ref: 61f4c085c402af665b436f6d010d61107551d8a3
dir: /sys/src/9/port/sdnvme.c/
#include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "io.h" #include "../port/pci.h" #include "ureg.h" #include "../port/error.h" #include "../port/sd.h" typedef struct WS WS; typedef struct CQ CQ; typedef struct SQ SQ; typedef struct Ctlr Ctlr; struct WS { u32int cdw0; ushort status; Rendez *sleep; WS **link; SQ *queue; }; struct CQ { u32int head; u32int mask; u32int shift; u32int *base; Ctlr *ctlr; }; struct SQ { u32int tail; u32int mask; u32int shift; u32int *base; WS **wait; Ctlr *ctlr; Lock; }; struct Ctlr { QLock; Lock intr; u32int ints; u32int irqc[2]; Pcidev *pci; u32int *reg; u64int cap; uchar *ident; u32int *nsid; int nnsid; u32int mps; /* mps = 1<<mpsshift */ u32int mpsshift; u32int dstrd; u32int nsq; CQ cq[1+1]; SQ sq[1+MAXMACH]; Ctlr *next; }; /* controller registers */ enum { Cap0, Cap1, Ver, IntMs, IntMc, CCfg, CSts = 0x1C/4, Nssr, AQAttr, ASQBase0, ASQBase1, ACQBase0, ACQBase1, DBell = 0x1000/4, }; static u32int* qcmd(WS *ws, Ctlr *ctlr, int adm, u32int opc, u32int nsid, void *data, ulong len) { u32int cid, *e; u64int pa; SQ *sq; if(!adm){ Retry: splhi(); sq = &ctlr->sq[1+(m->machno % ctlr->nsq)]; if(conf.nmach > ctlr->nsq) lock(sq); } else { qlock(ctlr); sq = &ctlr->sq[0]; } ws->sleep = &up->sleep; ws->queue = sq; ws->link = &sq->wait[sq->tail & sq->mask]; while(*ws->link != nil){ /* should be very rare */ if(!adm){ if(conf.nmach > ctlr->nsq) unlock(sq); sched(); goto Retry; } sched(); } *ws->link = ws; e = &sq->base[((cid = sq->tail++) & sq->mask)<<4]; e[0] = opc | cid<<16; e[1] = nsid; e[2] = 0; e[3] = 0; e[4] = 0; e[5] = 0; if(len > 0){ dmaflush(1, data, len); pa = PCIWADDR(data); e[6] = pa; e[7] = pa>>32; if(len > ctlr->mps - (pa & ctlr->mps-1)) pa += ctlr->mps - (pa & ctlr->mps-1); else pa = 0; } else { e[6] = 0; e[7] = 0; pa = 0; } e[8] = pa; e[9] = pa>>32; return e; } static void nvmeintr(Ureg *, void *arg) { u32int phaseshift, *e; WS *ws, **wp; Ctlr *ctlr; SQ *sq; CQ *cq; ctlr = arg; if(ctlr->ints == 0) return; ilock(&ctlr->intr); ctlr->reg[IntMs] = ctlr->ints; for(cq = &ctlr->cq[nelem(ctlr->cq)-1]; cq >= ctlr->cq; cq--){ if(cq->base == nil) continue; phaseshift = 16 - cq->shift; for(;;){ e = &cq->base[(cq->head & cq->mask)<<2]; dmaflush(0, e, 32); if(((e[3] ^ (cq->head << phaseshift)) & 0x10000) == 0) break; if(0) iprint("nvmeintr: cq%d [%.4ux] %.8ux %.8ux %.8ux %.8ux\n", (int)(cq - ctlr->cq), cq->head & cq->mask, e[0], e[1], e[2], e[3]); sq = &ctlr->sq[e[2] >> 16]; wp = &sq->wait[e[3] & sq->mask]; if((ws = *wp) != nil && ws->link == wp){ Rendez *z = ws->sleep; ws->cdw0 = e[0]; ws->status = e[3]>>17; *wp = nil; wakeup(z); } ctlr->reg[DBell + ((cq-ctlr->cq)*2+1 << ctlr->dstrd)] = ++cq->head & cq->mask; } } ctlr->reg[IntMc] = ctlr->ints; iunlock(&ctlr->intr); } static int wdone(void *arg) { WS *ws = arg; return *ws->link != ws; } static u32int wcmd(WS *ws, u32int *e) { SQ *sq = ws->queue; Ctlr *ctlr = sq->ctlr; if(e != nil){ dmaflush(1, e, 64); } coherence(); ctlr->reg[DBell + ((sq-ctlr->sq)*2+0 << ctlr->dstrd)] = sq->tail & sq->mask; if(sq > ctlr->sq) { assert(sq == &ctlr->sq[1+(m->machno % ctlr->nsq)]); if(conf.nmach > ctlr->nsq) unlock(sq); spllo(); } else qunlock(sq->ctlr); while(waserror()) ; tsleep(ws->sleep, wdone, ws, 5); while(!wdone(ws)){ nvmeintr(nil, ctlr); tsleep(ws->sleep, wdone, ws, 10); } poperror(); return ws->status; } void checkstatus(u32int status, char *info) { if(status == 0) return; snprint(up->genbuf, sizeof(up->genbuf), "%s: status %ux", info, status); error(up->genbuf); } static long nvmebio(SDunit *u, int lun, int write, void *a, long count, uvlong lba) { u32int nsid, s, n, m, *e; Ctlr *ctlr; uchar *p; WS ws; USED(lun); ctlr = u->dev->ctlr; nsid = ctlr->nsid[u->subno]; s = u->secsize; p = a; while(count > 0){ m = (2*ctlr->mps - ((uintptr)p & ctlr->mps-1)) / s; if((n = count) > m) n = m; e = qcmd(&ws, ctlr, 0, write ? 0x01 : 0x02, nsid, p, n*s); e[10] = lba; e[11] = lba>>32; e[12] = n-1; e[13] = (count>n)<<6; /* sequential request */ e[14] = 0; e[15] = 0; checkstatus(wcmd(&ws, e), write ? "write" : "read"); p += n*s; count -= n; lba += n; } if(!write){ dmaflush(0, a, p - (uchar*)a); } return p - (uchar*)a; } static int nvmerio(SDreq *r) { int i, count, rw; uvlong lba; SDunit *u; u = r->unit; if(r->cmd[0] == 0x35 || r->cmd[0] == 0x91) return sdsetsense(r, SDok, 0, 0, 0); if((i = sdfakescsi(r)) != SDnostatus) return r->status = i; if((i = sdfakescsirw(r, &lba, &count, &rw)) != SDnostatus) return i; r->rlen = nvmebio(u, r->lun, rw == SDwrite, r->data, count, lba); return r->status = SDok; } static u64int get64(uchar *p) { return p[0] | p[1]<<8 | p[2]<<16 | p[3]<<24 | (u64int)p[4]<<32 | (u64int)p[5]<<40 | (u64int)p[6]<<48 | (u64int)p[7]<<56; } static long readsmart(SDunit *u, Chan *, void *a, long n, vlong off) { Ctlr *ctlr = u->dev->ctlr; char *buf, *p, *e; uchar *info; u32int nsid, *q; WS ws; buf = smalloc(READSTR); if(waserror()){ free(buf); nexterror(); } p = buf; e = buf + READSTR; info = mallocalign(0x1000, ctlr->mps, 0, 0); if(info == nil) error(Enomem); if(waserror()){ free(info); nexterror(); } /* * Log Page Attributes (LPA) Bit0: If set to '1' then te controller * supports SMART / Health information log page on a per namespace basis. */ nsid = (ctlr->ident[261] & 1) != 0 ? ctlr->nsid[u->subno] : 0xffffffff; q = qcmd(&ws, ctlr, 1, 0x02, nsid, info, 0x1000); q[10] = (512/4)<<16 | 0x2; q[11] = 0; q[12] = 0; q[13] = 0; q[14] = 0; checkstatus(wcmd(&ws, q), "read SMART/health info"); dmaflush(0, info, 0x1000); p = seprint(p, e, "Critical Warning:\t"); if(info[0]&(1<<0)) p = seprint(p, e, "Available Spare,"); if(info[0]&(1<<1)) p = seprint(p, e, "Temperature Exceeded,"); if(info[0]&(1<<2)) p = seprint(p, e, "Reliability Degraded,"); if(info[0]&(1<<3)) p = seprint(p, e, "Read only mode,"); if(info[0]&(1<<4)) p = seprint(p, e, "Backup failed,"); p[-1] = '\n'; p = seprint(p, e, "Temperature:\t%d\n", (info[2]<<8 | info[1]) - 273); p = seprint(p, e, "Available Spare:\t%d%%\n", info[3]); p = seprint(p, e, "Available Spare Threshold:\t%d%%\n", info[4]); p = seprint(p, e, "Percentage Used:\t%d%%\n", info[5]); p = seprint(p, e, "Data Units Read:\t%llud\n", get64(info+32)); p = seprint(p, e, "Data Units Written:\t%llud\n", get64(info+48)); p = seprint(p, e, "Host Read Commands:\t%llud\n", get64(info+64)); p = seprint(p, e, "Host Write Commands:\t%llud\n", get64(info+80)); p = seprint(p, e, "Controller Busy Time:\t%llud:%.2d\n", get64(info+96)/60, (int)(get64(info+96)%60)); p = seprint(p, e, "Power Cycles:\t%llud\n", get64(info+112)); p = seprint(p, e, "Power On Hours:\t%llud\n", get64(info+128)); p = seprint(p, e, "Unsafe Shutdowns:\t%llud\n", get64(info+144)); p = seprint(p, e, "Media Errors:\t%llud\n", get64(info+160)); USED(p); free(info); poperror(); n = readstr(off, a, n, buf); free(buf); poperror(); return n; } static int nvmeverify(SDunit *u) { Ctlr *ctlr = u->dev->ctlr; if(u->subno >= ctlr->nnsid) return 0; sdaddfile(u, "smart", 0440, eve, readsmart, nil); return 1; } static int nvmeonline(SDunit *u) { u32int *e, lbaf; uchar *info, *p; Ctlr *ctlr; WS ws; if(u->sectors != 0) return 1; ctlr = u->dev->ctlr; if((info = mallocalign(0x1000, ctlr->mps, 0, 0)) == nil) return 0; e = qcmd(&ws, ctlr, 1, 0x06, ctlr->nsid[u->subno], info, 0x1000); e[10] = 0; // identify namespace if(wcmd(&ws, e) != 0){ free(info); return 0; } dmaflush(0, info, 0x1000); u->sectors = get64(info); p = &info[128 + 4*(info[26]&15)]; lbaf = p[0] | p[1]<<8 | p[2]<<16 | p[3]<<24; u->secsize = 1<<((lbaf>>16)&0xFF); free(info); memset(u->inquiry, 0, sizeof u->inquiry); u->inquiry[2] = 2; u->inquiry[3] = 2; u->inquiry[4] = sizeof u->inquiry - 4; memmove(u->inquiry+8, ctlr->ident+24, 20); return 2; } static int nvmerctl(SDunit *u, char *p, int l) { Ctlr *ctlr; char *e, *s; if((ctlr = u->dev->ctlr) == nil || ctlr->ident == nil) return 0; e = p+l; s = p; p = seprint(p, e, "model\t%.40s\n", (char*)ctlr->ident+24); p = seprint(p, e, "serial\t%.20s\n", (char*)ctlr->ident+4); p = seprint(p, e, "firm\t%.8s\n", (char*)ctlr->ident+64); p = seprint(p, e, "geometry %llud %lud\n", u->sectors, u->secsize); return p-s; } static void* cqalloc(Ctlr *ctlr, CQ *cq, u32int lgsize) { cq->ctlr = ctlr; cq->head = 0; cq->shift = lgsize-4; cq->mask = (1<<cq->shift)-1; if((cq->base = mallocalign(1<<lgsize, ctlr->mps, 0, 0)) == nil) error(Enomem); memset(cq->base, 0, 1<<lgsize); return cq->base; } static void* sqalloc(Ctlr *ctlr, SQ *sq, u32int lgsize) { sq->ctlr = ctlr; sq->tail = 0; sq->shift = lgsize-6; sq->mask = (1<<sq->shift)-1; if((sq->base = mallocalign(1<<lgsize, ctlr->mps, 0, 0)) == nil) error(Enomem); if((sq->wait = mallocz(sizeof(WS*)*(sq->mask+1), 1)) == nil) error(Enomem); memset(sq->base, 0, 1<<lgsize); return sq->base; } static void setupqueues(Ctlr *ctlr) { u32int mqes, lgcqsize, lgsqsize, nsq, st, *e; CQ *cq; SQ *sq; WS ws; int i; mqes = 1 + (ctlr->cap & 0xFFFF); if(mqes < 2) mqes = 2; for(lgsqsize = 0; 1<<lgsqsize < mqes; lgsqsize++) ; if(lgsqsize > 12-6) lgsqsize = 12-6; nsq = conf.nmach; while((lgcqsize = lgsqsize) > 0){ while(nsq >= 1<<lgcqsize) nsq >>= 1; while(1<<lgcqsize < nsq<<lgsqsize) lgcqsize++; if(1<<lgcqsize <= mqes) break; lgsqsize--; } lgsqsize += 6; lgcqsize += 4; /* CQID1: shared completion queue */ cq = &ctlr->cq[1]; cqalloc(ctlr, cq, lgcqsize); e = qcmd(&ws, ctlr, 1, 0x05, 0, cq->base, 1<<lgcqsize); e[10] = (cq - ctlr->cq) | cq->mask<<16; e[11] = 3; /* IEN | PC */ checkstatus(wcmd(&ws, e), "create completion queue"); st = 0; /* SQID[1..nmach]: submission queue per cpu */ for(i=1; i<=nsq; i++){ sq = &ctlr->sq[i]; sqalloc(ctlr, sq, lgsqsize); e = qcmd(&ws, ctlr, 1, 0x01, 0, sq->base, 1<<lgsqsize); e[10] = i | sq->mask<<16; e[11] = (cq - ctlr->cq)<<16 | 1; /* CQID<<16 | PC */ st = wcmd(&ws, e); if(st != 0){ free(sq->base); free(sq->wait); memset(sq, 0, sizeof(*sq)); break; } } ctlr->nsq = i - 1; if(ctlr->nsq < 1) checkstatus(st, "create submission queues"); ilock(&ctlr->intr); ctlr->ints |= 1<<(cq - ctlr->cq); ctlr->reg[IntMc] = ctlr->ints; iunlock(&ctlr->intr); } static void identify(Ctlr *ctlr) { u32int *e; WS ws; if(ctlr->ident == nil) if((ctlr->ident = mallocalign(0x1000, ctlr->mps, 0, 0)) == nil) error(Enomem); if(ctlr->nsid == nil) if((ctlr->nsid = mallocalign(0x1000, ctlr->mps, 0, 0)) == nil) error(Enomem); e = qcmd(&ws, ctlr, 1, 0x06, 0, ctlr->ident, 0x1000); e[10] = 1; // identify controller checkstatus(wcmd(&ws, e), "identify controller"); dmaflush(0, ctlr->ident, 0x1000); e = qcmd(&ws, ctlr, 1, 0x06, 0, ctlr->nsid, 0x1000); e[10] = 2; // namespace list if(wcmd(&ws, e) == 0) { dmaflush(0, ctlr->nsid, 0x1000); } else ctlr->nsid[0] = 1; /* assume namespace #1 */ ctlr->nnsid = 0; while(ctlr->nnsid < 1024 && ctlr->nsid[ctlr->nnsid] != 0) ctlr->nnsid++; } static int nvmedisable(SDev *sd) { char name[32]; Ctlr *ctlr; int i; ctlr = sd->ctlr; /* mask interrupts */ ilock(&ctlr->intr); ctlr->ints = 0; ctlr->reg[IntMs] = ~ctlr->ints; iunlock(&ctlr->intr); /* notify normal power off */ ctlr->reg[CCfg] = (ctlr->reg[CCfg] & ~(3<<14)) | 1<<14; for(i = 0; i < 3000; i++){ if((ctlr->reg[CSts] & 0xc) == 0x8) break; delay(1); } /* disable controller */ ctlr->reg[CCfg] = 0; for(i = 0; i < 1000; i++){ if((ctlr->reg[CSts] & 1) == 0) break; delay(1); } snprint(name, sizeof(name), "%s (%s)", sd->name, sd->ifc->name); intrdisable(ctlr->pci->intl, nvmeintr, ctlr, ctlr->pci->tbdf, name); pciclrbme(ctlr->pci); /* dma disable */ for(i=0; i<nelem(ctlr->sq); i++){ free(ctlr->sq[i].base); free(ctlr->sq[i].wait); } for(i=0; i<nelem(ctlr->cq); i++) free(ctlr->cq[i].base); memset(ctlr->sq, 0, sizeof(ctlr->sq)); memset(ctlr->cq, 0, sizeof(ctlr->cq)); free(ctlr->ident); ctlr->ident = nil; free(ctlr->nsid); ctlr->nsid = nil; ctlr->nnsid = 0; return 1; } static int nvmeenable(SDev *sd) { char name[32]; Ctlr *ctlr; u64int pa; int to; ctlr = sd->ctlr; snprint(name, sizeof(name), "%s (%s)", sd->name, sd->ifc->name); intrenable(ctlr->pci->intl, nvmeintr, ctlr, ctlr->pci->tbdf, name); if(waserror()){ print("%s: %s\n", name, up->errstr); nvmedisable(sd); sd->nunit = 0; /* hack: prevent further probing */ return 0; } pa = PCIWADDR(cqalloc(ctlr, &ctlr->cq[0], ctlr->mpsshift)); dmaflush(1, ctlr->cq[0].base, 1<<ctlr->mpsshift); ctlr->reg[ACQBase0] = pa; ctlr->reg[ACQBase1] = pa>>32; pa = PCIWADDR(sqalloc(ctlr, &ctlr->sq[0], ctlr->mpsshift)); dmaflush(1, ctlr->sq[0].base, 1<<ctlr->mpsshift); ctlr->reg[ASQBase0] = pa; ctlr->reg[ASQBase1] = pa>>32; ctlr->reg[AQAttr] = ctlr->sq[0].mask | ctlr->cq[0].mask<<16; /* dma enable */ pcisetbme(ctlr->pci); /* enable interrupt */ ilock(&ctlr->intr); ctlr->ints = 1; ctlr->reg[IntMc] = ctlr->ints; iunlock(&ctlr->intr); /* enable controller */ ctlr->reg[CCfg] = 1 | (ctlr->mpsshift-12)<<7 | 6<<16 | 4<<20; for(to = (ctlr->cap>>24) & 255; to >= 0; to--){ tsleep(&up->sleep, return0, nil, 500); if((ctlr->reg[CSts] & 3) == 1) goto Ready; } if(ctlr->reg[CSts] & 2) error("fatal controller status during initialization"); error("controller initialization timeout"); Ready: identify(ctlr); setupqueues(ctlr); print("%s: using %d submit queues\n", name, ctlr->nsq); poperror(); return 1; } static Ctlr* nvmepnpctlrs(void) { Ctlr *ctlr, *h, *t; Pcidev *p; int i; h = t = nil; for(p = nil; p = pcimatch(p, 0, 0);){ if(p->ccrb != 1 || p->ccru != 8 || p->ccrp != 2) continue; if(p->mem[0].size == 0 || (p->mem[0].bar & 1) != 0) continue; if((ctlr = malloc(sizeof(*ctlr))) == nil){ print("nvme: no memory for Ctlr\n"); break; } pcienable(p); ctlr->pci = p; ctlr->reg = vmap(p->mem[0].bar & ~0xF, p->mem[0].size); if(ctlr->reg == nil){ print("nvme: can't vmap bar0\n"); Bad: if(ctlr->reg != nil) vunmap(ctlr->reg, p->mem[0].size); pcidisable(p); free(ctlr); continue; } ctlr->cap = ctlr->reg[Cap0]; ctlr->cap |= (u64int)ctlr->reg[Cap1]<<32; /* mask interrupts */ ctlr->ints = 0; ctlr->reg[IntMs] = ~ctlr->ints; /* disable controller */ ctlr->reg[CCfg] = 0; if((ctlr->cap&(1ULL<<37)) == 0){ print("nvme: doesnt support NVM commactlr set: %ux\n", (u32int)(ctlr->cap>>37) & 0xFF); goto Bad; } /* use 64K page size when possible */ ctlr->dstrd = (ctlr->cap >> 32) & 15; for(i = (ctlr->cap >> 48) & 15; i < ((ctlr->cap >> 52) & 15); i++){ if(i >= 16-12) /* 64K */ break; } ctlr->mpsshift = i+12; ctlr->mps = 1 << ctlr->mpsshift; if(h == nil) h = ctlr; else t->next = ctlr; t = ctlr; } return h; } SDifc sdnvmeifc; static SDev* nvmepnp(void) { SDev *s, *h, *t; Ctlr *ctlr; int id; h = t = nil; id = 'N'; for(ctlr = nvmepnpctlrs(); ctlr != nil; ctlr = ctlr->next){ if((s = malloc(sizeof(*s))) == nil) break; s->ctlr = ctlr; s->idno = id++; s->ifc = &sdnvmeifc; s->nunit = 1024; if(h) t->next = s; else h = s; t = s; } return h; } SDifc sdnvmeifc = { "nvme", /* name */ nvmepnp, /* pnp */ nil, /* legacy */ nvmeenable, /* enable */ nvmedisable, /* disable */ nvmeverify, /* verify */ nvmeonline, /* online */ nvmerio, /* rio */ nvmerctl, /* rctl */ nil, /* wctl */ nvmebio, /* bio */ nil, /* probe */ nil, /* clear */ nil, /* rtopctl */ nil, /* wtopctl */ };