// 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 #include #include #include "db/dbformat.h" #include "db/memtable.h" #include "db/skiplistrep.h" #include "db/write_batch_internal.h" #include "leveldb/db.h" #include "leveldb/env.h" #include "leveldb/iterator.h" #include "leveldb/table_builder.h" #include "table/block.h" #include "table/block_builder.h" #include "table/format.h" #include "table/table.h" #include "util/random.h" #include "util/testharness.h" #include "util/testutil.h" namespace leveldb { // Return reverse of "key". // Used to test non-lexicographic comparators. static std::string Reverse(const Slice& key) { std::string str(key.ToString()); std::string rev(""); for (std::string::reverse_iterator rit = str.rbegin(); rit != str.rend(); ++rit) { rev.push_back(*rit); } return rev; } namespace { class ReverseKeyComparator : public Comparator { public: virtual const char* Name() const { return "leveldb.ReverseBytewiseComparator"; } virtual int Compare(const Slice& a, const Slice& b) const { return BytewiseComparator()->Compare(Reverse(a), Reverse(b)); } virtual void FindShortestSeparator( std::string* start, const Slice& limit) const { std::string s = Reverse(*start); std::string l = Reverse(limit); BytewiseComparator()->FindShortestSeparator(&s, l); *start = Reverse(s); } virtual void FindShortSuccessor(std::string* key) const { std::string s = Reverse(*key); BytewiseComparator()->FindShortSuccessor(&s); *key = Reverse(s); } }; } // namespace static ReverseKeyComparator reverse_key_comparator; static void Increment(const Comparator* cmp, std::string* key) { if (cmp == BytewiseComparator()) { key->push_back('\0'); } else { assert(cmp == &reverse_key_comparator); std::string rev = Reverse(*key); rev.push_back('\0'); *key = Reverse(rev); } } // An STL comparator that uses a Comparator namespace anon { struct STLLessThan { const Comparator* cmp; STLLessThan() : cmp(BytewiseComparator()) { } explicit STLLessThan(const Comparator* c) : cmp(c) { } bool operator()(const std::string& a, const std::string& b) const { return cmp->Compare(Slice(a), Slice(b)) < 0; } }; } // namespace class StringSink: public WritableFile { public: ~StringSink() { } const std::string& contents() const { return contents_; } virtual Status Close() { return Status::OK(); } virtual Status Flush() { return Status::OK(); } virtual Status Sync() { return Status::OK(); } virtual Status Append(const Slice& data) { contents_.append(data.data(), data.size()); return Status::OK(); } private: std::string contents_; }; class StringSource: public RandomAccessFile { public: StringSource(const Slice& contents, uint64_t uniq_id) : contents_(contents.data(), contents.size()), uniq_id_(uniq_id) { } virtual ~StringSource() { } uint64_t Size() const { return contents_.size(); } virtual Status Read(uint64_t offset, size_t n, Slice* result, char* scratch) const { if (offset > contents_.size()) { return Status::InvalidArgument("invalid Read offset"); } if (offset + n > contents_.size()) { n = contents_.size() - offset; } memcpy(scratch, &contents_[offset], n); *result = Slice(scratch, n); return Status::OK(); } virtual size_t GetUniqueId(char* id, size_t max_size) const { if (max_size < 20) { return 0; } char* rid = id; rid = EncodeVarint64(rid, uniq_id_); rid = EncodeVarint64(rid, 0); return static_cast(rid-id); } private: std::string contents_; uint64_t uniq_id_; }; typedef std::map KVMap; // Helper class for tests to unify the interface between // BlockBuilder/TableBuilder and Block/Table. class Constructor { public: explicit Constructor(const Comparator* cmp) : data_(anon::STLLessThan(cmp)) { } virtual ~Constructor() { } void Add(const std::string& key, const Slice& value) { data_[key] = value.ToString(); } // Finish constructing the data structure with all the keys that have // been added so far. Returns the keys in sorted order in "*keys" // and stores the key/value pairs in "*kvmap" void Finish(const Options& options, std::vector* keys, KVMap* kvmap) { *kvmap = data_; keys->clear(); for (KVMap::const_iterator it = data_.begin(); it != data_.end(); ++it) { keys->push_back(it->first); } data_.clear(); Status s = FinishImpl(options, *kvmap); ASSERT_TRUE(s.ok()) << s.ToString(); } // Construct the data structure from the data in "data" virtual Status FinishImpl(const Options& options, const KVMap& data) = 0; virtual Iterator* NewIterator() const = 0; virtual const KVMap& data() { return data_; } virtual DB* db() const { return nullptr; } // Overridden in DBConstructor private: KVMap data_; }; class BlockConstructor: public Constructor { public: explicit BlockConstructor(const Comparator* cmp) : Constructor(cmp), comparator_(cmp), block_(nullptr) { } ~BlockConstructor() { delete block_; } virtual Status FinishImpl(const Options& options, const KVMap& data) { delete block_; block_ = nullptr; BlockBuilder builder(&options); for (KVMap::const_iterator it = data.begin(); it != data.end(); ++it) { builder.Add(it->first, it->second); } // Open the block data_ = builder.Finish().ToString(); BlockContents contents; contents.data = data_; contents.cachable = false; contents.heap_allocated = false; block_ = new Block(contents); return Status::OK(); } virtual Iterator* NewIterator() const { return block_->NewIterator(comparator_); } private: const Comparator* comparator_; std::string data_; Block* block_; BlockConstructor(); }; class TableConstructor: public Constructor { public: explicit TableConstructor(const Comparator* cmp) : Constructor(cmp) { } ~TableConstructor() { Reset(); } virtual Status FinishImpl(const Options& options, const KVMap& data) { Reset(); sink_.reset(new StringSink()); TableBuilder builder(options, sink_.get()); for (KVMap::const_iterator it = data.begin(); it != data.end(); ++it) { builder.Add(it->first, it->second); ASSERT_TRUE(builder.status().ok()); } Status s = builder.Finish(); ASSERT_TRUE(s.ok()) << s.ToString(); ASSERT_EQ(sink_->contents().size(), builder.FileSize()); // Open the table uniq_id_ = cur_uniq_id_++; source_.reset(new StringSource(sink_->contents(), uniq_id_)); return Table::Open(options, soptions, std::move(source_), sink_->contents().size(), &table_); } virtual Iterator* NewIterator() const { return table_->NewIterator(ReadOptions()); } uint64_t ApproximateOffsetOf(const Slice& key) const { return table_->ApproximateOffsetOf(key); } virtual Status Reopen(const Options& options) { source_.reset(new StringSource(sink_->contents(), uniq_id_)); return Table::Open(options, soptions, std::move(source_), sink_->contents().size(), &table_); } virtual Table* table() { return table_.get(); } private: void Reset() { uniq_id_ = 0; table_.reset(); sink_.reset(); source_.reset(); } uint64_t uniq_id_; unique_ptr sink_; unique_ptr source_; unique_ptr table_; TableConstructor(); static uint64_t cur_uniq_id_; const EnvOptions soptions; }; uint64_t TableConstructor::cur_uniq_id_ = 1; // A helper class that converts internal format keys into user keys class KeyConvertingIterator: public Iterator { public: explicit KeyConvertingIterator(Iterator* iter) : iter_(iter) { } virtual ~KeyConvertingIterator() { delete iter_; } virtual bool Valid() const { return iter_->Valid(); } virtual void Seek(const Slice& target) { ParsedInternalKey ikey(target, kMaxSequenceNumber, kTypeValue); std::string encoded; AppendInternalKey(&encoded, ikey); iter_->Seek(encoded); } virtual void SeekToFirst() { iter_->SeekToFirst(); } virtual void SeekToLast() { iter_->SeekToLast(); } virtual void Next() { iter_->Next(); } virtual void Prev() { iter_->Prev(); } virtual Slice key() const { assert(Valid()); ParsedInternalKey key; if (!ParseInternalKey(iter_->key(), &key)) { status_ = Status::Corruption("malformed internal key"); return Slice("corrupted key"); } return key.user_key; } virtual Slice value() const { return iter_->value(); } virtual Status status() const { return status_.ok() ? iter_->status() : status_; } private: mutable Status status_; Iterator* iter_; // No copying allowed KeyConvertingIterator(const KeyConvertingIterator&); void operator=(const KeyConvertingIterator&); }; class MemTableConstructor: public Constructor { public: explicit MemTableConstructor(const Comparator* cmp) : Constructor(cmp), internal_comparator_(cmp), table_factory_(new SkipListFactory) { memtable_ = new MemTable(internal_comparator_, table_factory_); memtable_->Ref(); } ~MemTableConstructor() { memtable_->Unref(); } virtual Status FinishImpl(const Options& options, const KVMap& data) { memtable_->Unref(); memtable_ = new MemTable(internal_comparator_, table_factory_); memtable_->Ref(); int seq = 1; for (KVMap::const_iterator it = data.begin(); it != data.end(); ++it) { memtable_->Add(seq, kTypeValue, it->first, it->second); seq++; } return Status::OK(); } virtual Iterator* NewIterator() const { return new KeyConvertingIterator(memtable_->NewIterator()); } private: InternalKeyComparator internal_comparator_; MemTable* memtable_; std::shared_ptr table_factory_; }; class DBConstructor: public Constructor { public: explicit DBConstructor(const Comparator* cmp) : Constructor(cmp), comparator_(cmp) { db_ = nullptr; NewDB(); } ~DBConstructor() { delete db_; } virtual Status FinishImpl(const Options& options, const KVMap& data) { delete db_; db_ = nullptr; NewDB(); for (KVMap::const_iterator it = data.begin(); it != data.end(); ++it) { WriteBatch batch; batch.Put(it->first, it->second); ASSERT_TRUE(db_->Write(WriteOptions(), &batch).ok()); } return Status::OK(); } virtual Iterator* NewIterator() const { return db_->NewIterator(ReadOptions()); } virtual DB* db() const { return db_; } private: void NewDB() { std::string name = test::TmpDir() + "/table_testdb"; Options options; options.comparator = comparator_; Status status = DestroyDB(name, options); ASSERT_TRUE(status.ok()) << status.ToString(); options.create_if_missing = true; options.error_if_exists = true; options.write_buffer_size = 10000; // Something small to force merging status = DB::Open(options, name, &db_); ASSERT_TRUE(status.ok()) << status.ToString(); } const Comparator* comparator_; DB* db_; }; static bool SnappyCompressionSupported() { std::string out; Slice in = "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa"; return port::Snappy_Compress(Options().compression_opts, in.data(), in.size(), &out); } static bool ZlibCompressionSupported() { std::string out; Slice in = "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa"; return port::Zlib_Compress(Options().compression_opts, in.data(), in.size(), &out); } #ifdef BZIP2 static bool BZip2CompressionSupported() { std::string out; Slice in = "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa"; return port::BZip2_Compress(Options().compression_opts, in.data(), in.size(), &out); } #endif enum TestType { TABLE_TEST, BLOCK_TEST, MEMTABLE_TEST, DB_TEST }; struct TestArgs { TestType type; bool reverse_compare; int restart_interval; CompressionType compression; }; static std::vector Generate_Arg_List() { std::vector ret; TestType test_type[4] = {TABLE_TEST, BLOCK_TEST, MEMTABLE_TEST, DB_TEST}; int test_type_len = 4; bool reverse_compare[2] = {false, true}; int reverse_compare_len = 2; int restart_interval[3] = {16, 1, 1024}; int restart_interval_len = 3; // Only add compression if it is supported std::vector compression_types; compression_types.push_back(kNoCompression); #ifdef SNAPPY if (SnappyCompressionSupported()) compression_types.push_back(kSnappyCompression); #endif #ifdef ZLIB if (ZlibCompressionSupported()) compression_types.push_back(kZlibCompression); #endif #ifdef BZIP2 if (BZip2CompressionSupported()) compression_types.push_back(kBZip2Compression); #endif for(int i =0; i < test_type_len; i++) for (int j =0; j < reverse_compare_len; j++) for (int k =0; k < restart_interval_len; k++) for (unsigned int n =0; n < compression_types.size(); n++) { TestArgs one_arg; one_arg.type = test_type[i]; one_arg.reverse_compare = reverse_compare[j]; one_arg.restart_interval = restart_interval[k]; one_arg.compression = compression_types[n]; ret.push_back(one_arg); } return ret; } class Harness { public: Harness() : constructor_(nullptr) { } void Init(const TestArgs& args) { delete constructor_; constructor_ = nullptr; options_ = Options(); options_.block_restart_interval = args.restart_interval; options_.compression = args.compression; // Use shorter block size for tests to exercise block boundary // conditions more. options_.block_size = 256; if (args.reverse_compare) { options_.comparator = &reverse_key_comparator; } switch (args.type) { case TABLE_TEST: constructor_ = new TableConstructor(options_.comparator); break; case BLOCK_TEST: constructor_ = new BlockConstructor(options_.comparator); break; case MEMTABLE_TEST: constructor_ = new MemTableConstructor(options_.comparator); break; case DB_TEST: constructor_ = new DBConstructor(options_.comparator); break; } } ~Harness() { delete constructor_; } void Add(const std::string& key, const std::string& value) { constructor_->Add(key, value); } void Test(Random* rnd) { std::vector keys; KVMap data; constructor_->Finish(options_, &keys, &data); TestForwardScan(keys, data); TestBackwardScan(keys, data); TestRandomAccess(rnd, keys, data); } void TestForwardScan(const std::vector& keys, const KVMap& data) { Iterator* iter = constructor_->NewIterator(); ASSERT_TRUE(!iter->Valid()); iter->SeekToFirst(); for (KVMap::const_iterator model_iter = data.begin(); model_iter != data.end(); ++model_iter) { ASSERT_EQ(ToString(data, model_iter), ToString(iter)); iter->Next(); } ASSERT_TRUE(!iter->Valid()); delete iter; } void TestBackwardScan(const std::vector& keys, const KVMap& data) { Iterator* iter = constructor_->NewIterator(); ASSERT_TRUE(!iter->Valid()); iter->SeekToLast(); for (KVMap::const_reverse_iterator model_iter = data.rbegin(); model_iter != data.rend(); ++model_iter) { ASSERT_EQ(ToString(data, model_iter), ToString(iter)); iter->Prev(); } ASSERT_TRUE(!iter->Valid()); delete iter; } void TestRandomAccess(Random* rnd, const std::vector& keys, const KVMap& data) { static const bool kVerbose = false; Iterator* iter = constructor_->NewIterator(); ASSERT_TRUE(!iter->Valid()); KVMap::const_iterator model_iter = data.begin(); if (kVerbose) fprintf(stderr, "---\n"); for (int i = 0; i < 200; i++) { const int toss = rnd->Uniform(5); switch (toss) { case 0: { if (iter->Valid()) { if (kVerbose) fprintf(stderr, "Next\n"); iter->Next(); ++model_iter; ASSERT_EQ(ToString(data, model_iter), ToString(iter)); } break; } case 1: { if (kVerbose) fprintf(stderr, "SeekToFirst\n"); iter->SeekToFirst(); model_iter = data.begin(); ASSERT_EQ(ToString(data, model_iter), ToString(iter)); break; } case 2: { std::string key = PickRandomKey(rnd, keys); model_iter = data.lower_bound(key); if (kVerbose) fprintf(stderr, "Seek '%s'\n", EscapeString(key).c_str()); iter->Seek(Slice(key)); ASSERT_EQ(ToString(data, model_iter), ToString(iter)); break; } case 3: { if (iter->Valid()) { if (kVerbose) fprintf(stderr, "Prev\n"); iter->Prev(); if (model_iter == data.begin()) { model_iter = data.end(); // Wrap around to invalid value } else { --model_iter; } ASSERT_EQ(ToString(data, model_iter), ToString(iter)); } break; } case 4: { if (kVerbose) fprintf(stderr, "SeekToLast\n"); iter->SeekToLast(); if (keys.empty()) { model_iter = data.end(); } else { std::string last = data.rbegin()->first; model_iter = data.lower_bound(last); } ASSERT_EQ(ToString(data, model_iter), ToString(iter)); break; } } } delete iter; } std::string ToString(const KVMap& data, const KVMap::const_iterator& it) { if (it == data.end()) { return "END"; } else { return "'" + it->first + "->" + it->second + "'"; } } std::string ToString(const KVMap& data, const KVMap::const_reverse_iterator& it) { if (it == data.rend()) { return "END"; } else { return "'" + it->first + "->" + it->second + "'"; } } std::string ToString(const Iterator* it) { if (!it->Valid()) { return "END"; } else { return "'" + it->key().ToString() + "->" + it->value().ToString() + "'"; } } std::string PickRandomKey(Random* rnd, const std::vector& keys) { if (keys.empty()) { return "foo"; } else { const int index = rnd->Uniform(keys.size()); std::string result = keys[index]; switch (rnd->Uniform(3)) { case 0: // Return an existing key break; case 1: { // Attempt to return something smaller than an existing key if (result.size() > 0 && result[result.size()-1] > '\0') { result[result.size()-1]--; } break; } case 2: { // Return something larger than an existing key Increment(options_.comparator, &result); break; } } return result; } } // Returns nullptr if not running against a DB DB* db() const { return constructor_->db(); } private: Options options_; Constructor* constructor_; }; // Test the empty key TEST(Harness, SimpleEmptyKey) { std::vector args = Generate_Arg_List(); for (unsigned int i = 0; i < args.size(); i++) { Init(args[i]); Random rnd(test::RandomSeed() + 1); Add("", "v"); Test(&rnd); } } TEST(Harness, SimpleSingle) { std::vector args = Generate_Arg_List(); for (unsigned int i = 0; i < args.size(); i++) { Init(args[i]); Random rnd(test::RandomSeed() + 2); Add("abc", "v"); Test(&rnd); } } TEST(Harness, SimpleMulti) { std::vector args = Generate_Arg_List(); for (unsigned int i = 0; i < args.size(); i++) { Init(args[i]); Random rnd(test::RandomSeed() + 3); Add("abc", "v"); Add("abcd", "v"); Add("ac", "v2"); Test(&rnd); } } TEST(Harness, SimpleSpecialKey) { std::vector args = Generate_Arg_List(); for (unsigned int i = 0; i < args.size(); i++) { Init(args[i]); Random rnd(test::RandomSeed() + 4); Add("\xff\xff", "v3"); Test(&rnd); } } TEST(Harness, Randomized) { std::vector args = Generate_Arg_List(); for (unsigned int i = 0; i < args.size(); i++) { Init(args[i]); Random rnd(test::RandomSeed() + 5); for (int num_entries = 0; num_entries < 2000; num_entries += (num_entries < 50 ? 1 : 200)) { if ((num_entries % 10) == 0) { fprintf(stderr, "case %d of %d: num_entries = %d\n", (i + 1), int(args.size()), num_entries); } for (int e = 0; e < num_entries; e++) { std::string v; Add(test::RandomKey(&rnd, rnd.Skewed(4)), test::RandomString(&rnd, rnd.Skewed(5), &v).ToString()); } Test(&rnd); } } } TEST(Harness, RandomizedLongDB) { Random rnd(test::RandomSeed()); TestArgs args = { DB_TEST, false, 16, kNoCompression }; Init(args); int num_entries = 100000; for (int e = 0; e < num_entries; e++) { std::string v; Add(test::RandomKey(&rnd, rnd.Skewed(4)), test::RandomString(&rnd, rnd.Skewed(5), &v).ToString()); } Test(&rnd); // We must have created enough data to force merging int files = 0; for (int level = 0; level < db()->NumberLevels(); level++) { std::string value; char name[100]; snprintf(name, sizeof(name), "leveldb.num-files-at-level%d", level); ASSERT_TRUE(db()->GetProperty(name, &value)); files += atoi(value.c_str()); } ASSERT_GT(files, 0); } class MemTableTest { }; TEST(MemTableTest, Simple) { InternalKeyComparator cmp(BytewiseComparator()); auto table_factory = std::make_shared(); MemTable* memtable = new MemTable(cmp, table_factory); memtable->Ref(); WriteBatch batch; WriteBatchInternal::SetSequence(&batch, 100); batch.Put(std::string("k1"), std::string("v1")); batch.Put(std::string("k2"), std::string("v2")); batch.Put(std::string("k3"), std::string("v3")); batch.Put(std::string("largekey"), std::string("vlarge")); ASSERT_TRUE(WriteBatchInternal::InsertInto(&batch, memtable).ok()); Iterator* iter = memtable->NewIterator(); iter->SeekToFirst(); while (iter->Valid()) { fprintf(stderr, "key: '%s' -> '%s'\n", iter->key().ToString().c_str(), iter->value().ToString().c_str()); iter->Next(); } delete iter; memtable->Unref(); } static bool Between(uint64_t val, uint64_t low, uint64_t high) { bool result = (val >= low) && (val <= high); if (!result) { fprintf(stderr, "Value %llu is not in range [%llu, %llu]\n", (unsigned long long)(val), (unsigned long long)(low), (unsigned long long)(high)); } return result; } class TableTest { }; TEST(TableTest, ApproximateOffsetOfPlain) { TableConstructor c(BytewiseComparator()); c.Add("k01", "hello"); c.Add("k02", "hello2"); c.Add("k03", std::string(10000, 'x')); c.Add("k04", std::string(200000, 'x')); c.Add("k05", std::string(300000, 'x')); c.Add("k06", "hello3"); c.Add("k07", std::string(100000, 'x')); std::vector keys; KVMap kvmap; Options options; options.block_size = 1024; options.compression = kNoCompression; c.Finish(options, &keys, &kvmap); ASSERT_TRUE(Between(c.ApproximateOffsetOf("abc"), 0, 0)); ASSERT_TRUE(Between(c.ApproximateOffsetOf("k01"), 0, 0)); ASSERT_TRUE(Between(c.ApproximateOffsetOf("k01a"), 0, 0)); ASSERT_TRUE(Between(c.ApproximateOffsetOf("k02"), 0, 0)); ASSERT_TRUE(Between(c.ApproximateOffsetOf("k03"), 0, 0)); ASSERT_TRUE(Between(c.ApproximateOffsetOf("k04"), 10000, 11000)); ASSERT_TRUE(Between(c.ApproximateOffsetOf("k04a"), 210000, 211000)); ASSERT_TRUE(Between(c.ApproximateOffsetOf("k05"), 210000, 211000)); ASSERT_TRUE(Between(c.ApproximateOffsetOf("k06"), 510000, 511000)); ASSERT_TRUE(Between(c.ApproximateOffsetOf("k07"), 510000, 511000)); ASSERT_TRUE(Between(c.ApproximateOffsetOf("xyz"), 610000, 612000)); } static void Do_Compression_Test(CompressionType comp) { Random rnd(301); TableConstructor c(BytewiseComparator()); std::string tmp; c.Add("k01", "hello"); c.Add("k02", test::CompressibleString(&rnd, 0.25, 10000, &tmp)); c.Add("k03", "hello3"); c.Add("k04", test::CompressibleString(&rnd, 0.25, 10000, &tmp)); std::vector keys; KVMap kvmap; Options options; options.block_size = 1024; options.compression = comp; c.Finish(options, &keys, &kvmap); ASSERT_TRUE(Between(c.ApproximateOffsetOf("abc"), 0, 0)); ASSERT_TRUE(Between(c.ApproximateOffsetOf("k01"), 0, 0)); ASSERT_TRUE(Between(c.ApproximateOffsetOf("k02"), 0, 0)); ASSERT_TRUE(Between(c.ApproximateOffsetOf("k03"), 2000, 3000)); ASSERT_TRUE(Between(c.ApproximateOffsetOf("k04"), 2000, 3000)); ASSERT_TRUE(Between(c.ApproximateOffsetOf("xyz"), 4000, 6000)); } TEST(TableTest, ApproximateOffsetOfCompressed) { CompressionType compression_state[2]; int valid = 0; if (!SnappyCompressionSupported()) { fprintf(stderr, "skipping snappy compression tests\n"); } else { compression_state[valid] = kSnappyCompression; valid++; } if (!ZlibCompressionSupported()) { fprintf(stderr, "skipping zlib compression tests\n"); } else { compression_state[valid] = kZlibCompression; valid++; } for(int i =0; i < valid; i++) { Do_Compression_Test(compression_state[i]); } } TEST(TableTest, BlockCacheLeak) { // Check that when we reopen a table we don't lose access to blocks already // in the cache. This test checks whether the Table actually makes use of the // unique ID from the file. Options opt; opt.block_size = 1024; opt.compression = kNoCompression; opt.block_cache = NewLRUCache(16*1024*1024); // big enough so we don't ever // lose cached values. TableConstructor c(BytewiseComparator()); c.Add("k01", "hello"); c.Add("k02", "hello2"); c.Add("k03", std::string(10000, 'x')); c.Add("k04", std::string(200000, 'x')); c.Add("k05", std::string(300000, 'x')); c.Add("k06", "hello3"); c.Add("k07", std::string(100000, 'x')); std::vector keys; KVMap kvmap; c.Finish(opt, &keys, &kvmap); unique_ptr iter(c.NewIterator()); iter->SeekToFirst(); while (iter->Valid()) { iter->key(); iter->value(); iter->Next(); } ASSERT_OK(iter->status()); ASSERT_OK(c.Reopen(opt)); for (const std::string& key: keys) { ASSERT_TRUE(c.table()->TEST_KeyInCache(ReadOptions(), key)); } } } // namespace leveldb int main(int argc, char** argv) { return leveldb::test::RunAllTests(); }