/* -*- mode: C; c-basic-offset: 4 -*- */ #ident "Copyright (c) 2007, 2008 Tokutek Inc. All rights reserved." /* Buffered repository tree. * Observation: The in-memory representation of a node doesn't have to be the same as the on-disk representation. * Goal for the in-memory representation: fast * Goal for on-disk: small * * So to get this running fast, I'll make a version that doesn't do range queries: * use a hash table for in-memory * simply write the strings on disk. * Later I'll do a PMA or a skiplist for the in-memory version. * Also, later I'll convert the format to network order fromn host order. * Later, for on disk, I'll compress it (perhaps with gzip, perhaps with the bzip2 algorithm.) * * The collection of nodes forms a data structure like a B-tree. The complexities of keeping it balanced apply. * * We always write nodes to a new location on disk. * The nodes themselves contain the information about the tree structure. * Q: During recovery, how do we find the root node without looking at every block on disk? * A: The root node is either the designated root near the front of the freelist. * The freelist is updated infrequently. Before updating the stable copy of the freelist, we make sure that * the root is up-to-date. We can make the freelist-and-root update be an arbitrarily small fraction of disk bandwidth. * */ #include #include #include #include #include #include #include #include "toku_assert.h" #include "brt-internal.h" #include "key.h" #include "log_header.h" #include "kv-pair.h" #include "mempool.h" #include "leafentry.h" extern long long n_items_malloced; static int malloc_diskblock (DISKOFF *res, BRT brt, int size, TOKULOGGER); static void verify_local_fingerprint_nonleaf (BRTNODE node); /* Frees a node, including all the stuff in the hash table. */ void toku_brtnode_free (BRTNODE *nodep) { BRTNODE node=*nodep; int i; //printf("%s:%d %p->mdict[0]=%p\n", __FILE__, __LINE__, node, node->mdicts[0]); if (node->height>0) { for (i=0; iu.n.n_children-1; i++) { toku_free(node->u.n.childkeys[i]); } for (i=0; iu.n.n_children; i++) { if (BNC_BUFFER(node,i)) { toku_fifo_free(&BNC_BUFFER(node,i)); } } toku_free(node->u.n.childkeys); toku_free(node->u.n.childinfos); } else { if (node->u.l.buffer) // The buffer may have been freed already, in some cases. toku_gpma_free(&node->u.l.buffer, 0, 0); void *mpbase = toku_mempool_get_base(&node->u.l.buffer_mempool); toku_mempool_fini(&node->u.l.buffer_mempool); toku_free(mpbase); } toku_free(node); *nodep=0; } static long brtnode_size(BRTNODE node) { long size; assert(node->tag == TYP_BRTNODE); if (node->height > 0) size = node->u.n.n_bytes_in_buffers; else size = node->u.l.n_bytes_in_buffer; return size; } static void toku_update_brtnode_loggerlsn(BRTNODE node, TOKULOGGER logger) { if (logger) { node->log_lsn = toku_logger_last_lsn(logger); } } static void fixup_child_fingerprint(BRTNODE node, int childnum_of_node, BRTNODE child, BRT brt, TOKULOGGER logger) { u_int32_t old_fingerprint = BNC_SUBTREE_FINGERPRINT(node,childnum_of_node); u_int32_t sum = child->local_fingerprint; if (child->height>0) { int i; for (i=0; iu.n.n_children; i++) { sum += BNC_SUBTREE_FINGERPRINT(child,i); } } // Don't try to get fancy about not modifying the fingerprint if it didn't change. // We only call this function if we have reason to believe that the child's fingerprint did change. BNC_SUBTREE_FINGERPRINT(node,childnum_of_node)=sum; node->dirty=1; toku_log_changechildfingerprint(logger, (LSN*)0, 0, toku_cachefile_filenum(brt->cf), node->thisnodename, childnum_of_node, old_fingerprint, sum); toku_update_brtnode_loggerlsn(node, logger); } // If you pass in data==0 then it only compares the key, not the data (even if is a DUPSORT database) static int brt_compare_pivot(BRT brt, DBT *key, DBT *data, bytevec ck) { int cmp; DBT mydbt; struct kv_pair *kv = (struct kv_pair *) ck; if (brt->flags & TOKU_DB_DUPSORT) { cmp = brt->compare_fun(brt->db, key, toku_fill_dbt(&mydbt, kv_pair_key(kv), kv_pair_keylen(kv))); if (cmp == 0 && data != 0) cmp = brt->dup_compare(brt->db, data, toku_fill_dbt(&mydbt, kv_pair_val(kv), kv_pair_vallen(kv))); } else { cmp = brt->compare_fun(brt->db, key, toku_fill_dbt(&mydbt, kv_pair_key(kv), kv_pair_keylen(kv))); } return cmp; } void toku_brtnode_flush_callback (CACHEFILE cachefile, DISKOFF nodename, void *brtnode_v, long size __attribute((unused)), BOOL write_me, BOOL keep_me, LSN modified_lsn __attribute__((__unused__)) , BOOL rename_p __attribute__((__unused__))) { BRTNODE brtnode = brtnode_v; // if ((write_me || keep_me) && (brtnode->height==0)) { // toku_pma_verify_fingerprint(brtnode->u.l.buffer, brtnode->rand4fingerprint, brtnode->subtree_fingerprint); // } if (0) { printf("%s:%d toku_brtnode_flush_callback %p thisnodename=%lld keep_me=%d height=%d", __FILE__, __LINE__, brtnode, (long long)brtnode->thisnodename, keep_me, brtnode->height); if (brtnode->height==0) printf(" pma=%p mempool-base=%p", brtnode->u.l.buffer, brtnode->u.l.buffer_mempool.base); printf("\n"); } //if (modified_lsn.lsn > brtnode->lsn.lsn) brtnode->lsn=modified_lsn; assert(brtnode->thisnodename==nodename); //printf("%s:%d %p->mdict[0]=%p\n", __FILE__, __LINE__, brtnode, brtnode->mdicts[0]); if (write_me) { toku_serialize_brtnode_to(toku_cachefile_fd(cachefile), brtnode->thisnodename, brtnode->nodesize, brtnode); } //printf("%s:%d %p->mdict[0]=%p\n", __FILE__, __LINE__, brtnode, brtnode->mdicts[0]); if (!keep_me) { toku_brtnode_free(&brtnode); } //printf("%s:%d n_items_malloced=%lld\n", __FILE__, __LINE__, n_items_malloced); } int toku_brtnode_fetch_callback (CACHEFILE cachefile, DISKOFF nodename, void **brtnode_pv, long *sizep, void*extraargs, LSN *written_lsn) { BRT t =(BRT)extraargs; BRTNODE *result=(BRTNODE*)brtnode_pv; int r = toku_deserialize_brtnode_from(toku_cachefile_fd(cachefile), nodename, result, t->flags, t->nodesize); if (r == 0) { *sizep = brtnode_size(*result); *written_lsn = (*result)->disk_lsn; } //(*result)->parent_brtnode = 0; /* Don't know it right now. */ //printf("%s:%d installed %p (offset=%lld)\n", __FILE__, __LINE__, *result, nodename); return r; } void toku_brtheader_flush_callback (CACHEFILE cachefile, DISKOFF nodename, void *header_v, long size __attribute((unused)), BOOL write_me, BOOL keep_me, LSN lsn __attribute__((__unused__)), BOOL rename_p __attribute__((__unused__))) { struct brt_header *h = header_v; assert(nodename==0); assert(!h->dirty); // shouldn't be dirty once it is unpinned. if (write_me) { toku_serialize_brt_header_to(toku_cachefile_fd(cachefile), h); } if (!keep_me) { if (h->n_named_roots>0) { int i; for (i=0; in_named_roots; i++) { toku_free(h->names[i]); } toku_free(h->names); toku_free(h->roots); } toku_free(h); } } int toku_brtheader_fetch_callback (CACHEFILE cachefile, DISKOFF nodename, void **headerp_v, long *sizep __attribute__((unused)), void*extraargs __attribute__((__unused__)), LSN *written_lsn) { struct brt_header **h = (struct brt_header **)headerp_v; assert(nodename==0); int r = toku_deserialize_brtheader_from(toku_cachefile_fd(cachefile), nodename, h); written_lsn->lsn = 0; // !!! WRONG. This should be stored or kept redundantly or something. return r; } int toku_read_and_pin_brt_header (CACHEFILE cf, struct brt_header **header) { void *header_p; //fprintf(stderr, "%s:%d read_and_pin_brt_header(...)\n", __FILE__, __LINE__); int r = toku_cachetable_get_and_pin(cf, 0, &header_p, NULL, toku_brtheader_flush_callback, toku_brtheader_fetch_callback, 0); if (r!=0) return r; *header = header_p; return 0; } int toku_unpin_brt_header (BRT brt) { int r = toku_cachetable_unpin(brt->cf, 0, brt->h->dirty, 0); brt->h->dirty=0; brt->h=0; return r; } int toku_unpin_brtnode (BRT brt, BRTNODE node) { // if (node->dirty && txn) { // // For now just update the log_lsn. Later we'll have to deal with the checksums. // node->log_lsn = toku_txn_get_last_lsn(txn); // //if (node->log_lsn.lsn>33320) printf("%s:%d node%lld lsn=%lld\n", __FILE__, __LINE__, node->thisnodename, node->log_lsn.lsn); // } //toku_verify_counts(node); return toku_cachetable_unpin(brt->cf, node->thisnodename, node->dirty, brtnode_size(node)); } typedef struct kvpair { bytevec key; unsigned int keylen; bytevec val; unsigned int vallen; } *KVPAIR; #if 0 int kvpair_compare (const void *av, const void *bv) { const KVPAIR a = (const KVPAIR)av; const KVPAIR b = (const KVPAIR)bv; int r = toku_keycompare(a->key, a->keylen, b->key, b->keylen); //printf("keycompare(%s,\n %s)-->%d\n", a->key, b->key, r); return r; } #endif /* Forgot to handle the case where there is something in the freelist. */ static int malloc_diskblock_header_is_in_memory (DISKOFF *res, BRT brt, int size, TOKULOGGER logger) { DISKOFF result = brt->h->unused_memory; brt->h->unused_memory+=size; brt->h->dirty = 1; int r = toku_log_changeunusedmemory(logger, (LSN*)0, 0, toku_cachefile_filenum(brt->cf), result, brt->h->unused_memory); *res = result; return r; } int malloc_diskblock (DISKOFF *res, BRT brt, int size, TOKULOGGER logger) { #if 0 int r = read_and_pin_brt_header(brt->fd, &brt->h); assert(r==0); { DISKOFF result = malloc_diskblock_header_is_in_memory(brt, size); r = write_brt_header(brt->fd, &brt->h); assert(r==0); return result; } #else return malloc_diskblock_header_is_in_memory(res, brt,size, logger); #endif } u_int32_t mp_pool_size_for_nodesize (u_int32_t nodesize) { #if 1 return nodesize+nodesize/4; #else return nodesize; #endif } static void initialize_brtnode (BRT t, BRTNODE n, DISKOFF nodename, int height) { n->tag = TYP_BRTNODE; n->nodesize = t->h->nodesize; n->flags = t->h->flags; n->thisnodename = nodename; n->disk_lsn.lsn = 0; // a new one can always be 0. n->log_lsn = n->disk_lsn; n->layout_version = 3; n->height = height; n->rand4fingerprint = random(); n->local_fingerprint = 0; n->dirty = 1; assert(height>=0); if (height>0) { n->u.n.n_children = 0; n->u.n.totalchildkeylens = 0; n->u.n.n_bytes_in_buffers = 0; n->u.n.childinfos=0; n->u.n.childkeys=0; } else { int r = toku_gpma_create(&n->u.l.buffer, 0); assert(r==0); { u_int32_t mpsize = mp_pool_size_for_nodesize(n->nodesize); void *mp = toku_malloc(mpsize); assert(mp); toku_mempool_init(&n->u.l.buffer_mempool, mp, mpsize); } static int rcount=0; //printf("%s:%d n PMA= %p (rcount=%d)\n", __FILE__, __LINE__, n->u.l.buffer, rcount); rcount++; n->u.l.n_bytes_in_buffer = 0; } } int toku_create_new_brtnode (BRT t, BRTNODE *result, int height, TOKULOGGER logger) { TAGMALLOC(BRTNODE, n); int r; DISKOFF name; r = malloc_diskblock(&name, t, t->h->nodesize, logger); assert(r==0); assert(n); assert(t->h->nodesize>0); //printf("%s:%d malloced %lld (and malloc again=%lld)\n", __FILE__, __LINE__, name, malloc_diskblock(t, t->nodesize)); initialize_brtnode(t, n, name, height); *result = n; assert(n->nodesize>0); // n->brt = t; //printf("%s:%d putting %p (%lld) parent=%p\n", __FILE__, __LINE__, n, n->thisnodename, parent_brtnode); r=toku_cachetable_put(t->cf, n->thisnodename, n, brtnode_size(n), toku_brtnode_flush_callback, toku_brtnode_fetch_callback, t); assert(r==0); r=toku_log_newbrtnode(logger, (LSN*)0, 0, toku_cachefile_filenum(t->cf), n->thisnodename, height, n->nodesize, (t->flags&TOKU_DB_DUPSORT)!=0, n->rand4fingerprint); assert(r==0); toku_update_brtnode_loggerlsn(n, logger); return 0; } static int insert_to_buffer_in_nonleaf (BRTNODE node, int childnum, DBT *k, DBT *v, int type, TXNID xid) { unsigned int n_bytes_added = BRT_CMD_OVERHEAD + KEY_VALUE_OVERHEAD + k->size + v->size; int r = toku_fifo_enq(BNC_BUFFER(node,childnum), k->data, k->size, v->data, v->size, type, xid); if (r!=0) return r; // printf("%s:%d fingerprint %08x -> ", __FILE__, __LINE__, node->local_fingerprint); node->local_fingerprint += node->rand4fingerprint*toku_calccrc32_cmd(type, xid, k->data, k->size, v->data, v->size); // printf(" %08x\n", node->local_fingerprint); BNC_NBYTESINBUF(node,childnum) += n_bytes_added; node->u.n.n_bytes_in_buffers += n_bytes_added; node->dirty = 1; return 0; } struct move_struct { TOKULOGGER logger; FILENUM filenum; BRTNODE from,to; struct gitem last_pair_remaining_in_from; }; int move_between_mempools (u_int32_t len, void *odata, void **ndata, void *extra) { struct move_struct *ms=extra; assert(ms->from->height==0); assert(ms->to->height==0); assert(len==(unsigned)kv_pair_size(odata)); void *newitem=mempool_malloc_from_gpma(ms->to->u.l.buffer, &ms->to->u.l.buffer_mempool, len); assert(newitem); memcpy(newitem, odata, len); toku_mempool_mfree(&ms->from->u.l.buffer_mempool, odata, len); *ndata = newitem; assert(len==(unsigned)kv_pair_size(newitem)); return 0; } int note_move_items_within_or_between (u_int32_t nitems, u_int32_t *froms, u_int32_t *tos, BRTNODE from, BRTNODE to, FILENUM filenum, TOKULOGGER logger, u_int32_t old_N, u_int32_t new_N) { INTPAIRARRAY ipa; MALLOC_N(nitems, ipa.array); if (ipa.array==0) return errno; u_int32_t i; for (i=0; ithisnodename, to->thisnodename, ipa, old_N, new_N); if (r!=0) return r; from->log_lsn=lsn; to->log_lsn =lsn; } toku_free(ipa.array); return 0; } static int note_move_items_within (u_int32_t nitems, u_int32_t *froms, u_int32_t *tos, struct gitem *items __attribute__((__unused__)), u_int32_t old_N, u_int32_t new_N, void *extra) { struct move_struct *ms=extra; assert(nitems>0); ms->last_pair_remaining_in_from=items[nitems-1]; return note_move_items_within_or_between(nitems, froms, tos, ms->from, ms->from, ms->filenum, ms->logger, old_N, new_N); } static int note_move_items_between (u_int32_t nitems, u_int32_t *froms, u_int32_t *tos, struct gitem *items, u_int32_t old_N, u_int32_t new_N, void *extra) { struct move_struct *ms=extra; int r = note_move_items_within_or_between(nitems, froms, tos, ms->from, ms->to, ms->filenum, ms->logger, old_N, new_N); if (r!=0) return r; u_int32_t i; u_int32_t diffsize = 0; u_int32_t diff_fp = 0; for (i=0; ifrom->local_fingerprint -= ms->from->rand4fingerprint * diff_fp; ms->to->local_fingerprint += ms->to->rand4fingerprint * diff_fp; ms->from->u.l.n_bytes_in_buffer -= diffsize; ms->to->u.l.n_bytes_in_buffer += diffsize; return 0; } struct delete_struct { BRTNODE node; }; static int brt_leaf_delete_callback (u_int32_t slotnum, u_int32_t len, void *data, void *extra) { struct delete_struct *d = extra; d->node->local_fingerprint -= d->node->rand4fingerprint*toku_calccrc32_kvpair_struct(data); d->node->u.l.n_bytes_in_buffer -= PMA_ITEM_OVERHEAD + len; toku_mempool_mfree(&d->node->u.l.buffer_mempool, data, len); d->node->dirty=1; // Should use slotnum for logging slotnum=slotnum; //???? return 0; } static int brtleaf_split (TOKULOGGER logger, FILENUM filenum, BRT t, BRTNODE node, BRTNODE *nodea, BRTNODE *nodeb, DBT *splitk) { BRTNODE B; assert(node->height==0); assert(t->h->nodesize>=node->nodesize); /* otherwise we might be in trouble because the nodesize shrank. */ toku_create_new_brtnode(t, &B, 0, logger); //printf("leaf_split %lld - %lld %lld\n", node->thisnodename, A->thisnodename, B->thisnodename); //printf("%s:%d A PMA= %p\n", __FILE__, __LINE__, A->u.l.buffer); //printf("%s:%d B PMA= %p\n", __FILE__, __LINE__, A->u.l.buffer); assert(B->nodesize>0); assert(node->nodesize>0); //printf("%s:%d A is at %lld\n", __FILE__, __LINE__, A->thisnodename); //printf("%s:%d B is at %lld nodesize=%d\n", __FILE__, __LINE__, B->thisnodename, B->nodesize); assert(node->height>0 || node->u.l.buffer!=0); int r; struct move_struct ms = {.logger=logger, .filenum=filenum, .from=node, .to=B}; //toku_verify_gpma(node->u.l.buffer); GPMA_ITERATE(node->u.l.buffer, idx, vlen, vdata, ({ struct kv_pair *p=vdata; //printf("%s:%d %d:%p ", __FILE__, __LINE__, idx, p); assert((char*)node->u.l.buffer_mempool.base<= (char*)p && (char*)p < (char*)node->u.l.buffer_mempool.base+node->u.l.buffer_mempool.size ); })); r = toku_gpma_split(node->u.l.buffer, B->u.l.buffer, PMA_ITEM_OVERHEAD, move_between_mempools, note_move_items_within, note_move_items_between, &ms); GPMA_ITERATE(node->u.l.buffer, idx, vlen, vdata, ({ struct kv_pair *p=vdata; //printf("%s:%d %d:%p ", __FILE__, __LINE__, idx, p); assert((char*)node->u.l.buffer_mempool.base<= (char*)p && (char*)p < (char*)node->u.l.buffer_mempool.base+node->u.l.buffer_mempool.size ); })); GPMA_ITERATE(B->u.l.buffer, idx, vlen, vdata, ({ struct kv_pair *p=vdata; //printf("%s:%d %d:%p\n", __FILE__, __LINE__, idx, p); assert((char*)B->u.l.buffer_mempool.base<= (char*)p && (char*)p < (char*)B->u.l.buffer_mempool.base+node->u.l.buffer_mempool.size ); })); //toku_verify_gpma(node->u.l.buffer); //toku_verify_gpma(B->u.l.buffer); if (splitk) { memset(splitk, 0, sizeof *splitk); struct kv_pair *kp=ms.last_pair_remaining_in_from.data; if (node->flags&TOKU_DB_DUPSORT) { splitk->size = kv_pair_keylen(kp)+kv_pair_vallen(kp); splitk->data = kv_pair_malloc(kv_pair_key(kp), kv_pair_keylen(kp), kv_pair_val(kp), kv_pair_vallen(kp)); } else { splitk->size = kv_pair_keylen(kp); splitk->data = kv_pair_malloc(kv_pair_key(kp), kv_pair_keylen(kp), 0, 0); } splitk->flags=0; } assert(r == 0); assert(node->height>0 || node->u.l.buffer!=0); /* Remove it from the cache table, and free its storage. */ //printf("%s:%d old pma = %p\n", __FILE__, __LINE__, node->u.l.buffer); *nodea = node; *nodeb = B; assert(toku_serialize_brtnode_size(node)nodesize); assert(toku_serialize_brtnode_size(B) nodesize); return 0; } #define MAX_PATHLEN_TO_ROOT 40 static int log_and_save_brtenq(TOKULOGGER logger, BRT t, BRTNODE node, int childnum, TXNID xid, int type, const char *key, int keylen, const char *data, int datalen, u_int32_t *fingerprint, DISKOFFARRAY path_to_parent) { BYTESTRING keybs = {.len=keylen, .data=(char*)key}; BYTESTRING databs = {.len=datalen, .data=(char*)data}; u_int32_t old_fingerprint = *fingerprint; u_int32_t fdiff=node->rand4fingerprint*toku_calccrc32_cmd(type, xid, key, keylen, data, datalen); u_int32_t new_fingerprint = old_fingerprint + fdiff; //printf("%s:%d node=%lld fingerprint old=%08x new=%08x diff=%08x xid=%lld\n", __FILE__, __LINE__, (long long)node->thisnodename, old_fingerprint, new_fingerprint, fdiff, (long long)xid); *fingerprint = new_fingerprint; int r = toku_log_brtenq(logger, (LSN*)0, 0, toku_cachefile_filenum(t->cf), node->thisnodename, childnum, xid, type, keybs, databs, old_fingerprint, new_fingerprint); if (r!=0) return r; TOKUTXN txn; if (0==toku_txnid2txn(logger, xid, &txn) && txn) { DISKOFFARRAY path = path_to_parent; path.array = toku_memdup(path.array, sizeof(path.array[0])*(1+path.len)); if (path.array==0) return errno; r = toku_logger_save_rollback_xactiontouchednonleaf(txn, toku_cachefile_filenum(t->cf), path, node->thisnodename); if (r!=0) return r; } return 0; } /* Side effect: sets splitk->data pointer to a malloc'd value */ static int brt_nonleaf_split (BRT t, BRTNODE node, BRTNODE *nodea, BRTNODE *nodeb, DBT *splitk, TOKULOGGER logger, DISKOFFARRAY path_to_parent) { int old_n_children = node->u.n.n_children; int n_children_in_a = old_n_children/2; int n_children_in_b = old_n_children-n_children_in_a; BRTNODE B; FILENUM fnum = toku_cachefile_filenum(t->cf); assert(node->height>0); assert(node->u.n.n_children>=2); // Otherwise, how do we split? We need at least two children to split. */ assert(t->h->nodesize>=node->nodesize); /* otherwise we might be in trouble because the nodesize shrank. */ toku_create_new_brtnode(t, &B, node->height, logger); MALLOC_N(n_children_in_b+1, B->u.n.childinfos); MALLOC_N(n_children_in_b, B->u.n.childkeys); B->u.n.n_children =n_children_in_b; //printf("%s:%d %p (%lld) becomes %p and %p\n", __FILE__, __LINE__, node, node->thisnodename, A, B); //printf("%s:%d A is at %lld\n", __FILE__, __LINE__, A->thisnodename); { /* The first n_children_in_a go into node a. * That means that the first n_children_in_a-1 keys go into node a. * The splitter key is key number n_children_in_a */ int i; for (i=0; ithisnodename; // Don't have to restore it since path_to_parent is passed by value, and this one not used again except in this loop. for (i=n_children_in_a; ithisnodename, targchild, thischilddiskoff, BNC_SUBTREE_FINGERPRINT(node, i)); if (r!=0) return r; while (1) { bytevec key, data; unsigned int keylen, datalen; u_int32_t type; TXNID xid; int fr = toku_fifo_peek(from_htab, &key, &keylen, &data, &datalen, &type, &xid); if (fr!=0) break; int n_bytes_moved = keylen+datalen + KEY_VALUE_OVERHEAD + BRT_CMD_OVERHEAD; BYTESTRING keybs = { .len = keylen, .data = (char*)key }; BYTESTRING databs = { .len = datalen, .data = (char*)data }; u_int32_t old_from_fingerprint = node->local_fingerprint; u_int32_t delta = toku_calccrc32_cmd(type, xid, key, keylen, data, datalen); u_int32_t new_from_fingerprint = old_from_fingerprint - node->rand4fingerprint*delta; if (r!=0) return r; r = toku_log_brtdeq(logger, (LSN*)0, 0, fnum, node->thisnodename, n_children_in_a, xid, type, keybs, databs, old_from_fingerprint, new_from_fingerprint); if (r!=0) return r; r = log_and_save_brtenq(logger, t, B, targchild, xid, type, key, keylen, data, datalen, &B->local_fingerprint, path_to_parent); r = toku_fifo_enq(to_htab, key, keylen, data, datalen, type, xid); if (r!=0) return r; toku_fifo_deq(from_htab); // key and data will no longer be valid node->local_fingerprint = new_from_fingerprint; B->u.n.n_bytes_in_buffers += n_bytes_moved; BNC_NBYTESINBUF(B, targchild) += n_bytes_moved; node->u.n.n_bytes_in_buffers -= n_bytes_moved; BNC_NBYTESINBUF(node, i) -= n_bytes_moved; // verify_local_fingerprint_nonleaf(B); // verify_local_fingerprint_nonleaf(node); } // Delete a child, removing it's fingerprint, and also the preceeding pivot key. The child number must be > 0 { BYTESTRING bs = { .len = kv_pair_keylen(node->u.n.childkeys[i-1]), .data = kv_pair_key(node->u.n.childkeys[i-1]) }; assert(i>0); r = toku_log_delchild(logger, (LSN*)0, 0, fnum, node->thisnodename, n_children_in_a, thischilddiskoff, BNC_SUBTREE_FINGERPRINT(node, i), bs); if (r!=0) return r; if (i>n_children_in_a) { r = toku_log_setpivot(logger, (LSN*)0, 0, fnum, B->thisnodename, targchild-1, bs); if (r!=0) return r; B->u.n.childkeys[targchild-1] = node->u.n.childkeys[i-1]; B->u.n.totalchildkeylens += toku_brt_pivot_key_len(t, node->u.n.childkeys[i-1]); node->u.n.totalchildkeylens -= toku_brt_pivot_key_len(t, node->u.n.childkeys[i-1]); node->u.n.childkeys[i-1] = 0; } } BNC_DISKOFF(node, i) = 0; BNC_SUBTREE_FINGERPRINT(B, targchild) = BNC_SUBTREE_FINGERPRINT(node, i); BNC_SUBTREE_FINGERPRINT(node, i) = 0; assert(BNC_NBYTESINBUF(node, i) == 0); } // Drop the n_children now (not earlier) so that we can do the fingerprint verification at any time. node->u.n.n_children=n_children_in_a; for (i=n_children_in_a; idata = (void*)(node->u.n.childkeys[n_children_in_a-1]); splitk->size = toku_brt_pivot_key_len(t, node->u.n.childkeys[n_children_in_a-1]); node->u.n.totalchildkeylens -= toku_brt_pivot_key_len(t, node->u.n.childkeys[n_children_in_a-1]); REALLOC_N(n_children_in_a+1, node->u.n.childinfos); REALLOC_N(n_children_in_a, node->u.n.childkeys); verify_local_fingerprint_nonleaf(node); verify_local_fingerprint_nonleaf(B); } *nodea = node; *nodeb = B; assert(toku_serialize_brtnode_size(node)nodesize); assert(toku_serialize_brtnode_size(B)nodesize); return 0; } static void find_heaviest_child (BRTNODE node, int *childnum) { int max_child = 0; int max_weight = BNC_NBYTESINBUF(node, 0); int i; if (0) printf("%s:%d weights: %d", __FILE__, __LINE__, max_weight); assert(node->u.n.n_children>0); for (i=1; iu.n.n_children; i++) { int this_weight = BNC_NBYTESINBUF(node,i); if (0) printf(" %d", this_weight); if (max_weight < this_weight) { max_child = i; max_weight = this_weight; } } *childnum = max_child; if (0) printf("\n"); } static int brtnode_put_cmd (BRT t, BRTNODE node, BRT_CMD cmd, int *did_split, BRTNODE *nodea, BRTNODE *nodeb, DBT *split, int debug, TOKULOGGER, DISKOFFARRAY path_to_parent); /* key is not in the buffer. Either put the key-value pair in the child, or put it in the node. */ static int push_brt_cmd_down_only_if_it_wont_push_more_else_put_here (BRT t, BRTNODE node, BRTNODE child, BRT_CMD cmd, int childnum_of_node, TOKULOGGER logger, DISKOFFARRAY path_to_parent) { assert(node->height>0); /* Not a leaf. */ DBT *k = cmd->u.id.key; DBT *v = cmd->u.id.val; unsigned int newsize = toku_serialize_brtnode_size(child) + k->size + v->size + KEY_VALUE_OVERHEAD; newsize += (child->height > 0) ? BRT_CMD_OVERHEAD : PMA_ITEM_OVERHEAD; #if 0 // This stuff is wrong. And we don't have a test to differentiate this from the previous line of code. unsigned int additionaloverhead = (child->height > 0) ? BRT_CMD_OVERHEAD : PMA_ITEM_OVERHEAD; newsize += additionaloverhead; // PMA_ITEM_OVERHEAD; // Was this printf("pbcdofiwpmeph newsize=%d\n", newsize); if (newsize<=node->nodesize && newsize+additionaloverhead-PMA_ITEM_OVERHEAD>node->nodesize) { printf("%s:%d\n", __FILE__, __LINE__); } #endif int to_child = newsize <= child->nodesize; if (toku_brt_debug_mode) { printf("%s:%d pushing %s to %s %d", __FILE__, __LINE__, (char*)k->data, to_child? "child" : "hash", childnum_of_node); if (childnum_of_node+1u.n.n_children) { DBT k2; printf(" nextsplitkey=%s\n", (char*)node->u.n.childkeys[childnum_of_node]); assert(t->compare_fun(t->db, k, toku_fill_dbt(&k2, node->u.n.childkeys[childnum_of_node], toku_brt_pivot_key_len(t, node->u.n.childkeys[childnum_of_node])))<=0); } else { printf("\n"); } } int r; if (to_child) { int again_split=-1; BRTNODE againa,againb; DBT againk; toku_init_dbt(&againk); //printf("%s:%d hello!\n", __FILE__, __LINE__); assert(path_to_parent.lenthisnodename; r = brtnode_put_cmd(t, child, cmd, &again_split, &againa, &againb, &againk, 0, logger, path_to_parent); if (r!=0) return r; assert(again_split==0); /* I only did the insert if I knew it wouldn't push down, and hence wouldn't split. */ } else { r=insert_to_buffer_in_nonleaf(node, childnum_of_node, k, v, cmd->type, cmd->xid); } fixup_child_fingerprint(node, childnum_of_node, child, t, logger); return r; } static int push_a_brt_cmd_down (BRT t, BRTNODE node, BRTNODE child, int childnum, BRT_CMD cmd, int *child_did_split, BRTNODE *childa, BRTNODE *childb, DBT *childsplitk, TOKULOGGER logger, DISKOFFARRAY path_to_parent) { //if (debug) printf("%s:%d %*sinserting down\n", __FILE__, __LINE__, debug, ""); //printf("%s:%d hello!\n", __FILE__, __LINE__); assert(node->height>0); { assert(path_to_parent.lenthisnodename; int r = brtnode_put_cmd(t, child, cmd, child_did_split, childa, childb, childsplitk, 0, logger, path_to_parent); if (r!=0) return r; } DBT *k = cmd->u.id.key; DBT *v = cmd->u.id.val; //if (debug) printf("%s:%d %*sinserted down child_did_split=%d\n", __FILE__, __LINE__, debug, "", child_did_split); u_int32_t old_fingerprint = node->local_fingerprint; u_int32_t new_fingerprint = old_fingerprint - node->rand4fingerprint*toku_calccrc32_cmdstruct(cmd); node->local_fingerprint = new_fingerprint; { BYTESTRING keybs = { .len=k->size, .data=(char*)k->data }; BYTESTRING databs = { .len=v->size, .data=(char*)v->data }; int r = toku_log_brtdeq(logger, (LSN*)0, 0, toku_cachefile_filenum(t->cf), node->thisnodename, childnum, cmd->xid, cmd->type, keybs, databs, old_fingerprint, new_fingerprint); assert(r==0); } { int r = toku_fifo_deq(BNC_BUFFER(node,childnum)); //printf("%s:%d deleted status=%d\n", __FILE__, __LINE__, r); if (r!=0) return r; } { int n_bytes_removed = (k->size + v->size + KEY_VALUE_OVERHEAD + BRT_CMD_OVERHEAD); node->u.n.n_bytes_in_buffers -= n_bytes_removed; BNC_NBYTESINBUF(node, childnum) -= n_bytes_removed; node->dirty = 1; } if (*child_did_split) { // Don't try to fix these up. //fixup_child_fingerprint(node, childnum, *childa, t, logger); //fixup_child_fingerprint(node, childnum+1, *childb, t, logger); } else { fixup_child_fingerprint(node, childnum, child, t, logger); } return 0; } static int brtnode_maybe_push_down(BRT t, BRTNODE node, int *did_split, BRTNODE *nodea, BRTNODE *nodeb, DBT *splitk, int debug, TOKULOGGER logger, DISKOFFARRAY path_to_parent); static int split_count=0; /* NODE is a node with a child. * childnum was split into two nodes childa, and childb. childa is the same as the original child. childb is a new child. * We must slide things around, & move things from the old table to the new tables. * We also move things to the new children as much as we can without doing any pushdowns or splitting of the child. * We must delete the old buffer (but the old child is already deleted.) * We also unpin the new children. */ static int handle_split_of_child (BRT t, BRTNODE node, int childnum, BRTNODE childa, BRTNODE childb, DBT *childsplitk, /* the data in the childsplitk is alloc'd and is consumed by this call. */ int *did_split, BRTNODE *nodea, BRTNODE *nodeb, DBT *splitk, TOKULOGGER logger, DISKOFFARRAY path_to_parent) { assert(node->height>0); assert(0 <= childnum && childnum < node->u.n.n_children); FIFO old_h = BNC_BUFFER(node,childnum); int old_count = BNC_NBYTESINBUF(node, childnum); int cnum; int r; assert(node->u.n.n_children<=TREE_FANOUT); if (toku_brt_debug_mode) { int i; printf("%s:%d Child %d did split on %s\n", __FILE__, __LINE__, childnum, (char*)childsplitk->data); printf("%s:%d oldsplitkeys:", __FILE__, __LINE__); for(i=0; iu.n.n_children-1; i++) printf(" %s", (char*)node->u.n.childkeys[i]); printf("\n"); } node->dirty = 1; //verify_local_fingerprint_nonleaf(node); REALLOC_N(node->u.n.n_children+2, node->u.n.childinfos); REALLOC_N(node->u.n.n_children+1, node->u.n.childkeys); // Slide the children over. BNC_SUBTREE_FINGERPRINT(node, node->u.n.n_children+1)=0; for (cnum=node->u.n.n_children; cnum>childnum+1; cnum--) { node->u.n.childinfos[cnum] = node->u.n.childinfos[cnum-1]; } r = toku_log_addchild(logger, (LSN*)0, 0, toku_cachefile_filenum(t->cf), node->thisnodename, childnum+1, childb->thisnodename, 0); node->u.n.n_children++; assert(BNC_DISKOFF(node, childnum)==childa->thisnodename); // use the same child BNC_DISKOFF(node, childnum+1) = childb->thisnodename; // BNC_SUBTREE_FINGERPRINT(node, childnum)=0; // leave the subtreefingerprint alone for the child, so we can log the change BNC_SUBTREE_FINGERPRINT(node, childnum+1)=0; fixup_child_fingerprint(node, childnum, childa, t, logger); fixup_child_fingerprint(node, childnum+1, childb, t, logger); r=toku_fifo_create(&BNC_BUFFER(node,childnum+1)); assert(r==0); //verify_local_fingerprint_nonleaf(node); // The fingerprint hasn't changed and everhything is still there. r=toku_fifo_create(&BNC_BUFFER(node,childnum)); assert(r==0); // ??? SHould handle this error case BNC_NBYTESINBUF(node, childnum) = 0; BNC_NBYTESINBUF(node, childnum+1) = 0; // Remove all the cmds from the local fingerprint. Some may get added in again when we try to push to the child. FIFO_ITERATE(old_h, skey, skeylen, sval, svallen, type, xid, ({ BYTESTRING keybs = { .len = skeylen, .data = (char*)skey }; BYTESTRING databs = { .len = svallen, .data = (char*)sval }; u_int32_t old_fingerprint = node->local_fingerprint; u_int32_t new_fingerprint = old_fingerprint - node->rand4fingerprint*toku_calccrc32_cmd(type, xid, skey, skeylen, sval, svallen); r = toku_log_brtdeq(logger, (LSN*)0, 0, toku_cachefile_filenum(t->cf), node->thisnodename, childnum, xid, type, keybs, databs, old_fingerprint, new_fingerprint); node->local_fingerprint = new_fingerprint; })); //verify_local_fingerprint_nonleaf(node); // Slide the keys over { struct kv_pair *pivot = childsplitk->data; BYTESTRING bs = { .len = childsplitk->size, .data = kv_pair_key(pivot) }; r = toku_log_setpivot(logger, (LSN*)0, 0, toku_cachefile_filenum(t->cf), node->thisnodename, childnum, bs); if (r!=0) return r; for (cnum=node->u.n.n_children-2; cnum>childnum; cnum--) { node->u.n.childkeys[cnum] = node->u.n.childkeys[cnum-1]; } //if (logger) assert((t->flags&TOKU_DB_DUPSORT)==0); // the setpivot is wrong for TOKU_DB_DUPSORT, so recovery will be broken. node->u.n.childkeys[childnum]= pivot; node->u.n.totalchildkeylens += toku_brt_pivot_key_len(t, pivot); } if (toku_brt_debug_mode) { int i; printf("%s:%d splitkeys:", __FILE__, __LINE__); for(i=0; iu.n.n_children-2; i++) printf(" %s", (char*)node->u.n.childkeys[i]); printf("\n"); } //verify_local_fingerprint_nonleaf(node); node->u.n.n_bytes_in_buffers -= old_count; /* By default, they are all removed. We might add them back in. */ /* Keep pushing to the children, but not if the children would require a pushdown */ FIFO_ITERATE(old_h, skey, skeylen, sval, svallen, type, xid, ({ DBT skd, svd; BRT_CMD_S brtcmd = { type, xid, .u.id= {toku_fill_dbt(&skd, skey, skeylen), toku_fill_dbt(&svd, sval, svallen)} }; //verify_local_fingerprint_nonleaf(childa); verify_local_fingerprint_nonleaf(childb); int pusha = 0, pushb = 0; switch (type) { case BRT_INSERT: case BRT_DELETE_BOTH: case BRT_DELETE: if (type!=BRT_DELETE || 0==(t->flags&TOKU_DB_DUPSORT)) { // If it's an INSERT or DELETE_BOTH or there are no duplicates then we just put the command into one subtree int cmp = brt_compare_pivot(t, &skd, &svd, childsplitk->data); if (cmp <= 0) pusha = 1; else pushb = 1; } else { assert(type==BRT_DELETE && t->flags&TOKU_DB_DUPSORT); // It is a DELETE and it's a DUPSORT database, in which case if the comparison function comes up 0 we must write the command to both children. (See #201) int cmp = brt_compare_pivot(t, &skd, 0, childsplitk->data); if (cmp<=0) pusha=1; if (cmp>=0) pushb=1; // Could be that both pusha and pushb are set } if (pusha) { // If we already have something in the buffer, we must add the new command to the buffer so that commands don't get out of order. if (toku_fifo_n_entries(BNC_BUFFER(node,childnum))==0) { r=push_brt_cmd_down_only_if_it_wont_push_more_else_put_here(t, node, childa, &brtcmd, childnum, logger, path_to_parent); } else { r=insert_to_buffer_in_nonleaf(node, childnum, &skd, &svd, type, xid); } } if (pushb) { // If we already have something in the buffer, we must add the new command to the buffer so that commands don't get out of order. if (toku_fifo_n_entries(BNC_BUFFER(node,childnum+1))==0) { r=push_brt_cmd_down_only_if_it_wont_push_more_else_put_here(t, node, childb, &brtcmd, childnum+1, logger, path_to_parent); } else { r=insert_to_buffer_in_nonleaf(node, childnum+1, &skd, &svd, type, xid); } } //verify_local_fingerprint_nonleaf(childa); verify_local_fingerprint_nonleaf(childb); if (r!=0) printf("r=%d\n", r); assert(r==0); goto ok; case BRT_NONE: // Don't have to do anything in this case, can just drop the command goto ok; } printf("Bad type %d\n", type); // Don't use default: because I want a compiler warning if I forget a enum case, and I want a runtime error if the type isn't one of the expected ones. assert(0); ok: /*nothing*/; })); toku_fifo_free(&old_h); //verify_local_fingerprint_nonleaf(childa); //verify_local_fingerprint_nonleaf(childb); //verify_local_fingerprint_nonleaf(node); //toku_verify_counts(node); //toku_verify_counts(childa); //toku_verify_counts(childb); r=toku_unpin_brtnode(t, childa); assert(r==0); r=toku_unpin_brtnode(t, childb); assert(r==0); if (node->u.n.n_children>TREE_FANOUT) { //printf("%s:%d about to split having pushed %d out of %d keys\n", __FILE__, __LINE__, i, n_pairs); r=brt_nonleaf_split(t, node, nodea, nodeb, splitk, logger, path_to_parent); if (r!=0) return r; //printf("%s:%d did split\n", __FILE__, __LINE__); split_count++; *did_split=1; assert((*nodea)->height>0); assert((*nodeb)->height>0); assert((*nodea)->u.n.n_children>0); assert((*nodeb)->u.n.n_children>0); assert(BNC_DISKOFF(*nodea, (*nodea)->u.n.n_children-1)!=0); assert(BNC_DISKOFF(*nodeb, (*nodeb)->u.n.n_children-1)!=0); assert(toku_serialize_brtnode_size(*nodea)<=(*nodea)->nodesize); assert(toku_serialize_brtnode_size(*nodeb)<=(*nodeb)->nodesize); //verify_local_fingerprint_nonleaf(*nodea); //verify_local_fingerprint_nonleaf(*nodeb); } else { *did_split=0; if (toku_serialize_brtnode_size(node) > node->nodesize) { /* lighten the node by pushing down its buffers. this may cause the current node to split and go away */ r = brtnode_maybe_push_down(t, node, did_split, nodea, nodeb, splitk, 0, logger, path_to_parent); assert(r == 0); } if (*did_split == 0) assert(toku_serialize_brtnode_size(node)<=node->nodesize); } return 0; } static int push_some_brt_cmds_down (BRT t, BRTNODE node, int childnum, int *did_split, BRTNODE *nodea, BRTNODE *nodeb, DBT *splitk, int debug, TOKULOGGER logger, DISKOFFARRAY path_to_parent) { void *childnode_v; BRTNODE child; int r; assert(node->height>0); DISKOFF targetchild = BNC_DISKOFF(node, childnum); assert(targetchild>=0 && targetchildh->unused_memory); // This assertion could fail in a concurrent setting since another process might have bumped unused memory. r = toku_cachetable_get_and_pin(t->cf, targetchild, &childnode_v, NULL, toku_brtnode_flush_callback, toku_brtnode_fetch_callback, t); if (r!=0) return r; //printf("%s:%d pin %p\n", __FILE__, __LINE__, childnode_v); child=childnode_v; //verify_local_fingerprint_nonleaf(child); //toku_verify_counts(child); //printf("%s:%d height=%d n_bytes_in_buffer = {%d, %d, %d, ...}\n", __FILE__, __LINE__, child->height, child->n_bytes_in_buffer[0], child->n_bytes_in_buffer[1], child->n_bytes_in_buffer[2]); if (child->height>0 && child->u.n.n_children>0) assert(BNC_DISKOFF(child, child->u.n.n_children-1)!=0); if (debug) printf("%s:%d %*spush_some_brt_cmds_down to %lld\n", __FILE__, __LINE__, debug, "", child->thisnodename); /* I am exposing the internals of the hash table here, mostly because I am not thinking of a really * good way to do it otherwise. I want to loop over the elements of the hash table, deleting some as I * go. The FIFO_ITERATE macro will break if I delete something from the hash table. */ if (0) { static int count=0; count++; printf("%s:%d pushing %d count=%d\n", __FILE__, __LINE__, childnum, count); } { bytevec key,val; ITEMLEN keylen, vallen; //printf("%s:%d Try random_pick, weight=%d \n", __FILE__, __LINE__, BNC_NBYTESINBUF(node, childnum)); assert(toku_fifo_n_entries(BNC_BUFFER(node,childnum))>0); u_int32_t type; TXNID xid; while(0==toku_fifo_peek(BNC_BUFFER(node,childnum), &key, &keylen, &val, &vallen, &type, &xid)) { int child_did_split=0; BRTNODE childa, childb; DBT hk,hv; DBT childsplitk; BRT_CMD_S brtcmd = { type, xid, .u.id= {toku_fill_dbt(&hk, key, keylen), toku_fill_dbt(&hv, val, vallen)} }; //printf("%s:%d random_picked\n", __FILE__, __LINE__); toku_init_dbt(&childsplitk); if (debug) printf("%s:%d %*spush down %s\n", __FILE__, __LINE__, debug, "", (char*)key); r = push_a_brt_cmd_down (t, node, child, childnum, &brtcmd, &child_did_split, &childa, &childb, &childsplitk, logger, path_to_parent); if (0){ unsigned int sum=0; FIFO_ITERATE(BNC_BUFFER(node,childnum), subhk __attribute__((__unused__)), hkl, hd __attribute__((__unused__)), hdl, subtype __attribute__((__unused__)), subxid __attribute__((__unused__)), sum+=hkl+hdl+KEY_VALUE_OVERHEAD+BRT_CMD_OVERHEAD); printf("%s:%d sum=%d\n", __FILE__, __LINE__, sum); assert(sum==BNC_NBYTESINBUF(node, childnum)); } if (BNC_NBYTESINBUF(node, childnum)>0) assert(toku_fifo_n_entries(BNC_BUFFER(node,childnum))>0); //printf("%s:%d %d=push_a_brt_cmd_down=(); child_did_split=%d (weight=%d)\n", __FILE__, __LINE__, r, child_did_split, BNC_NBYTESINBUF(node, childnum)); if (r!=0) return r; if (child_did_split) { // If the child splits, we don't push down any further. if (debug) printf("%s:%d %*shandle split splitkey=%s\n", __FILE__, __LINE__, debug, "", (char*)childsplitk.data); r=handle_split_of_child (t, node, childnum, childa, childb, &childsplitk, did_split, nodea, nodeb, splitk, logger, path_to_parent); //if (*did_split) { // verify_local_fingerprint_nonleaf(*nodea); // verify_local_fingerprint_nonleaf(*nodeb); //} return r; /* Don't do any more pushing if the child splits. */ } } if (0) printf("%s:%d done random picking\n", __FILE__, __LINE__); } if (debug) printf("%s:%d %*sdone push_some_brt_cmds_down, unpinning %lld\n", __FILE__, __LINE__, debug, "", targetchild); assert(toku_serialize_brtnode_size(node)<=node->nodesize); //verify_local_fingerprint_nonleaf(node); r=toku_unpin_brtnode(t, child); if (r!=0) return r; *did_split=0; return 0; } static int debugp1 (int debug) { return debug ? debug+1 : 0; } static int brtnode_maybe_push_down(BRT t, BRTNODE node, int *did_split, BRTNODE *nodea, BRTNODE *nodeb, DBT *splitk, int debug, TOKULOGGER logger, DISKOFFARRAY path_to_parent) /* If the buffer is too full, then push down. Possibly the child will split. That may make us split. */ { assert(node->height>0); if (debug) printf("%s:%d %*sIn maybe_push_down in_buffer=%d childkeylens=%d size=%d\n", __FILE__, __LINE__, debug, "", node->u.n.n_bytes_in_buffers, node->u.n.totalchildkeylens, toku_serialize_brtnode_size(node)); if (toku_serialize_brtnode_size(node) > node->nodesize ) { if (debug) printf("%s:%d %*stoo full, height=%d\n", __FILE__, __LINE__, debug, "", node->height); { /* Push to a child. */ /* Find the heaviest child, and push stuff to it. Keep pushing to the child until we run out. * But if the child pushes something to its child and our buffer has gotten small enough, then we stop pushing. */ int childnum; if (0) printf("%s:%d %*sfind_heaviest_data\n", __FILE__, __LINE__, debug, ""); find_heaviest_child(node, &childnum); if (0) printf("%s:%d %*spush some down from %lld into %lld (child %d)\n", __FILE__, __LINE__, debug, "", node->thisnodename, BNC_DISKOFF(node, childnum), childnum); assert(BNC_DISKOFF(node, childnum)!=0); int r = push_some_brt_cmds_down(t, node, childnum, did_split, nodea, nodeb, splitk, debugp1(debug), logger, path_to_parent); if (r!=0) return r; assert(*did_split==0 || *did_split==1); if (debug) printf("%s:%d %*sdid push_some_brt_cmds_down did_split=%d\n", __FILE__, __LINE__, debug, "", *did_split); if (*did_split) { assert(toku_serialize_brtnode_size(*nodea)<=(*nodea)->nodesize); assert(toku_serialize_brtnode_size(*nodeb)<=(*nodeb)->nodesize); assert((*nodea)->u.n.n_children>0); assert((*nodeb)->u.n.n_children>0); assert(BNC_DISKOFF(*nodea, (*nodea)->u.n.n_children-1)!=0); assert(BNC_DISKOFF(*nodeb, (*nodeb)->u.n.n_children-1)!=0); //verify_local_fingerprint_nonleaf(*nodea); //verify_local_fingerprint_nonleaf(*nodeb); } else { assert(toku_serialize_brtnode_size(node)<=node->nodesize); } } } else { *did_split=0; assert(toku_serialize_brtnode_size(node)<=node->nodesize); } //if (*did_split) { // verify_local_fingerprint_nonleaf(*nodea); // verify_local_fingerprint_nonleaf(*nodeb); //} else { // verify_local_fingerprint_nonleaf(node); //} return 0; } int toku_brtleaf_compare_fun (u_int32_t alen __attribute__((__unused__)), void *aval, u_int32_t blen __attribute__((__unused__)), void *bval, void *extra) { struct lc_pair *p = extra; BRT t = p->t; DBT k1,k2; int cmp = t->compare_fun (t->db, toku_fill_dbt(&k1, kv_pair_key(aval), kv_pair_keylen(aval)), toku_fill_dbt(&k2, kv_pair_key(bval), kv_pair_keylen(bval))); if (cmp == 0 && p->compare_both ) { return t->dup_compare(t->db, toku_fill_dbt(&k1, kv_pair_val(aval), kv_pair_vallen(aval)), toku_fill_dbt(&k2, kv_pair_val(bval), kv_pair_vallen(bval))); } else { return cmp; } } static int brt_leaf_put_cmd (BRT t, BRTNODE node, BRT_CMD cmd, int *did_split, BRTNODE *nodea, BRTNODE *nodeb, DBT *splitk, int debug, TOKULOGGER logger) { // toku_pma_verify_fingerprint(node->u.l.buffer, node->rand4fingerprint, node->subtree_fingerprint); assert(node->height==0); FILENUM filenum = toku_cachefile_filenum(t->cf); if (cmd->type == BRT_INSERT) { DBT *k = cmd->u.id.key; DBT *v = cmd->u.id.val; struct kv_pair *kv = brtnode_malloc_kv_pair(node->u.l.buffer, &node->u.l.buffer_mempool, k->data, k->size, v->data, v->size); assert(kv); u_int32_t storedlen; void *storeddata; u_int32_t idx; struct lc_pair lc = {t, node->flags & TOKU_DB_DUPSORT}; // for put operations we compare both keys if they are both there int r = toku_gpma_lookup_item(node->u.l.buffer, kv_pair_size(kv), kv, toku_brtleaf_compare_fun, &lc, &storedlen, &storeddata, &idx); if (r==0) { // It's already there. Note that it's gone and remove it from the mempool. node->u.l.n_bytes_in_buffer -= PMA_ITEM_OVERHEAD + storedlen; node->local_fingerprint -= node->rand4fingerprint*toku_calccrc32_kvpair_struct(storeddata); BYTESTRING okbs = { kv_pair_keylen(storeddata), kv_pair_key(storeddata) }; BYTESTRING odbs = { kv_pair_vallen(storeddata), kv_pair_val(storeddata) }; r = toku_log_deleteinleaf(logger, &node->log_lsn, 0, cmd->xid, filenum, node->thisnodename, idx, okbs, odbs); toku_mempool_mfree(&node->u.l.buffer_mempool, storeddata, storedlen); // Now put the new kv in. toku_gpma_set_at_index(node->u.l.buffer, idx, kv_pair_size(kv), kv); } else { // Insert it. struct move_struct ms = {.logger=logger, .filenum=filenum, .from=node, .to=node}; r = toku_gpma_insert(node->u.l.buffer, kv_pair_size(kv), kv, toku_brtleaf_compare_fun, &lc, note_move_items_within, &ms, &idx); if (r!=0) return r; } { BYTESTRING kbs = { kv_pair_keylen(kv), kv_pair_key(kv) }; BYTESTRING dbs = { kv_pair_vallen(kv), kv_pair_val(kv) }; r = toku_log_insertinleaf(logger, &node->log_lsn, 0, cmd->xid, filenum, node->thisnodename, idx, kbs, dbs); if (r!=0) return r; } node->u.l.n_bytes_in_buffer += PMA_ITEM_OVERHEAD + kv_pair_size(kv); node->local_fingerprint += node->rand4fingerprint*toku_calccrc32_kvpair_struct(kv); // printf("%s:%d rand4=%08x local_fingerprint=%08x this=%08x\n", __FILE__, __LINE__, node->rand4fingerprint, node->local_fingerprint, toku_calccrc32_kvpair_struct(kv)); node->dirty = 1; // toku_pma_verify_fingerprint(node->u.l.buffer, node->rand4fingerprint, node->subtree_fingerprint); // If it doesn't fit, then split the leaf. if (toku_serialize_brtnode_size(node) > node->nodesize) { r = brtleaf_split (logger, filenum, t, node, nodea, nodeb, splitk); if (r!=0) return r; //printf("%s:%d splitkey=%s\n", __FILE__, __LINE__, (char*)*splitkey); split_count++; *did_split = 1; if (debug) printf("%s:%d %*snodeb->thisnodename=%lld nodeb->size=%d\n", __FILE__, __LINE__, debug, "", (*nodeb)->thisnodename, (*nodeb)->nodesize); assert(toku_serialize_brtnode_size(*nodea)<=(*nodea)->nodesize); assert(toku_serialize_brtnode_size(*nodeb)<=(*nodeb)->nodesize); // toku_pma_verify_fingerprint((*nodea)->u.l.buffer, (*nodea)->rand4fingerprint, (*nodea)->subtree_fingerprint); // toku_pma_verify_fingerprint((*nodeb)->u.l.buffer, (*nodeb)->rand4fingerprint, (*nodeb)->subtree_fingerprint); } else { *did_split = 0; } return 0; } else if (cmd->type == BRT_DELETE || cmd->type == BRT_DELETE_BOTH) { DBT *k = cmd->u.id.key; DBT *v = cmd->u.id.val; struct kv_pair *kv = kv_pair_malloc(k->data, k->size, v->data, v->size); struct lc_pair lc = {t, (cmd->type == BRT_DELETE_BOTH) }; struct move_struct ms = {.logger=logger, .filenum=filenum, .from=node, .to=node}; struct delete_struct dp = {node}; int r = toku_gpma_delete_item(node->u.l.buffer, kv_pair_size(kv), kv, toku_brtleaf_compare_fun, &lc, brt_leaf_delete_callback, &dp, note_move_items_within, &ms); toku_free(kv); *did_split = 0; if (r==DB_NOTFOUND) return 0; return r; } else { return EINVAL; } } /* find the leftmost child that may contain the key */ unsigned int toku_brtnode_which_child (BRTNODE node , DBT *k, DBT *d, BRT t) { int i; assert(node->height>0); for (i=0; iu.n.n_children-1; i++) { int cmp = brt_compare_pivot(t, k, d, node->u.n.childkeys[i]); if (cmp > 0) continue; if (cmp < 0) return i; return i; } return node->u.n.n_children-1; } /* put a cmd into a nodes child */ static int brt_nonleaf_put_cmd_child_node (BRT t, BRTNODE node, BRT_CMD cmd, int *did_split, BRTNODE *nodea, BRTNODE *nodeb, DBT *splitk, int debug, TOKULOGGER logger, int childnum, int maybe, DISKOFFARRAY path_to_parent) { int r; void *child_v; BRTNODE child; int child_did_split; BRTNODE childa, childb; DBT childsplitk; *did_split = 0; if (maybe) r = toku_cachetable_maybe_get_and_pin(t->cf, BNC_DISKOFF(node, childnum), &child_v); else r = toku_cachetable_get_and_pin(t->cf, BNC_DISKOFF(node, childnum), &child_v, NULL, toku_brtnode_flush_callback, toku_brtnode_fetch_callback, t); if (r != 0) return r; child = child_v; child_did_split = 0; assert(path_to_parent.lenthisnodename; r = brtnode_put_cmd(t, child, cmd, &child_did_split, &childa, &childb, &childsplitk, debug, logger, path_to_parent); path_to_parent.len--; if (r != 0) { /* putting to the child failed for some reason, so unpin the child and return the error code */ int rr = toku_unpin_brtnode(t, child); assert(rr == 0); return r; } if (child_did_split) { if (0) printf("brt_nonleaf_insert child_split %p\n", child); assert(cmd->type <= BRT_DELETE_BOTH); r = handle_split_of_child(t, node, childnum, childa, childb, &childsplitk, did_split, nodea, nodeb, splitk, logger, path_to_parent); assert(r == 0); } else { //verify_local_fingerprint_nonleaf(child); fixup_child_fingerprint(node, childnum, child, t, logger); int rr = toku_unpin_brtnode(t, child); assert(rr == 0); } return r; } int toku_brt_do_push_cmd = 1; /* put a cmd into a node at childnum */ static int brt_nonleaf_put_cmd_child (BRT t, BRTNODE node, BRT_CMD cmd, int *did_split, BRTNODE *nodea, BRTNODE *nodeb, DBT *splitk, int debug, TOKULOGGER logger, unsigned int childnum, int can_push, int *do_push_down, DISKOFFARRAY path_to_parent) { //verify_local_fingerprint_nonleaf(node); /* try to push the cmd to the subtree if the buffer is empty and pushes are enabled */ if (BNC_NBYTESINBUF(node, childnum) == 0 && can_push && toku_brt_do_push_cmd) { int r = brt_nonleaf_put_cmd_child_node(t, node, cmd, did_split, nodea, nodeb, splitk, debug, logger, childnum, 1, path_to_parent); if (r == 0) return r; } //verify_local_fingerprint_nonleaf(node); /* append the cmd to the child buffer */ { int type = cmd->type; DBT *k = cmd->u.id.key; DBT *v = cmd->u.id.val; int r = log_and_save_brtenq(logger, t, node, childnum, cmd->xid, type, k->data, k->size, v->data, v->size, &node->local_fingerprint, path_to_parent); if (r!=0) return r; int diff = k->size + v->size + KEY_VALUE_OVERHEAD + BRT_CMD_OVERHEAD; r=toku_fifo_enq(BNC_BUFFER(node,childnum), k->data, k->size, v->data, v->size, type, cmd->xid); assert(r==0); node->u.n.n_bytes_in_buffers += diff; BNC_NBYTESINBUF(node, childnum) += diff; node->dirty = 1; } *do_push_down = 1; return 0; } static int brt_nonleaf_insert_cmd (BRT t, BRTNODE node, BRT_CMD cmd, int *did_split, BRTNODE *nodea, BRTNODE *nodeb, DBT *splitk, int debug, TOKULOGGER logger, DISKOFFARRAY path_to_parent) { //verify_local_fingerprint_nonleaf(node); unsigned int childnum; int r; /* find the right subtree */ childnum = toku_brtnode_which_child(node, cmd->u.id.key, cmd->u.id.val, t); /* put the cmd in the subtree */ int do_push_down = 0; r = brt_nonleaf_put_cmd_child(t, node, cmd, did_split, nodea, nodeb, splitk, debug, logger, childnum, 1, &do_push_down, path_to_parent); if (r != 0) return r; /* maybe push down */ if (do_push_down) { if (debug) printf("%s:%d %*sDoing maybe_push_down\n", __FILE__, __LINE__, debug, ""); //verify_local_fingerprint_nonleaf(node); r = brtnode_maybe_push_down(t, node, did_split, nodea, nodeb, splitk, debugp1(debug), logger, path_to_parent); if (r!=0) return r; if (debug) printf("%s:%d %*sDid maybe_push_down\n", __FILE__, __LINE__, debug, ""); if (*did_split) { assert(toku_serialize_brtnode_size(*nodea)<=(*nodea)->nodesize); assert(toku_serialize_brtnode_size(*nodeb)<=(*nodeb)->nodesize); assert((*nodea)->u.n.n_children>0); assert((*nodeb)->u.n.n_children>0); assert(BNC_DISKOFF(*nodea, (*nodea)->u.n.n_children-1)!=0); assert(BNC_DISKOFF(*nodeb, (*nodeb)->u.n.n_children-1)!=0); } else { assert(toku_serialize_brtnode_size(node)<=node->nodesize); } //if (*did_split) { // verify_local_fingerprint_nonleaf(*nodea); // verify_local_fingerprint_nonleaf(*nodeb); //} else { // verify_local_fingerprint_nonleaf(node); //} } return 0; } /* delete in all subtrees starting from the left most one which contains the key */ static int brt_nonleaf_delete_cmd (BRT t, BRTNODE node, BRT_CMD cmd, int *did_split, BRTNODE *nodea, BRTNODE *nodeb, DBT *splitk, int debug, TOKULOGGER logger, DISKOFFARRAY path_to_parent) { int r; /* find all children that need a delete cmd */ int delchild[TREE_FANOUT], delidx = 0; inline void delchild_append(int i) { if (delidx == 0 || delchild[delidx-1] != i) delchild[delidx++] = i; } int i; for (i = 0; i < node->u.n.n_children-1; i++) { int cmp = brt_compare_pivot(t, cmd->u.id.key, 0, node->u.n.childkeys[i]); if (cmp > 0) { continue; } else if (cmp < 0) { delchild_append(i); break; } else if (t->flags & TOKU_DB_DUPSORT) { delchild_append(i); delchild_append(i+1); } else { delchild_append(i); break; } } if (delidx == 0) delchild_append(node->u.n.n_children-1); /* issue the delete cmd to all of the children found previously */ int do_push_down = 0; for (i=0; inodesize); assert(toku_serialize_brtnode_size(*nodeb)<=(*nodeb)->nodesize); assert((*nodea)->u.n.n_children>0); assert((*nodeb)->u.n.n_children>0); assert(BNC_DISKOFF(*nodea,(*nodea)->u.n.n_children-1)!=0); assert(BNC_DISKOFF(*nodeb,(*nodeb)->u.n.n_children-1)!=0); } else { assert(toku_serialize_brtnode_size(node)<=node->nodesize); } //if (*did_split) { // verify_local_fingerprint_nonleaf(*nodea); // verify_local_fingerprint_nonleaf(*nodeb); //} else { // verify_local_fingerprint_nonleaf(node); //} } return 0; } static int brt_nonleaf_put_cmd (BRT t, BRTNODE node, BRT_CMD cmd, int *did_split, BRTNODE *nodea, BRTNODE *nodeb, DBT *splitk, int debug, TOKULOGGER logger, DISKOFFARRAY path_to_parent) { if (cmd->type == BRT_INSERT || cmd->type == BRT_DELETE_BOTH) { return brt_nonleaf_insert_cmd(t, node, cmd, did_split, nodea, nodeb, splitk, debug, logger, path_to_parent); } else if (cmd->type == BRT_DELETE) { return brt_nonleaf_delete_cmd(t, node, cmd, did_split, nodea, nodeb, splitk, debug, logger, path_to_parent); } else return EINVAL; } static void verify_local_fingerprint_nonleaf (BRTNODE node) { u_int32_t fp=0; int i; if (node->height==0) return; for (i=0; iu.n.n_children; i++) FIFO_ITERATE(BNC_BUFFER(node,i), key, keylen, data, datalen, type, xid, ({ fp += node->rand4fingerprint * toku_calccrc32_cmd(type, xid, key, keylen, data, datalen); })); assert(fp==node->local_fingerprint); } static int brtnode_put_cmd (BRT t, BRTNODE node, BRT_CMD cmd, int *did_split, BRTNODE *nodea, BRTNODE *nodeb, DBT *splitk, int debug, TOKULOGGER logger, DISKOFFARRAY path_to_parent) { //static int counter=0; // FOO //static int oldcounter=0; //int tmpcounter; //u_int32_t oldfingerprint=node->local_fingerprint; int r; //counter++; tmpcounter=counter; if (node->height==0) { // toku_pma_verify_fingerprint(node->u.l.buffer, node->rand4fingerprint, node->subtree_fingerprint); r = brt_leaf_put_cmd(t, node, cmd, did_split, nodea, nodeb, splitk, debug, logger); } else { r = brt_nonleaf_put_cmd(t, node, cmd, did_split, nodea, nodeb, splitk, debug, logger, path_to_parent); } //oldcounter=tmpcounter; // Watch out. If did_split then the original node is no longer allocated. if (*did_split) { assert(toku_serialize_brtnode_size(*nodea)<=(*nodea)->nodesize); assert(toku_serialize_brtnode_size(*nodeb)<=(*nodeb)->nodesize); // if ((*nodea)->height==0) { // toku_pma_verify_fingerprint((*nodea)->u.l.buffer, (*nodea)->rand4fingerprint, (*nodea)->subtree_fingerprint); // toku_pma_verify_fingerprint((*nodeb)->u.l.buffer, (*nodeb)->rand4fingerprint, (*nodeb)->subtree_fingerprint); // } } else { assert(toku_serialize_brtnode_size(node)<=node->nodesize); // if (node->height==0) { // toku_pma_verify_fingerprint(node->u.l.buffer, node->rand4fingerprint, node->local_fingerprint); // } else { // verify_local_fingerprint_nonleaf(node); // } } //if (node->local_fingerprint==3522421844U) { // if (*did_split) { // verify_local_fingerprint_nonleaf(*nodea); // verify_local_fingerprint_nonleaf(*nodeb); // } return r; } int toku_brt_create_cachetable(CACHETABLE *ct, long cachesize, LSN initial_lsn, TOKULOGGER logger) { if (cachesize == 0) cachesize = 128*1024*1024; return toku_create_cachetable(ct, cachesize, initial_lsn, logger); } static int setup_initial_brt_root_node (BRT t, DISKOFF offset, TOKULOGGER logger) { int r; TAGMALLOC(BRTNODE, node); assert(node); //printf("%s:%d\n", __FILE__, __LINE__); initialize_brtnode(t, node, offset, /* the location is one nodesize offset from 0. */ 0); // node->brt = t; if (0) { printf("%s:%d for tree %p node %p mdict_create--> %p\n", __FILE__, __LINE__, t, node, node->u.l.buffer); printf("%s:%d put root at %lld\n", __FILE__, __LINE__, offset); } //printf("%s:%d putting %p (%lld)\n", __FILE__, __LINE__, node, node->thisnodename); r=toku_cachetable_put(t->cf, offset, node, brtnode_size(node), toku_brtnode_flush_callback, toku_brtnode_fetch_callback, t); if (r!=0) { toku_free(node); return r; } // verify_local_fingerprint_nonleaf(node); toku_log_newbrtnode(logger, (LSN*)0, 0, toku_cachefile_filenum(t->cf), offset, 0, t->h->nodesize, (t->flags&TOKU_DB_DUPSORT)!=0, node->rand4fingerprint); toku_update_brtnode_loggerlsn(node, logger); r = toku_unpin_brtnode(t, node); if (r!=0) { toku_free(node); return r; } return 0; } //#define BRT_TRACE #ifdef BRT_TRACE #define WHEN_BRTTRACE(x) x #else #define WHEN_BRTTRACE(x) ((void)0) #endif int toku_brt_create(BRT *brt_ptr) { BRT brt = toku_malloc(sizeof *brt); if (brt == 0) return ENOMEM; memset(brt, 0, sizeof *brt); list_init(&brt->cursors); brt->flags = 0; brt->nodesize = BRT_DEFAULT_NODE_SIZE; brt->compare_fun = toku_default_compare_fun; brt->dup_compare = toku_default_compare_fun; *brt_ptr = brt; return 0; } int toku_brt_set_flags(BRT brt, unsigned int flags) { brt->flags = flags; return 0; } int toku_brt_get_flags(BRT brt, unsigned int *flags) { *flags = brt->flags; return 0; } int toku_brt_set_nodesize(BRT brt, unsigned int nodesize) { brt->nodesize = nodesize; return 0; } int toku_brt_get_nodesize(BRT brt, unsigned int *nodesize) { *nodesize = brt->nodesize; return 0; } int toku_brt_set_bt_compare(BRT brt, int (*bt_compare)(DB *, const DBT*, const DBT*)) { brt->compare_fun = bt_compare; return 0; } int toku_brt_set_dup_compare(BRT brt, int (*dup_compare)(DB *, const DBT*, const DBT*)) { brt->dup_compare = dup_compare; return 0; } int toku_brt_get_fd(BRT brt, int *fdp) { *fdp = toku_cachefile_fd(brt->cf); return 0; } int toku_brt_open(BRT t, const char *fname, const char *fname_in_env, const char *dbname, int is_create, int only_create, int load_flags, CACHETABLE cachetable, TOKUTXN txn, DB *db) { /* If dbname is NULL then we setup to hold a single tree. Otherwise we setup an array. */ int r; char *malloced_name=0; //printf("%s:%d %d alloced\n", __FILE__, __LINE__, get_n_items_malloced()); toku_print_malloced_items(); WHEN_BRTTRACE(fprintf(stderr, "BRTTRACE: %s:%d toku_brt_open(%s, \"%s\", %d, %p, %d, %p)\n", __FILE__, __LINE__, fname, dbname, is_create, newbrt, nodesize, cachetable)); if (0) { died0: assert(r); return r; } assert(is_create || !only_create); assert(!load_flags || !only_create); if (dbname) { malloced_name = toku_strdup(dbname); if (malloced_name==0) { r = ENOMEM; if (0) { died0a: if(malloced_name) toku_free(malloced_name); } goto died0; } } t->database_name = malloced_name; t->db = db; { int fd = open(fname, O_RDWR, 0777); r = errno; if (fd==-1) { if (errno==ENOENT) { if (!is_create) { t->database_name=0; goto died0a; } fd = open(fname, O_RDWR | O_CREAT, 0777); r = errno; if (fd==-1) { t->database_name=0; goto died0a; } r = toku_logger_log_fcreate(txn, fname_in_env, 0777); if (r!=0) goto died0a; } else goto died0a; } r=toku_cachetable_openfd(&t->cf, cachetable, fd, t); if (r != 0) goto died0a; toku_logger_log_fopen(txn, fname_in_env, toku_cachefile_filenum(t->cf)); } if (r!=0) { if (0) { died1: toku_cachefile_close(&t->cf); } t->database_name = 0; goto died0a; } assert(t->nodesize>0); //printf("%s:%d %d alloced\n", __FILE__, __LINE__, get_n_items_malloced()); toku_print_malloced_items(); if (0) { died_after_read_and_pin: toku_cachetable_unpin(t->cf, 0, 0, 0); // unpin the header goto died1; } if (is_create) { r = toku_read_and_pin_brt_header(t->cf, &t->h); if (r==-1) { /* construct a new header. */ if ((MALLOC(t->h))==0) { assert(errno==ENOMEM); r = ENOMEM; if (0) { died2: toku_free(t->h); } t->h=0; goto died_after_read_and_pin; } t->h->dirty=1; t->h->flags = t->flags; t->h->nodesize=t->nodesize; t->h->freelist=-1; t->h->unused_memory=2*t->nodesize; if (dbname) { t->h->unnamed_root = -1; t->h->n_named_roots = 1; if ((MALLOC_N(1, t->h->names))==0) { assert(errno==ENOMEM); r=ENOMEM; if (0) { died3: toku_free(t->h->names); } goto died2; } if ((MALLOC_N(1, t->h->roots))==0) { assert(errno==ENOMEM); r=ENOMEM; if (0) { died4: toku_free(t->h->roots); } goto died3; } if ((t->h->names[0] = toku_strdup(dbname))==0) { assert(errno==ENOMEM); r=ENOMEM; if (0) { died5: toku_free(t->h->names[0]); } goto died4; } t->h->roots[0] = t->nodesize; } else { t->h->unnamed_root = t->nodesize; t->h->n_named_roots = -1; t->h->names=0; t->h->roots=0; } { LOGGEDBRTHEADER lh = {.size= toku_serialize_brt_header_size(t->h), .flags = t->h->flags, .nodesize = t->h->nodesize, .freelist = t->h->freelist, .unused_memory = t->h->unused_memory, .n_named_roots = t->h->n_named_roots }; if (t->h->n_named_roots>0) { lh.u.many.names = t->h->names; lh.u.many.roots = t->h->roots; } else { lh.u.one.root = t->h->unnamed_root; } if ((r=toku_log_fheader(toku_txn_logger(txn), (LSN*)0, 0, toku_txn_get_txnid(txn), toku_cachefile_filenum(t->cf), lh))) { goto died6; } } if ((r=setup_initial_brt_root_node(t, t->nodesize, toku_txn_logger(txn)))!=0) { died6: if (dbname) goto died5; else goto died2; } if ((r=toku_cachetable_put(t->cf, 0, t->h, 0, toku_brtheader_flush_callback, toku_brtheader_fetch_callback, 0))) { goto died6; } } else if (r!=0) { goto died_after_read_and_pin; } else { int i; assert(r==0); assert(dbname); if (t->h->unnamed_root!=-1) { r=EINVAL; goto died_after_read_and_pin; } // Cannot create a subdb in a file that is not enabled for subdbs assert(t->h->n_named_roots>=0); for (i=0; ih->n_named_roots; i++) { if (strcmp(t->h->names[i], dbname)==0) { if (only_create) { r = EEXIST; goto died_after_read_and_pin; } else goto found_it; } } if ((t->h->names = toku_realloc(t->h->names, (1+t->h->n_named_roots)*sizeof(*t->h->names))) == 0) { assert(errno==ENOMEM); r=ENOMEM; goto died_after_read_and_pin; } if ((t->h->roots = toku_realloc(t->h->roots, (1+t->h->n_named_roots)*sizeof(*t->h->roots))) == 0) { assert(errno==ENOMEM); r=ENOMEM; goto died_after_read_and_pin; } t->h->n_named_roots++; if ((t->h->names[t->h->n_named_roots-1] = toku_strdup(dbname)) == 0) { assert(errno==ENOMEM); r=ENOMEM; goto died_after_read_and_pin; } //printf("%s:%d t=%p\n", __FILE__, __LINE__, t); r = malloc_diskblock_header_is_in_memory(&t->h->roots[t->h->n_named_roots-1], t, t->h->nodesize, toku_txn_logger(txn)); if (r!=0) goto died_after_read_and_pin; t->h->dirty = 1; if ((r=setup_initial_brt_root_node(t, t->h->roots[t->h->n_named_roots-1], toku_txn_logger(txn)))!=0) goto died_after_read_and_pin; } } else { if ((r = toku_read_and_pin_brt_header(t->cf, &t->h))!=0) goto died1; if (!dbname) { if (t->h->n_named_roots!=-1) { r = EINVAL; goto died_after_read_and_pin; } // requires a subdb } else { int i; if (t->h->n_named_roots==-1) { r=EINVAL; goto died_after_read_and_pin; } // no suddbs in the db // printf("%s:%d n_roots=%d\n", __FILE__, __LINE__, t->h->n_named_roots); for (i=0; ih->n_named_roots; i++) { if (strcmp(t->h->names[i], dbname)==0) { goto found_it; } } r=ENOENT; /* the database doesn't exist */ goto died_after_read_and_pin; } found_it: t->nodesize = t->h->nodesize; /* inherit the pagesize from the file */ if (t->flags != t->h->flags) { /* flags must match */ if (load_flags) t->flags = t->h->flags; else {r = EINVAL; goto died_after_read_and_pin;} } } assert(t->h); if ((r = toku_unpin_brt_header(t)) !=0) goto died1; // it's unpinned assert(t->h==0); WHEN_BRTTRACE(fprintf(stderr, "BRTTRACE -> %p\n", t)); return 0; } int toku_brt_remove_subdb(BRT brt, const char *dbname, u_int32_t flags) { int r; int r2 = 0; int i; int found = -1; assert(flags == 0); r = toku_read_and_pin_brt_header(brt->cf, &brt->h); //TODO: What if r != 0? Is this possible? // We just called toku_brt_open, so it should exist... assert(r==0); assert(brt->h->unnamed_root==-1); assert(brt->h->n_named_roots>=0); for (i = 0; i < brt->h->n_named_roots; i++) { if (strcmp(brt->h->names[i], dbname) == 0) { found = i; break; } } if (found == -1) { //Should not be possible. r = ENOENT; goto error; } //Free old db name toku_free(brt->h->names[found]); //TODO: Free Diskblocks including root for (i = found + 1; i < brt->h->n_named_roots; i++) { brt->h->names[i - 1] = brt->h->names[i]; brt->h->roots[i - 1] = brt->h->roots[i]; } brt->h->n_named_roots--; brt->h->dirty = 1; //TODO: What if n_named_roots becomes 0? Should we handle it specially? Should we delete the file? if ((brt->h->names = toku_realloc(brt->h->names, (brt->h->n_named_roots)*sizeof(*brt->h->names))) == 0) { assert(errno==ENOMEM); r=ENOMEM; goto error; } if ((brt->h->roots = toku_realloc(brt->h->roots, (brt->h->n_named_roots)*sizeof(*brt->h->roots))) == 0) { assert(errno==ENOMEM); r=ENOMEM; goto error; } error: r2 = toku_unpin_brt_header(brt); assert(r2==0);//TODO: Can r2 be non 0? assert(brt->h==0); return r ? r : r2; } // This one has no env int toku_open_brt (const char *fname, const char *dbname, int is_create, BRT *newbrt, int nodesize, CACHETABLE cachetable, TOKUTXN txn, int (*compare_fun)(DB*,const DBT*,const DBT*), DB *db) { BRT brt; int r; const int only_create = 0; const int load_flags = 0; r = toku_brt_create(&brt); if (r != 0) return r; toku_brt_set_nodesize(brt, nodesize); toku_brt_set_bt_compare(brt, compare_fun); r = toku_brt_open(brt, fname, fname, dbname, is_create, only_create, load_flags, cachetable, txn, db); if (r != 0) { return r; } *newbrt = brt; return r; } int toku_close_brt (BRT brt) { int r; while (!list_empty(&brt->cursors)) { BRT_CURSOR c = list_struct(list_pop(&brt->cursors), struct brt_cursor, cursors_link); r=toku_brt_cursor_close(c); if (r!=0) return r; } if (brt->cf) { assert(0==toku_cachefile_count_pinned(brt->cf, 1)); // For the brt, the pinned count should be zero. //printf("%s:%d closing cachetable\n", __FILE__, __LINE__); if ((r = toku_cachefile_close(&brt->cf))!=0) return r; } if (brt->database_name) toku_free(brt->database_name); if (brt->skey) { toku_free(brt->skey); } if (brt->sval) { toku_free(brt->sval); } toku_free(brt); return 0; } int toku_brt_debug_mode = 0;//strcmp(key,"hello387")==0; CACHEKEY* toku_calculate_root_offset_pointer (BRT brt) { if (brt->database_name==0) { return &brt->h->unnamed_root; } else { int i; for (i=0; ih->n_named_roots; i++) { if (strcmp(brt->database_name, brt->h->names[i])==0) { return &brt->h->roots[i]; } } } abort(); } static int brt_init_new_root(BRT brt, BRTNODE nodea, BRTNODE nodeb, DBT splitk, CACHEKEY *rootp, TOKULOGGER logger, BRTNODE *newrootp) { TAGMALLOC(BRTNODE, newroot); int r; int new_height = nodea->height+1; int new_nodesize = brt->h->nodesize; DISKOFF newroot_diskoff; r=malloc_diskblock(&newroot_diskoff, brt, new_nodesize, logger); assert(r==0); assert(newroot); if (brt->database_name==0) { toku_log_changeunnamedroot(logger, (LSN*)0, 0, toku_cachefile_filenum(brt->cf), *rootp, newroot_diskoff); } else { BYTESTRING bs; bs.len = 1+strlen(brt->database_name); bs.data = brt->database_name; toku_log_changenamedroot(logger, (LSN*)0, 0, toku_cachefile_filenum(brt->cf), bs, *rootp, newroot_diskoff); } *rootp=newroot_diskoff; brt->h->dirty=1; initialize_brtnode (brt, newroot, newroot_diskoff, new_height); //printf("new_root %lld %d %lld %lld\n", newroot_diskoff, newroot->height, nodea->thisnodename, nodeb->thisnodename); newroot->u.n.n_children=2; MALLOC_N(3, newroot->u.n.childinfos); MALLOC_N(2, newroot->u.n.childkeys); //printf("%s:%d Splitkey=%p %s\n", __FILE__, __LINE__, splitkey, splitkey); newroot->u.n.childkeys[0] = splitk.data; newroot->u.n.totalchildkeylens=splitk.size; BNC_DISKOFF(newroot,0)=nodea->thisnodename; BNC_DISKOFF(newroot,1)=nodeb->thisnodename; r=toku_fifo_create(&BNC_BUFFER(newroot,0)); if (r!=0) return r; r=toku_fifo_create(&BNC_BUFFER(newroot,1)); if (r!=0) return r; BNC_NBYTESINBUF(newroot, 0)=0; BNC_NBYTESINBUF(newroot, 1)=0; BNC_SUBTREE_FINGERPRINT(newroot, 0)=0; BNC_SUBTREE_FINGERPRINT(newroot, 1)=0; //verify_local_fingerprint_nonleaf(nodea); //verify_local_fingerprint_nonleaf(nodeb); r=toku_log_newbrtnode(logger, (LSN*)0, 0, toku_cachefile_filenum(brt->cf), newroot_diskoff, new_height, new_nodesize, (brt->flags&TOKU_DB_DUPSORT)!=0, newroot->rand4fingerprint); if (r!=0) return r; r=toku_log_addchild(logger, (LSN*)0, 0, toku_cachefile_filenum(brt->cf), newroot_diskoff, 0, nodea->thisnodename, 0); if (r!=0) return r; r=toku_log_addchild(logger, (LSN*)0, 0, toku_cachefile_filenum(brt->cf), newroot_diskoff, 1, nodeb->thisnodename, 0); if (r!=0) return r; fixup_child_fingerprint(newroot, 0, nodea, brt, logger); fixup_child_fingerprint(newroot, 1, nodeb, brt, logger); { BYTESTRING bs = { .len = kv_pair_keylen(newroot->u.n.childkeys[0]), .data = kv_pair_key(newroot->u.n.childkeys[0]) }; r=toku_log_setpivot(logger, (LSN*)0, 0, toku_cachefile_filenum(brt->cf), newroot_diskoff, 0, bs); if (r!=0) return r; toku_update_brtnode_loggerlsn(newroot, logger); } r = toku_unpin_brtnode(brt, nodea); if (r!=0) return r; r = toku_unpin_brtnode(brt, nodeb); if (r!=0) return r; //printf("%s:%d put %lld\n", __FILE__, __LINE__, brt->root); toku_cachetable_put(brt->cf, newroot_diskoff, newroot, brtnode_size(newroot), toku_brtnode_flush_callback, toku_brtnode_fetch_callback, brt); *newrootp = newroot; return 0; } static int brt_root_put_cmd(BRT brt, BRT_CMD cmd, TOKULOGGER logger, DISKOFFARRAY path_to_parent) { void *node_v; BRTNODE node; CACHEKEY *rootp; int result; int r; int did_split; BRTNODE nodea=0, nodeb=0; DBT splitk; int debug = toku_brt_debug_mode;//strcmp(key,"hello387")==0; //assert(0==toku_cachetable_assert_all_unpinned(brt->cachetable)); if ((r = toku_read_and_pin_brt_header(brt->cf, &brt->h))) { if (0) { died0: toku_unpin_brt_header(brt); } return r; } rootp = toku_calculate_root_offset_pointer(brt); if (debug) printf("%s:%d Getting %lld\n", __FILE__, __LINE__, *rootp); if ((r=toku_cachetable_get_and_pin(brt->cf, *rootp, &node_v, NULL, toku_brtnode_flush_callback, toku_brtnode_fetch_callback, brt))) { goto died0; } //printf("%s:%d pin %p\n", __FILE__, __LINE__, node_v); node=node_v; if (debug) printf("%s:%d node inserting\n", __FILE__, __LINE__); did_split = 0; result = brtnode_put_cmd(brt, node, cmd, &did_split, &nodea, &nodeb, &splitk, debug, logger, path_to_parent); if (debug) printf("%s:%d did_insert\n", __FILE__, __LINE__); if (did_split) { // node is unpinned, so now we have to proceed to update the root with a new node. //printf("%s:%d did_split=%d nodeb=%p nodeb->thisnodename=%lld nodeb->nodesize=%d\n", __FILE__, __LINE__, did_split, nodeb, nodeb->thisnodename, nodeb->nodesize); //printf("Did split, splitkey=%s\n", splitkey); if (nodeb->height>0) assert(BNC_DISKOFF(nodeb,nodeb->u.n.n_children-1)!=0); assert(nodeb->nodesize>0); r = brt_init_new_root(brt, nodea, nodeb, splitk, rootp, logger, &node); assert(r == 0); } else { if (node->height>0) assert(node->u.n.n_children<=TREE_FANOUT); } r = toku_unpin_brtnode(brt, node); assert(r==0); r = toku_unpin_brt_header(brt); assert(r == 0); //assert(0==toku_cachetable_assert_all_unpinned(brt->cachetable)); return result; } int toku_brt_insert (BRT brt, DBT *key, DBT *val, TOKUTXN txn) { int r; BRT_CMD_S brtcmd = { BRT_INSERT, toku_txn_get_txnid(txn), .u.id={key,val}}; DISKOFF path[MAX_PATHLEN_TO_ROOT]; DISKOFFARRAY path_to_parent = {0, path}; r = brt_root_put_cmd(brt, &brtcmd, toku_txn_logger(txn), path_to_parent); return r; } int toku_brt_lookup (BRT brt, DBT *k, DBT *v) { int r, rr; BRT_CURSOR cursor; rr = toku_brt_cursor(brt, &cursor, 1); if (rr != 0) return rr; int op = brt->flags & TOKU_DB_DUPSORT ? DB_GET_BOTH : DB_SET; r = toku_brt_cursor_get(cursor, k, v, op, 0); rr = toku_brt_cursor_close(cursor); assert(rr == 0); return r; } int toku_brt_delete(BRT brt, DBT *key, TOKUTXN txn) { int r; DBT val; BRT_CMD_S brtcmd = { BRT_DELETE, toku_txn_get_txnid(txn), .u.id={key, toku_init_dbt(&val)}}; DISKOFF path[MAX_PATHLEN_TO_ROOT]; DISKOFFARRAY path_to_parent = {0, path}; r = brt_root_put_cmd(brt, &brtcmd, toku_txn_logger(txn), path_to_parent); return r; } int toku_brt_delete_both(BRT brt, DBT *key, DBT *val, TOKUTXN txn) { int r; BRT_CMD_S brtcmd = { BRT_DELETE_BOTH, toku_txn_get_txnid(txn), .u.id={key,val}}; DISKOFF path[MAX_PATHLEN_TO_ROOT]; DISKOFFARRAY path_to_parent = {0, path}; r = brt_root_put_cmd(brt, &brtcmd, toku_txn_logger(txn), path_to_parent); return r; } int toku_verify_brtnode (BRT brt, DISKOFF off, bytevec lorange, ITEMLEN lolen, bytevec hirange, ITEMLEN hilen, int recurse, BRTNODE parent_brtnode); int toku_dump_brtnode (BRT brt, DISKOFF off, int depth, bytevec lorange, ITEMLEN lolen, bytevec hirange, ITEMLEN hilen, BRTNODE parent_brtnode) { int result=0; BRTNODE node; void *node_v; int r = toku_cachetable_get_and_pin(brt->cf, off, &node_v, NULL, toku_brtnode_flush_callback, toku_brtnode_fetch_callback, brt); assert(r==0); printf("%s:%d pin %p\n", __FILE__, __LINE__, node_v); node=node_v; result=toku_verify_brtnode(brt, off, lorange, lolen, hirange, hilen, 0, parent_brtnode); printf("%*sNode=%p\n", depth, "", node); if (node->height>0) { printf("%*sNode %lld nodesize=%d height=%d n_children=%d n_bytes_in_buffers=%d keyrange=%s %s\n", depth, "", off, node->nodesize, node->height, node->u.n.n_children, node->u.n.n_bytes_in_buffers, (char*)lorange, (char*)hirange); //printf("%s %s\n", lorange ? lorange : "NULL", hirange ? hirange : "NULL"); { int i; for (i=0; i< node->u.n.n_children; i++) { printf("%*schild %d buffered (%d entries):\n", depth+1, "", i, toku_fifo_n_entries(BNC_BUFFER(node,i))); FIFO_ITERATE(BNC_BUFFER(node,i), key, keylen, data, datalen, type, xid, ({ data=data; datalen=datalen; keylen=keylen; printf("%*s xid=%"PRId64" %d (type=%d)\n", depth+2, "", xid, ntohl(*(int*)key), type); //assert(strlen((char*)key)+1==keylen); //assert(strlen((char*)data)+1==datalen); })); } for (i=0; iu.n.n_children; i++) { printf("%*schild %d\n", depth, "", i); if (i>0) { printf("%*spivot %d len=%d %d\n", depth+1, "", i-1, node->u.n.childkeys[i-1]->keylen, ntohl(*(int*)&node->u.n.childkeys[i-1]->key)); } toku_dump_brtnode(brt, BNC_DISKOFF(node, i), depth+4, (i==0) ? lorange : node->u.n.childkeys[i-1], (i==0) ? lolen : toku_brt_pivot_key_len(brt, node->u.n.childkeys[i-1]), (i==node->u.n.n_children-1) ? hirange : node->u.n.childkeys[i], (i==node->u.n.n_children-1) ? hilen : toku_brt_pivot_key_len(brt, node->u.n.childkeys[i]), node ); } } } else { printf("%*sNode %lld nodesize=%d height=%d n_bytes_in_buffer=%d keyrange=%d %d\n", depth, "", off, node->nodesize, node->height, node->u.l.n_bytes_in_buffer, lorange ? ntohl(*(int*)lorange) : 0, hirange ? ntohl(*(int*)hirange) : 0); //GPMA_ITERATE(node->u.l.buffer, idx, len, data, // ( keylen=keylen, vallen=vallen, printf(" (%d)%d ", keylen, ntohl(*(int*)key)))); printf("\n"); } r = toku_cachetable_unpin(brt->cf, off, 0, 0); assert(r==0); return result; } int toku_dump_brt (BRT brt) { int r; CACHEKEY *rootp; struct brt_header *prev_header = brt->h; if ((r = toku_read_and_pin_brt_header(brt->cf, &brt->h))) { if (0) { died0: toku_unpin_brt_header(brt); } return r; } rootp = toku_calculate_root_offset_pointer(brt); printf("split_count=%d\n", split_count); if ((r = toku_dump_brtnode(brt, *rootp, 0, 0, 0, 0, 0, null_brtnode))) goto died0; if ((r = toku_unpin_brt_header(brt))!=0) return r; brt->h = prev_header; return 0; } static int show_brtnode_blocknumbers (BRT brt, DISKOFF off) { BRTNODE node; void *node_v; int i,r; assert(off%brt->h->nodesize==0); if ((r = toku_cachetable_get_and_pin(brt->cf, off, &node_v, NULL, toku_brtnode_flush_callback, toku_brtnode_fetch_callback, brt))) { if (0) { died0: toku_cachetable_unpin(brt->cf, off, 0, 0); } return r; } printf("%s:%d pin %p\n", __FILE__, __LINE__, node_v); node=node_v; printf(" %lld", off/brt->h->nodesize); if (node->height>0) { for (i=0; iu.n.n_children; i++) { if ((r=show_brtnode_blocknumbers(brt, BNC_DISKOFF(node, i)))) goto died0; } } r = toku_cachetable_unpin(brt->cf, off, 0, 0); return r; } #if 0 int show_brt_blocknumbers (BRT brt) { int r; CACHEKEY *rootp; if ((r = toku_read_and_pin_brt_header(brt->cf, &brt->h))) { if (0) { died0: toku_unpin_brt_header(brt); } return r; } rootp = toku_calculate_root_offset_pointer(brt); printf("BRT %p has blocks:", brt); if ((r=show_brtnode_blocknumbers (brt, *rootp, 0))) goto died0; printf("\n"); if ((r = toku_unpin_brt_header(brt))!=0) return r; return 0; } #endif int toku_brt_dbt_set_key(BRT brt, DBT *ybt, bytevec val, ITEMLEN vallen) { int r = toku_dbt_set_value(ybt, val, vallen, &brt->skey); return r; } int toku_brt_dbt_set_value(BRT brt, DBT *ybt, bytevec val, ITEMLEN vallen) { int r = toku_dbt_set_value(ybt, val, vallen, &brt->sval); return r; } typedef struct brt_split { int did_split; BRTNODE nodea; BRTNODE nodeb; DBT splitk; } BRT_SPLIT; static inline void brt_split_init(BRT_SPLIT *split) { split->did_split = 0; split->nodea = split->nodeb = 0; toku_init_dbt(&split->splitk); } static int brt_search_node(BRT brt, BRTNODE node, brt_search_t *search, DBT *newkey, DBT *newval, BRT_SPLIT *split, TOKULOGGER logger, DISKOFFARRAY path_to_parent); /* search in a node's child */ static int brt_search_child(BRT brt, BRTNODE node, int childnum, brt_search_t *search, DBT *newkey, DBT *newval, BRT_SPLIT *split, TOKULOGGER logger, DISKOFFARRAY path_to_parent) { int r, rr; /* if the child's buffer is not empty then try to empty it */ if (BNC_NBYTESINBUF(node, childnum) > 0) { rr = push_some_brt_cmds_down(brt, node, childnum, &split->did_split, &split->nodea, &split->nodeb, &split->splitk, 0, logger, path_to_parent); assert(rr == 0); /* push down may cause a child split, so childnum may not be appropriate, and the node itself may split, so retry */ return EAGAIN; } void *node_v; rr = toku_cachetable_get_and_pin(brt->cf, BNC_DISKOFF(node,childnum), &node_v, NULL, toku_brtnode_flush_callback, toku_brtnode_fetch_callback, brt); assert(rr == 0); assert(path_to_parent.lenthisnodename; for (;;) { BRTNODE childnode = node_v; BRT_SPLIT childsplit; brt_split_init(&childsplit); r = brt_search_node(brt, childnode, search, newkey, newval, &childsplit, logger, path_to_parent); if (childsplit.did_split) { rr = handle_split_of_child(brt, node, childnum, childsplit.nodea, childsplit.nodeb, &childsplit.splitk, &split->did_split, &split->nodea, &split->nodeb, &split->splitk, logger, path_to_parent); assert(rr == 0); break; } else { if (r == EAGAIN) continue; rr = toku_cachetable_unpin(brt->cf, childnode->thisnodename, childnode->dirty, brtnode_size(childnode)); assert(rr == 0); break; } } return r; } static int brt_search_nonleaf_node(BRT brt, BRTNODE node, brt_search_t *search, DBT *newkey, DBT *newval, BRT_SPLIT *split, TOKULOGGER logger, DISKOFFARRAY path_to_parent) { int r = DB_NOTFOUND; int c; /* binary search is overkill for a small array */ int child[node->u.n.n_children]; /* scan left to right or right to left depending on the search direction */ for (c = 0; c < node->u.n.n_children; c++) child[c] = search->direction & BRT_SEARCH_LEFT ? c : node->u.n.n_children - 1 - c; for (c = 0; c < node->u.n.n_children-1; c++) { int p = search->direction & BRT_SEARCH_LEFT ? child[c] : child[c] - 1; struct kv_pair *pivot = node->u.n.childkeys[p]; DBT pivotkey, pivotval; if (search->compare(search, toku_fill_dbt(&pivotkey, kv_pair_key(pivot), kv_pair_keylen(pivot)), brt->flags & TOKU_DB_DUPSORT ? toku_fill_dbt(&pivotval, kv_pair_val(pivot), kv_pair_vallen(pivot)): 0)) { r = brt_search_child(brt, node, child[c], search, newkey, newval, split, logger, path_to_parent); if (r == 0 || r == EAGAIN) break; } } /* check the first (left) or last (right) node if nothing has been found */ if (r == DB_NOTFOUND && c == node->u.n.n_children-1) r = brt_search_child(brt, node, child[c], search, newkey, newval, split, logger, path_to_parent); return r; } struct bessel_from_search_struct { brt_search_t *search; }; static int bessel_from_search_t (u_int32_t len __attribute__((__unused__)), void *data, void *extra) { struct bessel_from_search_struct *bs = extra; brt_search_t *search=bs->search; DBT x,y; struct kv_pair *kv = data; int cmp = search->compare(search, search->k ? toku_fill_dbt(&x, kv_pair_key(kv), kv_pair_keylen(kv)) : 0, search->v ? toku_fill_dbt(&y, kv_pair_val(kv), kv_pair_vallen(kv)) : 0); // For a left-to-right search, the search compare function returns 0 for all pairs < kv. We want the first value that is 1. // To convert it to a bessel, we have to convert the 0 to a -1. // For a right-to-left search, the search compare function returns 0 for all pairs > kv, and 1 for lesser values. We want the last value that is 1. // To convert it to a bessel, we have to convert 0 to +1, and 1 to -1. switch (search->direction) { case BRT_SEARCH_LEFT: return cmp==0 ? -1 : +1; case BRT_SEARCH_RIGHT: return cmp==0 ? +1 : -1; // Because the comparison runs backwards for right searches. } assert(0); return 0; } static int brt_search_leaf_node(BRT brt, BRTNODE node, brt_search_t *search, DBT *newkey, DBT *newval) { // Now we have to convert from brt_search_t to the bessel function with a direction. What a pain... struct bessel_from_search_struct bs = {search}; int direction; switch (search->direction) { case BRT_SEARCH_LEFT: direction = +1; goto ok; case BRT_SEARCH_RIGHT: direction = -1; goto ok; } return EINVAL; // This return and the goto are a hack to get both compile-time and run-time checking on enum ok: ; u_int32_t len; void * data; u_int32_t idx; // Don't need this int r = toku_gpma_lookup_bessel(node->u.l.buffer, bessel_from_search_t, direction, &bs, &len, &data, &idx); if (r!=0) return r; struct kv_pair *kv = data; if (newkey) { r = toku_dbt_set_value(newkey, kv_pair_key(kv), kv_pair_keylen(kv), &brt->skey); if (r!=0) return r; } if (newval) { r = toku_dbt_set_value(newval, kv_pair_val(kv), kv_pair_vallen(kv), &brt->sval); if (r!=0) return r; } return 0; } static int brt_search_node(BRT brt, BRTNODE node, brt_search_t *search, DBT *newkey, DBT *newval, BRT_SPLIT *split, TOKULOGGER logger, DISKOFFARRAY path_to_parent) { if (node->height > 0) return brt_search_nonleaf_node(brt, node, search, newkey, newval, split, logger, path_to_parent); else return brt_search_leaf_node(brt, node, search, newkey, newval); } int toku_brt_search(BRT brt, brt_search_t *search, DBT *newkey, DBT *newval, TOKULOGGER logger) { int r, rr; rr = toku_read_and_pin_brt_header(brt->cf, &brt->h); assert(rr == 0); CACHEKEY *rootp; rootp = toku_calculate_root_offset_pointer(brt); void *node_v; rr = toku_cachetable_get_and_pin(brt->cf, *rootp, &node_v, NULL, toku_brtnode_flush_callback, toku_brtnode_fetch_callback, brt); assert(rr == 0); BRTNODE node = node_v; for (;;) { BRT_SPLIT split; brt_split_init(&split); DISKOFF path[MAX_PATHLEN_TO_ROOT]; DISKOFFARRAY path_to_parent = {0, path}; r = brt_search_node(brt, node, search, newkey, newval, &split, logger, path_to_parent); if (split.did_split) { rr = brt_init_new_root(brt, split.nodea, split.nodeb, split.splitk, rootp, 0, &node); assert(rr == 0); } if (r != EAGAIN) break; } rr = toku_unpin_brtnode(brt, node); assert(rr == 0); rr = toku_unpin_brt_header(brt); assert(rr == 0); return r; } static inline void dbt_cleanup(DBT *dbt) { if (dbt->data && (dbt->flags & DB_DBT_MALLOC)) { toku_free_n(dbt->data, dbt->size); dbt->data = 0; } } static inline void brt_cursor_cleanup(BRT_CURSOR cursor) { dbt_cleanup(&cursor->key); dbt_cleanup(&cursor->val); } static inline int brt_cursor_not_set(BRT_CURSOR cursor) { return cursor->key.data == 0 || cursor->val.data == 0; } BOOL toku_brt_cursor_uninitialized(BRT_CURSOR c) { return brt_cursor_not_set(c); } static inline void brt_cursor_set_key_val(BRT_CURSOR cursor, DBT *newkey, DBT *newval) { brt_cursor_cleanup(cursor); cursor->key = *newkey; memset(newkey, 0, sizeof *newkey); cursor->val = *newval; memset(newval, 0, sizeof *newval); } int toku_brt_cursor (BRT brt, BRT_CURSOR *cursorptr, int is_temporary_cursor) { BRT_CURSOR cursor = toku_malloc(sizeof *cursor); if (cursor == 0) return ENOMEM; cursor->brt = brt; toku_init_dbt(&cursor->key); toku_init_dbt(&cursor->val); list_push(&brt->cursors, &cursor->cursors_link); cursor->is_temporary_cursor=is_temporary_cursor; cursor->skey = cursor->sval = 0; *cursorptr = cursor; return 0; } int toku_brt_cursor_close(BRT_CURSOR cursor) { brt_cursor_cleanup(cursor); if (cursor->skey) toku_free(cursor->skey); if (cursor->sval) toku_free(cursor->sval); list_remove(&cursor->cursors_link); toku_free_n(cursor, sizeof *cursor); return 0; } static inline int compare_k_x(BRT brt, DBT *k, DBT *x) { return brt->compare_fun(brt->db, k, x); } static inline int compare_v_y(BRT brt, DBT *v, DBT *y) { return brt->dup_compare(brt->db, v, y); } static inline int compare_kv_xy(BRT brt, DBT *k, DBT *v, DBT *x, DBT *y) { int cmp = brt->compare_fun(brt->db, k, x); if (cmp == 0 && v && y) cmp = brt->dup_compare(brt->db, v, y); return cmp; } static inline int brt_cursor_copyout(BRT_CURSOR cursor, DBT *key, DBT *val) { int r = 0; if (key) r = toku_dbt_set_value(key, cursor->key.data, cursor->key.size, cursor->is_temporary_cursor ? &cursor->brt->skey : &cursor->skey); if (r == 0 && val) r = toku_dbt_set_value(val, cursor->val.data, cursor->val.size, cursor->is_temporary_cursor ? &cursor->brt->sval : &cursor->sval); return r; } static int brt_cursor_compare_set(brt_search_t *search, DBT *x, DBT *y) { BRT brt = search->context; return compare_kv_xy(brt, search->k, search->v, x, y) <= 0; /* return min xy: kv <= xy */ } static int brt_cursor_current(BRT_CURSOR cursor, int op, DBT *outkey, DBT *outval, TOKULOGGER logger) { if (brt_cursor_not_set(cursor)) return EINVAL; if (op == DB_CURRENT) { DBT newkey; toku_init_dbt(&newkey); DBT newval; toku_init_dbt(&newval); brt_search_t search; brt_search_init(&search, brt_cursor_compare_set, BRT_SEARCH_LEFT, &cursor->key, &cursor->val, cursor->brt); int r = toku_brt_search(cursor->brt, &search, &newkey, &newval, logger); if (r != 0 || compare_kv_xy(cursor->brt, &cursor->key, &cursor->val, &newkey, &newval) != 0) return DB_KEYEMPTY; } return brt_cursor_copyout(cursor, outkey, outval); } /* search for the first kv pair that matches the search object */ static int brt_cursor_search(BRT_CURSOR cursor, brt_search_t *search, DBT *outkey, DBT *outval, TOKULOGGER logger) { DBT newkey; toku_init_dbt(&newkey); newkey.flags = DB_DBT_MALLOC; DBT newval; toku_init_dbt(&newval); newval.flags = DB_DBT_MALLOC; int r = toku_brt_search(cursor->brt, search, &newkey, &newval, logger); if (r == 0) { brt_cursor_set_key_val(cursor, &newkey, &newval); r = brt_cursor_copyout(cursor, outkey, outval); } dbt_cleanup(&newkey); dbt_cleanup(&newval); return r; } /* search for the kv pair that matches the search object and is equal to kv */ static int brt_cursor_search_eq_kv_xy(BRT_CURSOR cursor, brt_search_t *search, DBT *outkey, DBT *outval, TOKULOGGER logger) { DBT newkey; toku_init_dbt(&newkey); newkey.flags = DB_DBT_MALLOC; DBT newval; toku_init_dbt(&newval); newval.flags = DB_DBT_MALLOC; int r = toku_brt_search(cursor->brt, search, &newkey, &newval, logger); if (r == 0) { if (compare_kv_xy(cursor->brt, search->k, search->v, &newkey, &newval) == 0) { brt_cursor_set_key_val(cursor, &newkey, &newval); r = brt_cursor_copyout(cursor, outkey, outval); } else r = DB_NOTFOUND; } dbt_cleanup(&newkey); dbt_cleanup(&newval); return r; } /* search for the kv pair that matches the search object and is equal to k */ static int brt_cursor_search_eq_k_x(BRT_CURSOR cursor, brt_search_t *search, DBT *outkey, DBT *outval, TOKULOGGER logger) { DBT newkey; toku_init_dbt(&newkey); newkey.flags = DB_DBT_MALLOC; DBT newval; toku_init_dbt(&newval); newval.flags = DB_DBT_MALLOC; int r = toku_brt_search(cursor->brt, search, &newkey, &newval, logger); if (r == 0) { if (compare_k_x(cursor->brt, search->k, &newkey) == 0) { brt_cursor_set_key_val(cursor, &newkey, &newval); r = brt_cursor_copyout(cursor, outkey, outval); } else r = DB_NOTFOUND; } dbt_cleanup(&newkey); dbt_cleanup(&newval); return r; } static int brt_cursor_compare_one(brt_search_t *search, DBT *x, DBT *y) { search = search; x = x; y = y; return 1; } static int brt_cursor_first(BRT_CURSOR cursor, DBT *outkey, DBT *outval, TOKULOGGER logger) { brt_search_t search; brt_search_init(&search, brt_cursor_compare_one, BRT_SEARCH_LEFT, 0, 0, cursor->brt); return brt_cursor_search(cursor, &search, outkey, outval, logger); } static int brt_cursor_last(BRT_CURSOR cursor, DBT *outkey, DBT *outval, TOKULOGGER logger) { brt_search_t search; brt_search_init(&search, brt_cursor_compare_one, BRT_SEARCH_RIGHT, 0, 0, cursor->brt); return brt_cursor_search(cursor, &search, outkey, outval, logger); } static int brt_cursor_compare_next(brt_search_t *search, DBT *x, DBT *y) { BRT brt = search->context; return compare_kv_xy(brt, search->k, search->v, x, y) < 0; /* return min xy: kv < xy */ } static int brt_cursor_next(BRT_CURSOR cursor, DBT *outkey, DBT *outval, TOKULOGGER logger) { brt_search_t search; brt_search_init(&search, brt_cursor_compare_next, BRT_SEARCH_LEFT, &cursor->key, &cursor->val, cursor->brt); return brt_cursor_search(cursor, &search, outkey, outval, logger); } static int brt_cursor_compare_next_nodup(brt_search_t *search, DBT *x, DBT *y) { BRT brt = search->context; y = y; return compare_k_x(brt, search->k, x) < 0; /* return min x: k < x */ } static int brt_cursor_next_nodup(BRT_CURSOR cursor, DBT *outkey, DBT *outval, TOKULOGGER logger) { brt_search_t search; brt_search_init(&search, brt_cursor_compare_next_nodup, BRT_SEARCH_LEFT, &cursor->key, &cursor->val, cursor->brt); return brt_cursor_search(cursor, &search, outkey, outval, logger); } static int brt_cursor_compare_next_dup(brt_search_t *search, DBT *x, DBT *y) { BRT brt = search->context; int keycmp = compare_k_x(brt, search->k, x); if (keycmp < 0) return 1; else return keycmp == 0 && y && compare_v_y(brt, search->v, y) < 0; /* return min xy: k <= x && v < y */ } static int brt_cursor_next_dup(BRT_CURSOR cursor, DBT *outkey, DBT *outval, TOKULOGGER logger) { brt_search_t search; brt_search_init(&search, brt_cursor_compare_next_dup, BRT_SEARCH_LEFT, &cursor->key, &cursor->val, cursor->brt); return brt_cursor_search_eq_k_x(cursor, &search, outkey, outval, logger); } static int brt_cursor_compare_get_both_range(brt_search_t *search, DBT *x, DBT *y) { BRT brt = search->context; int keycmp = compare_k_x(brt, search->k, x); if (keycmp < 0) return 1; else return keycmp == 0 && (y == 0 || compare_v_y(brt, search->v, y) <= 0); /* return min xy: k <= x && v <= y */ } static int brt_cursor_get_both_range(BRT_CURSOR cursor, DBT *key, DBT *val, DBT *outkey, DBT *outval, TOKULOGGER logger) { brt_search_t search; brt_search_init(&search, brt_cursor_compare_get_both_range, BRT_SEARCH_LEFT, key, val, cursor->brt); return brt_cursor_search_eq_k_x(cursor, &search, outkey, outval, logger); } static int brt_cursor_compare_prev(brt_search_t *search, DBT *x, DBT *y) { BRT brt = search->context; return compare_kv_xy(brt, search->k, search->v, x, y) > 0; /* return max xy: kv > xy */ } static int brt_cursor_prev(BRT_CURSOR cursor, DBT *outkey, DBT *outval, TOKULOGGER logger) { brt_search_t search; brt_search_init(&search, brt_cursor_compare_prev, BRT_SEARCH_RIGHT, &cursor->key, &cursor->val, cursor->brt); return brt_cursor_search(cursor, &search, outkey, outval, logger); } static int brt_cursor_compare_prev_nodup(brt_search_t *search, DBT *x, DBT *y) { BRT brt = search->context; y = y; return compare_k_x(brt, search->k, x) > 0; /* return max x: k > x */ } static int brt_cursor_prev_nodup(BRT_CURSOR cursor, DBT *outkey, DBT *outval, TOKULOGGER logger) { brt_search_t search; brt_search_init(&search, brt_cursor_compare_prev_nodup, BRT_SEARCH_RIGHT, &cursor->key, &cursor->val, cursor->brt); return brt_cursor_search(cursor, &search, outkey, outval, logger); } #ifdef DB_PREV_DUP static int brt_cursor_compare_prev_dup(brt_search_t *search, DBT *x, DBT *y) { BRT brt = search->context; int keycmp = compare_k_x(brt, search->k, x); if (keycmp > 0) return 1; else return keycmp == 0 && y && compare_v_y(brt, search->v, y) > 0; /* return max xy: k >= x && v > y */ } static int brt_cursor_prev_dup(BRT_CURSOR cursor, DBT *outkey, DBT *outval, TOKULOGGER logger) { brt_search_t search; brt_search_init(&search, brt_cursor_compare_prev_dup, BRT_SEARCH_RIGHT, &cursor->key, &cursor->val, cursor->brt); return brt_cursor_search_eq_k_x(cursor, &search, outkey, outval, logger); } #endif static int brt_cursor_compare_set_range(brt_search_t *search, DBT *x, DBT *y) { BRT brt = search->context; return compare_kv_xy(brt, search->k, search->v, x, y) <= 0; /* return kv <= xy */ } static int brt_cursor_set(BRT_CURSOR cursor, DBT *key, DBT *val, DBT *outkey, DBT *outval, TOKULOGGER logger) { brt_search_t search; brt_search_init(&search, brt_cursor_compare_set_range, BRT_SEARCH_LEFT, key, val, cursor->brt); return brt_cursor_search_eq_kv_xy(cursor, &search, outkey, outval, logger); } static int brt_cursor_set_range(BRT_CURSOR cursor, DBT *key, DBT *outkey, DBT *outval, TOKULOGGER logger) { brt_search_t search; brt_search_init(&search, brt_cursor_compare_set_range, BRT_SEARCH_LEFT, key, 0, cursor->brt); return brt_cursor_search(cursor, &search, outkey, outval, logger); } int toku_brt_cursor_get (BRT_CURSOR cursor, DBT *key, DBT *val, int get_flags, TOKUTXN txn) { int r; int op = get_flags & DB_OPFLAGS_MASK; TOKULOGGER logger = toku_txn_logger(txn); if (get_flags & ~DB_OPFLAGS_MASK) return EINVAL; switch (op) { case DB_CURRENT: case DB_CURRENT_BINDING: r = brt_cursor_current(cursor, op, key, val, logger); break; case DB_FIRST: r = brt_cursor_first(cursor, key, val, logger); break; case DB_LAST: r = brt_cursor_last(cursor, key, val, logger); break; case DB_NEXT: if (brt_cursor_not_set(cursor)) r = brt_cursor_first(cursor, key, val, logger); else r = brt_cursor_next(cursor, key, val, logger); break; case DB_NEXT_DUP: if (brt_cursor_not_set(cursor)) r = EINVAL; else r = brt_cursor_next_dup(cursor, key, val, logger); break; case DB_NEXT_NODUP: if (brt_cursor_not_set(cursor)) r = brt_cursor_first(cursor, key, val, logger); else r = brt_cursor_next_nodup(cursor, key, val, logger); break; case DB_PREV: if (brt_cursor_not_set(cursor)) r = brt_cursor_last(cursor, key, val, logger); else r = brt_cursor_prev(cursor, key, val, logger); break; #ifdef DB_PREV_DUP case DB_PREV_DUP: if (brt_cursor_not_set(cursor)) r = EINVAL; else r = brt_cursor_prev_dup(cursor, key, val, logger); break; #endif case DB_PREV_NODUP: if (brt_cursor_not_set(cursor)) r = brt_cursor_last(cursor, key, val, logger); else r = brt_cursor_prev_nodup(cursor, key, val, logger); break; case DB_SET: r = brt_cursor_set(cursor, key, 0, 0, val, logger); break; case DB_SET_RANGE: r = brt_cursor_set_range(cursor, key, key, val, logger); break; case DB_GET_BOTH: r = brt_cursor_set(cursor, key, val, 0, 0, logger); break; case DB_GET_BOTH_RANGE: r = brt_cursor_get_both_range(cursor, key, val, 0, val, logger); break; default: r = EINVAL; break; } return r; } int toku_brt_cursor_delete(BRT_CURSOR cursor, int flags, TOKUTXN txn) { if ((flags & ~DB_DELETE_ANY) != 0) return EINVAL; if (brt_cursor_not_set(cursor)) return EINVAL; int r = 0; if (!(flags & DB_DELETE_ANY)) r = brt_cursor_current(cursor, DB_CURRENT, 0, 0, toku_txn_logger(txn)); if (r == 0) r = toku_brt_delete_both(cursor->brt, &cursor->key, &cursor->val, txn); return r; } int toku_brt_height_of_root(BRT brt, int *height) { // for an open brt, return the current height. int r; if ((r = toku_read_and_pin_brt_header(brt->cf, &brt->h))) { if (0) { died0: toku_unpin_brt_header(brt); } return r; } CACHEKEY *rootp = toku_calculate_root_offset_pointer(brt); void *node_v; if ((r=toku_cachetable_get_and_pin(brt->cf, *rootp, &node_v, NULL, toku_brtnode_flush_callback, toku_brtnode_fetch_callback, brt))) { goto died0; } BRTNODE node = node_v; *height = node->height; r = toku_unpin_brtnode(brt, node); assert(r==0); r = toku_unpin_brt_header(brt); assert(r==0); return 0; } struct callpair { BRTNODE node; int childnum; }; static int note_removal (bytevec key, ITEMLEN keylen, bytevec data, ITEMLEN datalen, int type, TXNID xid, void*cpairv) { struct callpair *cpair = cpairv; BRTNODE node = cpair->node; //printf("%s:%d Removed %s,%s fingerprint was %08x ", __FILE__, __LINE__, (char*)key, (char*)data, node->local_fingerprint); int childnum = cpair->childnum; u_int32_t old_fingerprint = node->local_fingerprint; u_int32_t diff = node->rand4fingerprint*toku_calccrc32_cmd(type, xid, key, keylen, data, datalen); node->local_fingerprint = old_fingerprint - diff; //printf("is %08x diff=%08x (addr=%p)\n", node->local_fingerprint, diff, &node->local_fingerprint); u_int32_t countdiff = keylen+datalen+KEY_VALUE_OVERHEAD+BRT_CMD_OVERHEAD; BNC_NBYTESINBUF(node,childnum) -= countdiff; node->u.n.n_bytes_in_buffers -= countdiff; return 0; } int toku_brt_nonleaf_expunge_xaction(BRT brt, DISKOFF diskoff, TXNID xid) { void *node_v; int r = toku_cachetable_get_and_pin(brt->cf, diskoff, &node_v, NULL, toku_brtnode_flush_callback, toku_brtnode_fetch_callback, brt); assert(r==0); if (r!=0) return r; BRTNODE node = node_v; verify_local_fingerprint_nonleaf(node); //printf("%s:%d node->local_fingerprint=%08x\n", __FILE__, __LINE__, node->local_fingerprint); int i; r=0; for (i=0; iu.n.n_children; i++) { struct callpair pair = { node, i }; int r3 = toku_fifo_expunge_xaction(BNC_BUFFER(node, i), xid, note_removal, &pair); if (r==0) r=r3; } int r2 = toku_cachetable_unpin(brt->cf, diskoff, 1, toku_serialize_brtnode_size(node)); return r ? r : r2; }