d9a8d6f998
git-svn-id: svn+ssh://svn.corp.yahoo.com/yahoo/yrl/labs/pnuts/code/logstore@3593 8dad8b1f-cf64-0410-95b6-bcf113ffbcfe
248 lines
7.8 KiB
C++
248 lines
7.8 KiB
C++
/*
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* diskTreeComponent.h
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*
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* Copyright 2010-2012 Yahoo! Inc.
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*
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* Licensed under the Apache License, Version 2.0 (the "License");
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* you may not use this file except in compliance with the License.
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* You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS,
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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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*
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* Created on: Feb 18, 2010
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* Author: sears
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*/
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#ifndef DISKTREECOMPONENT_H_
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#define DISKTREECOMPONENT_H_
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#include "datapage.h"
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#include "datatuple.h"
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#include "mergeStats.h"
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#include "bloomFilter.h"
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#include <stasis/util/crc32.h>
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extern "C" {
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static uint64_t diskTreeComponent_hash_func_a(const char* a, int len) {
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return stasis_crc32(a,len,0xcafebabe);
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}
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static uint64_t diskTreeComponent_hash_func_b(const char* a, int len) {
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return stasis_crc32(a,len,0xdeadbeef);
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}
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}
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class diskTreeComponent {
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public:
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class internalNodes;
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class iterator;
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diskTreeComponent(int xid, pageid_t internal_region_size, pageid_t datapage_region_size, pageid_t datapage_size,
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mergeStats* stats, uint64_t bloom_filter_size = 0) :
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ltree(new diskTreeComponent::internalNodes(xid, internal_region_size, datapage_region_size, datapage_size)),
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dp(0),
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datapage_size(datapage_size),
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stats(stats),
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bloom_filter(bloom_filter_size == 0
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? 0
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: bloom_filter_create(diskTreeComponent_hash_func_a,
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diskTreeComponent_hash_func_b,
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bloom_filter_size, 0.01)) {
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if(bloom_filter) bloom_filter_print_stats(bloom_filter);
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}
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diskTreeComponent(int xid, recordid root, recordid internal_node_state,
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recordid datapage_state, mergeStats* stats) :
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ltree(new diskTreeComponent::internalNodes(xid, root, internal_node_state, datapage_state)),
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dp(0),
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datapage_size(-1),
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stats(stats),
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bloom_filter(0) {}
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~diskTreeComponent() {
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if(bloom_filter) bloom_filter_destroy(bloom_filter);
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delete dp;
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delete ltree;
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}
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recordid get_root_rid();
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recordid get_datapage_allocator_rid();
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recordid get_internal_node_allocator_rid();
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internalNodes * get_internal_nodes() { return ltree; }
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datatuple* findTuple(int xid, datatuple::key_t key, size_t keySize);
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int insertTuple(int xid, datatuple *t);
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void writes_done();
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iterator * open_iterator(mergeManager * mgr = NULL, double target_size = 0, bool * flushing = NULL) {
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return new iterator(ltree, mgr, target_size, flushing);
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}
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iterator * open_iterator(datatuple * key) {
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if(key != NULL) {
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return new iterator(ltree, key);
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} else {
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return new iterator(ltree);
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}
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}
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void force(int xid);
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void dealloc(int xid);
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void list_regions(int xid, pageid_t *internal_node_region_length, pageid_t *internal_node_region_count, pageid_t **internal_node_regions,
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pageid_t *datapage_region_length, pageid_t *datapage_region_count, pageid_t **datapage_regions);
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void print_tree(int xid) {
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ltree->print_tree(xid);
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}
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private:
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DataPage* insertDataPage(int xid, datatuple *tuple);
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internalNodes * ltree;
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DataPage* dp;
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pageid_t datapage_size;
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/*mergeManager::mergeStats*/ void *stats; // XXX hack to work around circular includes.
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public:
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class internalNodes{
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public:
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internalNodes(int xid, pageid_t internal_region_size, pageid_t datapage_region_size, pageid_t datapage_size);
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internalNodes(int xid, recordid root, recordid internal_node_state, recordid datapage_state);
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~internalNodes();
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void print_tree(int xid);
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//returns the id of the data page that could contain the given key
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pageid_t findPage(int xid, const byte *key, size_t keySize);
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//appends a leaf page, val_page is the id of the leaf page
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recordid appendPage(int xid, const byte *key,size_t keySize, pageid_t val_page);
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inline RegionAllocator* get_datapage_alloc() { return datapage_alloc; }
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inline RegionAllocator* get_internal_node_alloc() { return internal_node_alloc; }
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const recordid &get_root_rec(){return root_rec;}
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private:
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recordid create(int xid);
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void writeNodeRecord(int xid, Page *p, recordid &rid,
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const byte *key, size_t keylen, pageid_t ptr);
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//reads the given record and returns the page id stored in it
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static pageid_t lookupLeafPageFromRid(int xid, recordid rid);
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recordid appendInternalNode(int xid, Page *p,
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int64_t depth,
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const byte *key, size_t key_len,
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pageid_t val_page);
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recordid buildPathToLeaf(int xid, recordid root, Page *root_p,
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int64_t depth, const byte *key, size_t key_len,
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pageid_t val_page);
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/**
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Initialize a page for use as an internal node of the tree.
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*/
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inline static void initializeNodePage(int xid, Page *p);
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//return the left-most leaf, these are not data pages, although referred to as leaf
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static pageid_t findFirstLeaf(int xid, Page *root, int64_t depth);
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//return the right-most leaf
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static pageid_t findLastLeaf(int xid, Page *root, int64_t depth) ;
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//returns a record that stores the pageid where the given key should be in, i.e. if it exists
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static recordid lookup(int xid, Page *node, int64_t depth, const byte *key,
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size_t keySize);
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const static int64_t DEPTH;
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const static int64_t COMPARATOR;
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const static int64_t FIRST_SLOT;
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const static ssize_t root_rec_size;
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const static int64_t PREV_LEAF;
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const static int64_t NEXT_LEAF;
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pageid_t lastLeaf;
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void print_tree(int xid, pageid_t pid, int64_t depth);
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recordid root_rec;
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RegionAllocator* internal_node_alloc;
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RegionAllocator* datapage_alloc;
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struct indexnode_rec {
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pageid_t ptr;
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};
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public:
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class iterator {
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public:
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iterator(int xid, RegionAllocator *ro_alloc, recordid root);
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iterator(int xid, RegionAllocator *ro_alloc, recordid root, const byte* key, len_t keylen);
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int next();
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void close();
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inline size_t key (byte **key) {
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*key = (byte*)(t+1);
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return current.size - sizeof(indexnode_rec);
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}
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inline size_t value(byte **value) {
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*value = (byte*)&(t->ptr);
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return sizeof(t->ptr);
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}
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inline void tupleDone() { }
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inline void releaseLock() { }
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private:
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RegionAllocator * ro_alloc_;
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Page * p;
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int xid_;
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bool done;
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recordid current;
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indexnode_rec *t;
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int justOnePage;
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};
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};
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bloom_filter_t * bloom_filter;
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class iterator
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{
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public:
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explicit iterator(diskTreeComponent::internalNodes *tree, mergeManager * mgr = NULL, double target_size = 0, bool * flushing = NULL);
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explicit iterator(diskTreeComponent::internalNodes *tree,datatuple *key);
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~iterator();
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datatuple * next_callerFrees();
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private:
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void init_iterators(datatuple * key1, datatuple * key2);
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inline void init_helper(datatuple * key1);
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explicit iterator() { abort(); }
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void operator=(iterator & t) { abort(); }
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int operator-(iterator & t) { abort(); }
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RegionAllocator * ro_alloc_; // has a filehandle that we use to optimize sequential scans.
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recordid tree_; //root of the tree
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mergeManager * mgr_;
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double target_progress_delta_;
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bool * flushing_;
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diskTreeComponent::internalNodes::iterator* lsmIterator_;
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pageid_t curr_pageid; //current page id
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DataPage *curr_page; //current page
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typedef DataPage::iterator DPITR_T;
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DPITR_T *dp_itr;
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};
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};
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#endif /* DISKTREECOMPONENT_H_ */
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