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269478ee46
Summary: This PR implements support for a three tier cache - primary block cache, compressed secondary cache, and a nvm (local flash) secondary cache. This allows more effective utilization of the nvm cache, and minimizes the number of reads from local flash by caching compressed blocks in the compressed secondary cache. The basic design is as follows - 1. A new secondary cache implementation, ```TieredSecondaryCache```, is introduced. It keeps the compressed and nvm secondary caches and manages the movement of blocks between them and the primary block cache. To setup a three tier cache, we allocate a ```CacheWithSecondaryAdapter```, with a ```TieredSecondaryCache``` instance as the secondary cache. 2. The table reader passes both the uncompressed and compressed block to ```FullTypedCacheInterface::InsertFull```, allowing the block cache to optionally store the compressed block. 3. When there's a miss, the block object is constructed and inserted in the primary cache, and the compressed block is inserted into the nvm cache by calling ```InsertSaved```. This avoids the overhead of recompressing the block, as well as avoiding putting more memory pressure on the compressed secondary cache. 4. When there's a hit in the nvm cache, we attempt to insert the block in the compressed secondary cache and the primary cache, subject to the admission policy of those caches (i.e admit on second access). Blocks/items evicted from any tier are simply discarded. We can easily implement additional admission policies if desired. Todo (In a subsequent PR): 1. Add to db_bench and run benchmarks 2. Add to db_stress Pull Request resolved: https://github.com/facebook/rocksdb/pull/11812 Reviewed By: pdillinger Differential Revision: D49461842 Pulled By: anand1976 fbshipit-source-id: b40ac1330ef7cd8c12efa0a3ca75128e602e3a0b
528 lines
21 KiB
C++
528 lines
21 KiB
C++
// Copyright (c) 2011-present, Facebook, Inc. All rights reserved.
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// This source code is licensed under both the GPLv2 (found in the
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// COPYING file in the root directory) and Apache 2.0 License
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// (found in the LICENSE.Apache file in the root directory).
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#include "table/block_fetcher.h"
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#include "db/table_properties_collector.h"
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#include "file/file_util.h"
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#include "options/options_helper.h"
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#include "port/port.h"
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#include "port/stack_trace.h"
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#include "rocksdb/db.h"
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#include "rocksdb/file_system.h"
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#include "table/block_based/binary_search_index_reader.h"
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#include "table/block_based/block_based_table_builder.h"
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#include "table/block_based/block_based_table_factory.h"
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#include "table/block_based/block_based_table_reader.h"
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#include "table/format.h"
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#include "test_util/testharness.h"
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#include "utilities/memory_allocators.h"
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namespace ROCKSDB_NAMESPACE {
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namespace {
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struct MemcpyStats {
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int num_stack_buf_memcpy;
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int num_heap_buf_memcpy;
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int num_compressed_buf_memcpy;
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};
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struct BufAllocationStats {
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int num_heap_buf_allocations;
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int num_compressed_buf_allocations;
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};
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struct TestStats {
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MemcpyStats memcpy_stats;
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BufAllocationStats buf_allocation_stats;
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};
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class BlockFetcherTest : public testing::Test {
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public:
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enum class Mode {
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kBufferedRead = 0,
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kBufferedMmap,
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kDirectRead,
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kNumModes,
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};
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// use NumModes as array size to avoid "size of array '...' has non-integral
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// type" errors.
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const static int NumModes = static_cast<int>(Mode::kNumModes);
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protected:
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void SetUp() override {
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SetupSyncPointsToMockDirectIO();
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test_dir_ = test::PerThreadDBPath("block_fetcher_test");
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env_ = Env::Default();
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fs_ = FileSystem::Default();
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ASSERT_OK(fs_->CreateDir(test_dir_, IOOptions(), nullptr));
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}
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void TearDown() override { EXPECT_OK(DestroyDir(env_, test_dir_)); }
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void AssertSameBlock(const std::string& block1, const std::string& block2) {
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ASSERT_EQ(block1, block2);
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}
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// Creates a table with kv pairs (i, i) where i ranges from 0 to 9, inclusive.
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void CreateTable(const std::string& table_name,
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const CompressionType& compression_type) {
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std::unique_ptr<WritableFileWriter> writer;
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NewFileWriter(table_name, &writer);
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// Create table builder.
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ImmutableOptions ioptions(options_);
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InternalKeyComparator comparator(options_.comparator);
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ColumnFamilyOptions cf_options(options_);
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MutableCFOptions moptions(cf_options);
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IntTblPropCollectorFactories factories;
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std::unique_ptr<TableBuilder> table_builder(table_factory_.NewTableBuilder(
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TableBuilderOptions(ioptions, moptions, comparator, &factories,
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compression_type, CompressionOptions(),
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0 /* column_family_id */, kDefaultColumnFamilyName,
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-1 /* level */),
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writer.get()));
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// Build table.
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for (int i = 0; i < 9; i++) {
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std::string key = ToInternalKey(std::to_string(i));
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// Append "00000000" to string value to enhance compression ratio
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std::string value = "00000000" + std::to_string(i);
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table_builder->Add(key, value);
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}
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ASSERT_OK(table_builder->Finish());
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}
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void FetchIndexBlock(const std::string& table_name,
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CountedMemoryAllocator* heap_buf_allocator,
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CountedMemoryAllocator* compressed_buf_allocator,
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MemcpyStats* memcpy_stats, BlockContents* index_block,
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std::string* result) {
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FileOptions fopt(options_);
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std::unique_ptr<RandomAccessFileReader> file;
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NewFileReader(table_name, fopt, &file);
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// Get handle of the index block.
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Footer footer;
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ReadFooter(file.get(), &footer);
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const BlockHandle& index_handle = footer.index_handle();
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// FIXME: index handle will need to come from metaindex for
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// format_version >= 6 when that becomes the default
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ASSERT_FALSE(index_handle.IsNull());
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CompressionType compression_type;
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FetchBlock(file.get(), index_handle, BlockType::kIndex,
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false /* compressed */, false /* do_uncompress */,
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heap_buf_allocator, compressed_buf_allocator, index_block,
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memcpy_stats, &compression_type);
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ASSERT_EQ(compression_type, CompressionType::kNoCompression);
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result->assign(index_block->data.ToString());
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}
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// Fetches the first data block in both direct IO and non-direct IO mode.
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//
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// compressed: whether the data blocks are compressed;
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// do_uncompress: whether the data blocks should be uncompressed on fetching.
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// compression_type: the expected compression type.
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//
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// Expects:
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// Block contents are the same.
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// Bufferr allocation and memory copy statistics are expected.
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void TestFetchDataBlock(
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const std::string& table_name_prefix, bool compressed, bool do_uncompress,
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std::array<TestStats, NumModes> expected_stats_by_mode) {
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for (CompressionType compression_type : GetSupportedCompressions()) {
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bool do_compress = compression_type != kNoCompression;
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if (compressed != do_compress) continue;
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std::string compression_type_str =
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CompressionTypeToString(compression_type);
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std::string table_name = table_name_prefix + compression_type_str;
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CreateTable(table_name, compression_type);
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CompressionType expected_compression_type_after_fetch =
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(compressed && !do_uncompress) ? compression_type : kNoCompression;
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BlockContents blocks[NumModes];
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std::string block_datas[NumModes];
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MemcpyStats memcpy_stats[NumModes];
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CountedMemoryAllocator heap_buf_allocators[NumModes];
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CountedMemoryAllocator compressed_buf_allocators[NumModes];
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for (int i = 0; i < NumModes; ++i) {
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SetMode(static_cast<Mode>(i));
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FetchFirstDataBlock(table_name, compressed, do_uncompress,
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expected_compression_type_after_fetch,
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&heap_buf_allocators[i],
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&compressed_buf_allocators[i], &blocks[i],
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&block_datas[i], &memcpy_stats[i]);
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}
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for (int i = 0; i < NumModes - 1; ++i) {
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AssertSameBlock(block_datas[i], block_datas[i + 1]);
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}
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// Check memcpy and buffer allocation statistics.
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for (int i = 0; i < NumModes; ++i) {
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const TestStats& expected_stats = expected_stats_by_mode[i];
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ASSERT_EQ(memcpy_stats[i].num_stack_buf_memcpy,
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expected_stats.memcpy_stats.num_stack_buf_memcpy);
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ASSERT_EQ(memcpy_stats[i].num_heap_buf_memcpy,
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expected_stats.memcpy_stats.num_heap_buf_memcpy);
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ASSERT_EQ(memcpy_stats[i].num_compressed_buf_memcpy,
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expected_stats.memcpy_stats.num_compressed_buf_memcpy);
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if (kXpressCompression == compression_type) {
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// XPRESS allocates memory internally, thus does not support for
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// custom allocator verification
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continue;
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} else {
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ASSERT_EQ(
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heap_buf_allocators[i].GetNumAllocations(),
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expected_stats.buf_allocation_stats.num_heap_buf_allocations);
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ASSERT_EQ(compressed_buf_allocators[i].GetNumAllocations(),
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expected_stats.buf_allocation_stats
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.num_compressed_buf_allocations);
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// The allocated buffers are not deallocated until
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// the block content is deleted.
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ASSERT_EQ(heap_buf_allocators[i].GetNumDeallocations(), 0);
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ASSERT_EQ(compressed_buf_allocators[i].GetNumDeallocations(), 0);
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blocks[i].allocation.reset();
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ASSERT_EQ(
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heap_buf_allocators[i].GetNumDeallocations(),
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expected_stats.buf_allocation_stats.num_heap_buf_allocations);
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ASSERT_EQ(compressed_buf_allocators[i].GetNumDeallocations(),
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expected_stats.buf_allocation_stats
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.num_compressed_buf_allocations);
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}
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}
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}
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}
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void SetMode(Mode mode) {
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switch (mode) {
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case Mode::kBufferedRead:
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options_.use_direct_reads = false;
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options_.allow_mmap_reads = false;
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break;
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case Mode::kBufferedMmap:
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options_.use_direct_reads = false;
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options_.allow_mmap_reads = true;
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break;
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case Mode::kDirectRead:
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options_.use_direct_reads = true;
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options_.allow_mmap_reads = false;
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break;
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case Mode::kNumModes:
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assert(false);
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}
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}
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private:
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std::string test_dir_;
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Env* env_;
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std::shared_ptr<FileSystem> fs_;
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BlockBasedTableFactory table_factory_;
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Options options_;
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std::string Path(const std::string& fname) { return test_dir_ + "/" + fname; }
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void WriteToFile(const std::string& content, const std::string& filename) {
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std::unique_ptr<FSWritableFile> f;
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ASSERT_OK(fs_->NewWritableFile(Path(filename), FileOptions(), &f, nullptr));
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ASSERT_OK(f->Append(content, IOOptions(), nullptr));
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ASSERT_OK(f->Close(IOOptions(), nullptr));
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}
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void NewFileWriter(const std::string& filename,
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std::unique_ptr<WritableFileWriter>* writer) {
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std::string path = Path(filename);
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FileOptions file_options;
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ASSERT_OK(WritableFileWriter::Create(env_->GetFileSystem(), path,
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file_options, writer, nullptr));
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}
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void NewFileReader(const std::string& filename, const FileOptions& opt,
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std::unique_ptr<RandomAccessFileReader>* reader) {
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std::string path = Path(filename);
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std::unique_ptr<FSRandomAccessFile> f;
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ASSERT_OK(fs_->NewRandomAccessFile(path, opt, &f, nullptr));
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reader->reset(new RandomAccessFileReader(std::move(f), path,
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env_->GetSystemClock().get()));
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}
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void NewTableReader(const ImmutableOptions& ioptions,
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const FileOptions& foptions,
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const InternalKeyComparator& comparator,
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const std::string& table_name,
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std::unique_ptr<BlockBasedTable>* table) {
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std::unique_ptr<RandomAccessFileReader> file;
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NewFileReader(table_name, foptions, &file);
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uint64_t file_size = 0;
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ASSERT_OK(env_->GetFileSize(Path(table_name), &file_size));
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std::unique_ptr<TableReader> table_reader;
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ReadOptions ro;
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const auto* table_options =
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table_factory_.GetOptions<BlockBasedTableOptions>();
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ASSERT_NE(table_options, nullptr);
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ASSERT_OK(BlockBasedTable::Open(ro, ioptions, EnvOptions(), *table_options,
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comparator, std::move(file), file_size,
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0 /* block_protection_bytes_per_key */,
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&table_reader, 0 /* tail_size */));
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table->reset(reinterpret_cast<BlockBasedTable*>(table_reader.release()));
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}
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std::string ToInternalKey(const std::string& key) {
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InternalKey internal_key(key, 0, ValueType::kTypeValue);
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return internal_key.Encode().ToString();
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}
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void ReadFooter(RandomAccessFileReader* file, Footer* footer) {
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uint64_t file_size = 0;
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ASSERT_OK(env_->GetFileSize(file->file_name(), &file_size));
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IOOptions opts;
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ASSERT_OK(ReadFooterFromFile(opts, file, *fs_,
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nullptr /* prefetch_buffer */, file_size,
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footer, kBlockBasedTableMagicNumber));
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}
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// NOTE: compression_type returns the compression type of the fetched block
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// contents, so if the block is fetched and uncompressed, then it's
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// kNoCompression.
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void FetchBlock(RandomAccessFileReader* file, const BlockHandle& block,
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BlockType block_type, bool compressed, bool do_uncompress,
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MemoryAllocator* heap_buf_allocator,
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MemoryAllocator* compressed_buf_allocator,
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BlockContents* contents, MemcpyStats* stats,
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CompressionType* compression_type) {
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ImmutableOptions ioptions(options_);
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ReadOptions roptions;
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PersistentCacheOptions persistent_cache_options;
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Footer footer;
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ReadFooter(file, &footer);
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std::unique_ptr<BlockFetcher> fetcher(new BlockFetcher(
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file, nullptr /* prefetch_buffer */, footer, roptions, block, contents,
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ioptions, do_uncompress, compressed, block_type,
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UncompressionDict::GetEmptyDict(), persistent_cache_options,
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heap_buf_allocator, compressed_buf_allocator));
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ASSERT_OK(fetcher->ReadBlockContents());
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stats->num_stack_buf_memcpy = fetcher->TEST_GetNumStackBufMemcpy();
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stats->num_heap_buf_memcpy = fetcher->TEST_GetNumHeapBufMemcpy();
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stats->num_compressed_buf_memcpy =
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fetcher->TEST_GetNumCompressedBufMemcpy();
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if (do_uncompress) {
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*compression_type = kNoCompression;
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} else {
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*compression_type = fetcher->get_compression_type();
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}
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}
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// NOTE: expected_compression_type is the expected compression
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// type of the fetched block content, if the block is uncompressed,
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// then the expected compression type is kNoCompression.
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void FetchFirstDataBlock(const std::string& table_name, bool compressed,
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bool do_uncompress,
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CompressionType expected_compression_type,
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MemoryAllocator* heap_buf_allocator,
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MemoryAllocator* compressed_buf_allocator,
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BlockContents* block, std::string* result,
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MemcpyStats* memcpy_stats) {
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ImmutableOptions ioptions(options_);
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InternalKeyComparator comparator(options_.comparator);
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FileOptions foptions(options_);
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// Get block handle for the first data block.
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std::unique_ptr<BlockBasedTable> table;
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NewTableReader(ioptions, foptions, comparator, table_name, &table);
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std::unique_ptr<BlockBasedTable::IndexReader> index_reader;
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ReadOptions ro;
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ASSERT_OK(BinarySearchIndexReader::Create(
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table.get(), ro, nullptr /* prefetch_buffer */, false /* use_cache */,
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false /* prefetch */, false /* pin */, nullptr /* lookup_context */,
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&index_reader));
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std::unique_ptr<InternalIteratorBase<IndexValue>> iter(
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index_reader->NewIterator(
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ReadOptions(), false /* disable_prefix_seek */, nullptr /* iter */,
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nullptr /* get_context */, nullptr /* lookup_context */));
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ASSERT_OK(iter->status());
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iter->SeekToFirst();
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BlockHandle first_block_handle = iter->value().handle;
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// Fetch first data block.
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std::unique_ptr<RandomAccessFileReader> file;
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NewFileReader(table_name, foptions, &file);
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CompressionType compression_type;
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FetchBlock(file.get(), first_block_handle, BlockType::kData, compressed,
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do_uncompress, heap_buf_allocator, compressed_buf_allocator,
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block, memcpy_stats, &compression_type);
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ASSERT_EQ(compression_type, expected_compression_type);
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result->assign(block->data.ToString());
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}
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};
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// Skip the following tests in lite mode since direct I/O is unsupported.
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// Fetch index block under both direct IO and non-direct IO.
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// Expects:
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// the index block contents are the same for both read modes.
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TEST_F(BlockFetcherTest, FetchIndexBlock) {
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for (CompressionType compression : GetSupportedCompressions()) {
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std::string table_name =
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"FetchIndexBlock" + CompressionTypeToString(compression);
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CreateTable(table_name, compression);
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CountedMemoryAllocator allocator;
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MemcpyStats memcpy_stats;
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BlockContents indexes[NumModes];
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std::string index_datas[NumModes];
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for (int i = 0; i < NumModes; ++i) {
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SetMode(static_cast<Mode>(i));
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FetchIndexBlock(table_name, &allocator, &allocator, &memcpy_stats,
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&indexes[i], &index_datas[i]);
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}
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for (int i = 0; i < NumModes - 1; ++i) {
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AssertSameBlock(index_datas[i], index_datas[i + 1]);
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}
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}
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}
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// Data blocks are not compressed,
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// fetch data block under direct IO, mmap IO,and non-direct IO.
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// Expects:
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// 1. in non-direct IO mode, allocate a heap buffer and memcpy the block
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// into the buffer;
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// 2. in direct IO mode, allocate a heap buffer and memcpy from the
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// direct IO buffer to the heap buffer.
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TEST_F(BlockFetcherTest, FetchUncompressedDataBlock) {
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TestStats expected_non_mmap_stats = {
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{
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0 /* num_stack_buf_memcpy */,
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1 /* num_heap_buf_memcpy */,
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0 /* num_compressed_buf_memcpy */,
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},
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{
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1 /* num_heap_buf_allocations */,
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0 /* num_compressed_buf_allocations */,
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}};
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TestStats expected_mmap_stats = {{
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0 /* num_stack_buf_memcpy */,
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0 /* num_heap_buf_memcpy */,
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0 /* num_compressed_buf_memcpy */,
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},
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{
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0 /* num_heap_buf_allocations */,
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0 /* num_compressed_buf_allocations */,
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}};
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std::array<TestStats, NumModes> expected_stats_by_mode{{
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expected_non_mmap_stats /* kBufferedRead */,
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expected_mmap_stats /* kBufferedMmap */,
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expected_non_mmap_stats /* kDirectRead */,
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}};
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TestFetchDataBlock("FetchUncompressedDataBlock", false, false,
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expected_stats_by_mode);
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}
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// Data blocks are compressed,
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// fetch data block under both direct IO and non-direct IO,
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// but do not uncompress.
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// Expects:
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// 1. in non-direct IO mode, allocate a compressed buffer and memcpy the block
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// into the buffer;
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// 2. in direct IO mode, allocate a compressed buffer and memcpy from the
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// direct IO buffer to the compressed buffer.
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TEST_F(BlockFetcherTest, FetchCompressedDataBlock) {
|
|
TestStats expected_non_mmap_stats = {
|
|
{
|
|
0 /* num_stack_buf_memcpy */,
|
|
0 /* num_heap_buf_memcpy */,
|
|
1 /* num_compressed_buf_memcpy */,
|
|
},
|
|
{
|
|
0 /* num_heap_buf_allocations */,
|
|
1 /* num_compressed_buf_allocations */,
|
|
}};
|
|
TestStats expected_mmap_stats = {{
|
|
0 /* num_stack_buf_memcpy */,
|
|
0 /* num_heap_buf_memcpy */,
|
|
0 /* num_compressed_buf_memcpy */,
|
|
},
|
|
{
|
|
0 /* num_heap_buf_allocations */,
|
|
0 /* num_compressed_buf_allocations */,
|
|
}};
|
|
std::array<TestStats, NumModes> expected_stats_by_mode{{
|
|
expected_non_mmap_stats /* kBufferedRead */,
|
|
expected_mmap_stats /* kBufferedMmap */,
|
|
expected_non_mmap_stats /* kDirectRead */,
|
|
}};
|
|
TestFetchDataBlock("FetchCompressedDataBlock", true, false,
|
|
expected_stats_by_mode);
|
|
}
|
|
|
|
// Data blocks are compressed,
|
|
// fetch and uncompress data block under both direct IO and non-direct IO.
|
|
// Expects:
|
|
// 1. in non-direct IO mode, since the block is small, so it's first memcpyed
|
|
// to the stack buffer, then a heap buffer is allocated and the block is
|
|
// uncompressed into the heap.
|
|
// 2. in direct IO mode mode, allocate a heap buffer, then directly uncompress
|
|
// and memcpy from the direct IO buffer to the heap buffer.
|
|
TEST_F(BlockFetcherTest, FetchAndUncompressCompressedDataBlock) {
|
|
TestStats expected_buffered_read_stats = {
|
|
{
|
|
1 /* num_stack_buf_memcpy */,
|
|
1 /* num_heap_buf_memcpy */,
|
|
0 /* num_compressed_buf_memcpy */,
|
|
},
|
|
{
|
|
1 /* num_heap_buf_allocations */,
|
|
0 /* num_compressed_buf_allocations */,
|
|
}};
|
|
TestStats expected_mmap_stats = {{
|
|
0 /* num_stack_buf_memcpy */,
|
|
1 /* num_heap_buf_memcpy */,
|
|
0 /* num_compressed_buf_memcpy */,
|
|
},
|
|
{
|
|
1 /* num_heap_buf_allocations */,
|
|
0 /* num_compressed_buf_allocations */,
|
|
}};
|
|
TestStats expected_direct_read_stats = {
|
|
{
|
|
0 /* num_stack_buf_memcpy */,
|
|
1 /* num_heap_buf_memcpy */,
|
|
0 /* num_compressed_buf_memcpy */,
|
|
},
|
|
{
|
|
1 /* num_heap_buf_allocations */,
|
|
0 /* num_compressed_buf_allocations */,
|
|
}};
|
|
std::array<TestStats, NumModes> expected_stats_by_mode{{
|
|
expected_buffered_read_stats,
|
|
expected_mmap_stats,
|
|
expected_direct_read_stats,
|
|
}};
|
|
TestFetchDataBlock("FetchAndUncompressCompressedDataBlock", true, true,
|
|
expected_stats_by_mode);
|
|
}
|
|
|
|
|
|
} // namespace
|
|
} // namespace ROCKSDB_NAMESPACE
|
|
|
|
int main(int argc, char** argv) {
|
|
ROCKSDB_NAMESPACE::port::InstallStackTraceHandler();
|
|
::testing::InitGoogleTest(&argc, argv);
|
|
return RUN_ALL_TESTS();
|
|
}
|