// Copyright (c) Facebook, Inc. and its affiliates. All Rights Reserved. // 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 "rocksdb/compaction_filter.h" #include "rocksdb/convenience.h" #include "rocksdb/merge_operator.h" #include "rocksdb/utilities/db_ttl.h" #include "rocksdb/utilities/object_registry.h" #include "test_util/testharness.h" #include "util/string_util.h" #include "utilities/merge_operators/bytesxor.h" #include "utilities/ttl/db_ttl_impl.h" #ifndef OS_WIN #include #endif namespace ROCKSDB_NAMESPACE { namespace { using KVMap = std::map; enum BatchOperation { OP_PUT = 0, OP_DELETE = 1 }; } // namespace class SpecialTimeEnv : public EnvWrapper { public: explicit SpecialTimeEnv(Env* base) : EnvWrapper(base) { EXPECT_OK(base->GetCurrentTime(¤t_time_)); } const char* Name() const override { return "SpecialTimeEnv"; } void Sleep(int64_t sleep_time) { current_time_ += sleep_time; } Status GetCurrentTime(int64_t* current_time) override { *current_time = current_time_; return Status::OK(); } private: int64_t current_time_ = 0; }; class TtlTest : public testing::Test { public: TtlTest() { env_.reset(new SpecialTimeEnv(Env::Default())); dbname_ = test::PerThreadDBPath("db_ttl"); options_.create_if_missing = true; options_.env = env_.get(); // ensure that compaction is kicked in to always strip timestamp from kvs options_.max_compaction_bytes = 1; // compaction should take place always from level0 for determinism db_ttl_ = nullptr; EXPECT_OK(DestroyDB(dbname_, Options())); } ~TtlTest() override { CloseTtl(); EXPECT_OK(DestroyDB(dbname_, Options())); } // Open database with TTL support when TTL not provided with db_ttl_ pointer void OpenTtl() { ASSERT_TRUE(db_ttl_ == nullptr); // db should be closed before opening again ASSERT_OK(DBWithTTL::Open(options_, dbname_, &db_ttl_)); } // Open database with TTL support when TTL provided with db_ttl_ pointer void OpenTtl(int32_t ttl) { ASSERT_TRUE(db_ttl_ == nullptr); ASSERT_OK(DBWithTTL::Open(options_, dbname_, &db_ttl_, ttl)); } // Open with TestFilter compaction filter void OpenTtlWithTestCompaction(int32_t ttl) { options_.compaction_filter_factory = std::shared_ptr( new TestFilterFactory(kSampleSize_, kNewValue_)); OpenTtl(ttl); } // Open database with TTL support in read_only mode void OpenReadOnlyTtl(int32_t ttl) { ASSERT_TRUE(db_ttl_ == nullptr); ASSERT_OK(DBWithTTL::Open(options_, dbname_, &db_ttl_, ttl, true)); } // Call db_ttl_->Close() before delete db_ttl_ void CloseTtl() { CloseTtlHelper(true); } // No db_ttl_->Close() before delete db_ttl_ void CloseTtlNoDBClose() { CloseTtlHelper(false); } void CloseTtlHelper(bool close_db) { if (db_ttl_ != nullptr) { if (close_db) { EXPECT_OK(db_ttl_->Close()); } delete db_ttl_; db_ttl_ = nullptr; } } // Populates and returns a kv-map void MakeKVMap(int64_t num_entries) { kvmap_.clear(); int digits = 1; for (int64_t dummy = num_entries; dummy /= 10; ++digits) { } int digits_in_i = 1; for (int64_t i = 0; i < num_entries; i++) { std::string key = "key"; std::string value = "value"; if (i % 10 == 0) { digits_in_i++; } for (int j = digits_in_i; j < digits; j++) { key.append("0"); value.append("0"); } AppendNumberTo(&key, i); AppendNumberTo(&value, i); kvmap_[key] = value; } ASSERT_EQ(static_cast(kvmap_.size()), num_entries); // check all insertions done } // Makes a write-batch with key-vals from kvmap_ and 'Write''s it void MakePutWriteBatch(const BatchOperation* batch_ops, int64_t num_ops) { ASSERT_LE(num_ops, static_cast(kvmap_.size())); static WriteOptions wopts; static FlushOptions flush_opts; WriteBatch batch; kv_it_ = kvmap_.begin(); for (int64_t i = 0; i < num_ops && kv_it_ != kvmap_.end(); i++, ++kv_it_) { switch (batch_ops[i]) { case OP_PUT: ASSERT_OK(batch.Put(kv_it_->first, kv_it_->second)); break; case OP_DELETE: ASSERT_OK(batch.Delete(kv_it_->first)); break; default: FAIL(); } } ASSERT_OK(db_ttl_->Write(wopts, &batch)); ASSERT_OK(db_ttl_->Flush(flush_opts)); } // Puts num_entries starting from start_pos_map from kvmap_ into the database void PutValues(int64_t start_pos_map, int64_t num_entries, bool flush = true, ColumnFamilyHandle* cf = nullptr) { ASSERT_TRUE(db_ttl_); ASSERT_LE(start_pos_map + num_entries, static_cast(kvmap_.size())); static WriteOptions wopts; static FlushOptions flush_opts; kv_it_ = kvmap_.begin(); advance(kv_it_, start_pos_map); for (int64_t i = 0; kv_it_ != kvmap_.end() && i < num_entries; i++, ++kv_it_) { ASSERT_OK(cf == nullptr ? db_ttl_->Put(wopts, kv_it_->first, kv_it_->second) : db_ttl_->Put(wopts, cf, kv_it_->first, kv_it_->second)); } // Put a mock kv at the end because CompactionFilter doesn't delete last key ASSERT_OK(cf == nullptr ? db_ttl_->Put(wopts, "keymock", "valuemock") : db_ttl_->Put(wopts, cf, "keymock", "valuemock")); if (flush) { if (cf == nullptr) { ASSERT_OK(db_ttl_->Flush(flush_opts)); } else { ASSERT_OK(db_ttl_->Flush(flush_opts, cf)); } } } // Runs a manual compaction Status ManualCompact(ColumnFamilyHandle* cf = nullptr) { assert(db_ttl_); if (cf == nullptr) { return db_ttl_->CompactRange(CompactRangeOptions(), nullptr, nullptr); } else { return db_ttl_->CompactRange(CompactRangeOptions(), cf, nullptr, nullptr); } } // Runs a DeleteRange void MakeDeleteRange(std::string start, std::string end, ColumnFamilyHandle* cf = nullptr) { ASSERT_TRUE(db_ttl_); static WriteOptions wops; WriteBatch wb; ASSERT_OK(cf == nullptr ? wb.DeleteRange(db_ttl_->DefaultColumnFamily(), start, end) : wb.DeleteRange(cf, start, end)); ASSERT_OK(db_ttl_->Write(wops, &wb)); } // checks the whole kvmap_ to return correct values using KeyMayExist void SimpleKeyMayExistCheck() { static ReadOptions ropts; bool value_found; std::string val; for (auto& kv : kvmap_) { bool ret = db_ttl_->KeyMayExist(ropts, kv.first, &val, &value_found); if (ret == false || value_found == false) { fprintf(stderr, "KeyMayExist could not find key=%s in the database but" " should have\n", kv.first.c_str()); FAIL(); } else if (val.compare(kv.second) != 0) { fprintf(stderr, " value for key=%s present in database is %s but" " should be %s\n", kv.first.c_str(), val.c_str(), kv.second.c_str()); FAIL(); } } } // checks the whole kvmap_ to return correct values using MultiGet void SimpleMultiGetTest() { static ReadOptions ropts; std::vector keys; std::vector values; for (auto& kv : kvmap_) { keys.emplace_back(kv.first); } auto statuses = db_ttl_->MultiGet(ropts, keys, &values); size_t i = 0; for (auto& kv : kvmap_) { ASSERT_OK(statuses[i]); ASSERT_EQ(values[i], kv.second); ++i; } } void CompactCheck(int64_t st_pos, int64_t span, bool check = true, bool test_compaction_change = false, ColumnFamilyHandle* cf = nullptr) { static ReadOptions ropts; kv_it_ = kvmap_.begin(); advance(kv_it_, st_pos); std::string v; for (int64_t i = 0; kv_it_ != kvmap_.end() && i < span; i++, ++kv_it_) { Status s = (cf == nullptr) ? db_ttl_->Get(ropts, kv_it_->first, &v) : db_ttl_->Get(ropts, cf, kv_it_->first, &v); if (s.ok() != check) { fprintf(stderr, "key=%s ", kv_it_->first.c_str()); if (!s.ok()) { fprintf(stderr, "is absent from db but was expected to be present\n"); } else { fprintf(stderr, "is present in db but was expected to be absent\n"); } FAIL(); } else if (s.ok()) { if (test_compaction_change && v.compare(kNewValue_) != 0) { fprintf(stderr, " value for key=%s present in database is %s but " " should be %s\n", kv_it_->first.c_str(), v.c_str(), kNewValue_.c_str()); FAIL(); } else if (!test_compaction_change && v.compare(kv_it_->second) != 0) { fprintf(stderr, " value for key=%s present in database is %s but " " should be %s\n", kv_it_->first.c_str(), v.c_str(), kv_it_->second.c_str()); FAIL(); } } } } // Sleeps for slp_tim then runs a manual compaction // Checks span starting from st_pos from kvmap_ in the db and // Gets should return true if check is true and false otherwise // Also checks that value that we got is the same as inserted; and =kNewValue // if test_compaction_change is true void SleepCompactCheck(int slp_tim, int64_t st_pos, int64_t span, bool check = true, bool test_compaction_change = false, ColumnFamilyHandle* cf = nullptr) { ASSERT_TRUE(db_ttl_); env_->Sleep(slp_tim); ASSERT_OK(ManualCompact(cf)); CompactCheck(st_pos, span, check, test_compaction_change, cf); } // Similar as SleepCompactCheck but uses TtlIterator to read from db void SleepCompactCheckIter(int slp, int st_pos, int64_t span, bool check = true) { ASSERT_TRUE(db_ttl_); env_->Sleep(slp); ASSERT_OK(ManualCompact()); static ReadOptions ropts; Iterator* dbiter = db_ttl_->NewIterator(ropts); kv_it_ = kvmap_.begin(); advance(kv_it_, st_pos); dbiter->Seek(kv_it_->first); if (!check) { if (dbiter->Valid()) { ASSERT_NE(dbiter->value().compare(kv_it_->second), 0); } } else { // dbiter should have found out kvmap_[st_pos] for (int64_t i = st_pos; kv_it_ != kvmap_.end() && i < st_pos + span; i++, ++kv_it_) { ASSERT_TRUE(dbiter->Valid()); ASSERT_EQ(dbiter->value().compare(kv_it_->second), 0); dbiter->Next(); } } ASSERT_OK(dbiter->status()); delete dbiter; } // Set ttl on open db void SetTtl(int32_t ttl, ColumnFamilyHandle* cf = nullptr) { ASSERT_TRUE(db_ttl_); cf == nullptr ? db_ttl_->SetTtl(ttl) : db_ttl_->SetTtl(cf, ttl); } class TestFilter : public CompactionFilter { public: TestFilter(const int64_t kSampleSize, const std::string& kNewValue) : kSampleSize_(kSampleSize), kNewValue_(kNewValue) {} // Works on keys of the form "key" // Drops key if number at the end of key is in [0, kSampleSize_/3), // Keeps key if it is in [kSampleSize_/3, 2*kSampleSize_/3), // Change value if it is in [2*kSampleSize_/3, kSampleSize_) // Eg. kSampleSize_=6. Drop:key0-1...Keep:key2-3...Change:key4-5... bool Filter(int /*level*/, const Slice& key, const Slice& /*value*/, std::string* new_value, bool* value_changed) const override { assert(new_value != nullptr); std::string search_str = "0123456789"; std::string key_string = key.ToString(); size_t pos = key_string.find_first_of(search_str); int num_key_end; if (pos != std::string::npos) { auto key_substr = key_string.substr(pos, key.size() - pos); #ifndef CYGWIN num_key_end = std::stoi(key_substr); #else num_key_end = std::strtol(key_substr.c_str(), 0, 10); #endif } else { return false; // Keep keys not matching the format "key" } int64_t partition = kSampleSize_ / 3; if (num_key_end < partition) { return true; } else if (num_key_end < partition * 2) { return false; } else { *new_value = kNewValue_; *value_changed = true; return false; } } const char* Name() const override { return "TestFilter"; } private: const int64_t kSampleSize_; const std::string kNewValue_; }; class TestFilterFactory : public CompactionFilterFactory { public: TestFilterFactory(const int64_t kSampleSize, const std::string& kNewValue) : kSampleSize_(kSampleSize), kNewValue_(kNewValue) {} std::unique_ptr CreateCompactionFilter( const CompactionFilter::Context& /*context*/) override { return std::unique_ptr( new TestFilter(kSampleSize_, kNewValue_)); } const char* Name() const override { return "TestFilterFactory"; } private: const int64_t kSampleSize_; const std::string kNewValue_; }; // Choose carefully so that Put, Gets & Compaction complete in 1 second buffer static const int64_t kSampleSize_ = 100; std::string dbname_; DBWithTTL* db_ttl_; std::unique_ptr env_; protected: Options options_; private: KVMap kvmap_; KVMap::iterator kv_it_; const std::string kNewValue_ = "new_value"; std::unique_ptr test_comp_filter_; }; // class TtlTest // If TTL is non positive or not provided, the behaviour is TTL = infinity // This test opens the db 3 times with such default behavior and inserts a // bunch of kvs each time. All kvs should accumulate in the db till the end // Partitions the sample-size provided into 3 sets over boundary1 and boundary2 TEST_F(TtlTest, NoEffect) { MakeKVMap(kSampleSize_); int64_t boundary1 = kSampleSize_ / 3; int64_t boundary2 = 2 * boundary1; OpenTtl(); PutValues(0, boundary1); // T=0: Set1 never deleted SleepCompactCheck(1, 0, boundary1); // T=1: Set1 still there CloseTtl(); OpenTtl(0); PutValues(boundary1, boundary2 - boundary1); // T=1: Set2 never deleted SleepCompactCheck(1, 0, boundary2); // T=2: Sets1 & 2 still there CloseTtl(); OpenTtl(-1); PutValues(boundary2, kSampleSize_ - boundary2); // T=3: Set3 never deleted SleepCompactCheck(1, 0, kSampleSize_, true); // T=4: Sets 1,2,3 still there CloseTtl(); } // Rerun the NoEffect test with a different version of CloseTtl // function, where db is directly deleted without close. TEST_F(TtlTest, DestructWithoutClose) { MakeKVMap(kSampleSize_); int64_t boundary1 = kSampleSize_ / 3; int64_t boundary2 = 2 * boundary1; OpenTtl(); PutValues(0, boundary1); // T=0: Set1 never deleted SleepCompactCheck(1, 0, boundary1); // T=1: Set1 still there CloseTtlNoDBClose(); OpenTtl(0); PutValues(boundary1, boundary2 - boundary1); // T=1: Set2 never deleted SleepCompactCheck(1, 0, boundary2); // T=2: Sets1 & 2 still there CloseTtlNoDBClose(); OpenTtl(-1); PutValues(boundary2, kSampleSize_ - boundary2); // T=3: Set3 never deleted SleepCompactCheck(1, 0, kSampleSize_, true); // T=4: Sets 1,2,3 still there CloseTtlNoDBClose(); } // Puts a set of values and checks its presence using Get during ttl TEST_F(TtlTest, PresentDuringTTL) { MakeKVMap(kSampleSize_); OpenTtl(2); // T=0:Open the db with ttl = 2 PutValues(0, kSampleSize_); // T=0:Insert Set1. Delete at t=2 SleepCompactCheck(1, 0, kSampleSize_, true); // T=1:Set1 should still be there CloseTtl(); } // Puts a set of values and checks its absence using Get after ttl TEST_F(TtlTest, AbsentAfterTTL) { MakeKVMap(kSampleSize_); OpenTtl(1); // T=0:Open the db with ttl = 2 PutValues(0, kSampleSize_); // T=0:Insert Set1. Delete at t=2 SleepCompactCheck(2, 0, kSampleSize_, false); // T=2:Set1 should not be there CloseTtl(); } // Resets the timestamp of a set of kvs by updating them and checks that they // are not deleted according to the old timestamp TEST_F(TtlTest, ResetTimestamp) { MakeKVMap(kSampleSize_); OpenTtl(3); PutValues(0, kSampleSize_); // T=0: Insert Set1. Delete at t=3 env_->Sleep(2); // T=2 PutValues(0, kSampleSize_); // T=2: Insert Set1. Delete at t=5 SleepCompactCheck(2, 0, kSampleSize_); // T=4: Set1 should still be there CloseTtl(); } // Similar to PresentDuringTTL but uses Iterator TEST_F(TtlTest, IterPresentDuringTTL) { MakeKVMap(kSampleSize_); OpenTtl(2); PutValues(0, kSampleSize_); // T=0: Insert. Delete at t=2 SleepCompactCheckIter(1, 0, kSampleSize_); // T=1: Set should be there CloseTtl(); } // Similar to AbsentAfterTTL but uses Iterator TEST_F(TtlTest, IterAbsentAfterTTL) { MakeKVMap(kSampleSize_); OpenTtl(1); PutValues(0, kSampleSize_); // T=0: Insert. Delete at t=1 SleepCompactCheckIter(2, 0, kSampleSize_, false); // T=2: Should not be there CloseTtl(); } // Checks presence while opening the same db more than once with the same ttl // Note: The second open will open the same db TEST_F(TtlTest, MultiOpenSamePresent) { MakeKVMap(kSampleSize_); OpenTtl(2); PutValues(0, kSampleSize_); // T=0: Insert. Delete at t=2 CloseTtl(); OpenTtl(2); // T=0. Delete at t=2 SleepCompactCheck(1, 0, kSampleSize_); // T=1: Set should be there CloseTtl(); } // Checks absence while opening the same db more than once with the same ttl // Note: The second open will open the same db TEST_F(TtlTest, MultiOpenSameAbsent) { MakeKVMap(kSampleSize_); OpenTtl(1); PutValues(0, kSampleSize_); // T=0: Insert. Delete at t=1 CloseTtl(); OpenTtl(1); // T=0.Delete at t=1 SleepCompactCheck(2, 0, kSampleSize_, false); // T=2: Set should not be there CloseTtl(); } // Checks presence while opening the same db more than once with bigger ttl TEST_F(TtlTest, MultiOpenDifferent) { MakeKVMap(kSampleSize_); OpenTtl(1); PutValues(0, kSampleSize_); // T=0: Insert. Delete at t=1 CloseTtl(); OpenTtl(3); // T=0: Set deleted at t=3 SleepCompactCheck(2, 0, kSampleSize_); // T=2: Set should be there CloseTtl(); } // Checks presence during ttl in read_only mode TEST_F(TtlTest, ReadOnlyPresentForever) { MakeKVMap(kSampleSize_); OpenTtl(1); // T=0:Open the db normally PutValues(0, kSampleSize_); // T=0:Insert Set1. Delete at t=1 CloseTtl(); OpenReadOnlyTtl(1); ASSERT_TRUE(db_ttl_); env_->Sleep(2); Status s = ManualCompact(); // T=2:Set1 should still be there ASSERT_TRUE(s.IsNotSupported()); CompactCheck(0, kSampleSize_); CloseTtl(); } // Checks whether WriteBatch works well with TTL // Puts all kvs in kvmap_ in a batch and writes first, then deletes first half TEST_F(TtlTest, WriteBatchTest) { MakeKVMap(kSampleSize_); BatchOperation batch_ops[kSampleSize_]; for (int i = 0; i < kSampleSize_; i++) { batch_ops[i] = OP_PUT; } OpenTtl(2); MakePutWriteBatch(batch_ops, kSampleSize_); for (int i = 0; i < kSampleSize_ / 2; i++) { batch_ops[i] = OP_DELETE; } MakePutWriteBatch(batch_ops, kSampleSize_ / 2); SleepCompactCheck(0, 0, kSampleSize_ / 2, false); SleepCompactCheck(0, kSampleSize_ / 2, kSampleSize_ - kSampleSize_ / 2); CloseTtl(); } // Checks user's compaction filter for correctness with TTL logic TEST_F(TtlTest, CompactionFilter) { MakeKVMap(kSampleSize_); OpenTtlWithTestCompaction(1); PutValues(0, kSampleSize_); // T=0:Insert Set1. Delete at t=1 // T=2: TTL logic takes precedence over TestFilter:-Set1 should not be there SleepCompactCheck(2, 0, kSampleSize_, false); CloseTtl(); OpenTtlWithTestCompaction(3); PutValues(0, kSampleSize_); // T=0:Insert Set1. int64_t partition = kSampleSize_ / 3; SleepCompactCheck(1, 0, partition, false); // Part dropped SleepCompactCheck(0, partition, partition); // Part kept SleepCompactCheck(0, 2 * partition, partition, true, true); // Part changed CloseTtl(); } TEST_F(TtlTest, UnregisteredMergeOperator) { class UnregisteredMergeOperator : public MergeOperator { public: const char* Name() const override { return "UnregisteredMergeOperator"; } }; options_.fail_if_options_file_error = true; options_.merge_operator = std::make_shared(); OpenTtl(); CloseTtl(); } // Insert some key-values which KeyMayExist should be able to get and check that // values returned are fine TEST_F(TtlTest, KeyMayExist) { MakeKVMap(kSampleSize_); OpenTtl(); PutValues(0, kSampleSize_, false); SimpleKeyMayExistCheck(); CloseTtl(); } TEST_F(TtlTest, MultiGetTest) { MakeKVMap(kSampleSize_); OpenTtl(); PutValues(0, kSampleSize_, false); SimpleMultiGetTest(); CloseTtl(); } TEST_F(TtlTest, TtlFiftenYears) { MakeKVMap(kSampleSize_); // 15 year will lead int32_t overflow from now const int kFifteenYearSeconds = 86400 * 365 * 15; OpenTtl(kFifteenYearSeconds); PutValues(0, kSampleSize_, true); // trigger the compaction SleepCompactCheck(1, 0, kSampleSize_); CloseTtl(); } TEST_F(TtlTest, ColumnFamiliesTest) { DB* db; Options options; options.create_if_missing = true; options.env = env_.get(); ASSERT_OK(DB::Open(options, dbname_, &db)); ColumnFamilyHandle* handle; ASSERT_OK(db->CreateColumnFamily(ColumnFamilyOptions(options), "ttl_column_family", &handle)); delete handle; delete db; std::vector column_families; column_families.emplace_back(kDefaultColumnFamilyName, ColumnFamilyOptions(options)); column_families.emplace_back("ttl_column_family", ColumnFamilyOptions(options)); std::vector handles; ASSERT_OK(DBWithTTL::Open(DBOptions(options), dbname_, column_families, &handles, &db_ttl_, {3, 5}, false)); ASSERT_EQ(handles.size(), 2U); ColumnFamilyHandle* new_handle; ASSERT_OK(db_ttl_->CreateColumnFamilyWithTtl(options, "ttl_column_family_2", &new_handle, 2)); handles.push_back(new_handle); MakeKVMap(kSampleSize_); PutValues(0, kSampleSize_, false, handles[0]); PutValues(0, kSampleSize_, false, handles[1]); PutValues(0, kSampleSize_, false, handles[2]); // everything should be there after 1 second SleepCompactCheck(1, 0, kSampleSize_, true, false, handles[0]); SleepCompactCheck(0, 0, kSampleSize_, true, false, handles[1]); SleepCompactCheck(0, 0, kSampleSize_, true, false, handles[2]); // only column family 1 should be alive after 4 seconds SleepCompactCheck(3, 0, kSampleSize_, false, false, handles[0]); SleepCompactCheck(0, 0, kSampleSize_, true, false, handles[1]); SleepCompactCheck(0, 0, kSampleSize_, false, false, handles[2]); // nothing should be there after 6 seconds SleepCompactCheck(2, 0, kSampleSize_, false, false, handles[0]); SleepCompactCheck(0, 0, kSampleSize_, false, false, handles[1]); SleepCompactCheck(0, 0, kSampleSize_, false, false, handles[2]); for (auto h : handles) { delete h; } delete db_ttl_; db_ttl_ = nullptr; } // Puts a set of values and checks its absence using Get after ttl TEST_F(TtlTest, ChangeTtlOnOpenDb) { MakeKVMap(kSampleSize_); OpenTtl(1); // T=0:Open the db with ttl = 2 SetTtl(3); PutValues(0, kSampleSize_); // T=0:Insert Set1. Delete at t=2 SleepCompactCheck(2, 0, kSampleSize_, true); // T=2:Set1 should be there CloseTtl(); } // Test DeleteRange for DBWithTtl TEST_F(TtlTest, DeleteRangeTest) { OpenTtl(); ASSERT_OK(db_ttl_->Put(WriteOptions(), "a", "val")); MakeDeleteRange("a", "b"); ASSERT_OK(db_ttl_->Put(WriteOptions(), "c", "val")); MakeDeleteRange("b", "d"); ASSERT_OK(db_ttl_->Put(WriteOptions(), "e", "val")); MakeDeleteRange("d", "e"); // first iteration verifies query correctness in memtable, second verifies // query correctness for a single SST file for (int i = 0; i < 2; i++) { if (i > 0) { ASSERT_OK(db_ttl_->Flush(FlushOptions())); } std::string value; ASSERT_TRUE(db_ttl_->Get(ReadOptions(), "a", &value).IsNotFound()); ASSERT_TRUE(db_ttl_->Get(ReadOptions(), "c", &value).IsNotFound()); ASSERT_OK(db_ttl_->Get(ReadOptions(), "e", &value)); } CloseTtl(); } class DummyFilter : public CompactionFilter { public: bool Filter(int /*level*/, const Slice& /*key*/, const Slice& /*value*/, std::string* /*new_value*/, bool* /*value_changed*/) const override { return false; } const char* Name() const override { return kClassName(); } static const char* kClassName() { return "DummyFilter"; } }; class DummyFilterFactory : public CompactionFilterFactory { public: const char* Name() const override { return kClassName(); } static const char* kClassName() { return "DummyFilterFactory"; } std::unique_ptr CreateCompactionFilter( const CompactionFilter::Context&) override { std::unique_ptr f(new DummyFilter()); return f; } }; static int RegisterTestObjects(ObjectLibrary& library, const std::string& /*arg*/) { library.AddFactory( "DummyFilter", [](const std::string& /*uri*/, std::unique_ptr* /*guard*/, std::string* /* errmsg */) { static DummyFilter dummy; return &dummy; }); library.AddFactory( "DummyFilterFactory", [](const std::string& /*uri*/, std::unique_ptr* guard, std::string* /* errmsg */) { guard->reset(new DummyFilterFactory()); return guard->get(); }); return 2; } class TtlOptionsTest : public testing::Test { public: TtlOptionsTest() { config_options_.registry->AddLibrary("RegisterTtlObjects", RegisterTtlObjects, ""); config_options_.registry->AddLibrary("RegisterTtlTestObjects", RegisterTestObjects, ""); } ConfigOptions config_options_; }; TEST_F(TtlOptionsTest, LoadTtlCompactionFilter) { const CompactionFilter* filter = nullptr; ASSERT_OK(CompactionFilter::CreateFromString( config_options_, TtlCompactionFilter::kClassName(), &filter)); ASSERT_NE(filter, nullptr); ASSERT_STREQ(filter->Name(), TtlCompactionFilter::kClassName()); auto ttl = filter->GetOptions("TTL"); ASSERT_NE(ttl, nullptr); ASSERT_EQ(*ttl, 0); ASSERT_OK(filter->ValidateOptions(DBOptions(), ColumnFamilyOptions())); delete filter; filter = nullptr; ASSERT_OK(CompactionFilter::CreateFromString( config_options_, "id=TtlCompactionFilter; ttl=123", &filter)); ASSERT_NE(filter, nullptr); ttl = filter->GetOptions("TTL"); ASSERT_NE(ttl, nullptr); ASSERT_EQ(*ttl, 123); ASSERT_OK(filter->ValidateOptions(DBOptions(), ColumnFamilyOptions())); delete filter; filter = nullptr; ASSERT_OK(CompactionFilter::CreateFromString( config_options_, "id=TtlCompactionFilter; ttl=456; user_filter=DummyFilter;", &filter)); ASSERT_NE(filter, nullptr); auto inner = filter->CheckedCast(); ASSERT_NE(inner, nullptr); ASSERT_OK(filter->ValidateOptions(DBOptions(), ColumnFamilyOptions())); std::string mismatch; std::string opts_str = filter->ToString(config_options_); const CompactionFilter* copy = nullptr; ASSERT_OK( CompactionFilter::CreateFromString(config_options_, opts_str, ©)); ASSERT_TRUE(filter->AreEquivalent(config_options_, copy, &mismatch)); delete filter; delete copy; } TEST_F(TtlOptionsTest, LoadTtlCompactionFilterFactory) { std::shared_ptr cff; ASSERT_OK(CompactionFilterFactory::CreateFromString( config_options_, TtlCompactionFilterFactory::kClassName(), &cff)); ASSERT_NE(cff.get(), nullptr); ASSERT_STREQ(cff->Name(), TtlCompactionFilterFactory::kClassName()); auto ttl = cff->GetOptions("TTL"); ASSERT_NE(ttl, nullptr); ASSERT_EQ(*ttl, 0); ASSERT_OK(cff->ValidateOptions(DBOptions(), ColumnFamilyOptions())); ASSERT_OK(CompactionFilterFactory::CreateFromString( config_options_, "id=TtlCompactionFilterFactory; ttl=123", &cff)); ASSERT_NE(cff.get(), nullptr); ASSERT_STREQ(cff->Name(), TtlCompactionFilterFactory::kClassName()); ttl = cff->GetOptions("TTL"); ASSERT_NE(ttl, nullptr); ASSERT_EQ(*ttl, 123); ASSERT_OK(cff->ValidateOptions(DBOptions(), ColumnFamilyOptions())); ASSERT_OK(CompactionFilterFactory::CreateFromString( config_options_, "id=TtlCompactionFilterFactory; ttl=456; " "user_filter_factory=DummyFilterFactory;", &cff)); ASSERT_NE(cff.get(), nullptr); auto filter = cff->CreateCompactionFilter(CompactionFilter::Context()); ASSERT_NE(filter.get(), nullptr); auto ttlf = filter->CheckedCast(); ASSERT_EQ(filter.get(), ttlf); auto user = filter->CheckedCast(); ASSERT_NE(user, nullptr); ASSERT_OK(cff->ValidateOptions(DBOptions(), ColumnFamilyOptions())); std::string opts_str = cff->ToString(config_options_); std::string mismatch; std::shared_ptr copy; ASSERT_OK(CompactionFilterFactory::CreateFromString(config_options_, opts_str, ©)); ASSERT_TRUE(cff->AreEquivalent(config_options_, copy.get(), &mismatch)); } TEST_F(TtlOptionsTest, LoadTtlMergeOperator) { std::shared_ptr mo; config_options_.invoke_prepare_options = false; ASSERT_OK(MergeOperator::CreateFromString( config_options_, TtlMergeOperator::kClassName(), &mo)); ASSERT_NE(mo.get(), nullptr); ASSERT_STREQ(mo->Name(), TtlMergeOperator::kClassName()); ASSERT_NOK(mo->ValidateOptions(DBOptions(), ColumnFamilyOptions())); config_options_.invoke_prepare_options = true; ASSERT_OK(MergeOperator::CreateFromString( config_options_, "id=TtlMergeOperator; user_operator=bytesxor", &mo)); ASSERT_NE(mo.get(), nullptr); ASSERT_STREQ(mo->Name(), TtlMergeOperator::kClassName()); ASSERT_OK(mo->ValidateOptions(DBOptions(), ColumnFamilyOptions())); auto ttl_mo = mo->CheckedCast(); ASSERT_EQ(mo.get(), ttl_mo); auto user = ttl_mo->CheckedCast(); ASSERT_NE(user, nullptr); std::string mismatch; std::string opts_str = mo->ToString(config_options_); std::shared_ptr copy; ASSERT_OK(MergeOperator::CreateFromString(config_options_, opts_str, ©)); ASSERT_TRUE(mo->AreEquivalent(config_options_, copy.get(), &mismatch)); // An unregistered user_operator will be null, which is not supported by the // `TtlMergeOperator` implementation. ASSERT_OK(MergeOperator::CreateFromString( config_options_, "id=TtlMergeOperator; user_operator=unknown", &mo)); ASSERT_NE(mo.get(), nullptr); ASSERT_STREQ(mo->Name(), TtlMergeOperator::kClassName()); ASSERT_NOK(mo->ValidateOptions(DBOptions(), ColumnFamilyOptions())); } } // namespace ROCKSDB_NAMESPACE // A black-box test for the ttl wrapper around rocksdb int main(int argc, char** argv) { ROCKSDB_NAMESPACE::port::InstallStackTraceHandler(); ::testing::InitGoogleTest(&argc, argv); return RUN_ALL_TESTS(); }