// 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/db.h" #include "leveldb/filter_policy.h" #include "db/db_impl.h" #include "db/filename.h" #include "db/version_set.h" #include "db/write_batch_internal.h" #include "leveldb/cache.h" #include "leveldb/env.h" #include "leveldb/table.h" #include "util/hash.h" #include "util/logging.h" #include "util/mutexlock.h" #include "util/testharness.h" #include "util/testutil.h" namespace leveldb { static std::string RandomString(Random* rnd, int len) { std::string r; test::RandomString(rnd, len, &r); return r; } namespace { class AtomicCounter { private: port::Mutex mu_; int count_; public: AtomicCounter() : count_(0) { } void Increment() { IncrementBy(1); } void IncrementBy(int count) { MutexLock l(&mu_); count_ += count; } int Read() { MutexLock l(&mu_); return count_; } void Reset() { MutexLock l(&mu_); count_ = 0; } }; void DelayMilliseconds(int millis) { Env::Default()->SleepForMicroseconds(millis * 1000); } } // Special Env used to delay background operations class SpecialEnv : public EnvWrapper { public: // sstable/log Sync() calls are blocked while this pointer is non-NULL. port::AtomicPointer delay_data_sync_; // sstable/log Sync() calls return an error. port::AtomicPointer data_sync_error_; // Simulate no-space errors while this pointer is non-NULL. port::AtomicPointer no_space_; // Simulate non-writable file system while this pointer is non-NULL port::AtomicPointer non_writable_; // Force sync of manifest files to fail while this pointer is non-NULL port::AtomicPointer manifest_sync_error_; // Force write to manifest files to fail while this pointer is non-NULL port::AtomicPointer manifest_write_error_; bool count_random_reads_; AtomicCounter random_read_counter_; explicit SpecialEnv(Env* base) : EnvWrapper(base) { delay_data_sync_.Release_Store(NULL); data_sync_error_.Release_Store(NULL); no_space_.Release_Store(NULL); non_writable_.Release_Store(NULL); count_random_reads_ = false; manifest_sync_error_.Release_Store(NULL); manifest_write_error_.Release_Store(NULL); } Status NewWritableFile(const std::string& f, WritableFile** r) { class DataFile : public WritableFile { private: SpecialEnv* env_; WritableFile* base_; public: DataFile(SpecialEnv* env, WritableFile* base) : env_(env), base_(base) { } ~DataFile() { delete base_; } Status Append(const Slice& data) { if (env_->no_space_.Acquire_Load() != NULL) { // Drop writes on the floor return Status::OK(); } else { return base_->Append(data); } } Status Close() { return base_->Close(); } Status Flush() { return base_->Flush(); } Status Sync() { if (env_->data_sync_error_.Acquire_Load() != NULL) { return Status::IOError("simulated data sync error"); } while (env_->delay_data_sync_.Acquire_Load() != NULL) { DelayMilliseconds(100); } return base_->Sync(); } }; class ManifestFile : public WritableFile { private: SpecialEnv* env_; WritableFile* base_; public: ManifestFile(SpecialEnv* env, WritableFile* b) : env_(env), base_(b) { } ~ManifestFile() { delete base_; } Status Append(const Slice& data) { if (env_->manifest_write_error_.Acquire_Load() != NULL) { return Status::IOError("simulated writer error"); } else { return base_->Append(data); } } Status Close() { return base_->Close(); } Status Flush() { return base_->Flush(); } Status Sync() { if (env_->manifest_sync_error_.Acquire_Load() != NULL) { return Status::IOError("simulated sync error"); } else { return base_->Sync(); } } }; if (non_writable_.Acquire_Load() != NULL) { return Status::IOError("simulated write error"); } Status s = target()->NewWritableFile(f, r); if (s.ok()) { if (strstr(f.c_str(), ".ldb") != NULL || strstr(f.c_str(), ".log") != NULL) { *r = new DataFile(this, *r); } else if (strstr(f.c_str(), "MANIFEST") != NULL) { *r = new ManifestFile(this, *r); } } return s; } Status NewRandomAccessFile(const std::string& f, RandomAccessFile** r) { class CountingFile : public RandomAccessFile { private: RandomAccessFile* target_; AtomicCounter* counter_; public: CountingFile(RandomAccessFile* target, AtomicCounter* counter) : target_(target), counter_(counter) { } virtual ~CountingFile() { delete target_; } virtual Status Read(uint64_t offset, size_t n, Slice* result, char* scratch) const { counter_->Increment(); return target_->Read(offset, n, result, scratch); } }; Status s = target()->NewRandomAccessFile(f, r); if (s.ok() && count_random_reads_) { *r = new CountingFile(*r, &random_read_counter_); } return s; } }; class DBTest { private: const FilterPolicy* filter_policy_; // Sequence of option configurations to try enum OptionConfig { kDefault, kFilter, kUncompressed, kEnd }; int option_config_; public: std::string dbname_; SpecialEnv* env_; DB* db_; Options last_options_; DBTest() : option_config_(kDefault), env_(new SpecialEnv(Env::Default())) { filter_policy_ = NewBloomFilterPolicy(10); dbname_ = test::TmpDir() + "/db_test"; DestroyDB(dbname_, Options()); db_ = NULL; Reopen(); } ~DBTest() { delete db_; DestroyDB(dbname_, Options()); delete env_; delete filter_policy_; } // Switch to a fresh database with the next option configuration to // test. Return false if there are no more configurations to test. bool ChangeOptions() { option_config_++; if (option_config_ >= kEnd) { return false; } else { DestroyAndReopen(); return true; } } // Return the current option configuration. Options CurrentOptions() { Options options; switch (option_config_) { case kFilter: options.filter_policy = filter_policy_; break; case kUncompressed: options.compression = kNoCompression; break; default: break; } return options; } DBImpl* dbfull() { return reinterpret_cast(db_); } void Reopen(Options* options = NULL) { ASSERT_OK(TryReopen(options)); } void Close() { delete db_; db_ = NULL; } void DestroyAndReopen(Options* options = NULL) { delete db_; db_ = NULL; DestroyDB(dbname_, Options()); ASSERT_OK(TryReopen(options)); } Status TryReopen(Options* options) { delete db_; db_ = NULL; Options opts; if (options != NULL) { opts = *options; } else { opts = CurrentOptions(); opts.create_if_missing = true; } last_options_ = opts; return DB::Open(opts, dbname_, &db_); } Status Put(const std::string& k, const std::string& v) { return db_->Put(WriteOptions(), k, v); } Status Delete(const std::string& k) { return db_->Delete(WriteOptions(), k); } std::string Get(const std::string& k, const Snapshot* snapshot = NULL) { ReadOptions options; options.snapshot = snapshot; std::string result; Status s = db_->Get(options, k, &result); if (s.IsNotFound()) { result = "NOT_FOUND"; } else if (!s.ok()) { result = s.ToString(); } return result; } // Return a string that contains all key,value pairs in order, // formatted like "(k1->v1)(k2->v2)". std::string Contents() { std::vector forward; std::string result; Iterator* iter = db_->NewIterator(ReadOptions()); for (iter->SeekToFirst(); iter->Valid(); iter->Next()) { std::string s = IterStatus(iter); result.push_back('('); result.append(s); result.push_back(')'); forward.push_back(s); } // Check reverse iteration results are the reverse of forward results size_t matched = 0; for (iter->SeekToLast(); iter->Valid(); iter->Prev()) { ASSERT_LT(matched, forward.size()); ASSERT_EQ(IterStatus(iter), forward[forward.size() - matched - 1]); matched++; } ASSERT_EQ(matched, forward.size()); delete iter; return result; } std::string AllEntriesFor(const Slice& user_key) { Iterator* iter = dbfull()->TEST_NewInternalIterator(); InternalKey target(user_key, kMaxSequenceNumber, kTypeValue); iter->Seek(target.Encode()); std::string result; if (!iter->status().ok()) { result = iter->status().ToString(); } else { result = "[ "; bool first = true; while (iter->Valid()) { ParsedInternalKey ikey; if (!ParseInternalKey(iter->key(), &ikey)) { result += "CORRUPTED"; } else { if (last_options_.comparator->Compare(ikey.user_key, user_key) != 0) { break; } if (!first) { result += ", "; } first = false; switch (ikey.type) { case kTypeValue: result += iter->value().ToString(); break; case kTypeDeletion: result += "DEL"; break; } } iter->Next(); } if (!first) { result += " "; } result += "]"; } delete iter; return result; } int NumTableFilesAtLevel(int level) { std::string property; ASSERT_TRUE( db_->GetProperty("leveldb.num-files-at-level" + NumberToString(level), &property)); return atoi(property.c_str()); } int TotalTableFiles() { int result = 0; for (int level = 0; level < config::kNumLevels; level++) { result += NumTableFilesAtLevel(level); } return result; } // Return spread of files per level std::string FilesPerLevel() { std::string result; int last_non_zero_offset = 0; for (int level = 0; level < config::kNumLevels; level++) { int f = NumTableFilesAtLevel(level); char buf[100]; snprintf(buf, sizeof(buf), "%s%d", (level ? "," : ""), f); result += buf; if (f > 0) { last_non_zero_offset = result.size(); } } result.resize(last_non_zero_offset); return result; } int CountFiles() { std::vector files; env_->GetChildren(dbname_, &files); return static_cast(files.size()); } uint64_t Size(const Slice& start, const Slice& limit) { Range r(start, limit); uint64_t size; db_->GetApproximateSizes(&r, 1, &size); return size; } void Compact(const Slice& start, const Slice& limit) { db_->CompactRange(&start, &limit); } // Do n memtable compactions, each of which produces an sstable // covering the range [small,large]. void MakeTables(int n, const std::string& small, const std::string& large) { for (int i = 0; i < n; i++) { Put(small, "begin"); Put(large, "end"); dbfull()->TEST_CompactMemTable(); } } // Prevent pushing of new sstables into deeper levels by adding // tables that cover a specified range to all levels. void FillLevels(const std::string& smallest, const std::string& largest) { MakeTables(config::kNumLevels, smallest, largest); } void DumpFileCounts(const char* label) { fprintf(stderr, "---\n%s:\n", label); fprintf(stderr, "maxoverlap: %lld\n", static_cast( dbfull()->TEST_MaxNextLevelOverlappingBytes())); for (int level = 0; level < config::kNumLevels; level++) { int num = NumTableFilesAtLevel(level); if (num > 0) { fprintf(stderr, " level %3d : %d files\n", level, num); } } } std::string DumpSSTableList() { std::string property; db_->GetProperty("leveldb.sstables", &property); return property; } std::string IterStatus(Iterator* iter) { std::string result; if (iter->Valid()) { result = iter->key().ToString() + "->" + iter->value().ToString(); } else { result = "(invalid)"; } return result; } bool DeleteAnSSTFile() { std::vector filenames; ASSERT_OK(env_->GetChildren(dbname_, &filenames)); uint64_t number; FileType type; for (size_t i = 0; i < filenames.size(); i++) { if (ParseFileName(filenames[i], &number, &type) && type == kTableFile) { ASSERT_OK(env_->DeleteFile(TableFileName(dbname_, number))); return true; } } return false; } // Returns number of files renamed. int RenameLDBToSST() { std::vector filenames; ASSERT_OK(env_->GetChildren(dbname_, &filenames)); uint64_t number; FileType type; int files_renamed = 0; for (size_t i = 0; i < filenames.size(); i++) { if (ParseFileName(filenames[i], &number, &type) && type == kTableFile) { const std::string from = TableFileName(dbname_, number); const std::string to = SSTTableFileName(dbname_, number); ASSERT_OK(env_->RenameFile(from, to)); files_renamed++; } } return files_renamed; } }; TEST(DBTest, Empty) { do { ASSERT_TRUE(db_ != NULL); ASSERT_EQ("NOT_FOUND", Get("foo")); } while (ChangeOptions()); } TEST(DBTest, ReadWrite) { do { ASSERT_OK(Put("foo", "v1")); ASSERT_EQ("v1", Get("foo")); ASSERT_OK(Put("bar", "v2")); ASSERT_OK(Put("foo", "v3")); ASSERT_EQ("v3", Get("foo")); ASSERT_EQ("v2", Get("bar")); } while (ChangeOptions()); } TEST(DBTest, PutDeleteGet) { do { ASSERT_OK(db_->Put(WriteOptions(), "foo", "v1")); ASSERT_EQ("v1", Get("foo")); ASSERT_OK(db_->Put(WriteOptions(), "foo", "v2")); ASSERT_EQ("v2", Get("foo")); ASSERT_OK(db_->Delete(WriteOptions(), "foo")); ASSERT_EQ("NOT_FOUND", Get("foo")); } while (ChangeOptions()); } TEST(DBTest, GetFromImmutableLayer) { do { Options options = CurrentOptions(); options.env = env_; options.write_buffer_size = 100000; // Small write buffer Reopen(&options); ASSERT_OK(Put("foo", "v1")); ASSERT_EQ("v1", Get("foo")); env_->delay_data_sync_.Release_Store(env_); // Block sync calls Put("k1", std::string(100000, 'x')); // Fill memtable Put("k2", std::string(100000, 'y')); // Trigger compaction ASSERT_EQ("v1", Get("foo")); env_->delay_data_sync_.Release_Store(NULL); // Release sync calls } while (ChangeOptions()); } TEST(DBTest, GetFromVersions) { do { ASSERT_OK(Put("foo", "v1")); dbfull()->TEST_CompactMemTable(); ASSERT_EQ("v1", Get("foo")); } while (ChangeOptions()); } TEST(DBTest, GetSnapshot) { do { // Try with both a short key and a long key for (int i = 0; i < 2; i++) { std::string key = (i == 0) ? std::string("foo") : std::string(200, 'x'); ASSERT_OK(Put(key, "v1")); const Snapshot* s1 = db_->GetSnapshot(); ASSERT_OK(Put(key, "v2")); ASSERT_EQ("v2", Get(key)); ASSERT_EQ("v1", Get(key, s1)); dbfull()->TEST_CompactMemTable(); ASSERT_EQ("v2", Get(key)); ASSERT_EQ("v1", Get(key, s1)); db_->ReleaseSnapshot(s1); } } while (ChangeOptions()); } TEST(DBTest, GetLevel0Ordering) { do { // Check that we process level-0 files in correct order. The code // below generates two level-0 files where the earlier one comes // before the later one in the level-0 file list since the earlier // one has a smaller "smallest" key. ASSERT_OK(Put("bar", "b")); ASSERT_OK(Put("foo", "v1")); dbfull()->TEST_CompactMemTable(); ASSERT_OK(Put("foo", "v2")); dbfull()->TEST_CompactMemTable(); ASSERT_EQ("v2", Get("foo")); } while (ChangeOptions()); } TEST(DBTest, GetOrderedByLevels) { do { ASSERT_OK(Put("foo", "v1")); Compact("a", "z"); ASSERT_EQ("v1", Get("foo")); ASSERT_OK(Put("foo", "v2")); ASSERT_EQ("v2", Get("foo")); dbfull()->TEST_CompactMemTable(); ASSERT_EQ("v2", Get("foo")); } while (ChangeOptions()); } TEST(DBTest, GetPicksCorrectFile) { do { // Arrange to have multiple files in a non-level-0 level. ASSERT_OK(Put("a", "va")); Compact("a", "b"); ASSERT_OK(Put("x", "vx")); Compact("x", "y"); ASSERT_OK(Put("f", "vf")); Compact("f", "g"); ASSERT_EQ("va", Get("a")); ASSERT_EQ("vf", Get("f")); ASSERT_EQ("vx", Get("x")); } while (ChangeOptions()); } TEST(DBTest, GetEncountersEmptyLevel) { do { // Arrange for the following to happen: // * sstable A in level 0 // * nothing in level 1 // * sstable B in level 2 // Then do enough Get() calls to arrange for an automatic compaction // of sstable A. A bug would cause the compaction to be marked as // occurring at level 1 (instead of the correct level 0). // Step 1: First place sstables in levels 0 and 2 int compaction_count = 0; while (NumTableFilesAtLevel(0) == 0 || NumTableFilesAtLevel(2) == 0) { ASSERT_LE(compaction_count, 100) << "could not fill levels 0 and 2"; compaction_count++; Put("a", "begin"); Put("z", "end"); dbfull()->TEST_CompactMemTable(); } // Step 2: clear level 1 if necessary. dbfull()->TEST_CompactRange(1, NULL, NULL); ASSERT_EQ(NumTableFilesAtLevel(0), 1); ASSERT_EQ(NumTableFilesAtLevel(1), 0); ASSERT_EQ(NumTableFilesAtLevel(2), 1); // Step 3: read a bunch of times for (int i = 0; i < 1000; i++) { ASSERT_EQ("NOT_FOUND", Get("missing")); } // Step 4: Wait for compaction to finish DelayMilliseconds(1000); ASSERT_EQ(NumTableFilesAtLevel(0), 0); } while (ChangeOptions()); } TEST(DBTest, IterEmpty) { Iterator* iter = db_->NewIterator(ReadOptions()); iter->SeekToFirst(); ASSERT_EQ(IterStatus(iter), "(invalid)"); iter->SeekToLast(); ASSERT_EQ(IterStatus(iter), "(invalid)"); iter->Seek("foo"); ASSERT_EQ(IterStatus(iter), "(invalid)"); delete iter; } TEST(DBTest, IterSingle) { ASSERT_OK(Put("a", "va")); Iterator* iter = db_->NewIterator(ReadOptions()); iter->SeekToFirst(); ASSERT_EQ(IterStatus(iter), "a->va"); iter->Next(); ASSERT_EQ(IterStatus(iter), "(invalid)"); iter->SeekToFirst(); ASSERT_EQ(IterStatus(iter), "a->va"); iter->Prev(); ASSERT_EQ(IterStatus(iter), "(invalid)"); iter->SeekToLast(); ASSERT_EQ(IterStatus(iter), "a->va"); iter->Next(); ASSERT_EQ(IterStatus(iter), "(invalid)"); iter->SeekToLast(); ASSERT_EQ(IterStatus(iter), "a->va"); iter->Prev(); ASSERT_EQ(IterStatus(iter), "(invalid)"); iter->Seek(""); ASSERT_EQ(IterStatus(iter), "a->va"); iter->Next(); ASSERT_EQ(IterStatus(iter), "(invalid)"); iter->Seek("a"); ASSERT_EQ(IterStatus(iter), "a->va"); iter->Next(); ASSERT_EQ(IterStatus(iter), "(invalid)"); iter->Seek("b"); ASSERT_EQ(IterStatus(iter), "(invalid)"); delete iter; } TEST(DBTest, IterMulti) { ASSERT_OK(Put("a", "va")); ASSERT_OK(Put("b", "vb")); ASSERT_OK(Put("c", "vc")); Iterator* iter = db_->NewIterator(ReadOptions()); iter->SeekToFirst(); ASSERT_EQ(IterStatus(iter), "a->va"); iter->Next(); ASSERT_EQ(IterStatus(iter), "b->vb"); iter->Next(); ASSERT_EQ(IterStatus(iter), "c->vc"); iter->Next(); ASSERT_EQ(IterStatus(iter), "(invalid)"); iter->SeekToFirst(); ASSERT_EQ(IterStatus(iter), "a->va"); iter->Prev(); ASSERT_EQ(IterStatus(iter), "(invalid)"); iter->SeekToLast(); ASSERT_EQ(IterStatus(iter), "c->vc"); iter->Prev(); ASSERT_EQ(IterStatus(iter), "b->vb"); iter->Prev(); ASSERT_EQ(IterStatus(iter), "a->va"); iter->Prev(); ASSERT_EQ(IterStatus(iter), "(invalid)"); iter->SeekToLast(); ASSERT_EQ(IterStatus(iter), "c->vc"); iter->Next(); ASSERT_EQ(IterStatus(iter), "(invalid)"); iter->Seek(""); ASSERT_EQ(IterStatus(iter), "a->va"); iter->Seek("a"); ASSERT_EQ(IterStatus(iter), "a->va"); iter->Seek("ax"); ASSERT_EQ(IterStatus(iter), "b->vb"); iter->Seek("b"); ASSERT_EQ(IterStatus(iter), "b->vb"); iter->Seek("z"); ASSERT_EQ(IterStatus(iter), "(invalid)"); // Switch from reverse to forward iter->SeekToLast(); iter->Prev(); iter->Prev(); iter->Next(); ASSERT_EQ(IterStatus(iter), "b->vb"); // Switch from forward to reverse iter->SeekToFirst(); iter->Next(); iter->Next(); iter->Prev(); ASSERT_EQ(IterStatus(iter), "b->vb"); // Make sure iter stays at snapshot ASSERT_OK(Put("a", "va2")); ASSERT_OK(Put("a2", "va3")); ASSERT_OK(Put("b", "vb2")); ASSERT_OK(Put("c", "vc2")); ASSERT_OK(Delete("b")); iter->SeekToFirst(); ASSERT_EQ(IterStatus(iter), "a->va"); iter->Next(); ASSERT_EQ(IterStatus(iter), "b->vb"); iter->Next(); ASSERT_EQ(IterStatus(iter), "c->vc"); iter->Next(); ASSERT_EQ(IterStatus(iter), "(invalid)"); iter->SeekToLast(); ASSERT_EQ(IterStatus(iter), "c->vc"); iter->Prev(); ASSERT_EQ(IterStatus(iter), "b->vb"); iter->Prev(); ASSERT_EQ(IterStatus(iter), "a->va"); iter->Prev(); ASSERT_EQ(IterStatus(iter), "(invalid)"); delete iter; } TEST(DBTest, IterSmallAndLargeMix) { ASSERT_OK(Put("a", "va")); ASSERT_OK(Put("b", std::string(100000, 'b'))); ASSERT_OK(Put("c", "vc")); ASSERT_OK(Put("d", std::string(100000, 'd'))); ASSERT_OK(Put("e", std::string(100000, 'e'))); Iterator* iter = db_->NewIterator(ReadOptions()); iter->SeekToFirst(); ASSERT_EQ(IterStatus(iter), "a->va"); iter->Next(); ASSERT_EQ(IterStatus(iter), "b->" + std::string(100000, 'b')); iter->Next(); ASSERT_EQ(IterStatus(iter), "c->vc"); iter->Next(); ASSERT_EQ(IterStatus(iter), "d->" + std::string(100000, 'd')); iter->Next(); ASSERT_EQ(IterStatus(iter), "e->" + std::string(100000, 'e')); iter->Next(); ASSERT_EQ(IterStatus(iter), "(invalid)"); iter->SeekToLast(); ASSERT_EQ(IterStatus(iter), "e->" + std::string(100000, 'e')); iter->Prev(); ASSERT_EQ(IterStatus(iter), "d->" + std::string(100000, 'd')); iter->Prev(); ASSERT_EQ(IterStatus(iter), "c->vc"); iter->Prev(); ASSERT_EQ(IterStatus(iter), "b->" + std::string(100000, 'b')); iter->Prev(); ASSERT_EQ(IterStatus(iter), "a->va"); iter->Prev(); ASSERT_EQ(IterStatus(iter), "(invalid)"); delete iter; } TEST(DBTest, IterMultiWithDelete) { do { ASSERT_OK(Put("a", "va")); ASSERT_OK(Put("b", "vb")); ASSERT_OK(Put("c", "vc")); ASSERT_OK(Delete("b")); ASSERT_EQ("NOT_FOUND", Get("b")); Iterator* iter = db_->NewIterator(ReadOptions()); iter->Seek("c"); ASSERT_EQ(IterStatus(iter), "c->vc"); iter->Prev(); ASSERT_EQ(IterStatus(iter), "a->va"); delete iter; } while (ChangeOptions()); } TEST(DBTest, Recover) { do { ASSERT_OK(Put("foo", "v1")); ASSERT_OK(Put("baz", "v5")); Reopen(); ASSERT_EQ("v1", Get("foo")); ASSERT_EQ("v1", Get("foo")); ASSERT_EQ("v5", Get("baz")); ASSERT_OK(Put("bar", "v2")); ASSERT_OK(Put("foo", "v3")); Reopen(); ASSERT_EQ("v3", Get("foo")); ASSERT_OK(Put("foo", "v4")); ASSERT_EQ("v4", Get("foo")); ASSERT_EQ("v2", Get("bar")); ASSERT_EQ("v5", Get("baz")); } while (ChangeOptions()); } TEST(DBTest, RecoveryWithEmptyLog) { do { ASSERT_OK(Put("foo", "v1")); ASSERT_OK(Put("foo", "v2")); Reopen(); Reopen(); ASSERT_OK(Put("foo", "v3")); Reopen(); ASSERT_EQ("v3", Get("foo")); } while (ChangeOptions()); } // Check that writes done during a memtable compaction are recovered // if the database is shutdown during the memtable compaction. TEST(DBTest, RecoverDuringMemtableCompaction) { do { Options options = CurrentOptions(); options.env = env_; options.write_buffer_size = 1000000; Reopen(&options); // Trigger a long memtable compaction and reopen the database during it ASSERT_OK(Put("foo", "v1")); // Goes to 1st log file ASSERT_OK(Put("big1", std::string(10000000, 'x'))); // Fills memtable ASSERT_OK(Put("big2", std::string(1000, 'y'))); // Triggers compaction ASSERT_OK(Put("bar", "v2")); // Goes to new log file Reopen(&options); ASSERT_EQ("v1", Get("foo")); ASSERT_EQ("v2", Get("bar")); ASSERT_EQ(std::string(10000000, 'x'), Get("big1")); ASSERT_EQ(std::string(1000, 'y'), Get("big2")); } while (ChangeOptions()); } static std::string Key(int i) { char buf[100]; snprintf(buf, sizeof(buf), "key%06d", i); return std::string(buf); } TEST(DBTest, MinorCompactionsHappen) { Options options = CurrentOptions(); options.write_buffer_size = 10000; Reopen(&options); const int N = 500; int starting_num_tables = TotalTableFiles(); for (int i = 0; i < N; i++) { ASSERT_OK(Put(Key(i), Key(i) + std::string(1000, 'v'))); } int ending_num_tables = TotalTableFiles(); ASSERT_GT(ending_num_tables, starting_num_tables); for (int i = 0; i < N; i++) { ASSERT_EQ(Key(i) + std::string(1000, 'v'), Get(Key(i))); } Reopen(); for (int i = 0; i < N; i++) { ASSERT_EQ(Key(i) + std::string(1000, 'v'), Get(Key(i))); } } TEST(DBTest, RecoverWithLargeLog) { { Options options = CurrentOptions(); Reopen(&options); ASSERT_OK(Put("big1", std::string(200000, '1'))); ASSERT_OK(Put("big2", std::string(200000, '2'))); ASSERT_OK(Put("small3", std::string(10, '3'))); ASSERT_OK(Put("small4", std::string(10, '4'))); ASSERT_EQ(NumTableFilesAtLevel(0), 0); } // Make sure that if we re-open with a small write buffer size that // we flush table files in the middle of a large log file. Options options = CurrentOptions(); options.write_buffer_size = 100000; Reopen(&options); ASSERT_EQ(NumTableFilesAtLevel(0), 3); ASSERT_EQ(std::string(200000, '1'), Get("big1")); ASSERT_EQ(std::string(200000, '2'), Get("big2")); ASSERT_EQ(std::string(10, '3'), Get("small3")); ASSERT_EQ(std::string(10, '4'), Get("small4")); ASSERT_GT(NumTableFilesAtLevel(0), 1); } TEST(DBTest, CompactionsGenerateMultipleFiles) { Options options = CurrentOptions(); options.write_buffer_size = 100000000; // Large write buffer Reopen(&options); Random rnd(301); // Write 8MB (80 values, each 100K) ASSERT_EQ(NumTableFilesAtLevel(0), 0); std::vector values; for (int i = 0; i < 80; i++) { values.push_back(RandomString(&rnd, 100000)); ASSERT_OK(Put(Key(i), values[i])); } // Reopening moves updates to level-0 Reopen(&options); dbfull()->TEST_CompactRange(0, NULL, NULL); ASSERT_EQ(NumTableFilesAtLevel(0), 0); ASSERT_GT(NumTableFilesAtLevel(1), 1); for (int i = 0; i < 80; i++) { ASSERT_EQ(Get(Key(i)), values[i]); } } TEST(DBTest, RepeatedWritesToSameKey) { Options options = CurrentOptions(); options.env = env_; options.write_buffer_size = 100000; // Small write buffer Reopen(&options); // We must have at most one file per level except for level-0, // which may have up to kL0_StopWritesTrigger files. const int kMaxFiles = config::kNumLevels + config::kL0_StopWritesTrigger; Random rnd(301); std::string value = RandomString(&rnd, 2 * options.write_buffer_size); for (int i = 0; i < 5 * kMaxFiles; i++) { Put("key", value); ASSERT_LE(TotalTableFiles(), kMaxFiles); fprintf(stderr, "after %d: %d files\n", int(i+1), TotalTableFiles()); } } TEST(DBTest, SparseMerge) { Options options = CurrentOptions(); options.compression = kNoCompression; Reopen(&options); FillLevels("A", "Z"); // Suppose there is: // small amount of data with prefix A // large amount of data with prefix B // small amount of data with prefix C // and that recent updates have made small changes to all three prefixes. // Check that we do not do a compaction that merges all of B in one shot. const std::string value(1000, 'x'); Put("A", "va"); // Write approximately 100MB of "B" values for (int i = 0; i < 100000; i++) { char key[100]; snprintf(key, sizeof(key), "B%010d", i); Put(key, value); } Put("C", "vc"); dbfull()->TEST_CompactMemTable(); dbfull()->TEST_CompactRange(0, NULL, NULL); // Make sparse update Put("A", "va2"); Put("B100", "bvalue2"); Put("C", "vc2"); dbfull()->TEST_CompactMemTable(); // Compactions should not cause us to create a situation where // a file overlaps too much data at the next level. ASSERT_LE(dbfull()->TEST_MaxNextLevelOverlappingBytes(), 20*1048576); dbfull()->TEST_CompactRange(0, NULL, NULL); ASSERT_LE(dbfull()->TEST_MaxNextLevelOverlappingBytes(), 20*1048576); dbfull()->TEST_CompactRange(1, NULL, NULL); ASSERT_LE(dbfull()->TEST_MaxNextLevelOverlappingBytes(), 20*1048576); } 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; } TEST(DBTest, ApproximateSizes) { do { Options options = CurrentOptions(); options.write_buffer_size = 100000000; // Large write buffer options.compression = kNoCompression; DestroyAndReopen(); ASSERT_TRUE(Between(Size("", "xyz"), 0, 0)); Reopen(&options); ASSERT_TRUE(Between(Size("", "xyz"), 0, 0)); // Write 8MB (80 values, each 100K) ASSERT_EQ(NumTableFilesAtLevel(0), 0); const int N = 80; static const int S1 = 100000; static const int S2 = 105000; // Allow some expansion from metadata Random rnd(301); for (int i = 0; i < N; i++) { ASSERT_OK(Put(Key(i), RandomString(&rnd, S1))); } // 0 because GetApproximateSizes() does not account for memtable space ASSERT_TRUE(Between(Size("", Key(50)), 0, 0)); // Check sizes across recovery by reopening a few times for (int run = 0; run < 3; run++) { Reopen(&options); for (int compact_start = 0; compact_start < N; compact_start += 10) { for (int i = 0; i < N; i += 10) { ASSERT_TRUE(Between(Size("", Key(i)), S1*i, S2*i)); ASSERT_TRUE(Between(Size("", Key(i)+".suffix"), S1*(i+1), S2*(i+1))); ASSERT_TRUE(Between(Size(Key(i), Key(i+10)), S1*10, S2*10)); } ASSERT_TRUE(Between(Size("", Key(50)), S1*50, S2*50)); ASSERT_TRUE(Between(Size("", Key(50)+".suffix"), S1*50, S2*50)); std::string cstart_str = Key(compact_start); std::string cend_str = Key(compact_start + 9); Slice cstart = cstart_str; Slice cend = cend_str; dbfull()->TEST_CompactRange(0, &cstart, &cend); } ASSERT_EQ(NumTableFilesAtLevel(0), 0); ASSERT_GT(NumTableFilesAtLevel(1), 0); } } while (ChangeOptions()); } TEST(DBTest, ApproximateSizes_MixOfSmallAndLarge) { do { Options options = CurrentOptions(); options.compression = kNoCompression; Reopen(); Random rnd(301); std::string big1 = RandomString(&rnd, 100000); ASSERT_OK(Put(Key(0), RandomString(&rnd, 10000))); ASSERT_OK(Put(Key(1), RandomString(&rnd, 10000))); ASSERT_OK(Put(Key(2), big1)); ASSERT_OK(Put(Key(3), RandomString(&rnd, 10000))); ASSERT_OK(Put(Key(4), big1)); ASSERT_OK(Put(Key(5), RandomString(&rnd, 10000))); ASSERT_OK(Put(Key(6), RandomString(&rnd, 300000))); ASSERT_OK(Put(Key(7), RandomString(&rnd, 10000))); // Check sizes across recovery by reopening a few times for (int run = 0; run < 3; run++) { Reopen(&options); ASSERT_TRUE(Between(Size("", Key(0)), 0, 0)); ASSERT_TRUE(Between(Size("", Key(1)), 10000, 11000)); ASSERT_TRUE(Between(Size("", Key(2)), 20000, 21000)); ASSERT_TRUE(Between(Size("", Key(3)), 120000, 121000)); ASSERT_TRUE(Between(Size("", Key(4)), 130000, 131000)); ASSERT_TRUE(Between(Size("", Key(5)), 230000, 231000)); ASSERT_TRUE(Between(Size("", Key(6)), 240000, 241000)); ASSERT_TRUE(Between(Size("", Key(7)), 540000, 541000)); ASSERT_TRUE(Between(Size("", Key(8)), 550000, 560000)); ASSERT_TRUE(Between(Size(Key(3), Key(5)), 110000, 111000)); dbfull()->TEST_CompactRange(0, NULL, NULL); } } while (ChangeOptions()); } TEST(DBTest, IteratorPinsRef) { Put("foo", "hello"); // Get iterator that will yield the current contents of the DB. Iterator* iter = db_->NewIterator(ReadOptions()); // Write to force compactions Put("foo", "newvalue1"); for (int i = 0; i < 100; i++) { ASSERT_OK(Put(Key(i), Key(i) + std::string(100000, 'v'))); // 100K values } Put("foo", "newvalue2"); iter->SeekToFirst(); ASSERT_TRUE(iter->Valid()); ASSERT_EQ("foo", iter->key().ToString()); ASSERT_EQ("hello", iter->value().ToString()); iter->Next(); ASSERT_TRUE(!iter->Valid()); delete iter; } TEST(DBTest, Snapshot) { do { Put("foo", "v1"); const Snapshot* s1 = db_->GetSnapshot(); Put("foo", "v2"); const Snapshot* s2 = db_->GetSnapshot(); Put("foo", "v3"); const Snapshot* s3 = db_->GetSnapshot(); Put("foo", "v4"); ASSERT_EQ("v1", Get("foo", s1)); ASSERT_EQ("v2", Get("foo", s2)); ASSERT_EQ("v3", Get("foo", s3)); ASSERT_EQ("v4", Get("foo")); db_->ReleaseSnapshot(s3); ASSERT_EQ("v1", Get("foo", s1)); ASSERT_EQ("v2", Get("foo", s2)); ASSERT_EQ("v4", Get("foo")); db_->ReleaseSnapshot(s1); ASSERT_EQ("v2", Get("foo", s2)); ASSERT_EQ("v4", Get("foo")); db_->ReleaseSnapshot(s2); ASSERT_EQ("v4", Get("foo")); } while (ChangeOptions()); } TEST(DBTest, HiddenValuesAreRemoved) { do { Random rnd(301); FillLevels("a", "z"); std::string big = RandomString(&rnd, 50000); Put("foo", big); Put("pastfoo", "v"); const Snapshot* snapshot = db_->GetSnapshot(); Put("foo", "tiny"); Put("pastfoo2", "v2"); // Advance sequence number one more ASSERT_OK(dbfull()->TEST_CompactMemTable()); ASSERT_GT(NumTableFilesAtLevel(0), 0); ASSERT_EQ(big, Get("foo", snapshot)); ASSERT_TRUE(Between(Size("", "pastfoo"), 50000, 60000)); db_->ReleaseSnapshot(snapshot); ASSERT_EQ(AllEntriesFor("foo"), "[ tiny, " + big + " ]"); Slice x("x"); dbfull()->TEST_CompactRange(0, NULL, &x); ASSERT_EQ(AllEntriesFor("foo"), "[ tiny ]"); ASSERT_EQ(NumTableFilesAtLevel(0), 0); ASSERT_GE(NumTableFilesAtLevel(1), 1); dbfull()->TEST_CompactRange(1, NULL, &x); ASSERT_EQ(AllEntriesFor("foo"), "[ tiny ]"); ASSERT_TRUE(Between(Size("", "pastfoo"), 0, 1000)); } while (ChangeOptions()); } TEST(DBTest, DeletionMarkers1) { Put("foo", "v1"); ASSERT_OK(dbfull()->TEST_CompactMemTable()); const int last = config::kMaxMemCompactLevel; ASSERT_EQ(NumTableFilesAtLevel(last), 1); // foo => v1 is now in last level // Place a table at level last-1 to prevent merging with preceding mutation Put("a", "begin"); Put("z", "end"); dbfull()->TEST_CompactMemTable(); ASSERT_EQ(NumTableFilesAtLevel(last), 1); ASSERT_EQ(NumTableFilesAtLevel(last-1), 1); Delete("foo"); Put("foo", "v2"); ASSERT_EQ(AllEntriesFor("foo"), "[ v2, DEL, v1 ]"); ASSERT_OK(dbfull()->TEST_CompactMemTable()); // Moves to level last-2 ASSERT_EQ(AllEntriesFor("foo"), "[ v2, DEL, v1 ]"); Slice z("z"); dbfull()->TEST_CompactRange(last-2, NULL, &z); // DEL eliminated, but v1 remains because we aren't compacting that level // (DEL can be eliminated because v2 hides v1). ASSERT_EQ(AllEntriesFor("foo"), "[ v2, v1 ]"); dbfull()->TEST_CompactRange(last-1, NULL, NULL); // Merging last-1 w/ last, so we are the base level for "foo", so // DEL is removed. (as is v1). ASSERT_EQ(AllEntriesFor("foo"), "[ v2 ]"); } TEST(DBTest, DeletionMarkers2) { Put("foo", "v1"); ASSERT_OK(dbfull()->TEST_CompactMemTable()); const int last = config::kMaxMemCompactLevel; ASSERT_EQ(NumTableFilesAtLevel(last), 1); // foo => v1 is now in last level // Place a table at level last-1 to prevent merging with preceding mutation Put("a", "begin"); Put("z", "end"); dbfull()->TEST_CompactMemTable(); ASSERT_EQ(NumTableFilesAtLevel(last), 1); ASSERT_EQ(NumTableFilesAtLevel(last-1), 1); Delete("foo"); ASSERT_EQ(AllEntriesFor("foo"), "[ DEL, v1 ]"); ASSERT_OK(dbfull()->TEST_CompactMemTable()); // Moves to level last-2 ASSERT_EQ(AllEntriesFor("foo"), "[ DEL, v1 ]"); dbfull()->TEST_CompactRange(last-2, NULL, NULL); // DEL kept: "last" file overlaps ASSERT_EQ(AllEntriesFor("foo"), "[ DEL, v1 ]"); dbfull()->TEST_CompactRange(last-1, NULL, NULL); // Merging last-1 w/ last, so we are the base level for "foo", so // DEL is removed. (as is v1). ASSERT_EQ(AllEntriesFor("foo"), "[ ]"); } TEST(DBTest, OverlapInLevel0) { do { ASSERT_EQ(config::kMaxMemCompactLevel, 2) << "Fix test to match config"; // Fill levels 1 and 2 to disable the pushing of new memtables to levels > 0. ASSERT_OK(Put("100", "v100")); ASSERT_OK(Put("999", "v999")); dbfull()->TEST_CompactMemTable(); ASSERT_OK(Delete("100")); ASSERT_OK(Delete("999")); dbfull()->TEST_CompactMemTable(); ASSERT_EQ("0,1,1", FilesPerLevel()); // Make files spanning the following ranges in level-0: // files[0] 200 .. 900 // files[1] 300 .. 500 // Note that files are sorted by smallest key. ASSERT_OK(Put("300", "v300")); ASSERT_OK(Put("500", "v500")); dbfull()->TEST_CompactMemTable(); ASSERT_OK(Put("200", "v200")); ASSERT_OK(Put("600", "v600")); ASSERT_OK(Put("900", "v900")); dbfull()->TEST_CompactMemTable(); ASSERT_EQ("2,1,1", FilesPerLevel()); // Compact away the placeholder files we created initially dbfull()->TEST_CompactRange(1, NULL, NULL); dbfull()->TEST_CompactRange(2, NULL, NULL); ASSERT_EQ("2", FilesPerLevel()); // Do a memtable compaction. Before bug-fix, the compaction would // not detect the overlap with level-0 files and would incorrectly place // the deletion in a deeper level. ASSERT_OK(Delete("600")); dbfull()->TEST_CompactMemTable(); ASSERT_EQ("3", FilesPerLevel()); ASSERT_EQ("NOT_FOUND", Get("600")); } while (ChangeOptions()); } TEST(DBTest, L0_CompactionBug_Issue44_a) { Reopen(); ASSERT_OK(Put("b", "v")); Reopen(); ASSERT_OK(Delete("b")); ASSERT_OK(Delete("a")); Reopen(); ASSERT_OK(Delete("a")); Reopen(); ASSERT_OK(Put("a", "v")); Reopen(); Reopen(); ASSERT_EQ("(a->v)", Contents()); DelayMilliseconds(1000); // Wait for compaction to finish ASSERT_EQ("(a->v)", Contents()); } TEST(DBTest, L0_CompactionBug_Issue44_b) { Reopen(); Put("",""); Reopen(); Delete("e"); Put("",""); Reopen(); Put("c", "cv"); Reopen(); Put("",""); Reopen(); Put("",""); DelayMilliseconds(1000); // Wait for compaction to finish Reopen(); Put("d","dv"); Reopen(); Put("",""); Reopen(); Delete("d"); Delete("b"); Reopen(); ASSERT_EQ("(->)(c->cv)", Contents()); DelayMilliseconds(1000); // Wait for compaction to finish ASSERT_EQ("(->)(c->cv)", Contents()); } TEST(DBTest, ComparatorCheck) { class NewComparator : public Comparator { public: virtual const char* Name() const { return "leveldb.NewComparator"; } virtual int Compare(const Slice& a, const Slice& b) const { return BytewiseComparator()->Compare(a, b); } virtual void FindShortestSeparator(std::string* s, const Slice& l) const { BytewiseComparator()->FindShortestSeparator(s, l); } virtual void FindShortSuccessor(std::string* key) const { BytewiseComparator()->FindShortSuccessor(key); } }; NewComparator cmp; Options new_options = CurrentOptions(); new_options.comparator = &cmp; Status s = TryReopen(&new_options); ASSERT_TRUE(!s.ok()); ASSERT_TRUE(s.ToString().find("comparator") != std::string::npos) << s.ToString(); } TEST(DBTest, CustomComparator) { class NumberComparator : public Comparator { public: virtual const char* Name() const { return "test.NumberComparator"; } virtual int Compare(const Slice& a, const Slice& b) const { return ToNumber(a) - ToNumber(b); } virtual void FindShortestSeparator(std::string* s, const Slice& l) const { ToNumber(*s); // Check format ToNumber(l); // Check format } virtual void FindShortSuccessor(std::string* key) const { ToNumber(*key); // Check format } private: static int ToNumber(const Slice& x) { // Check that there are no extra characters. ASSERT_TRUE(x.size() >= 2 && x[0] == '[' && x[x.size()-1] == ']') << EscapeString(x); int val; char ignored; ASSERT_TRUE(sscanf(x.ToString().c_str(), "[%i]%c", &val, &ignored) == 1) << EscapeString(x); return val; } }; NumberComparator cmp; Options new_options = CurrentOptions(); new_options.create_if_missing = true; new_options.comparator = &cmp; new_options.filter_policy = NULL; // Cannot use bloom filters new_options.write_buffer_size = 1000; // Compact more often DestroyAndReopen(&new_options); ASSERT_OK(Put("[10]", "ten")); ASSERT_OK(Put("[0x14]", "twenty")); for (int i = 0; i < 2; i++) { ASSERT_EQ("ten", Get("[10]")); ASSERT_EQ("ten", Get("[0xa]")); ASSERT_EQ("twenty", Get("[20]")); ASSERT_EQ("twenty", Get("[0x14]")); ASSERT_EQ("NOT_FOUND", Get("[15]")); ASSERT_EQ("NOT_FOUND", Get("[0xf]")); Compact("[0]", "[9999]"); } for (int run = 0; run < 2; run++) { for (int i = 0; i < 1000; i++) { char buf[100]; snprintf(buf, sizeof(buf), "[%d]", i*10); ASSERT_OK(Put(buf, buf)); } Compact("[0]", "[1000000]"); } } TEST(DBTest, ManualCompaction) { ASSERT_EQ(config::kMaxMemCompactLevel, 2) << "Need to update this test to match kMaxMemCompactLevel"; MakeTables(3, "p", "q"); ASSERT_EQ("1,1,1", FilesPerLevel()); // Compaction range falls before files Compact("", "c"); ASSERT_EQ("1,1,1", FilesPerLevel()); // Compaction range falls after files Compact("r", "z"); ASSERT_EQ("1,1,1", FilesPerLevel()); // Compaction range overlaps files Compact("p1", "p9"); ASSERT_EQ("0,0,1", FilesPerLevel()); // Populate a different range MakeTables(3, "c", "e"); ASSERT_EQ("1,1,2", FilesPerLevel()); // Compact just the new range Compact("b", "f"); ASSERT_EQ("0,0,2", FilesPerLevel()); // Compact all MakeTables(1, "a", "z"); ASSERT_EQ("0,1,2", FilesPerLevel()); db_->CompactRange(NULL, NULL); ASSERT_EQ("0,0,1", FilesPerLevel()); } TEST(DBTest, DBOpen_Options) { std::string dbname = test::TmpDir() + "/db_options_test"; DestroyDB(dbname, Options()); // Does not exist, and create_if_missing == false: error DB* db = NULL; Options opts; opts.create_if_missing = false; Status s = DB::Open(opts, dbname, &db); ASSERT_TRUE(strstr(s.ToString().c_str(), "does not exist") != NULL); ASSERT_TRUE(db == NULL); // Does not exist, and create_if_missing == true: OK opts.create_if_missing = true; s = DB::Open(opts, dbname, &db); ASSERT_OK(s); ASSERT_TRUE(db != NULL); delete db; db = NULL; // Does exist, and error_if_exists == true: error opts.create_if_missing = false; opts.error_if_exists = true; s = DB::Open(opts, dbname, &db); ASSERT_TRUE(strstr(s.ToString().c_str(), "exists") != NULL); ASSERT_TRUE(db == NULL); // Does exist, and error_if_exists == false: OK opts.create_if_missing = true; opts.error_if_exists = false; s = DB::Open(opts, dbname, &db); ASSERT_OK(s); ASSERT_TRUE(db != NULL); delete db; db = NULL; } TEST(DBTest, Locking) { DB* db2 = NULL; Status s = DB::Open(CurrentOptions(), dbname_, &db2); ASSERT_TRUE(!s.ok()) << "Locking did not prevent re-opening db"; } // Check that number of files does not grow when we are out of space TEST(DBTest, NoSpace) { Options options = CurrentOptions(); options.env = env_; Reopen(&options); ASSERT_OK(Put("foo", "v1")); ASSERT_EQ("v1", Get("foo")); Compact("a", "z"); const int num_files = CountFiles(); env_->no_space_.Release_Store(env_); // Force out-of-space errors for (int i = 0; i < 10; i++) { for (int level = 0; level < config::kNumLevels-1; level++) { dbfull()->TEST_CompactRange(level, NULL, NULL); } } env_->no_space_.Release_Store(NULL); ASSERT_LT(CountFiles(), num_files + 3); } TEST(DBTest, NonWritableFileSystem) { Options options = CurrentOptions(); options.write_buffer_size = 1000; options.env = env_; Reopen(&options); ASSERT_OK(Put("foo", "v1")); env_->non_writable_.Release_Store(env_); // Force errors for new files std::string big(100000, 'x'); int errors = 0; for (int i = 0; i < 20; i++) { fprintf(stderr, "iter %d; errors %d\n", i, errors); if (!Put("foo", big).ok()) { errors++; DelayMilliseconds(100); } } ASSERT_GT(errors, 0); env_->non_writable_.Release_Store(NULL); } TEST(DBTest, WriteSyncError) { // Check that log sync errors cause the DB to disallow future writes. // (a) Cause log sync calls to fail Options options = CurrentOptions(); options.env = env_; Reopen(&options); env_->data_sync_error_.Release_Store(env_); // (b) Normal write should succeed WriteOptions w; ASSERT_OK(db_->Put(w, "k1", "v1")); ASSERT_EQ("v1", Get("k1")); // (c) Do a sync write; should fail w.sync = true; ASSERT_TRUE(!db_->Put(w, "k2", "v2").ok()); ASSERT_EQ("v1", Get("k1")); ASSERT_EQ("NOT_FOUND", Get("k2")); // (d) make sync behave normally env_->data_sync_error_.Release_Store(NULL); // (e) Do a non-sync write; should fail w.sync = false; ASSERT_TRUE(!db_->Put(w, "k3", "v3").ok()); ASSERT_EQ("v1", Get("k1")); ASSERT_EQ("NOT_FOUND", Get("k2")); ASSERT_EQ("NOT_FOUND", Get("k3")); } TEST(DBTest, ManifestWriteError) { // Test for the following problem: // (a) Compaction produces file F // (b) Log record containing F is written to MANIFEST file, but Sync() fails // (c) GC deletes F // (d) After reopening DB, reads fail since deleted F is named in log record // We iterate twice. In the second iteration, everything is the // same except the log record never makes it to the MANIFEST file. for (int iter = 0; iter < 2; iter++) { port::AtomicPointer* error_type = (iter == 0) ? &env_->manifest_sync_error_ : &env_->manifest_write_error_; // Insert foo=>bar mapping Options options = CurrentOptions(); options.env = env_; options.create_if_missing = true; options.error_if_exists = false; DestroyAndReopen(&options); ASSERT_OK(Put("foo", "bar")); ASSERT_EQ("bar", Get("foo")); // Memtable compaction (will succeed) dbfull()->TEST_CompactMemTable(); ASSERT_EQ("bar", Get("foo")); const int last = config::kMaxMemCompactLevel; ASSERT_EQ(NumTableFilesAtLevel(last), 1); // foo=>bar is now in last level // Merging compaction (will fail) error_type->Release_Store(env_); dbfull()->TEST_CompactRange(last, NULL, NULL); // Should fail ASSERT_EQ("bar", Get("foo")); // Recovery: should not lose data error_type->Release_Store(NULL); Reopen(&options); ASSERT_EQ("bar", Get("foo")); } } TEST(DBTest, MissingSSTFile) { ASSERT_OK(Put("foo", "bar")); ASSERT_EQ("bar", Get("foo")); // Dump the memtable to disk. dbfull()->TEST_CompactMemTable(); ASSERT_EQ("bar", Get("foo")); Close(); ASSERT_TRUE(DeleteAnSSTFile()); Options options = CurrentOptions(); options.paranoid_checks = true; Status s = TryReopen(&options); ASSERT_TRUE(!s.ok()); ASSERT_TRUE(s.ToString().find("issing") != std::string::npos) << s.ToString(); } TEST(DBTest, StillReadSST) { ASSERT_OK(Put("foo", "bar")); ASSERT_EQ("bar", Get("foo")); // Dump the memtable to disk. dbfull()->TEST_CompactMemTable(); ASSERT_EQ("bar", Get("foo")); Close(); ASSERT_GT(RenameLDBToSST(), 0); Options options = CurrentOptions(); options.paranoid_checks = true; Status s = TryReopen(&options); ASSERT_TRUE(s.ok()); ASSERT_EQ("bar", Get("foo")); } TEST(DBTest, FilesDeletedAfterCompaction) { ASSERT_OK(Put("foo", "v2")); Compact("a", "z"); const int num_files = CountFiles(); for (int i = 0; i < 10; i++) { ASSERT_OK(Put("foo", "v2")); Compact("a", "z"); } ASSERT_EQ(CountFiles(), num_files); } TEST(DBTest, BloomFilter) { env_->count_random_reads_ = true; Options options = CurrentOptions(); options.env = env_; options.block_cache = NewLRUCache(0); // Prevent cache hits options.filter_policy = NewBloomFilterPolicy(10); Reopen(&options); // Populate multiple layers const int N = 10000; for (int i = 0; i < N; i++) { ASSERT_OK(Put(Key(i), Key(i))); } Compact("a", "z"); for (int i = 0; i < N; i += 100) { ASSERT_OK(Put(Key(i), Key(i))); } dbfull()->TEST_CompactMemTable(); // Prevent auto compactions triggered by seeks env_->delay_data_sync_.Release_Store(env_); // Lookup present keys. Should rarely read from small sstable. env_->random_read_counter_.Reset(); for (int i = 0; i < N; i++) { ASSERT_EQ(Key(i), Get(Key(i))); } int reads = env_->random_read_counter_.Read(); fprintf(stderr, "%d present => %d reads\n", N, reads); ASSERT_GE(reads, N); ASSERT_LE(reads, N + 2*N/100); // Lookup present keys. Should rarely read from either sstable. env_->random_read_counter_.Reset(); for (int i = 0; i < N; i++) { ASSERT_EQ("NOT_FOUND", Get(Key(i) + ".missing")); } reads = env_->random_read_counter_.Read(); fprintf(stderr, "%d missing => %d reads\n", N, reads); ASSERT_LE(reads, 3*N/100); env_->delay_data_sync_.Release_Store(NULL); Close(); delete options.block_cache; delete options.filter_policy; } // Multi-threaded test: namespace { static const int kNumThreads = 4; static const int kTestSeconds = 10; static const int kNumKeys = 1000; struct MTState { DBTest* test; port::AtomicPointer stop; port::AtomicPointer counter[kNumThreads]; port::AtomicPointer thread_done[kNumThreads]; }; struct MTThread { MTState* state; int id; }; static void MTThreadBody(void* arg) { MTThread* t = reinterpret_cast(arg); int id = t->id; DB* db = t->state->test->db_; uintptr_t counter = 0; fprintf(stderr, "... starting thread %d\n", id); Random rnd(1000 + id); std::string value; char valbuf[1500]; while (t->state->stop.Acquire_Load() == NULL) { t->state->counter[id].Release_Store(reinterpret_cast(counter)); int key = rnd.Uniform(kNumKeys); char keybuf[20]; snprintf(keybuf, sizeof(keybuf), "%016d", key); if (rnd.OneIn(2)) { // Write values of the form . // We add some padding for force compactions. snprintf(valbuf, sizeof(valbuf), "%d.%d.%-1000d", key, id, static_cast(counter)); ASSERT_OK(db->Put(WriteOptions(), Slice(keybuf), Slice(valbuf))); } else { // Read a value and verify that it matches the pattern written above. Status s = db->Get(ReadOptions(), Slice(keybuf), &value); if (s.IsNotFound()) { // Key has not yet been written } else { // Check that the writer thread counter is >= the counter in the value ASSERT_OK(s); int k, w, c; ASSERT_EQ(3, sscanf(value.c_str(), "%d.%d.%d", &k, &w, &c)) << value; ASSERT_EQ(k, key); ASSERT_GE(w, 0); ASSERT_LT(w, kNumThreads); ASSERT_LE(static_cast(c), reinterpret_cast( t->state->counter[w].Acquire_Load())); } } counter++; } t->state->thread_done[id].Release_Store(t); fprintf(stderr, "... stopping thread %d after %d ops\n", id, int(counter)); } } // namespace TEST(DBTest, MultiThreaded) { do { // Initialize state MTState mt; mt.test = this; mt.stop.Release_Store(0); for (int id = 0; id < kNumThreads; id++) { mt.counter[id].Release_Store(0); mt.thread_done[id].Release_Store(0); } // Start threads MTThread thread[kNumThreads]; for (int id = 0; id < kNumThreads; id++) { thread[id].state = &mt; thread[id].id = id; env_->StartThread(MTThreadBody, &thread[id]); } // Let them run for a while DelayMilliseconds(kTestSeconds * 1000); // Stop the threads and wait for them to finish mt.stop.Release_Store(&mt); for (int id = 0; id < kNumThreads; id++) { while (mt.thread_done[id].Acquire_Load() == NULL) { DelayMilliseconds(100); } } } while (ChangeOptions()); } namespace { typedef std::map KVMap; } class ModelDB: public DB { public: class ModelSnapshot : public Snapshot { public: KVMap map_; }; explicit ModelDB(const Options& options): options_(options) { } ~ModelDB() { } virtual Status Put(const WriteOptions& o, const Slice& k, const Slice& v) { return DB::Put(o, k, v); } virtual Status Delete(const WriteOptions& o, const Slice& key) { return DB::Delete(o, key); } virtual Status Get(const ReadOptions& options, const Slice& key, std::string* value) { assert(false); // Not implemented return Status::NotFound(key); } virtual Iterator* NewIterator(const ReadOptions& options) { if (options.snapshot == NULL) { KVMap* saved = new KVMap; *saved = map_; return new ModelIter(saved, true); } else { const KVMap* snapshot_state = &(reinterpret_cast(options.snapshot)->map_); return new ModelIter(snapshot_state, false); } } virtual const Snapshot* GetSnapshot() { ModelSnapshot* snapshot = new ModelSnapshot; snapshot->map_ = map_; return snapshot; } virtual void ReleaseSnapshot(const Snapshot* snapshot) { delete reinterpret_cast(snapshot); } virtual Status Write(const WriteOptions& options, WriteBatch* batch) { class Handler : public WriteBatch::Handler { public: KVMap* map_; virtual void Put(const Slice& key, const Slice& value) { (*map_)[key.ToString()] = value.ToString(); } virtual void Delete(const Slice& key) { map_->erase(key.ToString()); } }; Handler handler; handler.map_ = &map_; return batch->Iterate(&handler); } virtual bool GetProperty(const Slice& property, std::string* value) { return false; } virtual void GetApproximateSizes(const Range* r, int n, uint64_t* sizes) { for (int i = 0; i < n; i++) { sizes[i] = 0; } } virtual void CompactRange(const Slice* start, const Slice* end) { } private: class ModelIter: public Iterator { public: ModelIter(const KVMap* map, bool owned) : map_(map), owned_(owned), iter_(map_->end()) { } ~ModelIter() { if (owned_) delete map_; } virtual bool Valid() const { return iter_ != map_->end(); } virtual void SeekToFirst() { iter_ = map_->begin(); } virtual void SeekToLast() { if (map_->empty()) { iter_ = map_->end(); } else { iter_ = map_->find(map_->rbegin()->first); } } virtual void Seek(const Slice& k) { iter_ = map_->lower_bound(k.ToString()); } virtual void Next() { ++iter_; } virtual void Prev() { --iter_; } virtual Slice key() const { return iter_->first; } virtual Slice value() const { return iter_->second; } virtual Status status() const { return Status::OK(); } private: const KVMap* const map_; const bool owned_; // Do we own map_ KVMap::const_iterator iter_; }; const Options options_; KVMap map_; }; static std::string RandomKey(Random* rnd) { int len = (rnd->OneIn(3) ? 1 // Short sometimes to encourage collisions : (rnd->OneIn(100) ? rnd->Skewed(10) : rnd->Uniform(10))); return test::RandomKey(rnd, len); } static bool CompareIterators(int step, DB* model, DB* db, const Snapshot* model_snap, const Snapshot* db_snap) { ReadOptions options; options.snapshot = model_snap; Iterator* miter = model->NewIterator(options); options.snapshot = db_snap; Iterator* dbiter = db->NewIterator(options); bool ok = true; int count = 0; for (miter->SeekToFirst(), dbiter->SeekToFirst(); ok && miter->Valid() && dbiter->Valid(); miter->Next(), dbiter->Next()) { count++; if (miter->key().compare(dbiter->key()) != 0) { fprintf(stderr, "step %d: Key mismatch: '%s' vs. '%s'\n", step, EscapeString(miter->key()).c_str(), EscapeString(dbiter->key()).c_str()); ok = false; break; } if (miter->value().compare(dbiter->value()) != 0) { fprintf(stderr, "step %d: Value mismatch for key '%s': '%s' vs. '%s'\n", step, EscapeString(miter->key()).c_str(), EscapeString(miter->value()).c_str(), EscapeString(miter->value()).c_str()); ok = false; } } if (ok) { if (miter->Valid() != dbiter->Valid()) { fprintf(stderr, "step %d: Mismatch at end of iterators: %d vs. %d\n", step, miter->Valid(), dbiter->Valid()); ok = false; } } fprintf(stderr, "%d entries compared: ok=%d\n", count, ok); delete miter; delete dbiter; return ok; } TEST(DBTest, Randomized) { Random rnd(test::RandomSeed()); do { ModelDB model(CurrentOptions()); const int N = 10000; const Snapshot* model_snap = NULL; const Snapshot* db_snap = NULL; std::string k, v; for (int step = 0; step < N; step++) { if (step % 100 == 0) { fprintf(stderr, "Step %d of %d\n", step, N); } // TODO(sanjay): Test Get() works int p = rnd.Uniform(100); if (p < 45) { // Put k = RandomKey(&rnd); v = RandomString(&rnd, rnd.OneIn(20) ? 100 + rnd.Uniform(100) : rnd.Uniform(8)); ASSERT_OK(model.Put(WriteOptions(), k, v)); ASSERT_OK(db_->Put(WriteOptions(), k, v)); } else if (p < 90) { // Delete k = RandomKey(&rnd); ASSERT_OK(model.Delete(WriteOptions(), k)); ASSERT_OK(db_->Delete(WriteOptions(), k)); } else { // Multi-element batch WriteBatch b; const int num = rnd.Uniform(8); for (int i = 0; i < num; i++) { if (i == 0 || !rnd.OneIn(10)) { k = RandomKey(&rnd); } else { // Periodically re-use the same key from the previous iter, so // we have multiple entries in the write batch for the same key } if (rnd.OneIn(2)) { v = RandomString(&rnd, rnd.Uniform(10)); b.Put(k, v); } else { b.Delete(k); } } ASSERT_OK(model.Write(WriteOptions(), &b)); ASSERT_OK(db_->Write(WriteOptions(), &b)); } if ((step % 100) == 0) { ASSERT_TRUE(CompareIterators(step, &model, db_, NULL, NULL)); ASSERT_TRUE(CompareIterators(step, &model, db_, model_snap, db_snap)); // Save a snapshot from each DB this time that we'll use next // time we compare things, to make sure the current state is // preserved with the snapshot if (model_snap != NULL) model.ReleaseSnapshot(model_snap); if (db_snap != NULL) db_->ReleaseSnapshot(db_snap); Reopen(); ASSERT_TRUE(CompareIterators(step, &model, db_, NULL, NULL)); model_snap = model.GetSnapshot(); db_snap = db_->GetSnapshot(); } } if (model_snap != NULL) model.ReleaseSnapshot(model_snap); if (db_snap != NULL) db_->ReleaseSnapshot(db_snap); } while (ChangeOptions()); } std::string MakeKey(unsigned int num) { char buf[30]; snprintf(buf, sizeof(buf), "%016u", num); return std::string(buf); } void BM_LogAndApply(int iters, int num_base_files) { std::string dbname = test::TmpDir() + "/leveldb_test_benchmark"; DestroyDB(dbname, Options()); DB* db = NULL; Options opts; opts.create_if_missing = true; Status s = DB::Open(opts, dbname, &db); ASSERT_OK(s); ASSERT_TRUE(db != NULL); delete db; db = NULL; Env* env = Env::Default(); port::Mutex mu; MutexLock l(&mu); InternalKeyComparator cmp(BytewiseComparator()); Options options; VersionSet vset(dbname, &options, NULL, &cmp); ASSERT_OK(vset.Recover()); VersionEdit vbase; uint64_t fnum = 1; for (int i = 0; i < num_base_files; i++) { InternalKey start(MakeKey(2*fnum), 1, kTypeValue); InternalKey limit(MakeKey(2*fnum+1), 1, kTypeDeletion); vbase.AddFile(2, fnum++, 1 /* file size */, start, limit); } ASSERT_OK(vset.LogAndApply(&vbase, &mu)); uint64_t start_micros = env->NowMicros(); for (int i = 0; i < iters; i++) { VersionEdit vedit; vedit.DeleteFile(2, fnum); InternalKey start(MakeKey(2*fnum), 1, kTypeValue); InternalKey limit(MakeKey(2*fnum+1), 1, kTypeDeletion); vedit.AddFile(2, fnum++, 1 /* file size */, start, limit); vset.LogAndApply(&vedit, &mu); } uint64_t stop_micros = env->NowMicros(); unsigned int us = stop_micros - start_micros; char buf[16]; snprintf(buf, sizeof(buf), "%d", num_base_files); fprintf(stderr, "BM_LogAndApply/%-6s %8d iters : %9u us (%7.0f us / iter)\n", buf, iters, us, ((float)us) / iters); } } // namespace leveldb int main(int argc, char** argv) { if (argc > 1 && std::string(argv[1]) == "--benchmark") { leveldb::BM_LogAndApply(1000, 1); leveldb::BM_LogAndApply(1000, 100); leveldb::BM_LogAndApply(1000, 10000); leveldb::BM_LogAndApply(100, 100000); return 0; } return leveldb::test::RunAllTests(); }