// Copyright (c) 2011 The LevelDB Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. See the AUTHORS file for names of contributors. #include "leveldb/table.h" #include "leveldb/cache.h" #include "leveldb/comparator.h" #include "leveldb/env.h" #include "leveldb/filter_policy.h" #include "leveldb/options.h" #include "table/block.h" #include "table/filter_block.h" #include "table/format.h" #include "table/two_level_iterator.h" #include "util/coding.h" #include "db/dbformat.h" #include namespace leveldb { struct Table::Rep { ~Rep() { delete filter; delete[] filter_data; delete index_block; } Options options; Status status; RandomAccessFile* file; uint64_t cache_id; FilterBlockReader* filter; const char* filter_data; BlockHandle metaindex_handle; // Handle to metaindex_block: saved from footer Block* index_block; }; Status Table::Open(const Options& options, RandomAccessFile* file, uint64_t size, Table** table) { *table = nullptr; if (size < Footer::kEncodedLength) { return Status::Corruption("file is too short to be an sstable"); } char footer_space[Footer::kEncodedLength]; Slice footer_input; Status s = file->Read(size - Footer::kEncodedLength, Footer::kEncodedLength, &footer_input, footer_space); if (!s.ok()) return s; Footer footer; s = footer.DecodeFrom(&footer_input); if (!s.ok()) return s; // Read the index block BlockContents index_block_contents; ReadOptions opt; if (options.paranoid_checks) { opt.verify_checksums = true; } s = ReadBlock(file, opt, footer.index_handle(), &index_block_contents); if (s.ok()) { // We've successfully read the footer and the index block: we're // ready to serve requests. Block* index_block = new Block(index_block_contents); Rep* rep = new Table::Rep; rep->options = options; rep->file = file; rep->metaindex_handle = footer.metaindex_handle(); rep->index_block = index_block; rep->cache_id = (options.block_cache ? options.block_cache->NewId() : 0); rep->filter_data = nullptr; rep->filter = nullptr; *table = new Table(rep); (*table)->ReadMeta(footer); } return s; } void Table::ReadMeta(const Footer& footer) { if (rep_->options.filter_policy == nullptr) { return; // Do not need any metadata } // TODO(sanjay): Skip this if footer.metaindex_handle() size indicates // it is an empty block. ReadOptions opt; if (rep_->options.paranoid_checks) { opt.verify_checksums = true; } BlockContents contents; if (!ReadBlock(rep_->file, opt, footer.metaindex_handle(), &contents).ok()) { // Do not propagate errors since meta info is not needed for operation return; } Block* meta = new Block(contents); Iterator* iter = meta->NewIterator(BytewiseComparator()); std::string key = "filter."; key.append(rep_->options.filter_policy->Name()); iter->Seek(key); if (iter->Valid() && iter->key() == Slice(key)) { ReadFilter(iter->value()); } delete iter; delete meta; } void Table::ReadFilter(const Slice& filter_handle_value) { Slice v = filter_handle_value; BlockHandle filter_handle; if (!filter_handle.DecodeFrom(&v).ok()) { return; } // We might want to unify with ReadBlock() if we start // requiring checksum verification in Table::Open. ReadOptions opt; if (rep_->options.paranoid_checks) { opt.verify_checksums = true; } BlockContents block; if (!ReadBlock(rep_->file, opt, filter_handle, &block).ok()) { return; } if (block.heap_allocated) { rep_->filter_data = block.data.data(); // Will need to delete later } rep_->filter = new FilterBlockReader(rep_->options.filter_policy, block.data); } Table::~Table() { delete rep_; } static void DeleteBlock(void* arg, void* ignored) { delete reinterpret_cast(arg); } static void DeleteCachedBlock(const Slice& key, void* value) { Block* block = reinterpret_cast(value); delete block; } static void ReleaseBlock(void* arg, void* h) { Cache* cache = reinterpret_cast(arg); Cache::Handle* handle = reinterpret_cast(h); cache->Release(handle); } // Convert an index iterator value (i.e., an encoded BlockHandle) // into an iterator over the contents of the corresponding block. Iterator* Table::BlockReader(void* arg, const ReadOptions& options, const Slice& index_value) { Table* table = reinterpret_cast(arg); Cache* block_cache = table->rep_->options.block_cache; Block* block = nullptr; Cache::Handle* cache_handle = nullptr; BlockHandle handle; Slice input = index_value; Status s = handle.DecodeFrom(&input); // We intentionally allow extra stuff in index_value so that we // can add more features in the future. if (s.ok()) { BlockContents contents; if (block_cache != nullptr) { char cache_key_buffer[16]; EncodeFixed64(cache_key_buffer, table->rep_->cache_id); EncodeFixed64(cache_key_buffer + 8, handle.offset()); Slice key(cache_key_buffer, sizeof(cache_key_buffer)); cache_handle = block_cache->Lookup(key); if (cache_handle != nullptr) { block = reinterpret_cast(block_cache->Value(cache_handle)); } else { s = ReadBlock(table->rep_->file, options, handle, &contents); if (s.ok()) { block = new Block(contents); if (contents.cachable && options.fill_cache) { cache_handle = block_cache->Insert(key, block, block->size(), &DeleteCachedBlock); } } } } else { s = ReadBlock(table->rep_->file, options, handle, &contents); if (s.ok()) { block = new Block(contents); } } } Iterator* iter; if (block != nullptr) { iter = block->NewIterator(table->rep_->options.comparator); if (cache_handle == nullptr) { iter->RegisterCleanup(&DeleteBlock, block, nullptr); } else { iter->RegisterCleanup(&ReleaseBlock, block_cache, cache_handle); } } else { iter = NewErrorIterator(s); } return iter; } Iterator* Table::NewIterator(const ReadOptions& options) const { return NewTwoLevelIterator( rep_->index_block->NewIterator(rep_->options.comparator), &Table::BlockReader, const_cast(this), options); } Status Table::InternalGet(const ReadOptions& options, const Slice& k, void* arg, void (*handle_result)(void*, const Slice&, const Slice&)) { Status s; Iterator* iiter = rep_->index_block->NewIterator(rep_->options.comparator); // const Comparator *comparator = rep_->options.comparator; const InternalKeyComparator *comparator = static_cast(rep_->options.comparator); const Comparator *user_comparator = comparator->user_comparator(); std::cout<<"-----------iter on index-------------\n"; iiter->Seek(k); if (iiter->Valid()) { Slice handle_value = iiter->value(); FilterBlockReader* filter = rep_->filter; BlockHandle handle; if (filter != nullptr && handle.DecodeFrom(&handle_value).ok() && !filter->KeyMayMatch(handle.offset(), k)) { // Not found } else { // Iterator* block_iter = BlockReader(this, options, iiter->value()); std::cout<<"-----------iter on data-------------\n"; // block_iter->Seek(k); // if (block_iter->Valid()) { // (*handle_result)(arg, block_iter->key(), block_iter->value()); // } // s = block_iter->status(); // delete block_iter; bool found = false; while(iiter->Valid()) { std::cout<<"-----------iter on new block-------------\n"; Iterator* block_iter = BlockReader(this,options,iiter->value()); block_iter->Seek(k); ParsedInternalKey target,now; ParseInternalKey(k,&target); ParseInternalKey(block_iter->key(),&now); if(user_comparator->Compare(target.user_key,now.user_key) < 0) { std::cout<<"target key :"<key(),block_iter->value()); delete block_iter; break; } while(block_iter->Valid()) { ParseInternalKey(block_iter->key(),&now); std::cout<<"target key :"< now.deadTime) { block_iter->Next(); continue; } if(user_comparator->Compare(target.user_key,now.user_key) < 0) { break; } (*handle_result)(arg,block_iter->key(),block_iter->value()); found = true; break; // block_iter->Next(); } s = block_iter->status(); delete block_iter; if(found) break; iiter->Next(); } } } if (s.ok()) { s = iiter->status(); } delete iiter; return s; } uint64_t Table::ApproximateOffsetOf(const Slice& key) const { Iterator* index_iter = rep_->index_block->NewIterator(rep_->options.comparator); index_iter->Seek(key); uint64_t result; if (index_iter->Valid()) { BlockHandle handle; Slice input = index_iter->value(); Status s = handle.DecodeFrom(&input); if (s.ok()) { result = handle.offset(); } else { // Strange: we can't decode the block handle in the index block. // We'll just return the offset of the metaindex block, which is // close to the whole file size for this case. result = rep_->metaindex_handle.offset(); } } else { // key is past the last key in the file. Approximate the offset // by returning the offset of the metaindex block (which is // right near the end of the file). result = rep_->metaindex_handle.offset(); } delete index_iter; return result; } } // namespace leveldb