ref: e2a8d3493ab0fdc345b6513a53f30f2b4f36ed97
dir: /sys/src/libventi/cache.c/
/* * Memory-only VtBlock cache. * * The cached Venti blocks are in the hash chains. * The cached local blocks are only in the blocks array. * The free blocks are in the heap, which is supposed to * be indexed by second-to-last use but actually * appears to be last use. */ #include <u.h> #include <libc.h> #include <venti.h> int vtcachenread; int vtcachencopy; int vtcachenwrite; int vttracelevel; enum { BioLocal = 1, BioVenti, BioReading, BioWriting, BioEmpty, BioVentiError }; enum { BadHeap = ~0 }; struct VtCache { QLock lk; VtConn *z; u32int blocksize; u32int now; /* ticks for usage time stamps */ VtBlock **hash; /* hash table for finding addresses */ int nhash; VtBlock **heap; /* heap for finding victims */ int nheap; VtBlock *block; /* all allocated blocks */ int nblock; uchar *mem; /* memory for all blocks and data */ int (*write)(VtConn*, uchar[VtScoreSize], uint, uchar*, int); }; static void cachecheck(VtCache*); VtCache* vtcachealloc(VtConn *z, int blocksize, ulong nblock) { uchar *p; VtCache *c; int i; VtBlock *b; c = vtmallocz(sizeof(VtCache)); c->z = z; c->blocksize = (blocksize + 127) & ~127; c->nblock = nblock; c->nhash = nblock; c->hash = vtmallocz(nblock*sizeof(VtBlock*)); c->heap = vtmallocz(nblock*sizeof(VtBlock*)); c->block = vtmallocz(nblock*sizeof(VtBlock)); c->mem = vtmallocz(nblock*c->blocksize); c->write = vtwrite; p = c->mem; for(i=0; i<nblock; i++){ b = &c->block[i]; b->addr = NilBlock; b->c = c; b->data = p; b->heap = i; c->heap[i] = b; p += c->blocksize; } c->nheap = nblock; cachecheck(c); return c; } /* * BUG This is here so that vbackup can override it and do some * pipelining of writes. Arguably vtwrite or vtwritepacket or the * cache itself should be providing this functionality. */ void vtcachesetwrite(VtCache *c, int (*write)(VtConn*, uchar[VtScoreSize], uint, uchar*, int)) { if(write == nil) write = vtwrite; c->write = write; } void vtcachefree(VtCache *c) { int i; qlock(&c->lk); cachecheck(c); for(i=0; i<c->nblock; i++) assert(c->block[i].ref == 0); vtfree(c->hash); vtfree(c->heap); vtfree(c->block); vtfree(c->mem); vtfree(c); } static void vtcachedump(VtCache *c) { int i; VtBlock *b; for(i=0; i<c->nblock; i++){ b = &c->block[i]; print("cache block %d: type %d score %V iostate %d addr %d ref %d nlock %d\n", i, b->type, b->score, b->iostate, b->addr, b->ref, b->nlock); } } static void cachecheck(VtCache *c) { u32int size, now; int i, k, refed; VtBlock *b; size = c->blocksize; now = c->now; for(i = 0; i < c->nheap; i++){ if(c->heap[i]->heap != i) sysfatal("mis-heaped at %d: %d", i, c->heap[i]->heap); if(i > 0 && c->heap[(i - 1) >> 1]->used - now > c->heap[i]->used - now) sysfatal("bad heap ordering"); k = (i << 1) + 1; if(k < c->nheap && c->heap[i]->used - now > c->heap[k]->used - now) sysfatal("bad heap ordering"); k++; if(k < c->nheap && c->heap[i]->used - now > c->heap[k]->used - now) sysfatal("bad heap ordering"); } refed = 0; for(i = 0; i < c->nblock; i++){ b = &c->block[i]; if(b->data != &c->mem[i * size]) sysfatal("mis-blocked at %d", i); if(b->ref && b->heap == BadHeap) refed++; else if(b->addr != NilBlock) refed++; } assert(c->nheap + refed == c->nblock); refed = 0; for(i = 0; i < c->nblock; i++){ b = &c->block[i]; if(b->ref){ refed++; } } } static int upheap(int i, VtBlock *b) { VtBlock *bb; u32int now; int p; VtCache *c; c = b->c; now = c->now; for(; i != 0; i = p){ p = (i - 1) >> 1; bb = c->heap[p]; if(b->used - now >= bb->used - now) break; c->heap[i] = bb; bb->heap = i; } c->heap[i] = b; b->heap = i; return i; } static int downheap(int i, VtBlock *b) { VtBlock *bb; u32int now; int k; VtCache *c; c = b->c; now = c->now; for(; ; i = k){ k = (i << 1) + 1; if(k >= c->nheap) break; if(k + 1 < c->nheap && c->heap[k]->used - now > c->heap[k + 1]->used - now) k++; bb = c->heap[k]; if(b->used - now <= bb->used - now) break; c->heap[i] = bb; bb->heap = i; } c->heap[i] = b; b->heap = i; return i; } /* * Delete a block from the heap. * Called with c->lk held. */ static void heapdel(VtBlock *b) { int i, si; VtCache *c; c = b->c; si = b->heap; if(si == BadHeap) return; b->heap = BadHeap; c->nheap--; if(si == c->nheap) return; b = c->heap[c->nheap]; i = upheap(si, b); if(i == si) downheap(i, b); } /* * Insert a block into the heap. * Called with c->lk held. */ static void heapins(VtBlock *b) { assert(b->heap == BadHeap); upheap(b->c->nheap++, b); } /* * locate the vtBlock with the oldest second to last use. * remove it from the heap, and fix up the heap. */ /* called with c->lk held */ static VtBlock* vtcachebumpblock(VtCache *c) { VtBlock *b; /* * locate the vtBlock with the oldest second to last use. * remove it from the heap, and fix up the heap. */ if(c->nheap == 0){ vtcachedump(c); fprint(2, "vtcachebumpblock: no free blocks in vtCache"); abort(); } b = c->heap[0]; heapdel(b); assert(b->heap == BadHeap); assert(b->ref == 0); /* * unchain the vtBlock from hash chain if any */ if(b->prev){ *(b->prev) = b->next; if(b->next) b->next->prev = b->prev; b->prev = nil; } if(0)fprint(2, "droping %x:%V\n", b->addr, b->score); /* set vtBlock to a reasonable state */ b->ref = 1; b->iostate = BioEmpty; return b; } /* * fetch a local block from the memory cache. * if it's not there, load it, bumping some other Block. * if we're out of free blocks, we're screwed. */ VtBlock* vtcachelocal(VtCache *c, u32int addr, int type) { VtBlock *b; if(addr == 0) sysfatal("vtcachelocal: asked for nonexistent block 0"); if(addr > c->nblock) sysfatal("vtcachelocal: asked for block #%ud; only %d blocks", addr, c->nblock); b = &c->block[addr-1]; if(b->addr == NilBlock || b->iostate != BioLocal) sysfatal("vtcachelocal: block is not local"); if(b->type != type) sysfatal("vtcachelocal: block has wrong type %d != %d", b->type, type); qlock(&c->lk); b->ref++; qunlock(&c->lk); qlock(&b->lk); b->nlock = 1; b->pc = getcallerpc(&c); return b; } VtBlock* vtcacheallocblock(VtCache *c, int type) { VtBlock *b; qlock(&c->lk); b = vtcachebumpblock(c); b->iostate = BioLocal; b->type = type; b->addr = (b - c->block)+1; vtzeroextend(type, b->data, 0, c->blocksize); vtlocaltoglobal(b->addr, b->score); qunlock(&c->lk); qlock(&b->lk); b->nlock = 1; b->pc = getcallerpc(&c); return b; } /* * fetch a global (Venti) block from the memory cache. * if it's not there, load it, bumping some other block. */ VtBlock* vtcacheglobal(VtCache *c, uchar score[VtScoreSize], int type) { VtBlock *b; ulong h; int n; u32int addr; if(vttracelevel) fprint(2, "vtcacheglobal %V %d from %p\n", score, type, getcallerpc(&c)); addr = vtglobaltolocal(score); if(addr != NilBlock){ if(vttracelevel) fprint(2, "vtcacheglobal %V %d => local\n", score, type); b = vtcachelocal(c, addr, type); if(b) b->pc = getcallerpc(&c); return b; } h = (u32int)(score[0]|(score[1]<<8)|(score[2]<<16)|(score[3]<<24)) % c->nhash; /* * look for the block in the cache */ qlock(&c->lk); for(b = c->hash[h]; b != nil; b = b->next){ if(b->addr != NilBlock || memcmp(b->score, score, VtScoreSize) != 0 || b->type != type) continue; heapdel(b); b->ref++; qunlock(&c->lk); if(vttracelevel) fprint(2, "vtcacheglobal %V %d => found in cache %p; locking\n", score, type, b); qlock(&b->lk); b->nlock = 1; if(b->iostate == BioVentiError){ if(chattyventi) fprint(2, "cached read error for %V\n", score); if(vttracelevel) fprint(2, "vtcacheglobal %V %d => cache read error\n", score, type); vtblockput(b); werrstr("venti i/o error"); return nil; } if(vttracelevel) fprint(2, "vtcacheglobal %V %d => found in cache; returning\n", score, type); b->pc = getcallerpc(&c); return b; } /* * not found */ b = vtcachebumpblock(c); b->addr = NilBlock; b->type = type; memmove(b->score, score, VtScoreSize); /* chain onto correct hash */ b->next = c->hash[h]; c->hash[h] = b; if(b->next != nil) b->next->prev = &b->next; b->prev = &c->hash[h]; /* * Lock b before unlocking c, so that others wait while we read. * * You might think there is a race between this qlock(b) before qunlock(c) * and the qlock(c) while holding a qlock(b) in vtblockwrite. However, * the block here can never be the block in a vtblockwrite, so we're safe. * We're certainly living on the edge. */ if(vttracelevel) fprint(2, "vtcacheglobal %V %d => bumped; locking %p\n", score, type, b); qlock(&b->lk); b->nlock = 1; qunlock(&c->lk); vtcachenread++; n = vtread(c->z, score, type, b->data, c->blocksize); if(n < 0){ if(chattyventi) fprint(2, "read %V: %r\n", score); if(vttracelevel) fprint(2, "vtcacheglobal %V %d => bumped; read error\n", score, type); b->iostate = BioVentiError; vtblockput(b); return nil; } vtzeroextend(type, b->data, n, c->blocksize); b->iostate = BioVenti; b->nlock = 1; if(vttracelevel) fprint(2, "vtcacheglobal %V %d => loaded into cache; returning\n", score, type); b->pc = getcallerpc(&b); return b; } /* * The thread that has locked b may refer to it by * multiple names. Nlock counts the number of * references the locking thread holds. It will call * vtblockput once per reference. */ void vtblockduplock(VtBlock *b) { assert(b->nlock > 0); b->nlock++; } /* * we're done with the block. * unlock it. can't use it after calling this. */ void vtblockput(VtBlock* b) { VtCache *c; if(b == nil) return; if(0)fprint(2, "vtblockput: %d: %x %d %d\n", getpid(), b->addr, c->nheap, b->iostate); if(vttracelevel) fprint(2, "vtblockput %p from %p\n", b, getcallerpc(&b)); if(--b->nlock > 0) return; /* * b->nlock should probably stay at zero while * the vtBlock is unlocked, but diskThread and vtSleep * conspire to assume that they can just qlock(&b->lk); vtblockput(b), * so we have to keep b->nlock set to 1 even * when the vtBlock is unlocked. */ assert(b->nlock == 0); b->nlock = 1; qunlock(&b->lk); c = b->c; qlock(&c->lk); if(--b->ref > 0){ qunlock(&c->lk); return; } assert(b->ref == 0); switch(b->iostate){ case BioVenti: /*if(b->addr != NilBlock) print("blockput %d\n", b->addr); */ b->used = c->now++; /* fall through */ case BioVentiError: heapins(b); break; case BioLocal: break; } qunlock(&c->lk); } int vtblockwrite(VtBlock *b) { uchar score[VtScoreSize]; VtCache *c; uint h; int n; if(b->iostate != BioLocal){ werrstr("vtblockwrite: not a local block"); return -1; } c = b->c; n = vtzerotruncate(b->type, b->data, c->blocksize); vtcachenwrite++; if(c->write(c->z, score, b->type, b->data, n) < 0) return -1; memmove(b->score, score, VtScoreSize); qlock(&c->lk); b->addr = NilBlock; /* now on venti */ b->iostate = BioVenti; h = (u32int)(score[0]|(score[1]<<8)|(score[2]<<16)|(score[3]<<24)) % c->nhash; b->next = c->hash[h]; c->hash[h] = b; if(b->next != nil) b->next->prev = &b->next; b->prev = &c->hash[h]; qunlock(&c->lk); return 0; } uint vtcacheblocksize(VtCache *c) { return c->blocksize; } VtBlock* vtblockcopy(VtBlock *b) { VtBlock *bb; vtcachencopy++; bb = vtcacheallocblock(b->c, b->type); if(bb == nil){ vtblockput(b); return nil; } memmove(bb->data, b->data, b->c->blocksize); vtblockput(b); bb->pc = getcallerpc(&b); return bb; } void vtlocaltoglobal(u32int addr, uchar score[VtScoreSize]) { memset(score, 0, 16); score[16] = addr>>24; score[17] = addr>>16; score[18] = addr>>8; score[19] = addr; } u32int vtglobaltolocal(uchar score[VtScoreSize]) { static uchar zero[16]; if(memcmp(score, zero, 16) != 0) return NilBlock; return (score[16]<<24)|(score[17]<<16)|(score[18]<<8)|score[19]; }