ref: a0e67fe7a4c9db6cfc59655a6a3611e90c344115
dir: /blk.c/
#include <u.h> #include <libc.h> #include <fcall.h> #include <avl.h> #include "dat.h" #include "fns.h" typedef struct Range Range; typedef struct Flushq Flushq; struct Range { vlong off; vlong len; }; struct Flushq { Blk **heap; int nheap; int heapsz; }; static vlong blkalloc_lk(Arena*); static vlong blkalloc(int); static int blkdealloc_lk(vlong); static Blk* initblk(vlong, int); static int logop(Arena *, vlong, vlong, int); static Blk magic; void setflag(Blk *b, int flg) { long ov, nv; while(1){ ov = b->flag; nv = ov | flg; if(cas(&b->flag, ov, nv)) break; } } void clrflag(Blk *b, int flg) { long ov, nv; while(1){ ov = b->flag; nv = ov & ~flg; if(cas(&b->flag, ov, nv)) break; } } int syncblk(Blk *b) { assert(b->flag & Bfinal); clrflag(b, Bqueued|Bdirty); return pwrite(fs->fd, b->buf, Blksz, b->bp.addr); } static Blk* readblk(vlong bp, int flg) { Blk *b; vlong off, rem, n; assert(bp != -1); if((b = malloc(sizeof(Blk))) == nil) return nil; off = bp; rem = Blksz; while(rem != 0){ n = pread(fs->fd, b->buf, rem, off); if(n <= 0){ free(b); return nil; } off += n; rem -= n; } b->ref = 1; b->cnext = nil; b->cprev = nil; b->hnext = nil; b->flag = 0; b->type = (flg&GBraw) ? Traw : GBIT16(b->buf+0); b->bp.addr = bp; b->bp.hash = -1; b->bp.gen = -1; b->data = b->buf + Hdrsz; b->fnext = nil; b->nval = 0; b->valsz = 0; b->nbuf = 0; b->bufsz = 0; b->logsz = 0; b->lognxt = 0; switch(b->type){ default: fprint(2, "invalid block @%llx\n", bp); abort(); break; case Tarena: case Traw: case Tlog: case Tdead: break; case Tpivot: b->nval = GBIT16(b->buf+2); b->valsz = GBIT16(b->buf+4); b->nbuf = GBIT16(b->buf+6); b->bufsz = GBIT16(b->buf+8); break; case Tleaf: b->nval = GBIT16(b->buf+2); b->valsz = GBIT16(b->buf+4); break; } return b; } static Arena* pickarena(int hint) { int n; n = hint+ainc(&fs->roundrobin)/(64*1024); return &fs->arenas[n%fs->narena]; } Arena* getarena(vlong b) { int i; i = b / fs->arenasz; if(i < 0 || i >= fs->narena){ werrstr("out of range block %lld", b); abort(); return nil; } return &fs->arenas[i]; } static int freerange(Avltree *t, vlong off, vlong len) { Arange *r, *s; assert(len % Blksz == 0); if((r = calloc(1, sizeof(Arange))) == nil) return -1; r->off = off; r->len = len; assert(avllookup(t, r, 0) == nil); avlinsert(t, r); Again: s = (Arange*)avlprev(r); if(s != nil && s->off+s->len == r->off){ avldelete(t, r); s->len = s->len + r->len; free(r); r = s; goto Again; } s = (Arange*)avlnext(r); if(s != nil && r->off+r->len == s->off){ avldelete(t, r); s->off = r->off; s->len = s->len + r->len; free(r); r = s; goto Again; } return 0; } static int syncarena(Arena *a) { packarena(a->b->data, Blkspc, a, fs); finalize(a->b); return syncblk(a->b); } static int grabrange(Avltree *t, vlong off, vlong len) { Arange *r, *s, q; vlong l; assert(len % Blksz == 0); q.off = off; q.len = len; r = (Arange*)avllookup(t, &q.Avl, -1); if(r == nil || off + len > r->off + r->len) abort(); if(off == r->off){ r->off += len; r->len -= len; }else if(off + len == r->off + r->len){ r->len -= len; }else if(off > r->off && off+len < r->off + r->len){ if((s = malloc(sizeof(Arange))) == nil) return -1; l = r->len; s->off = off + len; r->len = off - r->off; s->len = l - r->len - len; avlinsert(t, s); }else abort(); if(r->len == 0){ avldelete(t, r); free(r); } return 0; } /* * Logs an allocation. Must be called * with arena lock held. Duplicates some * of the work in allocblk to prevent * recursion. */ static int logappend(Arena *a, vlong off, vlong len, int op, Blk **tl) { Blk *pb, *lb; vlong o; char *p; assert(off % Blksz == 0); assert(op == LogAlloc || op == LogFree); o = -1; lb = *tl; dprint("logop %llx+%llx@%llx: %s\n", off, len, lb->logsz, (op == LogAlloc) ? "Alloc" : "Free"); /* * move to the next block when we have * 40 bytes in the log: * We're appending up to 16 bytes as * part of the operation, followed by * 16 bytes of new log entry allocation * and chaining. */ if(lb == nil || lb->logsz >= Logspc - 40){ pb = lb; if((o = blkalloc_lk(a)) == -1) return -1; if((lb = initblk(o, Tlog)) == nil) return -1; cacheblk(lb); lb->logsz = Loghdsz; p = lb->data + lb->logsz; PBIT64(p, (uvlong)LogEnd); finalize(lb); if(syncblk(lb) == -1){ putblk(lb); return -1; } if(pb != nil){ p = pb->data + pb->logsz; PBIT64(p, lb->bp.addr|LogChain); finalize(pb); if(syncblk(pb) == -1){ putblk(pb); return -1; } putblk(pb); } *tl = lb; } if(len == Blksz){ if(op == LogAlloc) op = LogAlloc1; else if(op == LogFree) op = LogFree1; } off |= op; p = lb->data + lb->logsz; PBIT64(p, off); lb->logsz += 8; if(op >= Log2wide){ PBIT64(p+8, len); lb->logsz += 8; } /* * The newly allocated log block needs * to be recorded. If we're compressing * a log, it needs to go to the tail of * the new log, rather than after the * current allocation. * * Because we've just grown the log, we * know it won't recurse. */ if(o != -1) logop(a, o, Blksz, LogAlloc); /* this gets overwritten by the next append */ p = lb->data + lb->logsz; PBIT64(p, (uvlong)LogEnd); return 0; } static int logop(Arena *a, vlong off, vlong len, int op) { if(logappend(a, off, len, op, &a->tail) == -1) return -1; if(a->head.addr == -1) a->head = a->tail->bp; return 0; } int loadlog(Arena *a) { vlong ent, off, len; int op, i, n; uvlong bh; Bptr bp; char *d; Blk *b; bp = a->head; Nextblk: if((b = getblk(bp, GBnochk)) == nil) return -1; bh = GBIT64(b->data); /* the hash covers the log and offset */ if(bh != siphash(b->data+8, Blkspc-8)){ werrstr("corrupt log"); return -1; } for(i = Loghdsz; i < Logspc; i += n){ d = b->data + i; ent = GBIT64(d); op = ent & 0xff; off = ent & ~0xff; n = (op >= Log2wide) ? 16 : 8; switch(op){ case LogEnd: dprint("log@%d: end\n", i); return 0; case LogChain: bp.addr = off & ~0xff; bp.hash = -1; bp.gen = -1; dprint("log@%d: chain %B\n", i, bp); b->logsz = i+n; goto Nextblk; break; case LogAlloc: case LogAlloc1: len = (op >= Log2wide) ? GBIT64(d+8) : Blksz; dprint("log@%d alloc: %llx+%llx\n", i, off, len); if(grabrange(a->free, off & ~0xff, len) == -1) return -1; break; case LogFree: case LogFree1: len = (op >= Log2wide) ? GBIT64(d+8) : Blksz; dprint("log@%d free: %llx+%llx\n", i, off, len); if(freerange(a->free, off & ~0xff, len) == -1) return -1; break; default: n = 0; dprint("log@%d: log op %d\n", i, op); abort(); break; } } return -1; } int compresslog(Arena *a) { Arange *r; Range *log, *nlog; vlong v, ba, na, graft, oldhd; int i, n, sz; Blk *b, *hd, *tl; Bptr bp; char *p; /* * Sync the current log to disk, and * set up a new block log tail. While * compressing the log, nothing else is * using this arena, so any allocs come * from the log compression, and go into * this new log segment. * * A bit of copy paste from newblk, * because otherwise we have a deadlock * allocating the block. */ if((ba = blkalloc_lk(a)) == -1) return -1; if((b = initblk(ba, Tlog)) == nil) return -1; setflag(b, Bdirty); b->logsz = Loghdsz; p = b->data + b->logsz; PBIT64(p, (uvlong)LogEnd); finalize(b); if(syncblk(b) == -1){ free(b); return -1; } graft = b->bp.addr; if(a->tail != nil){ finalize(a->tail); if(syncblk(a->tail) == -1){ free(b); return -1; } } a->tail = b; /* * Prepare what we're writing back. * Arenas must be sized so that we can * keep the merged log in memory for * a rewrite. */ n = 0; sz = 512; if((log = malloc(sz*sizeof(Range))) == nil) return -1; /* * we need to allocate this block before * we prepare the ranges we write back, * so we don't record this block as * available when we compress the log. */ if((ba = blkalloc_lk(a)) == -1){ free(log); return -1; } if((b = initblk(ba, Tlog)) == nil){ free(log); return -1; } for(r = (Arange*)avlmin(a->free); r != nil; r = (Arange*)avlnext(r)){ if(n == sz){ sz *= 2; if((nlog = realloc(log, sz*sizeof(Range))) == nil){ free(log); return -1; } log = nlog; } log[n].off = r->off; log[n].len = r->len; n++; } hd = b; tl = b; b->logsz = Loghdsz; for(i = 0; i < n; i++) if(logappend(a, log[i].off, log[i].len, LogFree, &tl) == -1) return -1; p = tl->data + tl->logsz; PBIT64(p, LogChain|graft); free(log); finalize(tl); if(syncblk(tl) == -1) return -1; oldhd = a->head.addr; a->head.addr = hd->bp.addr; a->head.hash = blkhash(hd); a->head.gen = -1; if(syncarena(a) == -1) return -1; if(oldhd != -1){ for(ba = oldhd; ba != -1; ba = na){ na = -1; bp.addr = ba; bp.hash = -1; bp.gen = -1; if((b = getblk(bp, GBnochk)) == nil) return -1; for(i = Loghdsz; i < Logspc; i += n){ p = b->data + i; v = GBIT64(p); n = ((v&0xff) >= Log2wide) ? 16 : 8; if((v&0xff) == LogChain){ na = v & ~0xff; break; }else if((v&0xff) == LogEnd){ na = -1; break; } } lock(a); if(blkdealloc_lk(ba) == -1){ unlock(a); return -1; } unlock(a); } } finalize(a->tail); if(syncblk(a->tail) == -1) return -1; return 0; } /* * Allocate from an arena, with lock * held. May be called multiple times * per operation, to alloc space for * the alloc log. */ static vlong blkalloc_lk(Arena *a) { Avltree *t; Arange *r; vlong b; t = a->free; r = (Arange*)t->root; if(r == nil){ unlock(a); return -1; } /* * A bit of sleight of hand here: * while we're changing the sorting * key, but we know it won't change * the sort order because the tree * covers disjoint ranges */ b = r->off; r->len -= Blksz; r->off += Blksz; if(r->len == 0){ avldelete(t, r); free(r); } a->used += Blksz; return b; } static int blkdealloc_lk(vlong b) { Arena *a; int r; r = -1; a = getarena(b); if(freerange(a->free, b, Blksz) == -1) goto out; if(logop(a, b, Blksz, LogFree) == -1) goto out; a->used -= Blksz; r = 0; out: return r; } static vlong blkalloc(int hint) { Arena *a; vlong b; int tries; tries = 0; Again: a = pickarena(hint+tries); if(a == nil || tries == fs->narena){ werrstr("no empty arenas"); return -1; } /* * TODO: there's an extreme edge case * here. * * If the file system has room to alloc * a data block but no log block, then * we end up with it in a stuck state. * The fix is to reserve alloc blocks, * so that we're guaranteed to be able * to log an alloc if the disk is working * correctly. */ tries++; lock(a); if((b = blkalloc_lk(a)) == -1){ unlock(a); goto Again; } if(logop(a, b, Blksz, LogAlloc) == -1){ unlock(a); return -1; } unlock(a); return b; } static Blk* initblk(vlong bp, int t) { Blk *b; if((b = lookupblk(bp)) == nil){ if((b = malloc(sizeof(Blk))) == nil) return nil; setmalloctag(b, getcallerpc(&bp)); /* * If the block is cached, * then the cache holds a ref * to the block, so we only * want to reset the refs * on an allocation. */ b->ref = 1; b->cnext = nil; b->cprev = nil; b->hnext = nil; b->flag = 0; } b->type = t; b->bp.addr = bp; b->bp.hash = -1; b->bp.gen = fs->nextgen; b->data = b->buf + Hdrsz; b->fnext = nil; setflag(b, Bdirty); b->nval = 0; b->valsz = 0; b->nbuf = 0; b->bufsz = 0; b->logsz = 0; b->lognxt = 0; return cacheblk(b); } Blk* newblk(int t) { vlong bp; Blk *b; if((bp = blkalloc(t)) == -1) return nil; if((b = initblk(bp, t)) == nil) return nil; setmalloctag(b, getcallerpc(&t)); return b; } Blk* dupblk(Blk *b) { Blk *r; if((r = newblk(b->type)) == nil) return nil; setflag(r, Bdirty); r->bp.hash = b->bp.hash; r->nval = b->nval; r->valsz = b->valsz; r->nbuf = b->nbuf; r->bufsz = b->bufsz; r->logsz = b->logsz; r->lognxt = b->lognxt; memcpy(r->buf, b->buf, sizeof(r->buf)); setmalloctag(b, getcallerpc(&b)); return r; } void finalize(Blk *b) { vlong h; setflag(b, Bfinal); if(b->type != Traw) PBIT16(b->buf, b->type); switch(b->type){ default: case Tnone: abort(); break; case Tpivot: PBIT16(b->buf+2, b->nval); PBIT16(b->buf+4, b->valsz); PBIT16(b->buf+6, b->nbuf); PBIT16(b->buf+8, b->bufsz); b->bp.hash = blkhash(b); break; case Tleaf: PBIT16(b->buf+2, b->nval); PBIT16(b->buf+4, b->valsz); b->bp.hash = blkhash(b); break; case Tlog: case Tdead: h = siphash(b->data + 8, Blkspc-8); PBIT64(b->data, h); b->bp.hash = blkhash(b); break; case Traw: b->bp.hash = blkhash(b); break; case Tarena: break; } } Blk* getblk(Bptr bp, int flg) { uvlong h; Blk *b; int i; if((b = lookupblk(bp.addr)) != nil) return cacheblk(b); i = ihash(bp.addr) % nelem(fs->blklk); qlock(&fs->blklk[i]); if((b = lookupblk(bp.addr)) != nil){ cacheblk(b); qunlock(&fs->blklk[i]); return b; } if((b = readblk(bp.addr, flg)) == nil){ qunlock(&fs->blklk[i]); return nil; }else setmalloctag(b, getcallerpc(&bp)); h = blkhash(b); if((flg&GBnochk) == 0 && h != bp.hash){ fprint(2, "corrupt block %B: %llx != %llx\n", bp, blkhash(b), bp.hash); qunlock(&fs->blklk[i]); abort(); return nil; } b->bp.hash = h; b->bp.gen = bp.gen; cacheblk(b); qunlock(&fs->blklk[i]); return b; } Blk* refblk(Blk *b) { ainc(&b->ref); return b; } ushort blkfill(Blk *b) { switch(b->type){ case Tpivot: return 2*b->nbuf + b->bufsz + 2*b->nval + b->valsz; case Tleaf: return 2*b->nval + b->valsz; default: fprint(2, "invalid block @%lld\n", b->bp.addr); abort(); } return 0; // shut up kencc } void putblk(Blk *b) { if(b == nil || adec(&b->ref) != 0) return; assert(!(b->flag & Bcached)); assert((b->flag & Bfreed) || !(b->flag & Bdirty)); free(b); } void freebp(Tree *t, Bptr bp) { Bfree *f; dprint("[%s] free blk %B\n", (t == &fs->snap) ? "snap" : "data", bp); if(t != nil && bp.gen <= t->gen){ killblk(t, bp); return; } if((f = malloc(sizeof(Bfree))) == nil) return; f->bp = bp; lock(&fs->freelk); f->next = fs->freehd; fs->freehd = f; unlock(&fs->freelk); } void freeblk(Tree *t, Blk *b) { b->freed = getcallerpc(&b); setflag(b, Bfreed); freebp(t, b->bp); } void reclaimblk(Bptr bp) { Arena *a; a = getarena(bp.addr); lock(a); blkdealloc_lk(bp.addr); cachedel(bp.addr); unlock(a); } void quiesce(int tid) { int i, allquiesced; Bfree *p, *n; lock(&fs->activelk); allquiesced = 1; fs->active[tid]++; for(i = 0; i < fs->nquiesce; i++){ /* * Odd parity on quiescence implies * that we're between the exit from * and waiting for the next message * that enters us into the critical * section. */ if((fs->active[i] & 1) == 0) continue; if(fs->active[i] == fs->lastactive[i]) allquiesced = 0; } if(allquiesced) for(i = 0; i < fs->nquiesce; i++) fs->lastactive[i] = fs->active[i]; unlock(&fs->activelk); if(!allquiesced) return; lock(&fs->freelk); p = nil; if(fs->freep != nil){ p = fs->freep->next; fs->freep->next = nil; } unlock(&fs->freelk); while(p != nil){ n = p->next; reclaimblk(p->bp); free(p); p = n; } fs->freep = fs->freehd; } int blkcmp(Blk *a, Blk *b) { if(a->bp.gen != b->bp.gen) return (a->bp.gen < b->bp.gen) ? -1 : 1; if(a->bp.addr != b->bp.addr) return (a->bp.addr < b->bp.addr) ? -1 : 1; return 0; } void enqueue(Blk *b) { Arena *a; a = getarena(b->bp.addr); assert(b->flag & Bdirty); refblk(b); finalize(b); chsend(a->sync, b); } static void qput(Flushq *q, Blk *b) { Blk *t; int i; if(q->nheap == q->heapsz) abort(); q->heap[q->nheap] = b; for(i = q->nheap; i > 0; i = (i-1)/2){ if(blkcmp(q->heap[i], q->heap[(i-1)/2]) == -1) break; t = q->heap[i]; q->heap[i] = q->heap[(i-1)/2]; q->heap[(i-1)/2] = t; } q->nheap++; } static Blk* qpop(Flushq *q) { int i, l, r, m; Blk *b, *t; if(q->nheap == 0) return nil; b = q->heap[0]; if(--q->nheap == 0) return b; i = 0; q->heap[0] = q->heap[q->nheap]; while(1){ m = i; l = 2*i+1; r = 2*i+2; if(l < q->nheap && blkcmp(q->heap[m], q->heap[l]) == -1) m = l; if(r < q->nheap && blkcmp(q->heap[m], q->heap[r]) == -1) m = r; if(m == i) break; t = q->heap[m]; q->heap[m] = q->heap[i]; q->heap[i] = t; i = m; } return b; } void runsync(int, void *p) { Flushq q; Chan *c; Blk *b; c = p; q.nheap = 0; q.heapsz = fs->cmax; if((q.heap = malloc(q.heapsz*sizeof(Blk*))) == nil) sysfatal("alloc queue: %r"); while(1){ while(q.nheap < q.heapsz){ b = chrecv(c, q.nheap == 0); if(b == &magic){ qlock(&fs->synclk); if(--fs->syncing == 0) rwakeupall(&fs->syncrz); qunlock(&fs->synclk); continue; } if(b != nil) qput(&q, b); if(b == nil || q.nheap == q.heapsz) break; } b = qpop(&q); if(!(b->flag & Bfreed)){ if(syncblk(b) == -1){ ainc(&fs->broken); fprint(2, "write: %r"); abort(); } } putblk(b); } } void sync(void) { Arena *a; int i; qlock(&fs->synclk); fs->syncing = fs->nsyncers; for(i = 0; i < fs->nsyncers; i++) chsend(fs->chsync[i], &magic); while(fs->syncing != 0) rsleep(&fs->syncrz); for(i = 0; i < fs->narena; i++){ a = &fs->arenas[i]; finalize(a->tail); if(syncblk(a->tail) == -1) sysfatal("sync arena: %r"); if(syncarena(a) == -1) sysfatal("sync arena: %r"); } qunlock(&fs->synclk); }