// 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 "table/block_based/block.h" #include #include #include #include #include #include #include #include "db/db_test_util.h" #include "db/dbformat.h" #include "db/memtable.h" #include "db/write_batch_internal.h" #include "rocksdb/db.h" #include "rocksdb/env.h" #include "rocksdb/iterator.h" #include "rocksdb/slice_transform.h" #include "rocksdb/table.h" #include "table/block_based/block_based_table_reader.h" #include "table/block_based/block_builder.h" #include "table/format.h" #include "test_util/testharness.h" #include "test_util/testutil.h" #include "util/random.h" namespace ROCKSDB_NAMESPACE { std::string GenerateInternalKey(int primary_key, int secondary_key, int padding_size, Random *rnd) { char buf[50]; char *p = &buf[0]; snprintf(buf, sizeof(buf), "%6d%4d", primary_key, secondary_key); std::string k(p); if (padding_size) { k += rnd->RandomString(padding_size); } AppendInternalKeyFooter(&k, 0 /* seqno */, kTypeValue); return k; } // Generate random key value pairs. // The generated key will be sorted. You can tune the parameters to generated // different kinds of test key/value pairs for different scenario. void GenerateRandomKVs(std::vector *keys, std::vector *values, const int from, const int len, const int step = 1, const int padding_size = 0, const int keys_share_prefix = 1) { Random rnd(302); // generate different prefix for (int i = from; i < from + len; i += step) { // generating keys that shares the prefix for (int j = 0; j < keys_share_prefix; ++j) { // `DataBlockIter` assumes it reads only internal keys. keys->emplace_back(GenerateInternalKey(i, j, padding_size, &rnd)); // 100 bytes values values->emplace_back(rnd.RandomString(100)); } } } class BlockTest : public testing::Test {}; // block test TEST_F(BlockTest, SimpleTest) { Random rnd(301); Options options = Options(); std::vector keys; std::vector values; BlockBuilder builder(16); int num_records = 100000; GenerateRandomKVs(&keys, &values, 0, num_records); // add a bunch of records to a block for (int i = 0; i < num_records; i++) { builder.Add(keys[i], values[i]); } // read serialized contents of the block Slice rawblock = builder.Finish(); // create block reader BlockContents contents; contents.data = rawblock; Block reader(std::move(contents)); // read contents of block sequentially int count = 0; InternalIterator *iter = reader.NewDataIterator(options.comparator, kDisableGlobalSequenceNumber); for (iter->SeekToFirst(); iter->Valid(); count++, iter->Next()) { // read kv from block Slice k = iter->key(); Slice v = iter->value(); // compare with lookaside array ASSERT_EQ(k.ToString().compare(keys[count]), 0); ASSERT_EQ(v.ToString().compare(values[count]), 0); } delete iter; // read block contents randomly iter = reader.NewDataIterator(options.comparator, kDisableGlobalSequenceNumber); for (int i = 0; i < num_records; i++) { // find a random key in the lookaside array int index = rnd.Uniform(num_records); Slice k(keys[index]); // search in block for this key iter->Seek(k); ASSERT_TRUE(iter->Valid()); Slice v = iter->value(); ASSERT_EQ(v.ToString().compare(values[index]), 0); } delete iter; } // return the block contents BlockContents GetBlockContents(std::unique_ptr *builder, const std::vector &keys, const std::vector &values, const int /*prefix_group_size*/ = 1) { builder->reset(new BlockBuilder(1 /* restart interval */)); // Add only half of the keys for (size_t i = 0; i < keys.size(); ++i) { (*builder)->Add(keys[i], values[i]); } Slice rawblock = (*builder)->Finish(); BlockContents contents; contents.data = rawblock; return contents; } void CheckBlockContents(BlockContents contents, const int max_key, const std::vector &keys, const std::vector &values) { const size_t prefix_size = 6; // create block reader BlockContents contents_ref(contents.data); Block reader1(std::move(contents)); Block reader2(std::move(contents_ref)); std::unique_ptr prefix_extractor( NewFixedPrefixTransform(prefix_size)); std::unique_ptr regular_iter(reader2.NewDataIterator( BytewiseComparator(), kDisableGlobalSequenceNumber)); // Seek existent keys for (size_t i = 0; i < keys.size(); i++) { regular_iter->Seek(keys[i]); ASSERT_OK(regular_iter->status()); ASSERT_TRUE(regular_iter->Valid()); Slice v = regular_iter->value(); ASSERT_EQ(v.ToString().compare(values[i]), 0); } // Seek non-existent keys. // For hash index, if no key with a given prefix is not found, iterator will // simply be set as invalid; whereas the binary search based iterator will // return the one that is closest. for (int i = 1; i < max_key - 1; i += 2) { // `DataBlockIter` assumes its APIs receive only internal keys. auto key = GenerateInternalKey(i, 0, 0, nullptr); regular_iter->Seek(key); ASSERT_TRUE(regular_iter->Valid()); } } // In this test case, no two key share same prefix. TEST_F(BlockTest, SimpleIndexHash) { const int kMaxKey = 100000; std::vector keys; std::vector values; GenerateRandomKVs(&keys, &values, 0 /* first key id */, kMaxKey /* last key id */, 2 /* step */, 8 /* padding size (8 bytes randomly generated suffix) */); std::unique_ptr builder; auto contents = GetBlockContents(&builder, keys, values); CheckBlockContents(std::move(contents), kMaxKey, keys, values); } TEST_F(BlockTest, IndexHashWithSharedPrefix) { const int kMaxKey = 100000; // for each prefix, there will be 5 keys starts with it. const int kPrefixGroup = 5; std::vector keys; std::vector values; // Generate keys with same prefix. GenerateRandomKVs(&keys, &values, 0, // first key id kMaxKey, // last key id 2, // step 10, // padding size, kPrefixGroup); std::unique_ptr builder; auto contents = GetBlockContents(&builder, keys, values, kPrefixGroup); CheckBlockContents(std::move(contents), kMaxKey, keys, values); } // A slow and accurate version of BlockReadAmpBitmap that simply store // all the marked ranges in a set. class BlockReadAmpBitmapSlowAndAccurate { public: void Mark(size_t start_offset, size_t end_offset) { assert(end_offset >= start_offset); marked_ranges_.emplace(end_offset, start_offset); } void ResetCheckSequence() { iter_valid_ = false; } // Return true if any byte in this range was Marked // This does linear search from the previous position. When calling // multiple times, `offset` needs to be incremental to get correct results. // Call ResetCheckSequence() to reset it. bool IsPinMarked(size_t offset) { if (iter_valid_) { // Has existing iterator, try linear search from // the iterator. for (int i = 0; i < 64; i++) { if (offset < iter_->second) { return false; } if (offset <= iter_->first) { return true; } iter_++; if (iter_ == marked_ranges_.end()) { iter_valid_ = false; return false; } } } // Initial call or have linear searched too many times. // Do binary search. iter_ = marked_ranges_.lower_bound( std::make_pair(offset, static_cast(0))); if (iter_ == marked_ranges_.end()) { iter_valid_ = false; return false; } iter_valid_ = true; return offset <= iter_->first && offset >= iter_->second; } private: std::set> marked_ranges_; std::set>::iterator iter_; bool iter_valid_ = false; }; TEST_F(BlockTest, BlockReadAmpBitmap) { uint32_t pin_offset = 0; SyncPoint::GetInstance()->SetCallBack( "BlockReadAmpBitmap:rnd", [&pin_offset](void *arg) { pin_offset = *(static_cast(arg)); }); SyncPoint::GetInstance()->EnableProcessing(); std::vector block_sizes = { 1, // 1 byte 32, // 32 bytes 61, // 61 bytes 64, // 64 bytes 512, // 0.5 KB 1024, // 1 KB 1024 * 4, // 4 KB 1024 * 10, // 10 KB 1024 * 50, // 50 KB 1024 * 1024 * 4, // 5 MB 777, 124653, }; const size_t kBytesPerBit = 64; Random rnd(301); for (size_t block_size : block_sizes) { std::shared_ptr stats = ROCKSDB_NAMESPACE::CreateDBStatistics(); BlockReadAmpBitmap read_amp_bitmap(block_size, kBytesPerBit, stats.get()); BlockReadAmpBitmapSlowAndAccurate read_amp_slow_and_accurate; size_t needed_bits = (block_size / kBytesPerBit); if (block_size % kBytesPerBit != 0) { needed_bits++; } ASSERT_EQ(stats->getTickerCount(READ_AMP_TOTAL_READ_BYTES), block_size); // Generate some random entries std::vector random_entry_offsets; for (int i = 0; i < 1000; i++) { random_entry_offsets.push_back(rnd.Next() % block_size); } std::sort(random_entry_offsets.begin(), random_entry_offsets.end()); auto it = std::unique(random_entry_offsets.begin(), random_entry_offsets.end()); random_entry_offsets.resize( std::distance(random_entry_offsets.begin(), it)); std::vector> random_entries; for (size_t i = 0; i < random_entry_offsets.size(); i++) { size_t entry_start = random_entry_offsets[i]; size_t entry_end; if (i + 1 < random_entry_offsets.size()) { entry_end = random_entry_offsets[i + 1] - 1; } else { entry_end = block_size - 1; } random_entries.emplace_back(entry_start, entry_end); } for (size_t i = 0; i < random_entries.size(); i++) { read_amp_slow_and_accurate.ResetCheckSequence(); auto ¤t_entry = random_entries[rnd.Next() % random_entries.size()]; read_amp_bitmap.Mark(static_cast(current_entry.first), static_cast(current_entry.second)); read_amp_slow_and_accurate.Mark(current_entry.first, current_entry.second); size_t total_bits = 0; for (size_t bit_idx = 0; bit_idx < needed_bits; bit_idx++) { total_bits += read_amp_slow_and_accurate.IsPinMarked( bit_idx * kBytesPerBit + pin_offset); } size_t expected_estimate_useful = total_bits * kBytesPerBit; size_t got_estimate_useful = stats->getTickerCount(READ_AMP_ESTIMATE_USEFUL_BYTES); ASSERT_EQ(expected_estimate_useful, got_estimate_useful); } } SyncPoint::GetInstance()->DisableProcessing(); SyncPoint::GetInstance()->ClearAllCallBacks(); } TEST_F(BlockTest, BlockWithReadAmpBitmap) { Random rnd(301); Options options = Options(); std::vector keys; std::vector values; BlockBuilder builder(16); int num_records = 10000; GenerateRandomKVs(&keys, &values, 0, num_records, 1); // add a bunch of records to a block for (int i = 0; i < num_records; i++) { builder.Add(keys[i], values[i]); } Slice rawblock = builder.Finish(); const size_t kBytesPerBit = 8; // Read the block sequentially using Next() { std::shared_ptr stats = ROCKSDB_NAMESPACE::CreateDBStatistics(); // create block reader BlockContents contents; contents.data = rawblock; Block reader(std::move(contents), kBytesPerBit, stats.get()); // read contents of block sequentially size_t read_bytes = 0; DataBlockIter *iter = reader.NewDataIterator( options.comparator, kDisableGlobalSequenceNumber, nullptr, stats.get()); for (iter->SeekToFirst(); iter->Valid(); iter->Next()) { iter->value(); read_bytes += iter->TEST_CurrentEntrySize(); double semi_acc_read_amp = static_cast(read_bytes) / rawblock.size(); double read_amp = static_cast(stats->getTickerCount( READ_AMP_ESTIMATE_USEFUL_BYTES)) / stats->getTickerCount(READ_AMP_TOTAL_READ_BYTES); // Error in read amplification will be less than 1% if we are reading // sequentially double error_pct = fabs(semi_acc_read_amp - read_amp) * 100; EXPECT_LT(error_pct, 1); } delete iter; } // Read the block sequentially using Seek() { std::shared_ptr stats = ROCKSDB_NAMESPACE::CreateDBStatistics(); // create block reader BlockContents contents; contents.data = rawblock; Block reader(std::move(contents), kBytesPerBit, stats.get()); size_t read_bytes = 0; DataBlockIter *iter = reader.NewDataIterator( options.comparator, kDisableGlobalSequenceNumber, nullptr, stats.get()); for (int i = 0; i < num_records; i++) { Slice k(keys[i]); // search in block for this key iter->Seek(k); iter->value(); read_bytes += iter->TEST_CurrentEntrySize(); double semi_acc_read_amp = static_cast(read_bytes) / rawblock.size(); double read_amp = static_cast(stats->getTickerCount( READ_AMP_ESTIMATE_USEFUL_BYTES)) / stats->getTickerCount(READ_AMP_TOTAL_READ_BYTES); // Error in read amplification will be less than 1% if we are reading // sequentially double error_pct = fabs(semi_acc_read_amp - read_amp) * 100; EXPECT_LT(error_pct, 1); } delete iter; } // Read the block randomly { std::shared_ptr stats = ROCKSDB_NAMESPACE::CreateDBStatistics(); // create block reader BlockContents contents; contents.data = rawblock; Block reader(std::move(contents), kBytesPerBit, stats.get()); size_t read_bytes = 0; DataBlockIter *iter = reader.NewDataIterator( options.comparator, kDisableGlobalSequenceNumber, nullptr, stats.get()); std::unordered_set read_keys; for (int i = 0; i < num_records; i++) { int index = rnd.Uniform(num_records); Slice k(keys[index]); iter->Seek(k); iter->value(); if (read_keys.find(index) == read_keys.end()) { read_keys.insert(index); read_bytes += iter->TEST_CurrentEntrySize(); } double semi_acc_read_amp = static_cast(read_bytes) / rawblock.size(); double read_amp = static_cast(stats->getTickerCount( READ_AMP_ESTIMATE_USEFUL_BYTES)) / stats->getTickerCount(READ_AMP_TOTAL_READ_BYTES); double error_pct = fabs(semi_acc_read_amp - read_amp) * 100; // Error in read amplification will be less than 2% if we are reading // randomly EXPECT_LT(error_pct, 2); } delete iter; } } TEST_F(BlockTest, ReadAmpBitmapPow2) { std::shared_ptr stats = ROCKSDB_NAMESPACE::CreateDBStatistics(); ASSERT_EQ(BlockReadAmpBitmap(100, 1, stats.get()).GetBytesPerBit(), 1u); ASSERT_EQ(BlockReadAmpBitmap(100, 2, stats.get()).GetBytesPerBit(), 2u); ASSERT_EQ(BlockReadAmpBitmap(100, 4, stats.get()).GetBytesPerBit(), 4u); ASSERT_EQ(BlockReadAmpBitmap(100, 8, stats.get()).GetBytesPerBit(), 8u); ASSERT_EQ(BlockReadAmpBitmap(100, 16, stats.get()).GetBytesPerBit(), 16u); ASSERT_EQ(BlockReadAmpBitmap(100, 32, stats.get()).GetBytesPerBit(), 32u); ASSERT_EQ(BlockReadAmpBitmap(100, 3, stats.get()).GetBytesPerBit(), 2u); ASSERT_EQ(BlockReadAmpBitmap(100, 7, stats.get()).GetBytesPerBit(), 4u); ASSERT_EQ(BlockReadAmpBitmap(100, 11, stats.get()).GetBytesPerBit(), 8u); ASSERT_EQ(BlockReadAmpBitmap(100, 17, stats.get()).GetBytesPerBit(), 16u); ASSERT_EQ(BlockReadAmpBitmap(100, 33, stats.get()).GetBytesPerBit(), 32u); ASSERT_EQ(BlockReadAmpBitmap(100, 35, stats.get()).GetBytesPerBit(), 32u); } class IndexBlockTest : public testing::Test, public testing::WithParamInterface> { public: IndexBlockTest() = default; bool useValueDeltaEncoding() const { return std::get<0>(GetParam()); } bool includeFirstKey() const { return std::get<1>(GetParam()); } }; // Similar to GenerateRandomKVs but for index block contents. void GenerateRandomIndexEntries(std::vector *separators, std::vector *block_handles, std::vector *first_keys, const int len, bool zero_seqno = false) { Random rnd(42); // For each of `len` blocks, we need to generate a first and last key. // Let's generate n*2 random keys, sort them, group into consecutive pairs. std::set keys; while ((int)keys.size() < len * 2) { // Keys need to be at least 8 bytes long to look like internal keys. std::string new_key = test::RandomKey(&rnd, 12); if (zero_seqno) { AppendInternalKeyFooter(&new_key, 0 /* seqno */, kTypeValue); } keys.insert(std::move(new_key)); } uint64_t offset = 0; for (auto it = keys.begin(); it != keys.end();) { first_keys->emplace_back(*it++); separators->emplace_back(*it++); uint64_t size = rnd.Uniform(1024 * 16); BlockHandle handle(offset, size); offset += size + BlockBasedTable::kBlockTrailerSize; block_handles->emplace_back(handle); } } TEST_P(IndexBlockTest, IndexValueEncodingTest) { Random rnd(301); Options options = Options(); std::vector separators; std::vector block_handles; std::vector first_keys; const bool kUseDeltaEncoding = true; BlockBuilder builder(16, kUseDeltaEncoding, useValueDeltaEncoding()); int num_records = 100; GenerateRandomIndexEntries(&separators, &block_handles, &first_keys, num_records); BlockHandle last_encoded_handle; for (int i = 0; i < num_records; i++) { IndexValue entry(block_handles[i], first_keys[i]); std::string encoded_entry; std::string delta_encoded_entry; entry.EncodeTo(&encoded_entry, includeFirstKey(), nullptr); if (useValueDeltaEncoding() && i > 0) { entry.EncodeTo(&delta_encoded_entry, includeFirstKey(), &last_encoded_handle); } last_encoded_handle = entry.handle; const Slice delta_encoded_entry_slice(delta_encoded_entry); builder.Add(separators[i], encoded_entry, &delta_encoded_entry_slice); } // read serialized contents of the block Slice rawblock = builder.Finish(); // create block reader BlockContents contents; contents.data = rawblock; Block reader(std::move(contents)); const bool kTotalOrderSeek = true; const bool kIncludesSeq = true; const bool kValueIsFull = !useValueDeltaEncoding(); IndexBlockIter *kNullIter = nullptr; Statistics *kNullStats = nullptr; // read contents of block sequentially InternalIteratorBase *iter = reader.NewIndexIterator( options.comparator, kDisableGlobalSequenceNumber, kNullIter, kNullStats, kTotalOrderSeek, includeFirstKey(), kIncludesSeq, kValueIsFull); iter->SeekToFirst(); for (int index = 0; index < num_records; ++index) { ASSERT_TRUE(iter->Valid()); Slice k = iter->key(); IndexValue v = iter->value(); EXPECT_EQ(separators[index], k.ToString()); EXPECT_EQ(block_handles[index].offset(), v.handle.offset()); EXPECT_EQ(block_handles[index].size(), v.handle.size()); EXPECT_EQ(includeFirstKey() ? first_keys[index] : "", v.first_internal_key.ToString()); iter->Next(); } delete iter; // read block contents randomly iter = reader.NewIndexIterator( options.comparator, kDisableGlobalSequenceNumber, kNullIter, kNullStats, kTotalOrderSeek, includeFirstKey(), kIncludesSeq, kValueIsFull); for (int i = 0; i < num_records * 2; i++) { // find a random key in the lookaside array int index = rnd.Uniform(num_records); Slice k(separators[index]); // search in block for this key iter->Seek(k); ASSERT_TRUE(iter->Valid()); IndexValue v = iter->value(); EXPECT_EQ(separators[index], iter->key().ToString()); EXPECT_EQ(block_handles[index].offset(), v.handle.offset()); EXPECT_EQ(block_handles[index].size(), v.handle.size()); EXPECT_EQ(includeFirstKey() ? first_keys[index] : "", v.first_internal_key.ToString()); } delete iter; } INSTANTIATE_TEST_CASE_P(P, IndexBlockTest, ::testing::Values(std::make_tuple(false, false), std::make_tuple(false, true), std::make_tuple(true, false), std::make_tuple(true, true))); class BlockPerKVChecksumTest : public DBTestBase { public: BlockPerKVChecksumTest() : DBTestBase("block_per_kv_checksum", /*env_do_fsync=*/false) {} template void TestIterateForward(std::unique_ptr &biter, size_t &verification_count) { while (biter->Valid()) { verification_count = 0; biter->Next(); if (biter->Valid()) { ASSERT_GE(verification_count, 1); } } } template void TestIterateBackward(std::unique_ptr &biter, size_t &verification_count) { while (biter->Valid()) { verification_count = 0; biter->Prev(); if (biter->Valid()) { ASSERT_GE(verification_count, 1); } } } template void TestSeekToFirst(std::unique_ptr &biter, size_t &verification_count) { verification_count = 0; biter->SeekToFirst(); ASSERT_GE(verification_count, 1); TestIterateForward(biter, verification_count); } template void TestSeekToLast(std::unique_ptr &biter, size_t &verification_count) { verification_count = 0; biter->SeekToLast(); ASSERT_GE(verification_count, 1); TestIterateBackward(biter, verification_count); } template void TestSeekForPrev(std::unique_ptr &biter, size_t &verification_count, std::string k) { verification_count = 0; biter->SeekForPrev(k); ASSERT_GE(verification_count, 1); TestIterateBackward(biter, verification_count); } template void TestSeek(std::unique_ptr &biter, size_t &verification_count, std::string k) { verification_count = 0; biter->Seek(k); ASSERT_GE(verification_count, 1); TestIterateForward(biter, verification_count); } bool VerifyChecksum(uint32_t checksum_len, const char *checksum_ptr, const Slice &key, const Slice &val) { if (!checksum_len) { return checksum_ptr == nullptr; } return ProtectionInfo64().ProtectKV(key, val).Verify( static_cast(checksum_len), checksum_ptr); } }; TEST_F(BlockPerKVChecksumTest, EmptyBlock) { // Tests that empty block code path is not broken by per kv checksum. BlockBuilder builder( 16 /* block_restart_interval */, true /* use_delta_encoding */, false /* use_value_delta_encoding */, BlockBasedTableOptions::DataBlockIndexType::kDataBlockBinarySearch); Slice raw_block = builder.Finish(); BlockContents contents; contents.data = raw_block; std::unique_ptr data_block; Options options = Options(); BlockBasedTableOptions tbo; uint8_t protection_bytes_per_key = 8; BlockCreateContext create_context{ &tbo, nullptr /* statistics */, false /* using_zstd */, protection_bytes_per_key, options.comparator}; create_context.Create(&data_block, std::move(contents)); std::unique_ptr biter{data_block->NewDataIterator( options.comparator, kDisableGlobalSequenceNumber)}; biter->SeekToFirst(); ASSERT_FALSE(biter->Valid()); ASSERT_OK(biter->status()); Random rnd(33); biter->SeekForGet(GenerateInternalKey(1, 1, 10, &rnd)); ASSERT_FALSE(biter->Valid()); ASSERT_OK(biter->status()); biter->SeekToLast(); ASSERT_FALSE(biter->Valid()); ASSERT_OK(biter->status()); biter->Seek(GenerateInternalKey(1, 1, 10, &rnd)); ASSERT_FALSE(biter->Valid()); ASSERT_OK(biter->status()); biter->SeekForPrev(GenerateInternalKey(1, 1, 10, &rnd)); ASSERT_FALSE(biter->Valid()); ASSERT_OK(biter->status()); } TEST_F(BlockPerKVChecksumTest, UnsupportedOptionValue) { Options options = Options(); options.block_protection_bytes_per_key = 128; Destroy(options); ASSERT_TRUE(TryReopen(options).IsNotSupported()); } TEST_F(BlockPerKVChecksumTest, InitializeProtectionInfo) { // Make sure that the checksum construction code path does not break // when the block is itself already corrupted. Options options = Options(); BlockBasedTableOptions tbo; uint8_t protection_bytes_per_key = 8; BlockCreateContext create_context{ &tbo, nullptr /* statistics */, false /* using_zstd */, protection_bytes_per_key, options.comparator}; { std::string invalid_content = "1"; Slice raw_block = invalid_content; BlockContents contents; contents.data = raw_block; std::unique_ptr data_block; create_context.Create(&data_block, std::move(contents)); std::unique_ptr iter{data_block->NewDataIterator( options.comparator, kDisableGlobalSequenceNumber)}; ASSERT_TRUE(iter->status().IsCorruption()); } { std::string invalid_content = "1"; Slice raw_block = invalid_content; BlockContents contents; contents.data = raw_block; std::unique_ptr index_block; create_context.Create(&index_block, std::move(contents)); std::unique_ptr iter{index_block->NewIndexIterator( options.comparator, kDisableGlobalSequenceNumber, nullptr, nullptr, true, false, true, true)}; ASSERT_TRUE(iter->status().IsCorruption()); } { std::string invalid_content = "1"; Slice raw_block = invalid_content; BlockContents contents; contents.data = raw_block; std::unique_ptr meta_block; create_context.Create(&meta_block, std::move(contents)); std::unique_ptr iter{meta_block->NewMetaIterator(true)}; ASSERT_TRUE(iter->status().IsCorruption()); } } TEST_F(BlockPerKVChecksumTest, ApproximateMemory) { // Tests that ApproximateMemoryUsage() includes memory used by block kv // checksum. const int kNumRecords = 20; std::vector keys; std::vector values; GenerateRandomKVs(&keys, &values, 0, kNumRecords, 1 /* step */, 24 /* padding_size */); std::unique_ptr builder; auto generate_block_content = [&]() { builder = std::make_unique(16 /* restart_interval */); for (int i = 0; i < kNumRecords; ++i) { builder->Add(keys[i], values[i]); } Slice raw_block = builder->Finish(); BlockContents contents; contents.data = raw_block; return contents; }; Options options = Options(); BlockBasedTableOptions tbo; uint8_t protection_bytes_per_key = 8; BlockCreateContext with_checksum_create_context{ &tbo, nullptr /* statistics */, false /* using_zstd */, protection_bytes_per_key, options.comparator, true /* index_value_is_full */}; BlockCreateContext create_context{ &tbo, nullptr /* statistics */, false /* using_zstd */, 0, options.comparator, true /* index_value_is_full */}; { std::unique_ptr data_block; create_context.Create(&data_block, generate_block_content()); size_t block_memory = data_block->ApproximateMemoryUsage(); std::unique_ptr with_checksum_data_block; with_checksum_create_context.Create(&with_checksum_data_block, generate_block_content()); ASSERT_GT(with_checksum_data_block->ApproximateMemoryUsage() - block_memory, 100); } { std::unique_ptr meta_block; create_context.Create(&meta_block, generate_block_content()); size_t block_memory = meta_block->ApproximateMemoryUsage(); std::unique_ptr with_checksum_meta_block; with_checksum_create_context.Create(&with_checksum_meta_block, generate_block_content()); // Rough comparison to avoid flaky test due to memory allocation alignment. ASSERT_GT(with_checksum_meta_block->ApproximateMemoryUsage() - block_memory, 100); } { // Index block has different contents. std::vector separators; std::vector block_handles; std::vector first_keys; GenerateRandomIndexEntries(&separators, &block_handles, &first_keys, kNumRecords); auto generate_index_content = [&]() { builder = std::make_unique(16 /* restart_interval */); BlockHandle last_encoded_handle; for (int i = 0; i < kNumRecords; ++i) { IndexValue entry(block_handles[i], first_keys[i]); std::string encoded_entry; std::string delta_encoded_entry; entry.EncodeTo(&encoded_entry, false, nullptr); last_encoded_handle = entry.handle; const Slice delta_encoded_entry_slice(delta_encoded_entry); builder->Add(separators[i], encoded_entry, &delta_encoded_entry_slice); } Slice raw_block = builder->Finish(); BlockContents contents; contents.data = raw_block; return contents; }; std::unique_ptr index_block; create_context.Create(&index_block, generate_index_content()); size_t block_memory = index_block->ApproximateMemoryUsage(); std::unique_ptr with_checksum_index_block; with_checksum_create_context.Create(&with_checksum_index_block, generate_index_content()); ASSERT_GT( with_checksum_index_block->ApproximateMemoryUsage() - block_memory, 100); } } std::string GetDataBlockIndexTypeStr( BlockBasedTableOptions::DataBlockIndexType t) { return t == BlockBasedTableOptions::DataBlockIndexType::kDataBlockBinarySearch ? "BinarySearch" : "BinaryAndHash"; } class DataBlockKVChecksumTest : public BlockPerKVChecksumTest, public testing::WithParamInterface> { public: DataBlockKVChecksumTest() = default; BlockBasedTableOptions::DataBlockIndexType GetDataBlockIndexType() const { return std::get<0>(GetParam()); } uint8_t GetChecksumLen() const { return std::get<1>(GetParam()); } uint32_t GetRestartInterval() const { return std::get<2>(GetParam()); } bool GetUseDeltaEncoding() const { return std::get<3>(GetParam()); } std::unique_ptr GenerateDataBlock( std::vector &keys, std::vector &values, int num_record) { BlockBasedTableOptions tbo; BlockCreateContext create_context{&tbo, nullptr /* statistics */, false /* using_zstd */, GetChecksumLen(), Options().comparator}; builder_ = std::make_unique( static_cast(GetRestartInterval()), GetUseDeltaEncoding() /* use_delta_encoding */, false /* use_value_delta_encoding */, GetDataBlockIndexType()); for (int i = 0; i < num_record; i++) { builder_->Add(keys[i], values[i]); } Slice raw_block = builder_->Finish(); BlockContents contents; contents.data = raw_block; std::unique_ptr data_block; create_context.Create(&data_block, std::move(contents)); return data_block; } std::unique_ptr builder_; }; INSTANTIATE_TEST_CASE_P( P, DataBlockKVChecksumTest, ::testing::Combine( ::testing::Values( BlockBasedTableOptions::DataBlockIndexType::kDataBlockBinarySearch, BlockBasedTableOptions::DataBlockIndexType:: kDataBlockBinaryAndHash), ::testing::Values(0, 1, 2, 4, 8) /* protection_bytes_per_key */, ::testing::Values(1, 2, 3, 8, 16) /* restart_interval */, ::testing::Values(false, true)) /* delta_encoding */, [](const testing::TestParamInfo> &args) { std::ostringstream oss; oss << GetDataBlockIndexTypeStr(std::get<0>(args.param)) << "ProtectionPerKey" << std::to_string(std::get<1>(args.param)) << "RestartInterval" << std::to_string(std::get<2>(args.param)) << "DeltaEncode" << std::to_string(std::get<3>(args.param)); return oss.str(); }); TEST_P(DataBlockKVChecksumTest, ChecksumConstructionAndVerification) { uint8_t protection_bytes_per_key = GetChecksumLen(); std::vector num_restart_intervals = {1, 16}; for (const auto num_restart_interval : num_restart_intervals) { const int kNumRecords = num_restart_interval * static_cast(GetRestartInterval()); std::vector keys; std::vector values; GenerateRandomKVs(&keys, &values, 0, kNumRecords + 1, 1 /* step */, 24 /* padding_size */); SyncPoint::GetInstance()->DisableProcessing(); std::unique_ptr data_block = GenerateDataBlock(keys, values, kNumRecords); const char *checksum_ptr = data_block->TEST_GetKVChecksum(); // Check checksum of correct length is generated for (int i = 0; i < kNumRecords; i++) { ASSERT_TRUE(VerifyChecksum(protection_bytes_per_key, checksum_ptr + i * protection_bytes_per_key, keys[i], values[i])); } std::vector seqnos{kDisableGlobalSequenceNumber, 0}; // Could just use a boolean flag. Use a counter here just to keep open the // possibility of checking the exact number of verifications in the future. size_t verification_count = 0; // The SyncPoint is placed before checking checksum_len == 0 in // Block::VerifyChecksum(). So verification count is incremented even with // protection_bytes_per_key = 0. No actual checksum computation is done in // that case (see Block::VerifyChecksum()). SyncPoint::GetInstance()->SetCallBack( "Block::VerifyChecksum::checksum_len", [&verification_count, protection_bytes_per_key](void *checksum_len) { ASSERT_EQ((*static_cast(checksum_len)), protection_bytes_per_key); ++verification_count; }); SyncPoint::GetInstance()->EnableProcessing(); for (const auto seqno : seqnos) { std::unique_ptr biter{ data_block->NewDataIterator(Options().comparator, seqno)}; // SeekForGet() some key that does not exist biter->SeekForGet(keys[kNumRecords]); TestIterateForward(biter, verification_count); verification_count = 0; biter->SeekForGet(keys[kNumRecords / 2]); ASSERT_GE(verification_count, 1); TestIterateForward(biter, verification_count); TestSeekToFirst(biter, verification_count); TestSeekToLast(biter, verification_count); TestSeekForPrev(biter, verification_count, keys[kNumRecords / 2]); TestSeek(biter, verification_count, keys[kNumRecords / 2]); } } } class IndexBlockKVChecksumTest : public BlockPerKVChecksumTest, public testing::WithParamInterface< std::tuple> { public: IndexBlockKVChecksumTest() = default; BlockBasedTableOptions::DataBlockIndexType GetDataBlockIndexType() const { return std::get<0>(GetParam()); } uint8_t GetChecksumLen() const { return std::get<1>(GetParam()); } uint32_t GetRestartInterval() const { return std::get<2>(GetParam()); } bool UseValueDeltaEncoding() const { return std::get<3>(GetParam()); } bool IncludeFirstKey() const { return std::get<4>(GetParam()); } std::unique_ptr GenerateIndexBlock( std::vector &separators, std::vector &block_handles, std::vector &first_keys, int num_record) { Options options = Options(); BlockBasedTableOptions tbo; uint8_t protection_bytes_per_key = GetChecksumLen(); BlockCreateContext create_context{ &tbo, nullptr /* statistics */, false /* _using_zstd */, protection_bytes_per_key, options.comparator, !UseValueDeltaEncoding() /* value_is_full */, IncludeFirstKey()}; builder_ = std::make_unique( static_cast(GetRestartInterval()), true /* use_delta_encoding */, UseValueDeltaEncoding() /* use_value_delta_encoding */, GetDataBlockIndexType()); BlockHandle last_encoded_handle; for (int i = 0; i < num_record; i++) { IndexValue entry(block_handles[i], first_keys[i]); std::string encoded_entry; std::string delta_encoded_entry; entry.EncodeTo(&encoded_entry, IncludeFirstKey(), nullptr); if (UseValueDeltaEncoding() && i > 0) { entry.EncodeTo(&delta_encoded_entry, IncludeFirstKey(), &last_encoded_handle); } last_encoded_handle = entry.handle; const Slice delta_encoded_entry_slice(delta_encoded_entry); builder_->Add(separators[i], encoded_entry, &delta_encoded_entry_slice); } // read serialized contents of the block Slice raw_block = builder_->Finish(); // create block reader BlockContents contents; contents.data = raw_block; std::unique_ptr index_block; create_context.Create(&index_block, std::move(contents)); return index_block; } std::unique_ptr builder_; }; INSTANTIATE_TEST_CASE_P( P, IndexBlockKVChecksumTest, ::testing::Combine( ::testing::Values( BlockBasedTableOptions::DataBlockIndexType::kDataBlockBinarySearch, BlockBasedTableOptions::DataBlockIndexType:: kDataBlockBinaryAndHash), ::testing::Values(0, 1, 2, 4, 8), ::testing::Values(1, 3, 8, 16), ::testing::Values(true, false), ::testing::Values(true, false)), [](const testing::TestParamInfo< std::tuple> &args) { std::ostringstream oss; oss << GetDataBlockIndexTypeStr(std::get<0>(args.param)) << "ProtBytes" << std::to_string(std::get<1>(args.param)) << "RestartInterval" << std::to_string(std::get<2>(args.param)) << "ValueDeltaEncode" << std::to_string(std::get<3>(args.param)) << "IncludeFirstKey" << std::to_string(std::get<4>(args.param)); return oss.str(); }); TEST_P(IndexBlockKVChecksumTest, ChecksumConstructionAndVerification) { Options options = Options(); uint8_t protection_bytes_per_key = GetChecksumLen(); std::vector num_restart_intervals = {1, 16}; std::vector seqnos{kDisableGlobalSequenceNumber, 10001}; for (const auto num_restart_interval : num_restart_intervals) { const int kNumRecords = num_restart_interval * static_cast(GetRestartInterval()); for (const auto seqno : seqnos) { std::vector separators; std::vector block_handles; std::vector first_keys; GenerateRandomIndexEntries(&separators, &block_handles, &first_keys, kNumRecords, seqno != kDisableGlobalSequenceNumber); SyncPoint::GetInstance()->DisableProcessing(); std::unique_ptr index_block = GenerateIndexBlock( separators, block_handles, first_keys, kNumRecords); IndexBlockIter *kNullIter = nullptr; Statistics *kNullStats = nullptr; // read contents of block sequentially std::unique_ptr biter{index_block->NewIndexIterator( options.comparator, seqno, kNullIter, kNullStats, true /* total_order_seek */, IncludeFirstKey() /* have_first_key */, true /* key_includes_seq */, !UseValueDeltaEncoding() /* value_is_full */, true /* block_contents_pinned */, nullptr /* prefix_index */)}; biter->SeekToFirst(); const char *checksum_ptr = index_block->TEST_GetKVChecksum(); // Check checksum of correct length is generated for (int i = 0; i < kNumRecords; i++) { // Obtaining the actual content written as value to index block is not // trivial: delta-encoded value is only persisted when not at block // restart point and that keys share some byte (see more in // BlockBuilder::AddWithLastKeyImpl()). So here we just do verification // using value from iterator unlike tests for DataBlockIter or // MetaBlockIter. ASSERT_TRUE(VerifyChecksum(protection_bytes_per_key, checksum_ptr, biter->key(), biter->raw_value())); } size_t verification_count = 0; // The SyncPoint is placed before checking checksum_len == 0 in // Block::VerifyChecksum(). To make the testing code below simpler and not // having to differentiate 0 vs non-0 checksum_len, we do an explicit // assert checking on checksum_len here. SyncPoint::GetInstance()->SetCallBack( "Block::VerifyChecksum::checksum_len", [&verification_count, protection_bytes_per_key](void *checksum_len) { ASSERT_EQ((*static_cast(checksum_len)), protection_bytes_per_key); ++verification_count; }); SyncPoint::GetInstance()->EnableProcessing(); TestSeekToFirst(biter, verification_count); TestSeekToLast(biter, verification_count); TestSeek(biter, verification_count, first_keys[kNumRecords / 2]); } } } class MetaIndexBlockKVChecksumTest : public BlockPerKVChecksumTest, public testing::WithParamInterface< uint8_t /* block_protection_bytes_per_key */> { public: MetaIndexBlockKVChecksumTest() = default; uint8_t GetChecksumLen() const { return GetParam(); } uint32_t GetRestartInterval() const { return 1; } std::unique_ptr GenerateMetaIndexBlock( std::vector &keys, std::vector &values, int num_record) { Options options = Options(); BlockBasedTableOptions tbo; uint8_t protection_bytes_per_key = GetChecksumLen(); BlockCreateContext create_context{ &tbo, nullptr /* statistics */, false /* using_zstd */, protection_bytes_per_key, options.comparator}; builder_ = std::make_unique(static_cast(GetRestartInterval())); // add a bunch of records to a block for (int i = 0; i < num_record; i++) { builder_->Add(keys[i], values[i]); } Slice raw_block = builder_->Finish(); BlockContents contents; contents.data = raw_block; std::unique_ptr meta_block; create_context.Create(&meta_block, std::move(contents)); return meta_block; } std::unique_ptr builder_; }; INSTANTIATE_TEST_CASE_P(P, MetaIndexBlockKVChecksumTest, ::testing::Values(0, 1, 2, 4, 8), [](const testing::TestParamInfo &args) { std::ostringstream oss; oss << "ProtBytes" << std::to_string(args.param); return oss.str(); }); TEST_P(MetaIndexBlockKVChecksumTest, ChecksumConstructionAndVerification) { Options options = Options(); BlockBasedTableOptions tbo; uint8_t protection_bytes_per_key = GetChecksumLen(); BlockCreateContext create_context{ &tbo, nullptr /* statistics */, false /* using_zstd */, protection_bytes_per_key, options.comparator}; std::vector num_restart_intervals = {1, 16}; for (const auto num_restart_interval : num_restart_intervals) { const int kNumRecords = num_restart_interval * GetRestartInterval(); std::vector keys; std::vector values; GenerateRandomKVs(&keys, &values, 0, kNumRecords + 1, 1 /* step */, 24 /* padding_size */); SyncPoint::GetInstance()->DisableProcessing(); std::unique_ptr meta_block = GenerateMetaIndexBlock(keys, values, kNumRecords); const char *checksum_ptr = meta_block->TEST_GetKVChecksum(); // Check checksum of correct length is generated for (int i = 0; i < kNumRecords; i++) { ASSERT_TRUE(VerifyChecksum(protection_bytes_per_key, checksum_ptr + i * protection_bytes_per_key, keys[i], values[i])); } size_t verification_count = 0; // The SyncPoint is placed before checking checksum_len == 0 in // Block::VerifyChecksum(). To make the testing code below simpler and not // having to differentiate 0 vs non-0 checksum_len, we do an explicit assert // checking on checksum_len here. SyncPoint::GetInstance()->SetCallBack( "Block::VerifyChecksum::checksum_len", [&verification_count, protection_bytes_per_key](void *checksum_len) { ASSERT_EQ((*static_cast(checksum_len)), protection_bytes_per_key); ++verification_count; }); SyncPoint::GetInstance()->EnableProcessing(); // Check that block iterator does checksum verification std::unique_ptr biter{ meta_block->NewMetaIterator(true /* block_contents_pinned */)}; TestSeekToFirst(biter, verification_count); TestSeekToLast(biter, verification_count); TestSeek(biter, verification_count, keys[kNumRecords / 2]); TestSeekForPrev(biter, verification_count, keys[kNumRecords / 2]); } } class DataBlockKVChecksumCorruptionTest : public DataBlockKVChecksumTest { public: DataBlockKVChecksumCorruptionTest() = default; std::unique_ptr GenerateDataBlockIter( std::vector &keys, std::vector &values, int num_record) { // During Block construction, we may create block iter to initialize per kv // checksum. Disable syncpoint that may be created for block iter methods. SyncPoint::GetInstance()->DisableProcessing(); block_ = GenerateDataBlock(keys, values, num_record); std::unique_ptr biter{block_->NewDataIterator( Options().comparator, kDisableGlobalSequenceNumber)}; SyncPoint::GetInstance()->EnableProcessing(); return biter; } protected: std::unique_ptr block_; }; TEST_P(DataBlockKVChecksumCorruptionTest, CorruptEntry) { std::vector num_restart_intervals = {1, 3}; for (const auto num_restart_interval : num_restart_intervals) { const int kNumRecords = num_restart_interval * static_cast(GetRestartInterval()); std::vector keys; std::vector values; GenerateRandomKVs(&keys, &values, 0, kNumRecords + 1, 1 /* step */, 24 /* padding_size */); SyncPoint::GetInstance()->SetCallBack( "BlockIter::UpdateKey::value", [](void *arg) { char *value = static_cast(arg); // values generated by GenerateRandomKVs are of length 100 ++value[10]; }); // Purely for reducing the number of lines of code. typedef std::unique_ptr IterPtr; typedef void(IterAPI)(IterPtr & iter, std::string &); std::string seek_key = keys[kNumRecords / 2]; auto test_seek = [&](IterAPI iter_api) { IterPtr biter = GenerateDataBlockIter(keys, values, kNumRecords); ASSERT_OK(biter->status()); iter_api(biter, seek_key); ASSERT_FALSE(biter->Valid()); ASSERT_TRUE(biter->status().IsCorruption()); }; test_seek([](IterPtr &iter, std::string &) { iter->SeekToFirst(); }); test_seek([](IterPtr &iter, std::string &) { iter->SeekToLast(); }); test_seek([](IterPtr &iter, std::string &k) { iter->Seek(k); }); test_seek([](IterPtr &iter, std::string &k) { iter->SeekForPrev(k); }); test_seek([](IterPtr &iter, std::string &k) { iter->SeekForGet(k); }); typedef void (DataBlockIter::*IterStepAPI)(); auto test_step = [&](IterStepAPI iter_api, std::string &k) { IterPtr biter = GenerateDataBlockIter(keys, values, kNumRecords); SyncPoint::GetInstance()->DisableProcessing(); biter->Seek(k); ASSERT_TRUE(biter->Valid()); ASSERT_OK(biter->status()); SyncPoint::GetInstance()->EnableProcessing(); std::invoke(iter_api, biter); ASSERT_FALSE(biter->Valid()); ASSERT_TRUE(biter->status().IsCorruption()); }; if (kNumRecords > 1) { test_step(&DataBlockIter::Prev, seek_key); test_step(&DataBlockIter::Next, seek_key); } } } INSTANTIATE_TEST_CASE_P( P, DataBlockKVChecksumCorruptionTest, ::testing::Combine( ::testing::Values( BlockBasedTableOptions::DataBlockIndexType::kDataBlockBinarySearch, BlockBasedTableOptions::DataBlockIndexType:: kDataBlockBinaryAndHash), ::testing::Values(4, 8) /* block_protection_bytes_per_key */, ::testing::Values(1, 3, 8, 16) /* restart_interval */, ::testing::Values(false, true)), [](const testing::TestParamInfo> &args) { std::ostringstream oss; oss << GetDataBlockIndexTypeStr(std::get<0>(args.param)) << "ProtBytes" << std::to_string(std::get<1>(args.param)) << "RestartInterval" << std::to_string(std::get<2>(args.param)) << "DeltaEncode" << std::to_string(std::get<3>(args.param)); return oss.str(); }); class IndexBlockKVChecksumCorruptionTest : public IndexBlockKVChecksumTest { public: IndexBlockKVChecksumCorruptionTest() = default; std::unique_ptr GenerateIndexBlockIter( std::vector &separators, std::vector &block_handles, std::vector &first_keys, int num_record, SequenceNumber seqno) { SyncPoint::GetInstance()->DisableProcessing(); block_ = GenerateIndexBlock(separators, block_handles, first_keys, num_record); std::unique_ptr biter{block_->NewIndexIterator( Options().comparator, seqno, nullptr, nullptr, true /* total_order_seek */, IncludeFirstKey() /* have_first_key */, true /* key_includes_seq */, !UseValueDeltaEncoding() /* value_is_full */, true /* block_contents_pinned */, nullptr /* prefix_index */)}; SyncPoint::GetInstance()->EnableProcessing(); return biter; } protected: std::unique_ptr block_; }; INSTANTIATE_TEST_CASE_P( P, IndexBlockKVChecksumCorruptionTest, ::testing::Combine( ::testing::Values( BlockBasedTableOptions::DataBlockIndexType::kDataBlockBinarySearch, BlockBasedTableOptions::DataBlockIndexType:: kDataBlockBinaryAndHash), ::testing::Values(4, 8) /* block_protection_bytes_per_key */, ::testing::Values(1, 3, 8, 16) /* restart_interval */, ::testing::Values(true, false), ::testing::Values(true, false)), [](const testing::TestParamInfo< std::tuple> &args) { std::ostringstream oss; oss << GetDataBlockIndexTypeStr(std::get<0>(args.param)) << "ProtBytes" << std::to_string(std::get<1>(args.param)) << "RestartInterval" << std::to_string(std::get<2>(args.param)) << "ValueDeltaEncode" << std::to_string(std::get<3>(args.param)) << "IncludeFirstKey" << std::to_string(std::get<4>(args.param)); return oss.str(); }); TEST_P(IndexBlockKVChecksumCorruptionTest, CorruptEntry) { std::vector num_restart_intervals = {1, 3}; std::vector seqnos{kDisableGlobalSequenceNumber, 10001}; for (const auto num_restart_interval : num_restart_intervals) { const int kNumRecords = num_restart_interval * static_cast(GetRestartInterval()); for (const auto seqno : seqnos) { std::vector separators; std::vector block_handles; std::vector first_keys; GenerateRandomIndexEntries(&separators, &block_handles, &first_keys, kNumRecords, seqno != kDisableGlobalSequenceNumber); SyncPoint::GetInstance()->SetCallBack( "BlockIter::UpdateKey::value", [](void *arg) { char *value = static_cast(arg); // value can be delta-encoded with different lengths, so we corrupt // first bytes here to be safe ++value[0]; }); typedef std::unique_ptr IterPtr; typedef void(IterAPI)(IterPtr & iter, std::string &); std::string seek_key = first_keys[kNumRecords / 2]; auto test_seek = [&](IterAPI iter_api) { std::unique_ptr biter = GenerateIndexBlockIter( separators, block_handles, first_keys, kNumRecords, seqno); ASSERT_OK(biter->status()); iter_api(biter, seek_key); ASSERT_FALSE(biter->Valid()); ASSERT_TRUE(biter->status().IsCorruption()); }; test_seek([](IterPtr &iter, std::string &) { iter->SeekToFirst(); }); test_seek([](IterPtr &iter, std::string &) { iter->SeekToLast(); }); test_seek([](IterPtr &iter, std::string &k) { iter->Seek(k); }); typedef void (IndexBlockIter::*IterStepAPI)(); auto test_step = [&](IterStepAPI iter_api, std::string &k) { std::unique_ptr biter = GenerateIndexBlockIter( separators, block_handles, first_keys, kNumRecords, seqno); SyncPoint::GetInstance()->DisableProcessing(); biter->Seek(k); ASSERT_TRUE(biter->Valid()); ASSERT_OK(biter->status()); SyncPoint::GetInstance()->EnableProcessing(); std::invoke(iter_api, biter); ASSERT_FALSE(biter->Valid()); ASSERT_TRUE(biter->status().IsCorruption()); }; if (kNumRecords > 1) { test_step(&IndexBlockIter::Prev, seek_key); test_step(&IndexBlockIter::Next, seek_key); } } } } class MetaIndexBlockKVChecksumCorruptionTest : public MetaIndexBlockKVChecksumTest { public: MetaIndexBlockKVChecksumCorruptionTest() = default; std::unique_ptr GenerateMetaIndexBlockIter( std::vector &keys, std::vector &values, int num_record) { SyncPoint::GetInstance()->DisableProcessing(); block_ = GenerateMetaIndexBlock(keys, values, num_record); std::unique_ptr biter{ block_->NewMetaIterator(true /* block_contents_pinned */)}; SyncPoint::GetInstance()->EnableProcessing(); return biter; } protected: std::unique_ptr block_; }; INSTANTIATE_TEST_CASE_P( P, MetaIndexBlockKVChecksumCorruptionTest, ::testing::Values(4, 8) /* block_protection_bytes_per_key */, [](const testing::TestParamInfo &args) { std::ostringstream oss; oss << "ProtBytes" << std::to_string(args.param); return oss.str(); }); TEST_P(MetaIndexBlockKVChecksumCorruptionTest, CorruptEntry) { Options options = Options(); std::vector num_restart_intervals = {1, 3}; for (const auto num_restart_interval : num_restart_intervals) { const int kNumRecords = num_restart_interval * static_cast(GetRestartInterval()); std::vector keys; std::vector values; GenerateRandomKVs(&keys, &values, 0, kNumRecords + 1, 1 /* step */, 24 /* padding_size */); SyncPoint::GetInstance()->SetCallBack( "BlockIter::UpdateKey::value", [](void *arg) { char *value = static_cast(arg); // values generated by GenerateRandomKVs are of length 100 ++value[10]; }); typedef std::unique_ptr IterPtr; typedef void(IterAPI)(IterPtr & iter, std::string &); typedef void (MetaBlockIter::*IterStepAPI)(); std::string seek_key = keys[kNumRecords / 2]; auto test_seek = [&](IterAPI iter_api) { IterPtr biter = GenerateMetaIndexBlockIter(keys, values, kNumRecords); ASSERT_OK(biter->status()); iter_api(biter, seek_key); ASSERT_FALSE(biter->Valid()); ASSERT_TRUE(biter->status().IsCorruption()); }; test_seek([](IterPtr &iter, std::string &) { iter->SeekToFirst(); }); test_seek([](IterPtr &iter, std::string &) { iter->SeekToLast(); }); test_seek([](IterPtr &iter, std::string &k) { iter->Seek(k); }); test_seek([](IterPtr &iter, std::string &k) { iter->SeekForPrev(k); }); auto test_step = [&](IterStepAPI iter_api, const std::string &k) { IterPtr biter = GenerateMetaIndexBlockIter(keys, values, kNumRecords); SyncPoint::GetInstance()->DisableProcessing(); biter->Seek(k); ASSERT_TRUE(biter->Valid()); ASSERT_OK(biter->status()); SyncPoint::GetInstance()->EnableProcessing(); std::invoke(iter_api, biter); ASSERT_FALSE(biter->Valid()); ASSERT_TRUE(biter->status().IsCorruption()); }; if (kNumRecords > 1) { test_step(&MetaBlockIter::Prev, seek_key); test_step(&MetaBlockIter::Next, seek_key); } } } } // namespace ROCKSDB_NAMESPACE int main(int argc, char **argv) { ROCKSDB_NAMESPACE::port::InstallStackTraceHandler(); ::testing::InitGoogleTest(&argc, argv); return RUN_ALL_TESTS(); }