// Copyright (c) 2011-present, Facebook, Inc. All rights reserved. // This source code is licensed under both the GPLv2 (found in the // COPYING file in the root directory) and Apache 2.0 License // (found in the LICENSE.Apache file in the root directory). #include #include #include #include "memtable/stl_wrappers.h" #include "rocksdb/db.h" #include "rocksdb/env.h" #include "test_util/testharness.h" #include "test_util/testutil.h" #include "util/hash.h" #include "util/kv_map.h" #include "util/random.h" #include "util/string_util.h" #include "utilities/merge_operators.h" namespace ROCKSDB_NAMESPACE { namespace { static const Comparator* kTestComparator = nullptr; class KVIter : public Iterator { public: explicit KVIter(const stl_wrappers::KVMap* map) : map_(map), iter_(map_->end()) {} bool Valid() const override { return iter_ != map_->end(); } void SeekToFirst() override { iter_ = map_->begin(); } void SeekToLast() override { if (map_->empty()) { iter_ = map_->end(); } else { iter_ = map_->find(map_->rbegin()->first); } } void Seek(const Slice& k) override { iter_ = map_->lower_bound(k.ToString()); } void SeekForPrev(const Slice& k) override { iter_ = map_->upper_bound(k.ToString()); Prev(); } void Next() override { ++iter_; } void Prev() override { if (iter_ == map_->begin()) { iter_ = map_->end(); return; } --iter_; } Slice key() const override { return iter_->first; } Slice value() const override { return iter_->second; } Status status() const override { return Status::OK(); } private: const stl_wrappers::KVMap* const map_; stl_wrappers::KVMap::const_iterator iter_; }; void AssertItersEqual(Iterator* iter1, Iterator* iter2) { ASSERT_EQ(iter1->Valid(), iter2->Valid()); if (iter1->Valid()) { ASSERT_EQ(iter1->key().ToString(), iter2->key().ToString()); ASSERT_EQ(iter1->value().ToString(), iter2->value().ToString()); } } // Measuring operations on DB (expect to be empty). // source_strings are candidate keys void DoRandomIteraratorTest(DB* db, std::vector source_strings, Random* rnd, int num_writes, int num_iter_ops, int num_trigger_flush) { stl_wrappers::KVMap map((stl_wrappers::LessOfComparator(kTestComparator))); for (int i = 0; i < num_writes; i++) { if (num_trigger_flush > 0 && i != 0 && i % num_trigger_flush == 0) { ASSERT_OK(db->Flush(FlushOptions())); } int type = rnd->Uniform(2); int index = rnd->Uniform(static_cast(source_strings.size())); auto& key = source_strings[index]; switch (type) { case 0: // put map[key] = key; ASSERT_OK(db->Put(WriteOptions(), key, key)); break; case 1: // delete if (map.find(key) != map.end()) { map.erase(key); } ASSERT_OK(db->Delete(WriteOptions(), key)); break; default: assert(false); } } std::unique_ptr iter(db->NewIterator(ReadOptions())); std::unique_ptr result_iter(new KVIter(&map)); bool is_valid = false; for (int i = 0; i < num_iter_ops; i++) { // Random walk and make sure iter and result_iter returns the // same key and value int type = rnd->Uniform(6); ASSERT_OK(iter->status()); switch (type) { case 0: // Seek to First iter->SeekToFirst(); result_iter->SeekToFirst(); break; case 1: // Seek to last iter->SeekToLast(); result_iter->SeekToLast(); break; case 2: { // Seek to random key auto key_idx = rnd->Uniform(static_cast(source_strings.size())); auto key = source_strings[key_idx]; iter->Seek(key); result_iter->Seek(key); break; } case 3: // Next if (is_valid) { iter->Next(); result_iter->Next(); } else { continue; } break; case 4: // Prev if (is_valid) { iter->Prev(); result_iter->Prev(); } else { continue; } break; default: { assert(type == 5); auto key_idx = rnd->Uniform(static_cast(source_strings.size())); auto key = source_strings[key_idx]; std::string result; auto status = db->Get(ReadOptions(), key, &result); if (map.find(key) == map.end()) { ASSERT_TRUE(status.IsNotFound()); } else { ASSERT_OK(status); ASSERT_EQ(map[key], result); } break; } } AssertItersEqual(iter.get(), result_iter.get()); is_valid = iter->Valid(); } } class DoubleComparator : public Comparator { public: DoubleComparator() {} const char* Name() const override { return "DoubleComparator"; } int Compare(const Slice& a, const Slice& b) const override { #ifndef CYGWIN double da = std::stod(a.ToString()); double db = std::stod(b.ToString()); #else double da = std::strtod(a.ToString().c_str(), 0 /* endptr */); double db = std::strtod(a.ToString().c_str(), 0 /* endptr */); #endif if (da == db) { return a.compare(b); } else if (da > db) { return 1; } else { return -1; } } void FindShortestSeparator(std::string* /*start*/, const Slice& /*limit*/) const override {} void FindShortSuccessor(std::string* /*key*/) const override {} }; class HashComparator : public Comparator { public: HashComparator() {} const char* Name() const override { return "HashComparator"; } int Compare(const Slice& a, const Slice& b) const override { uint32_t ha = Hash(a.data(), a.size(), 66); uint32_t hb = Hash(b.data(), b.size(), 66); if (ha == hb) { return a.compare(b); } else if (ha > hb) { return 1; } else { return -1; } } void FindShortestSeparator(std::string* /*start*/, const Slice& /*limit*/) const override {} void FindShortSuccessor(std::string* /*key*/) const override {} }; class TwoStrComparator : public Comparator { public: TwoStrComparator() {} const char* Name() const override { return "TwoStrComparator"; } int Compare(const Slice& a, const Slice& b) const override { assert(a.size() >= 2); assert(b.size() >= 2); size_t size_a1 = static_cast(a[0]); size_t size_b1 = static_cast(b[0]); size_t size_a2 = static_cast(a[1]); size_t size_b2 = static_cast(b[1]); assert(size_a1 + size_a2 + 2 == a.size()); assert(size_b1 + size_b2 + 2 == b.size()); Slice a1 = Slice(a.data() + 2, size_a1); Slice b1 = Slice(b.data() + 2, size_b1); Slice a2 = Slice(a.data() + 2 + size_a1, size_a2); Slice b2 = Slice(b.data() + 2 + size_b1, size_b2); if (a1 != b1) { return a1.compare(b1); } return a2.compare(b2); } void FindShortestSeparator(std::string* /*start*/, const Slice& /*limit*/) const override {} void FindShortSuccessor(std::string* /*key*/) const override {} }; } // anonymous namespace class ComparatorDBTest : public testing::Test, virtual public ::testing::WithParamInterface { private: std::string dbname_; Env* env_; DB* db_; Options last_options_; std::unique_ptr comparator_guard; public: ComparatorDBTest() : env_(Env::Default()), db_(nullptr) { kTestComparator = BytewiseComparator(); dbname_ = test::PerThreadDBPath("comparator_db_test"); BlockBasedTableOptions toptions; toptions.format_version = GetParam(); last_options_.table_factory.reset( ROCKSDB_NAMESPACE::NewBlockBasedTableFactory(toptions)); EXPECT_OK(DestroyDB(dbname_, last_options_)); } ~ComparatorDBTest() override { delete db_; EXPECT_OK(DestroyDB(dbname_, last_options_)); kTestComparator = BytewiseComparator(); } DB* GetDB() { return db_; } void SetOwnedComparator(const Comparator* cmp, bool owner = true) { if (owner) { comparator_guard.reset(cmp); } else { comparator_guard.reset(); } kTestComparator = cmp; last_options_.comparator = cmp; } // Return the current option configuration. Options* GetOptions() { return &last_options_; } void DestroyAndReopen() { // Destroy using last options Destroy(); ASSERT_OK(TryReopen()); } void Destroy() { delete db_; db_ = nullptr; ASSERT_OK(DestroyDB(dbname_, last_options_)); } Status TryReopen() { delete db_; db_ = nullptr; last_options_.create_if_missing = true; return DB::Open(last_options_, dbname_, &db_); } }; INSTANTIATE_TEST_CASE_P(FormatDef, ComparatorDBTest, testing::Values(test::kDefaultFormatVersion)); INSTANTIATE_TEST_CASE_P(FormatLatest, ComparatorDBTest, testing::Values(kLatestFormatVersion)); TEST_P(ComparatorDBTest, Bytewise) { for (int rand_seed = 301; rand_seed < 306; rand_seed++) { DestroyAndReopen(); Random rnd(rand_seed); DoRandomIteraratorTest(GetDB(), {"a", "b", "c", "d", "e", "f", "g", "h", "i"}, &rnd, 8, 100, 3); } } TEST_P(ComparatorDBTest, SimpleSuffixReverseComparator) { SetOwnedComparator(new test::SimpleSuffixReverseComparator()); for (int rnd_seed = 301; rnd_seed < 316; rnd_seed++) { Options* opt = GetOptions(); opt->comparator = kTestComparator; DestroyAndReopen(); Random rnd(rnd_seed); std::vector source_strings; std::vector source_prefixes; // Randomly generate 5 prefixes for (int i = 0; i < 5; i++) { source_prefixes.push_back(rnd.HumanReadableString(8)); } for (int j = 0; j < 20; j++) { int prefix_index = rnd.Uniform(static_cast(source_prefixes.size())); std::string key = source_prefixes[prefix_index] + rnd.HumanReadableString(rnd.Uniform(8)); source_strings.push_back(key); } DoRandomIteraratorTest(GetDB(), source_strings, &rnd, 30, 600, 66); } } TEST_P(ComparatorDBTest, Uint64Comparator) { SetOwnedComparator(test::Uint64Comparator(), false /* owner */); for (int rnd_seed = 301; rnd_seed < 316; rnd_seed++) { Options* opt = GetOptions(); opt->comparator = kTestComparator; DestroyAndReopen(); Random rnd(rnd_seed); Random64 rnd64(rnd_seed); std::vector source_strings; // Randomly generate source keys for (int i = 0; i < 100; i++) { uint64_t r = rnd64.Next(); std::string str; str.resize(8); memcpy(&str[0], static_cast(&r), 8); source_strings.push_back(str); } DoRandomIteraratorTest(GetDB(), source_strings, &rnd, 200, 1000, 66); } } TEST_P(ComparatorDBTest, DoubleComparator) { SetOwnedComparator(new DoubleComparator()); for (int rnd_seed = 301; rnd_seed < 316; rnd_seed++) { Options* opt = GetOptions(); opt->comparator = kTestComparator; DestroyAndReopen(); Random rnd(rnd_seed); std::vector source_strings; // Randomly generate source keys for (int i = 0; i < 100; i++) { uint32_t r = rnd.Next(); uint32_t divide_order = rnd.Uniform(8); double to_divide = 1.0; for (uint32_t j = 0; j < divide_order; j++) { to_divide *= 10.0; } source_strings.push_back(std::to_string(r / to_divide)); } DoRandomIteraratorTest(GetDB(), source_strings, &rnd, 200, 1000, 66); } } TEST_P(ComparatorDBTest, HashComparator) { SetOwnedComparator(new HashComparator()); for (int rnd_seed = 301; rnd_seed < 316; rnd_seed++) { Options* opt = GetOptions(); opt->comparator = kTestComparator; DestroyAndReopen(); Random rnd(rnd_seed); std::vector source_strings; // Randomly generate source keys for (int i = 0; i < 100; i++) { source_strings.push_back(test::RandomKey(&rnd, 8)); } DoRandomIteraratorTest(GetDB(), source_strings, &rnd, 200, 1000, 66); } } TEST_P(ComparatorDBTest, TwoStrComparator) { SetOwnedComparator(new TwoStrComparator()); for (int rnd_seed = 301; rnd_seed < 316; rnd_seed++) { Options* opt = GetOptions(); opt->comparator = kTestComparator; DestroyAndReopen(); Random rnd(rnd_seed); std::vector source_strings; // Randomly generate source keys for (int i = 0; i < 100; i++) { std::string str; uint32_t size1 = rnd.Uniform(8); uint32_t size2 = rnd.Uniform(8); str.append(1, static_cast(size1)); str.append(1, static_cast(size2)); str.append(test::RandomKey(&rnd, size1)); str.append(test::RandomKey(&rnd, size2)); source_strings.push_back(str); } DoRandomIteraratorTest(GetDB(), source_strings, &rnd, 200, 1000, 66); } } namespace { void VerifyNotSuccessor(const Slice& s, const Slice& t) { auto bc = BytewiseComparator(); auto rbc = ReverseBytewiseComparator(); ASSERT_FALSE(bc->IsSameLengthImmediateSuccessor(s, t)); ASSERT_FALSE(rbc->IsSameLengthImmediateSuccessor(s, t)); ASSERT_FALSE(bc->IsSameLengthImmediateSuccessor(t, s)); ASSERT_FALSE(rbc->IsSameLengthImmediateSuccessor(t, s)); } void VerifySuccessor(const Slice& s, const Slice& t) { auto bc = BytewiseComparator(); auto rbc = ReverseBytewiseComparator(); ASSERT_TRUE(bc->IsSameLengthImmediateSuccessor(s, t)); ASSERT_FALSE(rbc->IsSameLengthImmediateSuccessor(s, t)); ASSERT_FALSE(bc->IsSameLengthImmediateSuccessor(t, s)); // Should be true but that increases exposure to a design bug in // auto_prefix_mode, so currently set to FALSE ASSERT_FALSE(rbc->IsSameLengthImmediateSuccessor(t, s)); } } // anonymous namespace TEST_P(ComparatorDBTest, IsSameLengthImmediateSuccessor) { { // different length Slice s("abcxy"); Slice t("abcxyz"); VerifyNotSuccessor(s, t); } { Slice s("abcxyz"); Slice t("abcxy"); VerifyNotSuccessor(s, t); } { // not last byte different Slice s("abc1xyz"); Slice t("abc2xyz"); VerifyNotSuccessor(s, t); } { // same string Slice s("abcxyz"); Slice t("abcxyz"); VerifyNotSuccessor(s, t); } { Slice s("abcxy"); Slice t("abcxz"); VerifySuccessor(s, t); } { const char s_array[] = "\x50\x8a\xac"; const char t_array[] = "\x50\x8a\xad"; Slice s(s_array); Slice t(t_array); VerifySuccessor(s, t); } { const char s_array[] = "\x50\x8a\xff"; const char t_array[] = "\x50\x8b\x00"; Slice s(s_array, 3); Slice t(t_array, 3); VerifySuccessor(s, t); } { const char s_array[] = "\x50\x8a\xff\xff"; const char t_array[] = "\x50\x8b\x00\x00"; Slice s(s_array, 4); Slice t(t_array, 4); VerifySuccessor(s, t); } { const char s_array[] = "\x50\x8a\xff\xff"; const char t_array[] = "\x50\x8b\x00\x01"; Slice s(s_array, 4); Slice t(t_array, 4); VerifyNotSuccessor(s, t); } } TEST_P(ComparatorDBTest, FindShortestSeparator) { std::string s1 = "abc1xyz"; std::string s2 = "abc3xy"; BytewiseComparator()->FindShortestSeparator(&s1, s2); ASSERT_EQ("abc2", s1); s1 = "abc5xyztt"; ReverseBytewiseComparator()->FindShortestSeparator(&s1, s2); ASSERT_EQ("abc5", s1); s1 = "abc3"; s2 = "abc2xy"; ReverseBytewiseComparator()->FindShortestSeparator(&s1, s2); ASSERT_EQ("abc3", s1); s1 = "abc3xyz"; s2 = "abc2xy"; ReverseBytewiseComparator()->FindShortestSeparator(&s1, s2); ASSERT_EQ("abc3", s1); s1 = "abc3xyz"; s2 = "abc2"; ReverseBytewiseComparator()->FindShortestSeparator(&s1, s2); ASSERT_EQ("abc3", s1); std::string old_s1 = s1 = "abc2xy"; s2 = "abc2"; ReverseBytewiseComparator()->FindShortestSeparator(&s1, s2); ASSERT_TRUE(old_s1 >= s1); ASSERT_TRUE(s1 > s2); } TEST_P(ComparatorDBTest, SeparatorSuccessorRandomizeTest) { // Char list for boundary cases. std::array char_list{{0, 1, 2, 253, 254, 255}}; Random rnd(301); for (int attempts = 0; attempts < 1000; attempts++) { uint32_t size1 = rnd.Skewed(4); uint32_t size2; if (rnd.OneIn(2)) { // size2 to be random size size2 = rnd.Skewed(4); } else { // size1 is within [-2, +2] of size1 int diff = static_cast(rnd.Uniform(5)) - 2; int tmp_size2 = static_cast(size1) + diff; if (tmp_size2 < 0) { tmp_size2 = 0; } size2 = static_cast(tmp_size2); } std::string s1; std::string s2; for (uint32_t i = 0; i < size1; i++) { if (rnd.OneIn(2)) { // Use random byte s1 += static_cast(rnd.Uniform(256)); } else { // Use one byte in char_list char c = static_cast(char_list[rnd.Uniform(sizeof(char_list))]); s1 += c; } } // First set s2 to be the same as s1, and then modify s2. s2 = s1; s2.resize(size2); // We start from the back of the string if (size2 > 0) { uint32_t pos = size2 - 1; do { if (pos >= size1 || rnd.OneIn(4)) { // For 1/4 chance, use random byte s2[pos] = static_cast(rnd.Uniform(256)); } else if (rnd.OneIn(4)) { // In 1/4 chance, stop here. break; } else { // Create a char within [-2, +2] of the matching char of s1. int diff = static_cast(rnd.Uniform(5)) - 2; // char may be signed or unsigned based on platform. int s1_char = static_cast(static_cast(s1[pos])); int s2_char = s1_char + diff; if (s2_char < 0) { s2_char = 0; } if (s2_char > 255) { s2_char = 255; } s2[pos] = static_cast(s2_char); } } while (pos-- != 0); } // Test separators for (int rev = 0; rev < 2; rev++) { if (rev == 1) { // switch s1 and s2 std::string t = s1; s1 = s2; s2 = t; } std::string separator = s1; BytewiseComparator()->FindShortestSeparator(&separator, s2); std::string rev_separator = s1; ReverseBytewiseComparator()->FindShortestSeparator(&rev_separator, s2); if (s1 == s2) { ASSERT_EQ(s1, separator); ASSERT_EQ(s2, rev_separator); } else if (s1 < s2) { ASSERT_TRUE(s1 <= separator); ASSERT_TRUE(s2 > separator); ASSERT_LE(separator.size(), std::max(s1.size(), s2.size())); ASSERT_EQ(s1, rev_separator); } else { ASSERT_TRUE(s1 >= rev_separator); ASSERT_TRUE(s2 < rev_separator); ASSERT_LE(rev_separator.size(), std::max(s1.size(), s2.size())); ASSERT_EQ(s1, separator); } } // Test successors std::string succ = s1; BytewiseComparator()->FindShortSuccessor(&succ); ASSERT_TRUE(succ >= s1); succ = s1; ReverseBytewiseComparator()->FindShortSuccessor(&succ); ASSERT_TRUE(succ <= s1); } } } // namespace ROCKSDB_NAMESPACE int main(int argc, char** argv) { ROCKSDB_NAMESPACE::port::InstallStackTraceHandler(); ::testing::InitGoogleTest(&argc, argv); return RUN_ALL_TESTS(); }