// Copyright (c) 2011-present, Facebook, Inc. All rights reserved. // This source code is licensed under the BSD-style license found in the // LICENSE file in the root directory of this source tree. An additional grant // of patent rights can be found in the PATENTS file in the same directory. #include "db/compaction_iterator.h" #include #include #include "util/testharness.h" #include "util/testutil.h" namespace rocksdb { class LoggingForwardVectorIterator : public InternalIterator { public: struct Action { enum class Type { SEEK_TO_FIRST, SEEK, NEXT, }; Type type; std::string arg; explicit Action(Type _type, std::string _arg = "") : type(_type), arg(_arg) {} bool operator==(const Action& rhs) const { return std::tie(type, arg) == std::tie(rhs.type, rhs.arg); } }; LoggingForwardVectorIterator(const std::vector& keys, const std::vector& values) : keys_(keys), values_(values), current_(keys.size()) { assert(keys_.size() == values_.size()); } virtual bool Valid() const override { return current_ < keys_.size(); } virtual void SeekToFirst() override { log.emplace_back(Action::Type::SEEK_TO_FIRST); current_ = 0; } virtual void SeekToLast() override { assert(false); } virtual void Seek(const Slice& target) override { log.emplace_back(Action::Type::SEEK, target.ToString()); current_ = std::lower_bound(keys_.begin(), keys_.end(), target.ToString()) - keys_.begin(); } virtual void SeekForPrev(const Slice& target) override { assert(false); } virtual void Next() override { assert(Valid()); log.emplace_back(Action::Type::NEXT); current_++; } virtual void Prev() override { assert(false); } virtual Slice key() const override { assert(Valid()); return Slice(keys_[current_]); } virtual Slice value() const override { assert(Valid()); return Slice(values_[current_]); } virtual Status status() const override { return Status::OK(); } std::vector log; private: std::vector keys_; std::vector values_; size_t current_; }; class FakeCompaction : public CompactionIterator::CompactionProxy { public: FakeCompaction() = default; virtual int level(size_t compaction_input_level) const { return 0; } virtual bool KeyNotExistsBeyondOutputLevel( const Slice& user_key, std::vector* level_ptrs) const { return false; } virtual bool bottommost_level() const { return false; } virtual int number_levels() const { return 1; } virtual Slice GetLargestUserKey() const { return "\xff\xff\xff\xff\xff\xff\xff\xff\xff"; } }; class CompactionIteratorTest : public testing::Test { public: CompactionIteratorTest() : cmp_(BytewiseComparator()), icmp_(cmp_), snapshots_({}) {} void InitIterators(const std::vector& ks, const std::vector& vs, const std::vector& range_del_ks, const std::vector& range_del_vs, SequenceNumber last_sequence, MergeOperator* merge_op = nullptr, CompactionFilter* filter = nullptr) { std::unique_ptr range_del_iter( new test::VectorIterator(range_del_ks, range_del_vs)); range_del_agg_.reset(new RangeDelAggregator(icmp_, snapshots_)); ASSERT_OK(range_del_agg_->AddTombstones(std::move(range_del_iter))); std::unique_ptr compaction; if (filter) { compaction.reset(new FakeCompaction()); } merge_helper_.reset(new MergeHelper(Env::Default(), cmp_, merge_op, filter, nullptr, 0U, false, 0)); iter_.reset(new LoggingForwardVectorIterator(ks, vs)); iter_->SeekToFirst(); c_iter_.reset(new CompactionIterator( iter_.get(), cmp_, merge_helper_.get(), last_sequence, &snapshots_, kMaxSequenceNumber, Env::Default(), false, range_del_agg_.get(), std::move(compaction), filter)); } void AddSnapshot(SequenceNumber snapshot) { snapshots_.push_back(snapshot); } const Comparator* cmp_; const InternalKeyComparator icmp_; std::vector snapshots_; std::unique_ptr merge_helper_; std::unique_ptr iter_; std::unique_ptr c_iter_; std::unique_ptr range_del_agg_; }; // It is possible that the output of the compaction iterator is empty even if // the input is not. TEST_F(CompactionIteratorTest, EmptyResult) { InitIterators({test::KeyStr("a", 5, kTypeSingleDeletion), test::KeyStr("a", 3, kTypeValue)}, {"", "val"}, {}, {}, 5); c_iter_->SeekToFirst(); ASSERT_FALSE(c_iter_->Valid()); } // If there is a corruption after a single deletion, the corrupted key should // be preserved. TEST_F(CompactionIteratorTest, CorruptionAfterSingleDeletion) { InitIterators({test::KeyStr("a", 5, kTypeSingleDeletion), test::KeyStr("a", 3, kTypeValue, true), test::KeyStr("b", 10, kTypeValue)}, {"", "val", "val2"}, {}, {}, 10); c_iter_->SeekToFirst(); ASSERT_TRUE(c_iter_->Valid()); ASSERT_EQ(test::KeyStr("a", 5, kTypeSingleDeletion), c_iter_->key().ToString()); c_iter_->Next(); ASSERT_TRUE(c_iter_->Valid()); ASSERT_EQ(test::KeyStr("a", 3, kTypeValue, true), c_iter_->key().ToString()); c_iter_->Next(); ASSERT_TRUE(c_iter_->Valid()); ASSERT_EQ(test::KeyStr("b", 10, kTypeValue), c_iter_->key().ToString()); c_iter_->Next(); ASSERT_FALSE(c_iter_->Valid()); } TEST_F(CompactionIteratorTest, SimpleRangeDeletion) { InitIterators({test::KeyStr("morning", 5, kTypeValue), test::KeyStr("morning", 2, kTypeValue), test::KeyStr("night", 3, kTypeValue)}, {"zao", "zao", "wan"}, {test::KeyStr("ma", 4, kTypeRangeDeletion)}, {"mz"}, 5); c_iter_->SeekToFirst(); ASSERT_TRUE(c_iter_->Valid()); ASSERT_EQ(test::KeyStr("morning", 5, kTypeValue), c_iter_->key().ToString()); c_iter_->Next(); ASSERT_TRUE(c_iter_->Valid()); ASSERT_EQ(test::KeyStr("night", 3, kTypeValue), c_iter_->key().ToString()); c_iter_->Next(); ASSERT_FALSE(c_iter_->Valid()); } TEST_F(CompactionIteratorTest, RangeDeletionWithSnapshots) { AddSnapshot(10); std::vector ks1; ks1.push_back(test::KeyStr("ma", 28, kTypeRangeDeletion)); std::vector vs1{"mz"}; std::vector ks2{test::KeyStr("morning", 15, kTypeValue), test::KeyStr("morning", 5, kTypeValue), test::KeyStr("night", 40, kTypeValue), test::KeyStr("night", 20, kTypeValue)}; std::vector vs2{"zao 15", "zao 5", "wan 40", "wan 20"}; InitIterators(ks2, vs2, ks1, vs1, 40); c_iter_->SeekToFirst(); ASSERT_TRUE(c_iter_->Valid()); ASSERT_EQ(test::KeyStr("morning", 5, kTypeValue), c_iter_->key().ToString()); c_iter_->Next(); ASSERT_TRUE(c_iter_->Valid()); ASSERT_EQ(test::KeyStr("night", 40, kTypeValue), c_iter_->key().ToString()); c_iter_->Next(); ASSERT_FALSE(c_iter_->Valid()); } TEST_F(CompactionIteratorTest, CompactionFilterSkipUntil) { // Expect no merging attempts. class MergeOp : public MergeOperator { public: bool FullMergeV2(const MergeOperationInput& merge_in, MergeOperationOutput* merge_out) const override { ADD_FAILURE(); return false; } bool PartialMergeMulti(const Slice& key, const std::deque& operand_list, std::string* new_value, Logger* logger) const override { ADD_FAILURE(); return false; } const char* Name() const override { return "CompactionIteratorTest.CompactionFilterSkipUntil::MergeOp"; } }; class Filter : public CompactionFilter { virtual Decision FilterV2(int level, const Slice& key, ValueType t, const Slice& existing_value, std::string* new_value, std::string* skip_until) const override { std::string k = key.ToString(); std::string v = existing_value.ToString(); // See InitIterators() call below for the sequence of keys and their // filtering decisions. Here we closely assert that compaction filter is // called with the expected keys and only them, and with the right values. if (k == "a") { EXPECT_EQ(ValueType::kValue, t); EXPECT_EQ("av50", v); return Decision::kKeep; } if (k == "b") { EXPECT_EQ(ValueType::kValue, t); EXPECT_EQ("bv60", v); *skip_until = "d+"; return Decision::kRemoveAndSkipUntil; } if (k == "e") { EXPECT_EQ(ValueType::kMergeOperand, t); EXPECT_EQ("em71", v); return Decision::kKeep; } if (k == "f") { if (v == "fm65") { EXPECT_EQ(ValueType::kMergeOperand, t); *skip_until = "f"; } else { EXPECT_EQ("fm30", v); EXPECT_EQ(ValueType::kMergeOperand, t); *skip_until = "g+"; } return Decision::kRemoveAndSkipUntil; } if (k == "h") { EXPECT_EQ(ValueType::kValue, t); EXPECT_EQ("hv91", v); return Decision::kKeep; } if (k == "i") { EXPECT_EQ(ValueType::kValue, t); EXPECT_EQ("iv95", v); *skip_until = "z"; return Decision::kRemoveAndSkipUntil; } ADD_FAILURE(); return Decision::kKeep; } const char* Name() const override { return "CompactionIteratorTest.CompactionFilterSkipUntil::Filter"; } }; MergeOp merge_op; Filter filter; InitIterators( {test::KeyStr("a", 50, kTypeValue), // keep test::KeyStr("a", 45, kTypeMerge), test::KeyStr("b", 60, kTypeValue), // skip to "d+" test::KeyStr("b", 40, kTypeValue), test::KeyStr("c", 35, kTypeValue), test::KeyStr("d", 70, kTypeMerge), test::KeyStr("e", 71, kTypeMerge), // keep test::KeyStr("f", 65, kTypeMerge), // skip to "f", aka keep test::KeyStr("f", 30, kTypeMerge), // skip to "g+" test::KeyStr("f", 25, kTypeValue), test::KeyStr("g", 90, kTypeValue), test::KeyStr("h", 91, kTypeValue), // keep test::KeyStr("i", 95, kTypeValue), // skip to "z" test::KeyStr("j", 99, kTypeValue)}, {"av50", "am45", "bv60", "bv40", "cv35", "dm70", "em71", "fm65", "fm30", "fv25", "gv90", "hv91", "iv95", "jv99"}, {}, {}, kMaxSequenceNumber, &merge_op, &filter); // Compaction should output just "a", "e" and "h" keys. c_iter_->SeekToFirst(); ASSERT_TRUE(c_iter_->Valid()); ASSERT_EQ(test::KeyStr("a", 50, kTypeValue), c_iter_->key().ToString()); ASSERT_EQ("av50", c_iter_->value().ToString()); c_iter_->Next(); ASSERT_TRUE(c_iter_->Valid()); ASSERT_EQ(test::KeyStr("e", 71, kTypeMerge), c_iter_->key().ToString()); ASSERT_EQ("em71", c_iter_->value().ToString()); c_iter_->Next(); ASSERT_TRUE(c_iter_->Valid()); ASSERT_EQ(test::KeyStr("h", 91, kTypeValue), c_iter_->key().ToString()); ASSERT_EQ("hv91", c_iter_->value().ToString()); c_iter_->Next(); ASSERT_FALSE(c_iter_->Valid()); // Check that the compaction iterator did the correct sequence of calls on // the underlying iterator. using A = LoggingForwardVectorIterator::Action; using T = A::Type; std::vector expected_actions = { A(T::SEEK_TO_FIRST), A(T::NEXT), A(T::NEXT), A(T::SEEK, test::KeyStr("d+", kMaxSequenceNumber, kValueTypeForSeek)), A(T::NEXT), A(T::NEXT), A(T::SEEK, test::KeyStr("g+", kMaxSequenceNumber, kValueTypeForSeek)), A(T::NEXT), A(T::SEEK, test::KeyStr("z", kMaxSequenceNumber, kValueTypeForSeek))}; ASSERT_EQ(expected_actions, iter_->log); } } // namespace rocksdb int main(int argc, char** argv) { ::testing::InitGoogleTest(&argc, argv); return RUN_ALL_TESTS(); }