <= 3750000) c->ccf = 2; else if (c->sclk <= 50 * MEGA) c->ccf = 3; else if (c->sclk <= 75 * MEGA) c->ccf = 4; else if ((c->v->feature & ClockDouble) && c->sclk <= 80 * MEGA) c->ccf = 5; else if ((c->v->feature & ClockQuad) && c->sclk <= 120 * MEGA) c->ccf = 6; else if ((c->v->feature & ClockQuad) && c->sclk <= 160 * MEGA) c->ccf = 7; for (scf = 1; scf < maxscf; scf++) { /* check for legal core rate */ /* round up so we run slower for safety */ cr = (c->sclk * 2 + cf2[scf] - 1) / cf2[scf]; if (cr <= MAXSYNCCORERATE) { scsilimit = MAXSYNCSCSIRATE; fast = 0; } else if (cr <= MAXFASTSYNCCORERATE) { scsilimit = MAXFASTSYNCSCSIRATE; fast = 1; } else if ((c->v->feature & Ultra) && cr <= MAXULTRASYNCCORERATE) { scsilimit = MAXULTRASYNCSCSIRATE; fast = 2; } else if ((c->v->feature & Ultra2) && cr <= MAXULTRA2SYNCCORERATE) { scsilimit = MAXULTRA2SYNCSCSIRATE; fast = 3; } else continue; for (xferp = 11; xferp >= 4; xferp--) { int ok; int tp; /* calculate scsi rate - round up again */ /* start from sclk for accuracy */ int totaldivide = xferp * cf2[scf]; sr = (c->sclk * 2 + totaldivide - 1) / totaldivide; if (sr > scsilimit) break; /* * now work out transfer period * round down now so that period is pessimistic */ tp = (MEGA * 1000) / sr; /* * bounds check it */ if (tp < 25 || tp > 255 * 4) continue; /* * spot stupid special case for Ultra or Ultra2 * while working out factor */ if (tp == 25) tpf = 10; else if (tp == 50) tpf = 12; else if (tp < 52) continue; else tpf = tp / 4; /* * now check tpf looks sensible * given core rate */ switch (fast) { case 0: /* scf must be ccf for SCSI 1 */ ok = tpf >= 50 && scf == c->ccf; break; case 1: ok = tpf >= 25 && tpf < 50; break; case 2: /* * must use xferp of 4, or 5 at a pinch * for an Ultra transfer */ ok = xferp <= 5 && tpf >= 12 && tpf < 25; break; case 3: ok = xferp == 4 && (tpf == 10 || tpf == 11); break; default: ok = 0; } if (!ok) continue; c->synctab[scf - 1][xferp - 4] = tpf; } } #ifndef NO_ULTRA2 if (c->v->feature & Ultra2) tpf = 10; else #endif if (c->v->feature & Ultra) tpf = 12; else tpf = 25; for (; tpf < 256; tpf++) { if (chooserate(c, tpf, &scf, &xferp) == tpf) { unsigned tp = tpf == 10 ? 25 : (tpf == 12 ? 50 : tpf * 4); unsigned long khz = (MEGA + tp - 1) / (tp); KPRINT(PRINTPREFIX "tpf=%d scf=%d.%.1d xferp=%d mhz=%ld.%.3ld\n", tpf, cf2[scf] / 2, (cf2[scf] & 1) ? 5 : 0, xferp + 4, khz / 1000, khz % 1000); USED(khz); if (c->tpf == 0) c->tpf = tpf; /* note lowest value for controller */ } } } static void synctodsa(Dsa *dsa, Controller *c) { /* KPRINT("synctodsa(dsa=%lux, target=%d, scntl3=%.2lx sxfer=%.2x)\n", dsa, dsa->target, c->scntl3[dsa->target], c->sxfer[dsa->target]); */ dsa->scntl3 = c->scntl3[dsa->target]; dsa->sxfer = c->sxfer[dsa->target]; } static void setsync(Dsa *dsa, Controller *c, int target, uchar ultra, uchar scf, uchar xferp, uchar reqack) { c->scntl3[target] = (c->scntl3[target] & 0x08) | (((scf << 4) | c->ccf | (ultra << 7)) & ~0x08); c->sxfer[target] = (xferp << 5) | reqack; c->s[target] = BothDone; if (dsa) { synctodsa(dsa, c); c->n->scntl3 = c->scntl3[target]; c->n->sxfer = c->sxfer[target]; } } static void setasync(Dsa *dsa, Controller *c, int target) { setsync(dsa, c, target, 0, c->ccf, 0, 0); } static void setwide(Dsa *dsa, Controller *c, int target, uchar wide) { c->scntl3[target] = wide ? (1 << 3) : 0; setasync(dsa, c, target); c->s[target] = WideDone; } static int buildsdtrmsg(uchar *buf, uchar tpf, uchar offset) { *buf++ = X_MSG; *buf++ = 3; *buf++ = X_MSG_SDTR; *buf++ = tpf; *buf = offset; return 5; } static int buildwdtrmsg(uchar *buf, uchar expo) { *buf++ = X_MSG; *buf++ = 2; *buf++ = X_MSG_WDTR; *buf = expo; return 4; } static void start(Controller *c, long entry) { ulong p; if (c->running) panic(PRINTPREFIX "start called while running"); c->running = 1; p = c->scriptpa + entry; lesetl(c->n->dsp, p); coherence(); if (c->ssm) c->n->dcntl |= 0x4; /* start DMA in SSI mode */ } static void ncrcontinue(Controller *c) { if (c->running) panic(PRINTPREFIX "ncrcontinue called while running"); /* set the start DMA bit to continue execution */ c->running = 1; coherence(); c->n->dcntl |= 0x4; } static void softreset(Controller *c) { Ncr *n = c->n; n->istat = Srst; /* software reset */ n->istat = 0; /* general initialisation */ n->scid = (1 << 6) | 7; /* respond to reselect, ID 7 */ n->respid = 1 << 7; /* response ID = 7 */ #ifdef INTERNAL_SCLK n->stest1 = 0x80; /* disable external scsi clock */ #else n->stest1 = 0x00; #endif n->stime0 = 0xdd; /* about 0.5 second timeout on each device */ n->scntl0 |= 0x8; /* Enable parity checking */ /* continued setup */ n->sien0 = 0x8f; n->sien1 = 0x04; n->dien = 0x7d; n->stest3 = 0x80; /* TolerANT enable */ c->running = 0; if (c->v->feature & BigFifo) n->ctest5 = (1 << 5); n->dmode = c->v->burst << 6; /* set burst length bits */ if (c->v->burst & 4) n->ctest5 |= (1 << 2); /* including overflow into ctest5 bit 2 */ if (c->v->feature & Prefetch) n->dcntl |= (1 << 5); /* prefetch enable */ else if (c->v->feature & BurstOpCodeFetch) n->dmode |= (1 << 1); /* burst opcode fetch */ if (c->v->feature & Differential) { /* chip capable */ if ((c->feature & Differential) || bios_set_differential(c)) { /* user enabled, or some evidence bios set differential */ if (n->sstat2 & (1 << 2)) print(PRINTPREFIX "can't go differential; wrong cable\n"); else { n->stest2 = (1 << 5); print(PRINTPREFIX "differential mode set\n"); } } } if (c->clockmult) { n->stest1 |= (1 << 3); /* power up doubler */ delay(2); n->stest3 |= (1 << 5); /* stop clock */ n->stest1 |= (1 << 2); /* enable doubler */ n->stest3 &= ~(1 << 5); /* start clock */ /* pray */ } } static void msgsm(Dsa *dsa, Controller *c, int msg, int *cont, int *wakeme) { uchar histpf, hisreqack; int tpf; int scf, xferp; int len; Ncr *n = c->n; switch (c->s[dsa->target]) { case SyncInit: switch (msg) { case A_SIR_MSG_SDTR: /* reply to my SDTR */ histpf = n->scratcha[2]; hisreqack = n->scratcha[3]; KPRINT(PRINTPREFIX "%d: SDTN response %d %d\n", dsa->target, histpf, hisreqack); if (hisreqack == 0) setasync(dsa, c, dsa->target); else { /* hisreqack should be <= c->v->maxsyncoff */ tpf = chooserate(c, histpf, &scf, &xferp); KPRINT(PRINTPREFIX "%d: SDTN: using %d %d\n", dsa->target, tpf, hisreqack); setsync(dsa, c, dsa->target, tpf < 25, scf, xferp, hisreqack); } *cont = -2; return; case A_SIR_EV_PHASE_SWITCH_AFTER_ID: /* target ignored ATN for message after IDENTIFY - not SCSI-II */ KPRINT(PRINTPREFIX "%d: illegal phase switch after ID message - SCSI-1 device?\n", dsa->target); KPRINT(PRINTPREFIX "%d: SDTN: async\n", dsa->target); setasync(dsa, c, dsa->target); *cont = E_to_decisions; return; case A_SIR_MSG_REJECT: /* rejection of my SDTR */ KPRINT(PRINTPREFIX "%d: SDTN: rejected SDTR\n", dsa->target); //async: KPRINT(PRINTPREFIX "%d: SDTN: async\n", dsa->target); setasync(dsa, c, dsa->target); *cont = -2; return; } break; case WideInit: switch (msg) { case A_SIR_MSG_WDTR: /* reply to my WDTR */ KPRINT(PRINTPREFIX "%d: WDTN: response %d\n", dsa->target, n->scratcha[2]); setwide(dsa, c, dsa->target, n->scratcha[2]); *cont = -2; return; case A_SIR_EV_PHASE_SWITCH_AFTER_ID: /* target ignored ATN for message after IDENTIFY - not SCSI-II */ KPRINT(PRINTPREFIX "%d: illegal phase switch after ID message - SCSI-1 device?\n", dsa->target); setwide(dsa, c, dsa->target, 0); *cont = E_to_decisions; return; case A_SIR_MSG_REJECT: /* rejection of my SDTR */ KPRINT(PRINTPREFIX "%d: WDTN: rejected WDTR\n", dsa->target); setwide(dsa, c, dsa->target, 0); *cont = -2; return; } break; case NeitherDone: case WideDone: case BothDone: switch (msg) { case A_SIR_MSG_WDTR: { uchar hiswide, mywide; hiswide = n->scratcha[2]; mywide = (c->v->feature & Wide) != 0; KPRINT(PRINTPREFIX "%d: WDTN: target init %d\n", dsa->target, hiswide); if (hiswide < mywide) mywide = hiswide; KPRINT(PRINTPREFIX "%d: WDTN: responding %d\n", dsa->target, mywide); setwide(dsa, c, dsa->target, mywide); len = buildwdtrmsg(dsa->msg_out, mywide); setmovedata(&dsa->msg_out_buf, DMASEG(dsa->msg_out), len); *cont = E_response; c->s[dsa->target] = WideResponse; return; } case A_SIR_MSG_SDTR: #ifdef ASYNC_ONLY *cont = E_reject; return; #else /* target decides to renegotiate */ histpf = n->scratcha[2]; hisreqack = n->scratcha[3]; KPRINT(PRINTPREFIX "%d: SDTN: target init %d %d\n", dsa->target, histpf, hisreqack); if (hisreqack == 0) { /* he wants asynchronous */ setasync(dsa, c, dsa->target); tpf = 0; } else { /* he wants synchronous */ tpf = chooserate(c, histpf, &scf, &xferp); if (hisreqack > c->v->maxsyncoff) hisreqack = c->v->maxsyncoff; KPRINT(PRINTPREFIX "%d: using %d %d\n", dsa->target, tpf, hisreqack); setsync(dsa, c, dsa->target, tpf < 25, scf, xferp, hisreqack); } /* build my SDTR message */ len = buildsdtrmsg(dsa->msg_out, tpf, hisreqack); setmovedata(&dsa->msg_out_buf, DMASEG(dsa->msg_out), len); *cont = E_response; c->s[dsa->target] = SyncResponse; return; #endif } break; case WideResponse: switch (msg) { case A_SIR_EV_RESPONSE_OK: c->s[dsa->target] = WideDone; KPRINT(PRINTPREFIX "%d: WDTN: response accepted\n", dsa->target); *cont = -2; return; case A_SIR_MSG_REJECT: setwide(dsa, c, dsa->target, 0); KPRINT(PRINTPREFIX "%d: WDTN: response REJECTed\n", dsa->target); *cont = -2; return; } break; case SyncResponse: switch (msg) { case A_SIR_EV_RESPONSE_OK: c->s[dsa->target] = BothDone; KPRINT(PRINTPREFIX "%d: SDTN: response accepted (%s)\n", dsa->target, phase[n->sstat1 & 7]); *cont = -2; return; /* chf */ case A_SIR_MSG_REJECT: setasync(dsa, c, dsa->target); KPRINT(PRINTPREFIX "%d: SDTN: response REJECTed\n", dsa->target); *cont = -2; return; } break; } KPRINT(PRINTPREFIX "%d: msgsm: state %d msg %d\n", dsa->target, c->s[dsa->target], msg); *wakeme = 1; return; } static void calcblockdma(Dsa *d, ulong base, ulong count) { ulong blocks; if (DEBUG(3)) blocks = 0; else { blocks = count / A_BSIZE; if (blocks > 255) blocks = 255; } d->dmablks = blocks; d->dmaaddr[0] = base; d->dmaaddr[1] = base >> 8; d->dmaaddr[2] = base >> 16; d->dmaaddr[3] = base >> 24; setmovedata(&d->data_buf, base + blocks * A_BSIZE, count - blocks * A_BSIZE); d->flag = legetl(d->data_buf.dbc) == 0; } static ulong read_mismatch_recover(Controller *c, Ncr *n, Dsa *dsa) { ulong dbc; uchar dfifo = n->dfifo; int inchip; dbc = (n->dbc[2]<<16)|(n->dbc[1]<<8)|n->dbc[0]; if (n->ctest5 & (1 << 5)) inchip = ((dfifo | ((n->ctest5 & 3) << 8)) - (dbc & 0x3ff)) & 0x3ff; else inchip = ((dfifo & 0x7f) - (dbc & 0x7f)) & 0x7f; if (inchip) { IPRINT(PRINTPREFIX "%d/%d: read_mismatch_recover: DMA FIFO = %d\n", dsa->target, dsa->lun, inchip); } if (n->sxfer & SYNCOFFMASK(c)) { /* SCSI FIFO */ uchar fifo = n->sstat1 >> 4; if (c->v->maxsyncoff > 8) fifo |= (n->sstat2 & (1 << 4)); if (fifo) { inchip += fifo; IPRINT(PRINTPREFIX "%d/%d: read_mismatch_recover: SCSI FIFO = %d\n", dsa->target, dsa->lun, fifo); } } else { if (n->sstat0 & (1 << 7)) { inchip++; IPRINT(PRINTPREFIX "%d/%d: read_mismatch_recover: SIDL full\n", dsa->target, dsa->lun); } if (n->sstat2 & (1 << 7)) { inchip++; IPRINT(PRINTPREFIX "%d/%d: read_mismatch_recover: SIDL msb full\n", dsa->target, dsa->lun); } } USED(inchip); return dbc; } static ulong write_mismatch_recover(Controller *c, Ncr *n, Dsa *dsa) { ulong dbc; uchar dfifo = n->dfifo; int inchip; dbc = (n->dbc[2]<<16)|(n->dbc[1]<<8)|n->dbc[0]; USED(dsa); if (n->ctest5 & (1 << 5)) inchip = ((dfifo | ((n->ctest5 & 3) << 8)) - (dbc & 0x3ff)) & 0x3ff; else inchip = ((dfifo & 0x7f) - (dbc & 0x7f)) & 0x7f; #ifdef WMR_DEBUG if (inchip) { IPRINT(PRINTPREFIX "%d/%d: write_mismatch_recover: DMA FIFO = %d\n", dsa->target, dsa->lun, inchip); } #endif if (n->sstat0 & (1 << 5)) { inchip++; #ifdef WMR_DEBUG IPRINT(PRINTPREFIX "%d/%d: write_mismatch_recover: SODL full\n", dsa->target, dsa->lun); #endif } if (n->sstat2 & (1 << 5)) { inchip++; #ifdef WMR_DEBUG IPRINT(PRINTPREFIX "%d/%d: write_mismatch_recover: SODL msb full\n", dsa->target, dsa->lun); #endif } if (n->sxfer & SYNCOFFMASK(c)) { /* synchronous SODR */ if (n->sstat0 & (1 << 6)) { inchip++; #ifdef WMR_DEBUG IPRINT(PRINTPREFIX "%d/%d: write_mismatch_recover: SODR full\n", dsa->target, dsa->lun); #endif } if (n->sstat2 & (1 << 6)) { inchip++; #ifdef WMR_DEBUG IPRINT(PRINTPREFIX "%d/%d: write_mismatch_recover: SODR msb full\n", dsa->target, dsa->lun); #endif } } /* clear the dma fifo */ n->ctest3 |= (1 << 2); /* wait till done */ while ((n->dstat & Dfe) == 0) ; return dbc + inchip; } static void sd53c8xxinterrupt(Ureg *ur, void *a) { uchar istat, dstat; ushort sist; int wakeme = 0; int cont = -1; Dsa *dsa; ulong dsapa; Controller *c = a; Ncr *n = c->n; USED(ur); if (DEBUG(1)) { IPRINT(PRINTPREFIX "int\n"); } ilock(c); istat = n->istat; if (istat & Intf) { Dsa *d; int wokesomething = 0; if (DEBUG(1)) { IPRINT(PRINTPREFIX "Intfly\n"); } n->istat = Intf; /* search for structures in A_STATE_DONE */ for (d = KPTR(legetl(c->dsalist.head)); d != nil && d != dsaend; d = KPTR(legetl(d->next))) { if (d->stateb == A_STATE_DONE) { d->p9status = d->status; if (DEBUG(1)) { IPRINT(PRINTPREFIX "waking up dsa %#p\n", d); } wakeup(d); wokesomething = 1; } } if (!wokesomething) { IPRINT(PRINTPREFIX "nothing to wake up\n"); } } if ((istat & (Sip | Dip)) == 0) { if (DEBUG(1)) { IPRINT(PRINTPREFIX "int end %x\n", istat); } iunlock(c); return; } sist = (n->sist1<<8)|n->sist0; /* BUG? can two-byte read be inconsistent? */ dstat = n->dstat; dsapa = legetl(n->dsa); /* * Can't compute dsa until we know that dsapa is valid. */ if(DMASEG_TO_PADDR(dsapa) < -KZERO) dsa = (Dsa*)DMASEG_TO_KADDR(dsapa); else{ dsa = nil; /* * happens at startup on some cards but we * don't actually deref dsa because none of the * flags we are about are set. * still, print in case that changes and we're * about to dereference nil. */ iprint("sd53c8xxinterrupt: dsa=%.8lux istat=%ux sist=%ux dstat=%ux\n", dsapa, istat, sist, dstat); } c->running = 0; if (istat & Sip) { if (DEBUG(1)) { IPRINT("sist = %.4x\n", sist); } if (sist & 0x80) { ulong addr; ulong sa; ulong dbc; ulong tbc; int dmablks; ulong dmaaddr; addr = legetl(n->dsp); sa = addr - c->scriptpa; if (DEBUG(1) || DEBUG(2)) { IPRINT(PRINTPREFIX "%d/%d: Phase Mismatch sa=%.8lux\n", dsa->target, dsa->lun, sa); } /* * now recover */ if (sa == E_data_in_mismatch) { /* * though this is a failure in the residue, there may have been blocks * as well. if so, dmablks will not have been zeroed, since the state * was not saved by the microcode. */ dbc = read_mismatch_recover(c, n, dsa); tbc = legetl(dsa->data_buf.dbc) - dbc; dsa->dmablks = 0; n->scratcha[2] = 0; advancedata(&dsa->data_buf, tbc); if (DEBUG(1) || DEBUG(2)) { IPRINT(PRINTPREFIX "%d/%d: transferred = %ld residue = %ld\n", dsa->target, dsa->lun, tbc, legetl(dsa->data_buf.dbc)); } cont = E_data_mismatch_recover; } else if (sa == E_data_in_block_mismatch) { dbc = read_mismatch_recover(c, n, dsa); tbc = A_BSIZE - dbc; /* recover current state from registers */ dmablks = n->scratcha[2]; dmaaddr = legetl(n->scratchb); /* we have got to dmaaddr + tbc */ /* we have dmablks * A_BSIZE - tbc + residue left to do */ /* so remaining transfer is */ IPRINT("in_block_mismatch: dmaaddr = 0x%lux tbc=%lud dmablks=%d\n", dmaaddr, tbc, dmablks); calcblockdma(dsa, dmaaddr + tbc, dmablks * A_BSIZE - tbc + legetl(dsa->data_buf.dbc)); /* copy changes into scratch registers */ IPRINT("recalc: dmablks %d dmaaddr 0x%lx pa 0x%lx dbc %ld\n", dsa->dmablks, legetl(dsa->dmaaddr), legetl(dsa->data_buf.pa), legetl(dsa->data_buf.dbc)); n->scratcha[2] = dsa->dmablks; lesetl(n->scratchb, *((ulong*)dsa->dmaaddr)); cont = E_data_block_mismatch_recover; } else if (sa == E_data_out_mismatch) { dbc = write_mismatch_recover(c, n, dsa); tbc = legetl(dsa->data_buf.dbc) - dbc; dsa->dmablks = 0; n->scratcha[2] = 0; advancedata(&dsa->data_buf, tbc); if (DEBUG(1) || DEBUG(2)) { IPRINT(PRINTPREFIX "%d/%d: transferred = %ld residue = %ld\n", dsa->target, dsa->lun, tbc, legetl(dsa->data_buf.dbc)); } cont = E_data_mismatch_recover; } else if (sa == E_data_out_block_mismatch) { dbc = write_mismatch_recover(c, n, dsa); tbc = legetl(dsa->data_buf.dbc) - dbc; /* recover current state from registers */ dmablks = n->scratcha[2]; dmaaddr = legetl(n->scratchb); /* we have got to dmaaddr + tbc */ /* we have dmablks blocks - tbc + residue left to do */ /* so remaining transfer is */ IPRINT("out_block_mismatch: dmaaddr = %lux tbc=%lud dmablks=%d\n", dmaaddr, tbc, dmablks); calcblockdma(dsa, dmaaddr + tbc, dmablks * A_BSIZE - tbc + legetl(dsa->data_buf.dbc)); /* copy changes into scratch registers */ n->scratcha[2] = dsa->dmablks; lesetl(n->scratchb, *((ulong*)dsa->dmaaddr)); cont = E_data_block_mismatch_recover; } else if (sa == E_id_out_mismatch) { /* * target switched phases while attention held during * message out. The possibilities are: * 1. It didn't like the last message. This is indicated * by the new phase being message_in. Use script to recover * * 2. It's not SCSI-II compliant. The new phase will be other * than message_in. We should also indicate that the device * is asynchronous, if it's the SDTR that got ignored * * For now, if the phase switch is not to message_in, and * and it happens after IDENTIFY and before SDTR, we * notify the negotiation state machine. */ ulong lim = legetl(dsa->msg_out_buf.dbc); uchar p = n->sstat1 & 7; dbc = write_mismatch_recover(c, n, dsa); tbc = lim - dbc; IPRINT(PRINTPREFIX "%d/%d: msg_out_mismatch: %lud/%lud sent, phase %s\n", dsa->target, dsa->lun, tbc, lim, phase[p]); if (p != MessageIn && tbc == 1) { msgsm(dsa, c, A_SIR_EV_PHASE_SWITCH_AFTER_ID, &cont, &wakeme); } else cont = E_id_out_mismatch_recover; } else if (sa == E_cmd_out_mismatch) { /* * probably the command count is longer than the device wants ... */ ulong lim = legetl(dsa->cmd_buf.dbc); uchar p = n->sstat1 & 7; dbc = write_mismatch_recover(c, n, dsa); tbc = lim - dbc; IPRINT(PRINTPREFIX "%d/%d: cmd_out_mismatch: %lud/%lud sent, phase %s\n", dsa->target, dsa->lun, tbc, lim, phase[p]); USED(p, tbc); cont = E_to_decisions; } else { IPRINT(PRINTPREFIX "%d/%d: ma sa=%.8lux wanted=%s got=%s\n", dsa->target, dsa->lun, sa, phase[n->dcmd & 7], phase[n->sstat1 & 7]); dumpncrregs(c, 1); dsa->p9status = SDeio; /* chf */ wakeme = 1; } } /*else*/ if (sist & 0x400) { if (DEBUG(0)) { IPRINT(PRINTPREFIX "%d/%d Sto\n", dsa->target, dsa->lun); } dsa->p9status = SDtimeout; dsa->stateb = A_STATE_DONE; coherence(); softreset(c); cont = E_issue_check; wakeme = 1; } if (sist & 0x1) { IPRINT(PRINTPREFIX "%d/%d: parity error\n", dsa->target, dsa->lun); dsa->parityerror = 1; } if (sist & 0x4) { IPRINT(PRINTPREFIX "%s%d lun %d: unexpected disconnect\n", c->sdev->name, dsa->target, dsa->lun); dumpncrregs(c, 1); //wakeme = 1; dsa->p9status = SDeio; } } if (istat & Dip) { if (DEBUG(1)) { IPRINT("dstat = %.2x\n", dstat); } /*else*/ if (dstat & Ssi) { ulong w = legetl(n->dsp) - c->scriptpa; IPRINT("[%lux]", w); USED(w); cont = -2; /* restart */ } if (dstat & Sir) { switch (legetl(n->dsps)) { case A_SIR_MSG_IO_COMPLETE: dsa->p9status = dsa->status; wakeme = 1; break; case A_SIR_MSG_SDTR: case A_SIR_MSG_WDTR: case A_SIR_MSG_REJECT: case A_SIR_EV_RESPONSE_OK: msgsm(dsa, c, legetl(n->dsps), &cont, &wakeme); break; case A_SIR_MSG_IGNORE_WIDE_RESIDUE: /* back up one in the data transfer */ IPRINT(PRINTPREFIX "%d/%d: ignore wide residue %d, WSR = %d\n", dsa->target, dsa->lun, n->scratcha[1], n->scntl2 & 1); if (dsa->flag == 2) { IPRINT(PRINTPREFIX "%d/%d: transfer over; residue ignored\n", dsa->target, dsa->lun); } else { calcblockdma(dsa, legetl(dsa->dmaaddr) - 1, dsa->dmablks * A_BSIZE + legetl(dsa->data_buf.dbc) + 1); } cont = -2; break; case A_SIR_ERROR_NOT_MSG_IN_AFTER_RESELECT: IPRINT(PRINTPREFIX "%d: not msg_in after reselect (%s)", n->ssid & SSIDMASK(c), phase[n->sstat1 & 7]); dsa = dsafind(c, n->ssid & SSIDMASK(c), -1, A_STATE_DISCONNECTED); dumpncrregs(c, 1); wakeme = 1; break; case A_SIR_NOTIFY_LOAD_STATE: IPRINT(PRINTPREFIX ": load_state dsa=%p\n", dsa); if (dsa == nil) { dsadump(c); dumpncrregs(c, 1); panic("bad dsa in load_state"); } cont = -2; break; case A_SIR_NOTIFY_MSG_IN: IPRINT(PRINTPREFIX "%d/%d: msg_in %d\n", dsa->target, dsa->lun, n->sfbr); cont = -2; break; case A_SIR_NOTIFY_DISC: IPRINT(PRINTPREFIX "%d/%d: disconnect:", dsa->target, dsa->lun); goto dsadump; case A_SIR_NOTIFY_STATUS: IPRINT(PRINTPREFIX "%d/%d: status\n", dsa->target, dsa->lun); cont = -2; break; case A_SIR_NOTIFY_COMMAND: IPRINT(PRINTPREFIX "%d/%d: commands\n", dsa->target, dsa->lun); cont = -2; break; case A_SIR_NOTIFY_DATA_IN: IPRINT(PRINTPREFIX "%d/%d: data in a %lx b %lx\n", dsa->target, dsa->lun, legetl(n->scratcha), legetl(n->scratchb)); cont = -2; break; case A_SIR_NOTIFY_BLOCK_DATA_IN: IPRINT(PRINTPREFIX "%d/%d: block data in: a2 %x b %lx\n", dsa->target, dsa->lun, n->scratcha[2], legetl(n->scratchb)); cont = -2; break; case A_SIR_NOTIFY_DATA_OUT: IPRINT(PRINTPREFIX "%d/%d: data out\n", dsa->target, dsa->lun); cont = -2; break; case A_SIR_NOTIFY_DUMP: IPRINT(PRINTPREFIX "%d/%d: dump\n", dsa->target, dsa->lun); dumpncrregs(c, 1); cont = -2; break; case A_SIR_NOTIFY_DUMP2: IPRINT(PRINTPREFIX "%d/%d: dump2:", dsa->target, dsa->lun); IPRINT(" sa %lux", legetl(n->dsp) - c->scriptpa); IPRINT(" dsa %lux", legetl(n->dsa)); IPRINT(" sfbr %ux", n->sfbr); IPRINT(" a %lux", legetl(n->scratcha)); IPRINT(" b %lux", legetl(n->scratchb)); IPRINT(" ssid %ux", n->ssid); IPRINT("\n"); cont = -2; break; case A_SIR_NOTIFY_WAIT_RESELECT: IPRINT(PRINTPREFIX "wait reselect\n"); cont = -2; break; case A_SIR_NOTIFY_RESELECT: IPRINT(PRINTPREFIX "reselect: ssid %.2x sfbr %.2x at %ld\n", n->ssid, n->sfbr, TK2MS(m->ticks)); cont = -2; break; case A_SIR_NOTIFY_ISSUE: IPRINT(PRINTPREFIX "%d/%d: issue dsa=%p end=%p:", dsa->target, dsa->lun, dsa, dsaend); dsadump: IPRINT(" tgt=%d", dsa->target); IPRINT(" time=%ld", TK2MS(m->ticks)); IPRINT("\n"); cont = -2; break; case A_SIR_NOTIFY_ISSUE_CHECK: IPRINT(PRINTPREFIX "issue check\n"); cont = -2; break; case A_SIR_NOTIFY_SIGP: IPRINT(PRINTPREFIX "responded to SIGP\n"); cont = -2; break; case A_SIR_NOTIFY_DUMP_NEXT_CODE: { ulong *dsp = &c->script[(legetl(n->dsp)-c->scriptpa)/4]; int x; IPRINT(PRINTPREFIX "code at %lux", (ulong)(dsp - c->script)); for (x = 0; x < 6; x++) { IPRINT(" %.8lux", dsp[x]); } IPRINT("\n"); USED(dsp); cont = -2; break; } case A_SIR_NOTIFY_WSR: IPRINT(PRINTPREFIX "%d/%d: WSR set\n", dsa->target, dsa->lun); cont = -2; break; case A_SIR_NOTIFY_LOAD_SYNC: IPRINT(PRINTPREFIX "%d/%d: scntl=%.2x sxfer=%.2x\n", dsa->target, dsa->lun, n->scntl3, n->sxfer); cont = -2; break; case A_SIR_NOTIFY_RESELECTED_ON_SELECT: if (DEBUG(2)) { IPRINT(PRINTPREFIX "%d/%d: reselected during select\n", dsa->target, dsa->lun); } cont = -2; break; case A_error_reselected: /* dsa isn't valid here */ iprint(PRINTPREFIX "reselection error\n"); dumpncrregs(c, 1); for (dsa = KPTR(legetl(c->dsalist.head)); dsa != nil && dsa != dsaend; dsa = KPTR(legetl(dsa->next))) { IPRINT(PRINTPREFIX "dsa target %d lun %d state %d\n", dsa->target, dsa->lun, dsa->stateb); } break; default: IPRINT(PRINTPREFIX "%d/%d: script error %ld\n", dsa->target, dsa->lun, legetl(n->dsps)); dumpncrregs(c, 1); wakeme = 1; } } /*else*/ if (dstat & Iid) { int i, target, lun; ulong addr, dbc, *v; addr = legetl(n->dsp); if(dsa){ target = dsa->target; lun = dsa->lun; }else{ target = -1; lun = -1; } dbc = (n->dbc[2]<<16)|(n->dbc[1]<<8)|n->dbc[0]; // if(dsa == nil) idebug++; IPRINT(PRINTPREFIX "%d/%d: Iid pa=%.8lux sa=%.8lux dbc=%lux\n", target, lun, addr, addr - c->scriptpa, dbc); addr -= c->scriptpa; addr -= 64; addr &= ~63; v = &c->script[addr/4]; for(i=0; i<8; i++){ IPRINT("%.8lux: %.8lux %.8lux %.8lux %.8lux\n", addr, v[0], v[1], v[2], v[3]); addr += 4*4; v += 4; } USED(addr, dbc); if(dsa == nil){ dsadump(c); dumpncrregs(c, 1); panic("bad dsa"); } dsa->p9status = SDeio; wakeme = 1; } /*else*/ if (dstat & Bf) { IPRINT(PRINTPREFIX "%d/%d: Bus Fault\n", dsa->target, dsa->lun); dumpncrregs(c, 1); dsa->p9status = SDeio; wakeme = 1; } } if (cont == -2) ncrcontinue(c); else if (cont >= 0) start(c, cont); if (wakeme){ if(dsa->p9status == SDnostatus) dsa->p9status = SDeio; wakeup(dsa); } iunlock(c); if (DEBUG(1)) { IPRINT(PRINTPREFIX "int end 1\n"); } } static int done(void *arg) { return ((Dsa *)arg)->p9status != SDnostatus; } static void setmovedata(Movedata *d, ulong pa, ulong bc) { d->pa[0] = pa; d->pa[1] = pa>>8; d->pa[2] = pa>>16; d->pa[3] = pa>>24; d->dbc[0] = bc; d->dbc[1] = bc>>8; d->dbc[2] = bc>>16; d->dbc[3] = bc>>24; } static void advancedata(Movedata *d, long v) { lesetl(d->pa, legetl(d->pa) + v); lesetl(d->dbc, legetl(d->dbc) - v); } static void dumpwritedata(uchar *data, int datalen) { int i; uchar *bp; if (!DEBUG(0)){ USED(data, datalen); return; } if (datalen) { KPRINT(PRINTPREFIX "write:"); for (i = 0, bp = data; i < 50 && i < datalen; i++, bp++) { KPRINT("%.2ux", *bp); } if (i < datalen) { KPRINT("..."); } KPRINT("\n"); } } static void dumpreaddata(uchar *data, int datalen) { int i; uchar *bp; if (!DEBUG(0)){ USED(data, datalen); return; } if (datalen) { KPRINT(PRINTPREFIX "read:"); for (i = 0, bp = data; i < 50 && i < datalen; i++, bp++) { KPRINT("%.2ux", *bp); } if (i < datalen) { KPRINT("..."); } KPRINT("\n"); } } static void busreset(Controller *c) { int x, ntarget; /* bus reset */ c->n->scntl1 |= (1 << 3); delay(500); c->n->scntl1 &= ~(1 << 3); if(!(c->v->feature & Wide)) ntarget = 8; else ntarget = MAXTARGET; for (x = 0; x < ntarget; x++) { setwide(0, c, x, 0); #ifndef ASYNC_ONLY c->s[x] = NeitherDone; #endif } c->capvalid = 0; } static void reset(Controller *c) { /* should wakeup all pending tasks */ softreset(c); busreset(c); } static int sd53c8xxrio(SDreq* r) { Dsa *d; uchar *bp; Controller *c; uchar target_expo, my_expo; int bc, check, i, status, target; if((target = r->unit->subno) == 0x07) return r->status = SDtimeout; /* assign */ c = r->unit->dev->ctlr; check = 0; d = dsaalloc(c, target, r->lun); qlock(&c->q[target]); /* obtain access to target */ docheck: /* load the transfer control stuff */ d->scsi_id_buf[0] = 0; d->scsi_id_buf[1] = c->sxfer[target]; d->scsi_id_buf[2] = target; d->scsi_id_buf[3] = c->scntl3[target]; synctodsa(d, c); bc = 0; d->msg_out[bc] = 0x80 | r->lun; #ifndef NO_DISCONNECT d->msg_out[bc] |= (1 << 6); #endif bc++; /* work out what to do about negotiation */ switch (c->s[target]) { default: KPRINT(PRINTPREFIX "%d: strange nego state %d\n", target, c->s[target]); c->s[target] = NeitherDone; /* fall through */ case NeitherDone: if ((c->capvalid & (1 << target)) == 0) break; target_expo = (c->cap[target] >> 5) & 3; my_expo = (c->v->feature & Wide) != 0; if (target_expo < my_expo) my_expo = target_expo; #ifdef ALWAYS_DO_WDTR bc += buildwdtrmsg(d->msg_out + bc, my_expo); KPRINT(PRINTPREFIX "%d: WDTN: initiating expo %d\n", target, my_expo); c->s[target] = WideInit; break; #else if (my_expo) { bc += buildwdtrmsg(d->msg_out + bc, (c->v->feature & Wide) ? 1 : 0); KPRINT(PRINTPREFIX "%d: WDTN: initiating expo %d\n", target, my_expo); c->s[target] = WideInit; break; } KPRINT(PRINTPREFIX "%d: WDTN: narrow\n", target); /* fall through */ #endif case WideDone: if (c->cap[target] & (1 << 4)) { KPRINT(PRINTPREFIX "%d: SDTN: initiating %d %d\n", target, c->tpf, c->v->maxsyncoff); bc += buildsdtrmsg(d->msg_out + bc, c->tpf, c->v->maxsyncoff); c->s[target] = SyncInit; break; } KPRINT(PRINTPREFIX "%d: SDTN: async only\n", target); c->s[target] = BothDone; break; case BothDone: break; } setmovedata(&d->msg_out_buf, DMASEG(d->msg_out), bc); setmovedata(&d->cmd_buf, DMASEG(r->cmd), r->clen); calcblockdma(d, r->data ? DMASEG(r->data) : 0, r->dlen); if (DEBUG(0)) { KPRINT(PRINTPREFIX "%d/%d: exec: ", target, r->lun); for (bp = r->cmd; bp < &r->cmd[r->clen]; bp++) { KPRINT("%.2ux", *bp); } KPRINT("\n"); if (!r->write) { KPRINT(PRINTPREFIX "%d/%d: exec: limit=(%d)%ld\n", target, r->lun, d->dmablks, legetl(d->data_buf.dbc)); } else dumpwritedata(r->data, r->dlen); } setmovedata(&d->status_buf, DMASEG(&d->status), 1); d->p9status = SDnostatus; d->parityerror = 0; coherence(); d->stateb = A_STATE_ISSUE; /* start operation */ coherence(); ilock(c); if (c->ssm) c->n->dcntl |= 0x10; /* single step */ if (c->running) { c->n->istat = Sigp; } else { start(c, E_issue_check); } iunlock(c); while(waserror()) ; tsleep(d, done, d, 600 * 1000); poperror(); if (!done(d)) { KPRINT(PRINTPREFIX "%d/%d: exec: Timed out\n", target, r->lun); dumpncrregs(c, 0); dsafree(c, d); reset(c); qunlock(&c->q[target]); r->status = SDtimeout; return r->status = SDtimeout; /* assign */ } if((status = d->p9status) == SDeio) c->s[target] = NeitherDone; if (d->parityerror) { status = SDeio; } /* * adjust datalen */ r->rlen = r->dlen; if (DEBUG(0)) { KPRINT(PRINTPREFIX "%d/%d: exec: before rlen adjust: dmablks %d flag %d dbc %lud\n", target, r->lun, d->dmablks, d->flag, legetl(d->data_buf.dbc)); } r->rlen = r->dlen; if (d->flag != 2) { r->rlen -= d->dmablks * A_BSIZE; r->rlen -= legetl(d->data_buf.dbc); } if(!r->write) dumpreaddata(r->data, r->rlen); if (DEBUG(0)) { KPRINT(PRINTPREFIX "%d/%d: exec: p9status=%d status %d rlen %ld\n", target, r->lun, d->p9status, status, r->rlen); } /* * spot the identify */ if ((c->capvalid & (1 << target)) == 0 && (status == SDok || status == SDcheck) && r->cmd[0] == 0x12 && r->dlen >= 8) { c->capvalid |= 1 << target; bp = r->data; c->cap[target] = bp[7]; KPRINT(PRINTPREFIX "%d: capabilities %.2x\n", target, bp[7]); } if(!check && status == SDcheck && !(r->flags & SDnosense)){ check = 1; r->write = 0; memset(r->cmd, 0, sizeof(r->cmd)); r->cmd[0] = 0x03; r->cmd[1] = r->lun<<5; r->cmd[4] = sizeof(r->sense)-1; r->clen = 6; r->data = r->sense; r->dlen = sizeof(r->sense)-1; /* * Clear out the microcode state * so the Dsa can be re-used. */ lesetl(&d->stateb, A_STATE_ALLOCATED); coherence(); goto docheck; } qunlock(&c->q[target]); dsafree(c, d); if(status == SDok && check){ status = SDcheck; r->flags |= SDvalidsense; } if(DEBUG(0)) KPRINT(PRINTPREFIX "%d: r flags %8.8uX status %d rlen %ld\n", target, r->flags, status, r->rlen); if(r->flags & SDvalidsense){ if(!DEBUG(0)) KPRINT(PRINTPREFIX "%d: r flags %8.8uX status %d rlen %ld\n", target, r->flags, status, r->rlen); for(i = 0; i < r->rlen; i++) KPRINT(" %2.2uX", r->sense[i]); KPRINT("\n"); } return r->status = status; } static void cribbios(Controller *c) { c->bios.scntl3 = c->n->scntl3; c->bios.stest2 = c->n->stest2; print(PRINTPREFIX "%s: bios scntl3(%.2x) stest2(%.2x)\n", c->sdev->name, c->bios.scntl3, c->bios.stest2); } static int bios_set_differential(Controller *c) { /* Concept lifted from FreeBSD - thanks Gerard */ /* basically, if clock conversion factors are set, then there is * evidence the bios had a go at the chip, and if so, it would * have set the differential enable bit in stest2 */ return (c->bios.scntl3 & 7) != 0 && (c->bios.stest2 & 0x20) != 0; } #define NCR_VID 0x1000 #define NCR_810_DID 0x0001 #define NCR_820_DID 0x0002 /* don't know enough about this one to support it */ #define NCR_825_DID 0x0003 #define NCR_815_DID 0x0004 #define SYM_810AP_DID 0x0005 #define SYM_860_DID 0x0006 #define SYM_896_DID 0x000b #define SYM_895_DID 0x000c #define SYM_885_DID 0x000d /* ditto */ #define SYM_875_DID 0x000f /* ditto */ #define SYM_1010_DID 0x0020 #define SYM_1011_DID 0x0021 #define SYM_875J_DID 0x008f static Variant variant[] = { { NCR_810_DID, 0x0f, "NCR53C810", Burst16, 8, 24, 0 }, { NCR_810_DID, 0x1f, "SYM53C810ALV", Burst16, 8, 24, Prefetch }, { NCR_810_DID, 0xff, "SYM53C810A", Burst16, 8, 24, Prefetch }, { SYM_810AP_DID, 0xff, "SYM53C810AP", Burst16, 8, 24, Prefetch }, { NCR_815_DID, 0xff, "NCR53C815", Burst16, 8, 24, BurstOpCodeFetch }, { NCR_825_DID, 0x0f, "NCR53C825", Burst16, 8, 24, Wide|BurstOpCodeFetch|Differential }, { NCR_825_DID, 0xff, "SYM53C825A", Burst128, 16, 24, Prefetch|LocalRAM|BigFifo|Differential|Wide }, { SYM_860_DID, 0x0f, "SYM53C860", Burst16, 8, 24, Prefetch|Ultra }, { SYM_860_DID, 0xff, "SYM53C860LV", Burst16, 8, 24, Prefetch|Ultra }, { SYM_875_DID, 0x01, "SYM53C875r1", Burst128, 16, 24, Prefetch|LocalRAM|BigFifo|Differential|Wide|Ultra }, { SYM_875_DID, 0xff, "SYM53C875", Burst128, 16, 24, Prefetch|LocalRAM|BigFifo|Differential|Wide|Ultra|ClockDouble }, { SYM_875J_DID, 0xff, "SYM53C875j", Burst128, 16, 24, Prefetch|LocalRAM|BigFifo|Differential|Wide|Ultra|ClockDouble }, { SYM_885_DID, 0xff, "SYM53C885", Burst128, 16, 24, Prefetch|LocalRAM|BigFifo|Wide|Ultra|ClockDouble }, { SYM_895_DID, 0xff, "SYM53C895", Burst128, 16, 24, Prefetch|LocalRAM|BigFifo|Wide|Ultra|Ultra2 }, { SYM_896_DID, 0xff, "SYM53C896", Burst128, 16, 64, Prefetch|LocalRAM|BigFifo|Wide|Ultra|Ultra2 }, { SYM_1010_DID, 0xff, "SYM53C1010", Burst128, 16, 64, Prefetch|LocalRAM|BigFifo|Wide|Ultra|Ultra2 }, { SYM_1011_DID, 0xff, "SYM53C1010", Burst128, 16, 64, Prefetch|LocalRAM|BigFifo|Wide|Ultra|Ultra2 }, }; static int xfunc(Controller *c, enum na_external x, unsigned long *v) { switch (x) { default: print("xfunc: can't find external %d\n", x); return 0; case X_scsi_id_buf: *v = offsetof(Dsa, scsi_id_buf[0]); break; case X_msg_out_buf: *v = offsetof(Dsa, msg_out_buf); break; case X_cmd_buf: *v = offsetof(Dsa, cmd_buf); break; case X_data_buf: *v = offsetof(Dsa, data_buf); break; case X_status_buf: *v = offsetof(Dsa, status_buf); break; case X_dsa_head: *v = DMASEG(&c->dsalist.head[0]); break; case X_ssid_mask: *v = SSIDMASK(c); break; } return 1; } static int na_fixup(Controller *c, ulong pa_reg, struct na_patch *patch, int patches, int (*externval)(Controller*, int, ulong*)) { int p; int v; ulong *script, pa_script; unsigned long lw, lv; script = c->script; pa_script = c->scriptpa; for (p = 0; p < patches; p++) { switch (patch[p].type) { case 1: /* script relative */ script[patch[p].lwoff] += pa_script; break; case 2: /* register i/o relative */ script[patch[p].lwoff] += pa_reg; break; case 3: /* data external */ lw = script[patch[p].lwoff]; v = (lw >> 8) & 0xff; if (!(*externval)(c, v, &lv)) return 0; v = lv & 0xff; script[patch[p].lwoff] = (lw & 0xffff00ffL) | (v << 8); break; case 4: /* 32 bit external */ lw = script[patch[p].lwoff]; if (!(*externval)(c, lw, &lv)) return 0; script[patch[p].lwoff] = lv; break; case 5: /* 24 bit external */ lw = script[patch[p].lwoff]; if (!(*externval)(c, lw & 0xffffff, &lv)) return 0; script[patch[p].lwoff] = (lw & 0xff000000L) | (lv & 0xffffffL); break; } } return 1; } static SDev* sd53c8xxpnp(void) { char *cp; Pcidev *p; Variant *v; int ba, nctlr; void *scriptma; Controller *ctlr; SDev *sdev, *head, *tail; uvlong regpa, scriptpa; ulong *script; void *regva, *scriptva; if(cp = getconf("*maxsd53c8xx")) nctlr = strtoul(cp, 0, 0); else nctlr = 32; p = nil; head = tail = nil; while((p = pcimatch(p, NCR_VID, 0)) != nil && nctlr > 0){ for(v = variant; v < &variant[nelem(variant)]; v++){ if(p->did == v->did && p->rid <= v->maxrid) break; } if(v >= &variant[nelem(variant)]) { print("no match\n"); continue; } print(PRINTPREFIX "%s rev. 0x%2.2x intr=%d command=%4.4uX\n", v->name, p->rid, p->intl, p->pcr); regpa = p->mem[1].bar; ba = 2; if(regpa & 0x04){ if(p->mem[2].bar) continue; ba++; } regpa &= ~0xF; if(regpa == 0) print("regpa 0\n"); regva = vmap(regpa, p->mem[1].size); if(regva == nil){ print("sd53c8xx: can't map %llux\n", regpa); continue; } script = nil; scriptpa = 0; scriptva = nil; scriptma = nil; if((v->feature & LocalRAM) && sizeof(na_script) <= 4096){ scriptpa = p->mem[ba].bar; if((scriptpa & 0x04) && p->mem[ba+1].bar){ vunmap(regva, p->mem[1].size); continue; } scriptpa &= ~0x0F; scriptva = vmap(scriptpa, p->mem[ba].size); if(scriptva != nil) script = scriptva; } if(scriptpa == 0){ /* * Either the map failed, or this chip does not have * local RAM. It will need a copy of the microcode. */ scriptma = malloc(sizeof(na_script)); if(scriptma == nil){ vunmap(regva, p->mem[1].size); continue; } scriptpa = DMASEG(scriptma); script = scriptma; } ctlr = malloc(sizeof(Controller)); sdev = malloc(sizeof(SDev)); if(ctlr == nil || sdev == nil){ buggery: if(ctlr) free(ctlr); if(sdev) free(sdev); if(scriptma) free(scriptma); else if(scriptva) vunmap(scriptva, p->mem[ba].size); if(regva) vunmap(regva, p->mem[1].size); continue; } lock(&ctlr->dsalist); ctlr->dsalist.freechain = nil; if(dsaend == nil) dsaend = xalloc(sizeof *dsaend); if(dsaend == nil) panic("sd53c8xxpnp: no memory"); lesetl(&dsaend->stateb, A_STATE_END); lesetl(dsaend->next, DMASEG(dsaend)); coherence(); lesetl(ctlr->dsalist.head, DMASEG(dsaend)); coherence(); unlock(&ctlr->dsalist); ctlr->n = regva; ctlr->v = v; ctlr->script = script; memmove(ctlr->script, na_script, sizeof(na_script)); /* * Because we don't yet have an abstraction for the * addresses as seen from the controller side (and on * the 386 it doesn't matter), the following two lines * are different between the 386 and alpha copies of * this driver. */ ctlr->scriptpa = scriptpa; if(!na_fixup(ctlr, regpa, na_patches, NA_PATCHES, xfunc)){ print("script fixup failed\n"); goto buggery; } swabl(ctlr->script, ctlr->script, sizeof(na_script)); ctlr->pcidev = p; sdev->ifc = &sd53c8xxifc; sdev->ctlr = ctlr; sdev->idno = '0'; if(!(v->feature & Wide)) sdev->nunit = 8; else sdev->nunit = MAXTARGET; ctlr->sdev = sdev; if(head != nil) tail->next = sdev; else head = sdev; tail = sdev; nctlr--; } return head; } static int sd53c8xxenable(SDev* sdev) { Pcidev *pcidev; Controller *ctlr; char name[32]; ctlr = sdev->ctlr; pcidev = ctlr->pcidev; pcisetbme(pcidev); ilock(ctlr); synctabinit(ctlr); cribbios(ctlr); reset(ctlr); snprint(name, sizeof(name), "%s (%s)", sdev->name, sdev->ifc->name); intrenable(pcidev->intl, sd53c8xxinterrupt, ctlr, pcidev->tbdf, name); iunlock(ctlr); return 1; } SDifc sd53c8xxifc = { "53c8xx", /* name */ sd53c8xxpnp, /* pnp */ sd53c8xxenable, /* enable */ nil, /* disable */ scsiverify, /* verify */ scsionline, /* online */ sd53c8xxrio, /* rio */ nil, /* rctl */ nil, /* wctl */ scsibio, /* bio */ nil, /* probe */ nil, /* clear */ nil, /* rtopctl */ nil, /* wtopctl */ };