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rocksdb/microbench/db_basic_bench.cc
Changyu Bi c2aad555c3 Add CompressionOptions::checksum for enabling ZSTD checksum (#11666) 
Summary:
Optionally enable zstd checksum flag (d857369028/lib/zstd.h (L428)) to detect corruption during decompression. Main changes are in compression.h:
* User can set CompressionOptions::checksum to true to enable this feature.
* We enable this feature in ZSTD by setting the checksum flag in ZSTD compression context: `ZSTD_CCtx`.
* Uses `ZSTD_compress2()` to do compression since it supports frame parameter like the checksum flag. Compression level is also set in compression context as a flag.
* Error handling during decompression to propagate error message from ZSTD.
* Updated microbench to test read performance impact.

About compatibility, the current compression decoders should continue to work with the data created by the new compression API `ZSTD_compress2()`: https://github.com/facebook/zstd/issues/3711.

Pull Request resolved: https://github.com/facebook/rocksdb/pull/11666

Test Plan:
* Existing unit tests for zstd compression
* Add unit test `DBTest2.ZSTDChecksum` to test the corruption case
* Manually tested that compression levels, parallel compression, dictionary compression, index compression all work with the new ZSTD_compress2() API.
* Manually tested with `sst_dump --command=recompress` that different compression levels and dictionary compression settings all work.
* Manually tested compiling with older versions of ZSTD: v1.3.8, v1.1.0, v0.6.2.
* Perf impact: from public benchmark data: http://fastcompression.blogspot.com/2019/03/presenting-xxh3.html for checksum and https://github.com/facebook/zstd#benchmarks, if decompression is 1700MB/s and checksum computation is 70000MB/s, checksum computation is an additional ~2.4% time for decompression. Compression is slower and checksumming should be less noticeable.
* Microbench:
```
TEST_TMPDIR=/dev/shm ./branch_db_basic_bench --benchmark_filter=DBGet/comp_style:0/max_data:1048576/per_key_size:256/enable_statistics:0/negative_query:0/enable_filter:0/mmap:0/compression_type:7/compression_checksum:1/no_blockcache:1/iterations:10000/threads:1 --benchmark_repetitions=100

Min out of 100 runs:
Main:
10390 10436 10456 10484 10499 10535 10544 10545 10565 10568

After this PR, checksum=false
10285 10397 10503 10508 10515 10557 10562 10635 10640 10660

After this PR, checksum=true
10827 10876 10925 10949 10971 11052 11061 11063 11100 11109
```
* db_bench:
```
Write perf
TEST_TMPDIR=/dev/shm/ ./db_bench_ichecksum --benchmarks=fillseq[-X10] --compression_type=zstd --num=10000000 --compression_checksum=..

[FillSeq checksum=0]
fillseq [AVG    10 runs] : 281635 (± 31711) ops/sec;   31.2 (± 3.5) MB/sec
fillseq [MEDIAN 10 runs] : 294027 ops/sec;   32.5 MB/sec

[FillSeq checksum=1]
fillseq [AVG    10 runs] : 286961 (± 34700) ops/sec;   31.7 (± 3.8) MB/sec
fillseq [MEDIAN 10 runs] : 283278 ops/sec;   31.3 MB/sec

Read perf
TEST_TMPDIR=/dev/shm ./db_bench_ichecksum --benchmarks=readrandom[-X20] --num=100000000 --reads=1000000 --use_existing_db=true --readonly=1

[Readrandom checksum=1]
readrandom [AVG    20 runs] : 360928 (± 3579) ops/sec;    4.0 (± 0.0) MB/sec
readrandom [MEDIAN 20 runs] : 362468 ops/sec;    4.0 MB/sec

[Readrandom checksum=0]
readrandom [AVG    20 runs] : 380365 (± 2384) ops/sec;    4.2 (± 0.0) MB/sec
readrandom [MEDIAN 20 runs] : 379800 ops/sec;    4.2 MB/sec

Compression
TEST_TMPDIR=/dev/shm ./db_bench_ichecksum --benchmarks=compress[-X20] --compression_type=zstd --num=100000000 --compression_checksum=1

checksum=1
compress [AVG    20 runs] : 54074 (± 634) ops/sec;  211.2 (± 2.5) MB/sec
compress [MEDIAN 20 runs] : 54396 ops/sec;  212.5 MB/sec

checksum=0
compress [AVG    20 runs] : 54598 (± 393) ops/sec;  213.3 (± 1.5) MB/sec
compress [MEDIAN 20 runs] : 54592 ops/sec;  213.3 MB/sec

Decompression:
TEST_TMPDIR=/dev/shm ./db_bench_ichecksum --benchmarks=uncompress[-X20] --compression_type=zstd --compression_checksum=1

checksum = 0
uncompress [AVG    20 runs] : 167499 (± 962) ops/sec;  654.3 (± 3.8) MB/sec
uncompress [MEDIAN 20 runs] : 167210 ops/sec;  653.2 MB/sec
checksum = 1
uncompress [AVG    20 runs] : 167980 (± 924) ops/sec;  656.2 (± 3.6) MB/sec
uncompress [MEDIAN 20 runs] : 168465 ops/sec;  658.1 MB/sec
```

Reviewed By: ajkr

Differential Revision: D48019378

Pulled By: cbi42

fbshipit-source-id: 674120c6e1853c2ced1436ac8138559d0204feba
2023-08-18 15:01:59 -07:00

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// 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).
#ifndef OS_WIN
#include <unistd.h>
#endif // ! OS_WIN
#include "benchmark/benchmark.h"
#include "db/db_impl/db_impl.h"
#include "rocksdb/db.h"
#include "rocksdb/filter_policy.h"
#include "rocksdb/options.h"
#include "table/block_based/block.h"
#include "table/block_based/block_builder.h"
#include "util/random.h"
#include "utilities/merge_operators.h"
namespace ROCKSDB_NAMESPACE {
class KeyGenerator {
public:
// Generate next key
// buff: the caller needs to make sure there's enough space for generated key
// offset: to control the group of the key, 0 means normal key, 1 means
// non-existing key, 2 is reserved prefix_only: only return a prefix
Slice Next(char* buff, int8_t offset = 0, bool prefix_only = false) {
assert(max_key_ < std::numeric_limits<uint32_t>::max() /
MULTIPLIER); // TODO: add large key support
uint32_t k;
if (is_sequential_) {
assert(next_sequential_key_ < max_key_);
k = (next_sequential_key_ % max_key_) * MULTIPLIER + offset;
if (next_sequential_key_ + 1 == max_key_) {
next_sequential_key_ = 0;
} else {
next_sequential_key_++;
}
} else {
k = (rnd_->Next() % max_key_) * MULTIPLIER + offset;
}
// TODO: make sure the buff is large enough
memset(buff, 0, key_size_);
if (prefix_num_ > 0) {
uint32_t prefix = (k % prefix_num_) * MULTIPLIER + offset;
Encode(buff, prefix);
if (prefix_only) {
return {buff, prefix_size_};
}
}
Encode(buff + prefix_size_, k);
return {buff, key_size_};
}
// use internal buffer for generated key, make sure there's only one caller in
// single thread
Slice Next() { return Next(buff_); }
// user internal buffer for generated prefix
Slice NextPrefix() {
assert(prefix_num_ > 0);
return Next(buff_, 0, true);
}
// helper function to get non exist key
Slice NextNonExist() { return Next(buff_, 1); }
Slice MaxKey(char* buff) const {
memset(buff, 0xff, key_size_);
return {buff, key_size_};
}
Slice MinKey(char* buff) const {
memset(buff, 0, key_size_);
return {buff, key_size_};
}
// max_key: the max key that it could generate
// prefix_num: the max prefix number
// key_size: in bytes
explicit KeyGenerator(Random* rnd, uint64_t max_key = 100 * 1024 * 1024,
size_t prefix_num = 0, size_t key_size = 10) {
prefix_num_ = prefix_num;
key_size_ = key_size;
max_key_ = max_key;
rnd_ = rnd;
if (prefix_num > 0) {
prefix_size_ = 4; // TODO: support different prefix_size
}
}
// generate sequential keys
explicit KeyGenerator(uint64_t max_key = 100 * 1024 * 1024,
size_t key_size = 10) {
key_size_ = key_size;
max_key_ = max_key;
rnd_ = nullptr;
is_sequential_ = true;
}
private:
Random* rnd_;
size_t prefix_num_ = 0;
size_t prefix_size_ = 0;
size_t key_size_;
uint64_t max_key_;
bool is_sequential_ = false;
uint32_t next_sequential_key_ = 0;
char buff_[256] = {0};
const int MULTIPLIER = 3;
void static Encode(char* buf, uint32_t value) {
if (port::kLittleEndian) {
buf[0] = static_cast<char>((value >> 24) & 0xff);
buf[1] = static_cast<char>((value >> 16) & 0xff);
buf[2] = static_cast<char>((value >> 8) & 0xff);
buf[3] = static_cast<char>(value & 0xff);
} else {
memcpy(buf, &value, sizeof(value));
}
}
};
static void SetupDB(benchmark::State& state, Options& options,
std::unique_ptr<DB>* db,
const std::string& test_name = "") {
options.create_if_missing = true;
auto env = Env::Default();
std::string db_path;
Status s = env->GetTestDirectory(&db_path);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
return;
}
std::string db_name =
db_path + kFilePathSeparator + test_name + std::to_string(getpid());
DestroyDB(db_name, options);
DB* db_ptr = nullptr;
s = DB::Open(options, db_name, &db_ptr);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
return;
}
db->reset(db_ptr);
}
static void TeardownDB(benchmark::State& state, const std::unique_ptr<DB>& db,
const Options& options, KeyGenerator& kg) {
char min_buff[256], max_buff[256];
const Range r(kg.MinKey(min_buff), kg.MaxKey(max_buff));
uint64_t size;
Status s = db->GetApproximateSizes(&r, 1, &size);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
state.counters["db_size"] = static_cast<double>(size);
std::string db_name = db->GetName();
s = db->Close();
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
DestroyDB(db_name, options);
}
static void DBOpen(benchmark::State& state) {
// create DB
std::unique_ptr<DB> db;
Options options;
SetupDB(state, options, &db, "DBOpen");
std::string db_name = db->GetName();
db->Close();
options.create_if_missing = false;
auto rnd = Random(123);
for (auto _ : state) {
{
DB* db_ptr = nullptr;
Status s = DB::Open(options, db_name, &db_ptr);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
db.reset(db_ptr);
}
state.PauseTiming();
auto wo = WriteOptions();
Status s;
for (int i = 0; i < 2; i++) {
for (int j = 0; j < 100; j++) {
s = db->Put(wo, rnd.RandomString(10), rnd.RandomString(100));
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
s = db->Flush(FlushOptions());
}
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
s = db->Close();
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
state.ResumeTiming();
}
DestroyDB(db_name, options);
}
BENCHMARK(DBOpen)->Iterations(200); // specify iteration number as the db size
// is impacted by iteration number
static void DBClose(benchmark::State& state) {
// create DB
std::unique_ptr<DB> db;
Options options;
SetupDB(state, options, &db, "DBClose");
std::string db_name = db->GetName();
db->Close();
options.create_if_missing = false;
auto rnd = Random(12345);
for (auto _ : state) {
state.PauseTiming();
{
DB* db_ptr = nullptr;
Status s = DB::Open(options, db_name, &db_ptr);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
db.reset(db_ptr);
}
auto wo = WriteOptions();
Status s;
for (int i = 0; i < 2; i++) {
for (int j = 0; j < 100; j++) {
s = db->Put(wo, rnd.RandomString(10), rnd.RandomString(100));
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
s = db->Flush(FlushOptions());
}
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
state.ResumeTiming();
s = db->Close();
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
DestroyDB(db_name, options);
}
BENCHMARK(DBClose)->Iterations(200); // specify iteration number as the db size
// is impacted by iteration number
static void DBPut(benchmark::State& state) {
auto compaction_style = static_cast<CompactionStyle>(state.range(0));
uint64_t max_data = state.range(1);
uint64_t per_key_size = state.range(2);
bool enable_statistics = state.range(3);
bool enable_wal = state.range(4);
uint64_t key_num = max_data / per_key_size;
// setup DB
static std::unique_ptr<DB> db = nullptr;
Options options;
if (enable_statistics) {
options.statistics = CreateDBStatistics();
}
options.compaction_style = compaction_style;
auto rnd = Random(301 + state.thread_index());
KeyGenerator kg(&rnd, key_num);
if (state.thread_index() == 0) {
SetupDB(state, options, &db, "DBPut");
}
auto wo = WriteOptions();
wo.disableWAL = !enable_wal;
for (auto _ : state) {
state.PauseTiming();
Slice key = kg.Next();
std::string val = rnd.RandomString(static_cast<int>(per_key_size));
state.ResumeTiming();
Status s = db->Put(wo, key, val);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
if (state.thread_index() == 0) {
auto db_full = static_cast_with_check<DBImpl>(db.get());
Status s = db_full->WaitForCompact(WaitForCompactOptions());
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
return;
}
if (enable_statistics) {
HistogramData histogram_data;
options.statistics->histogramData(DB_WRITE, &histogram_data);
state.counters["put_mean"] = histogram_data.average * std::milli::den;
state.counters["put_p95"] = histogram_data.percentile95 * std::milli::den;
state.counters["put_p99"] = histogram_data.percentile99 * std::milli::den;
}
TeardownDB(state, db, options, kg);
}
}
static void DBPutArguments(benchmark::internal::Benchmark* b) {
for (int comp_style : {kCompactionStyleLevel, kCompactionStyleUniversal,
kCompactionStyleFIFO}) {
for (int64_t max_data : {100l << 30}) {
for (int64_t per_key_size : {256, 1024}) {
for (bool enable_statistics : {false, true}) {
for (bool wal : {false, true}) {
b->Args(
{comp_style, max_data, per_key_size, enable_statistics, wal});
}
}
}
}
}
b->ArgNames(
{"comp_style", "max_data", "per_key_size", "enable_statistics", "wal"});
}
static const uint64_t DBPutNum = 409600l;
BENCHMARK(DBPut)->Threads(1)->Iterations(DBPutNum)->Apply(DBPutArguments);
BENCHMARK(DBPut)->Threads(8)->Iterations(DBPutNum / 8)->Apply(DBPutArguments);
static void ManualCompaction(benchmark::State& state) {
auto compaction_style = static_cast<CompactionStyle>(state.range(0));
uint64_t max_data = state.range(1);
uint64_t per_key_size = state.range(2);
bool enable_statistics = state.range(3);
uint64_t key_num = max_data / per_key_size;
// setup DB
static std::unique_ptr<DB> db;
Options options;
if (enable_statistics) {
options.statistics = CreateDBStatistics();
}
options.compaction_style = compaction_style;
// No auto compaction
options.disable_auto_compactions = true;
options.level0_file_num_compaction_trigger = (1 << 30);
options.level0_slowdown_writes_trigger = (1 << 30);
options.level0_stop_writes_trigger = (1 << 30);
options.soft_pending_compaction_bytes_limit = 0;
options.hard_pending_compaction_bytes_limit = 0;
auto rnd = Random(301 + state.thread_index());
KeyGenerator kg(&rnd, key_num);
if (state.thread_index() == 0) {
SetupDB(state, options, &db, "ManualCompaction");
}
auto wo = WriteOptions();
wo.disableWAL = true;
uint64_t flush_mod = key_num / 4; // at least generate 4 files for compaction
for (uint64_t i = 0; i < key_num; i++) {
Status s = db->Put(wo, kg.Next(),
rnd.RandomString(static_cast<int>(per_key_size)));
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
if (i + 1 % flush_mod == 0) {
s = db->Flush(FlushOptions());
}
}
FlushOptions fo;
Status s = db->Flush(fo);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
std::vector<LiveFileMetaData> files_meta;
db->GetLiveFilesMetaData(&files_meta);
std::vector<std::string> files_before_compact;
files_before_compact.reserve(files_meta.size());
for (const LiveFileMetaData& file : files_meta) {
files_before_compact.emplace_back(file.name);
}
SetPerfLevel(kEnableTime);
get_perf_context()->EnablePerLevelPerfContext();
get_perf_context()->Reset();
CompactionOptions co;
for (auto _ : state) {
s = db->CompactFiles(co, files_before_compact, 1);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
if (state.thread_index() == 0) {
auto db_full = static_cast_with_check<DBImpl>(db.get());
s = db_full->WaitForCompact(WaitForCompactOptions());
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
return;
}
if (enable_statistics) {
HistogramData histogram_data;
options.statistics->histogramData(COMPACTION_TIME, &histogram_data);
state.counters["comp_time"] = histogram_data.average;
options.statistics->histogramData(COMPACTION_CPU_TIME, &histogram_data);
state.counters["comp_cpu_time"] = histogram_data.average;
options.statistics->histogramData(COMPACTION_OUTFILE_SYNC_MICROS,
&histogram_data);
state.counters["comp_outfile_sync"] = histogram_data.average;
state.counters["comp_read"] = static_cast<double>(
options.statistics->getTickerCount(COMPACT_READ_BYTES));
state.counters["comp_write"] = static_cast<double>(
options.statistics->getTickerCount(COMPACT_WRITE_BYTES));
state.counters["user_key_comparison_count"] =
static_cast<double>(get_perf_context()->user_key_comparison_count);
state.counters["block_read_count"] =
static_cast<double>(get_perf_context()->block_read_count);
state.counters["block_read_time"] =
static_cast<double>(get_perf_context()->block_read_time);
state.counters["block_read_cpu_time"] =
static_cast<double>(get_perf_context()->block_read_cpu_time);
state.counters["block_checksum_time"] =
static_cast<double>(get_perf_context()->block_checksum_time);
state.counters["new_table_block_iter_nanos"] =
static_cast<double>(get_perf_context()->new_table_block_iter_nanos);
state.counters["new_table_iterator_nanos"] =
static_cast<double>(get_perf_context()->new_table_iterator_nanos);
state.counters["find_table_nanos"] =
static_cast<double>(get_perf_context()->find_table_nanos);
}
TeardownDB(state, db, options, kg);
}
}
static void ManualCompactionArguments(benchmark::internal::Benchmark* b) {
for (int comp_style : {kCompactionStyleLevel, kCompactionStyleUniversal}) {
for (int64_t max_data : {32l << 20, 128l << 20}) {
for (int64_t per_key_size : {256, 1024}) {
for (bool enable_statistics : {false, true}) {
b->Args({comp_style, max_data, per_key_size, enable_statistics});
}
}
}
}
b->ArgNames({"comp_style", "max_data", "per_key_size", "enable_statistics"});
}
BENCHMARK(ManualCompaction)->Iterations(1)->Apply(ManualCompactionArguments);
static void ManualFlush(benchmark::State& state) {
uint64_t key_num = state.range(0);
uint64_t per_key_size = state.range(1);
bool enable_statistics = true;
// setup DB
static std::unique_ptr<DB> db;
Options options;
if (enable_statistics) {
options.statistics = CreateDBStatistics();
}
options.disable_auto_compactions = true;
options.level0_file_num_compaction_trigger = (1 << 30);
options.level0_slowdown_writes_trigger = (1 << 30);
options.level0_stop_writes_trigger = (1 << 30);
options.soft_pending_compaction_bytes_limit = 0;
options.hard_pending_compaction_bytes_limit = 0;
options.write_buffer_size = 2l << 30; // 2G to avoid auto flush
auto rnd = Random(301 + state.thread_index());
KeyGenerator kg(&rnd, key_num);
if (state.thread_index() == 0) {
SetupDB(state, options, &db, "ManualFlush");
}
auto wo = WriteOptions();
for (auto _ : state) {
state.PauseTiming();
for (uint64_t i = 0; i < key_num; i++) {
Status s = db->Put(wo, kg.Next(),
rnd.RandomString(static_cast<int>(per_key_size)));
}
FlushOptions fo;
state.ResumeTiming();
Status s = db->Flush(fo);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
if (state.thread_index() == 0) {
auto db_full = static_cast_with_check<DBImpl>(db.get());
Status s = db_full->WaitForCompact(WaitForCompactOptions());
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
return;
}
if (enable_statistics) {
HistogramData histogram_data;
options.statistics->histogramData(FLUSH_TIME, &histogram_data);
state.counters["flush_time"] = histogram_data.average;
state.counters["flush_write_bytes"] = static_cast<double>(
options.statistics->getTickerCount(FLUSH_WRITE_BYTES));
}
TeardownDB(state, db, options, kg);
}
}
static void ManualFlushArguments(benchmark::internal::Benchmark* b) {
for (int64_t key_num : {1l << 10, 8l << 10, 64l << 10}) {
for (int64_t per_key_size : {256, 1024}) {
b->Args({key_num, per_key_size});
}
}
b->ArgNames({"key_num", "per_key_size"});
}
BENCHMARK(ManualFlush)->Iterations(1)->Apply(ManualFlushArguments);
// Copied from test_util.cc to not depend on rocksdb_test_lib
// when building microbench binaries.
static Slice CompressibleString(Random* rnd, double compressed_fraction,
int len, std::string* dst) {
int raw = static_cast<int>(len * compressed_fraction);
if (raw < 1) raw = 1;
std::string raw_data = rnd->RandomBinaryString(raw);
// Duplicate the random data until we have filled "len" bytes
dst->clear();
while (dst->size() < (unsigned int)len) {
dst->append(raw_data);
}
dst->resize(len);
return Slice(*dst);
}
static void DBGet(benchmark::State& state) {
auto compaction_style = static_cast<CompactionStyle>(state.range(0));
uint64_t max_data = state.range(1);
uint64_t per_key_size = state.range(2);
bool enable_statistics = state.range(3);
bool negative_query = state.range(4);
bool enable_filter = state.range(5);
bool mmap = state.range(6);
auto compression_type = static_cast<CompressionType>(state.range(7));
bool compression_checksum = static_cast<bool>(state.range(8));
bool no_blockcache = state.range(9);
uint64_t key_num = max_data / per_key_size;
// setup DB
static std::unique_ptr<DB> db;
Options options;
if (enable_statistics) {
options.statistics = CreateDBStatistics();
}
if (mmap) {
options.allow_mmap_reads = true;
options.compression = kNoCompression;
}
options.compaction_style = compaction_style;
BlockBasedTableOptions table_options;
if (enable_filter) {
table_options.filter_policy.reset(NewBloomFilterPolicy(10, false));
}
if (mmap) {
table_options.no_block_cache = true;
table_options.block_restart_interval = 1;
}
options.compression = compression_type;
options.compression_opts.checksum = compression_checksum;
if (no_blockcache) {
table_options.no_block_cache = true;
} else {
table_options.block_cache = NewLRUCache(100 << 20);
}
options.table_factory.reset(NewBlockBasedTableFactory(table_options));
auto rnd = Random(301 + state.thread_index());
if (state.thread_index() == 0) {
KeyGenerator kg_seq(key_num /* max_key */);
SetupDB(state, options, &db, "DBGet");
// Load all valid keys into DB. That way, iterations in `!negative_query`
// runs can always find the key even though it is generated from a random
// number.
auto wo = WriteOptions();
wo.disableWAL = true;
std::string val;
for (uint64_t i = 0; i < key_num; i++) {
CompressibleString(&rnd, 0.5, static_cast<int>(per_key_size), &val);
Status s = db->Put(wo, kg_seq.Next(), val);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
// Compact whole DB into one level, so each iteration will consider the same
// number of files (one).
Status s = db->CompactRange(CompactRangeOptions(), nullptr /* begin */,
nullptr /* end */);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
KeyGenerator kg_rnd(&rnd, key_num /* max_key */);
auto ro = ReadOptions();
if (mmap) {
ro.verify_checksums = false;
}
size_t not_found = 0;
if (negative_query) {
for (auto _ : state) {
std::string val;
Status s = db->Get(ro, kg_rnd.NextNonExist(), &val);
if (s.IsNotFound()) {
not_found++;
}
}
} else {
for (auto _ : state) {
std::string val;
Status s = db->Get(ro, kg_rnd.Next(), &val);
if (s.IsNotFound()) {
not_found++;
}
}
}
state.counters["neg_qu_pct"] = benchmark::Counter(
static_cast<double>(not_found * 100), benchmark::Counter::kAvgIterations);
if (state.thread_index() == 0) {
if (enable_statistics) {
HistogramData histogram_data;
options.statistics->histogramData(DB_GET, &histogram_data);
state.counters["get_mean"] = histogram_data.average * std::milli::den;
state.counters["get_p95"] = histogram_data.percentile95 * std::milli::den;
state.counters["get_p99"] = histogram_data.percentile99 * std::milli::den;
}
TeardownDB(state, db, options, kg_rnd);
}
}
static void DBGetArguments(benchmark::internal::Benchmark* b) {
for (int comp_style : {kCompactionStyleLevel, kCompactionStyleUniversal,
kCompactionStyleFIFO}) {
for (int64_t max_data : {1l << 20, 128l << 20, 512l << 20}) {
for (int64_t per_key_size : {256, 1024}) {
for (bool enable_statistics : {false, true}) {
for (bool negative_query : {false, true}) {
for (bool enable_filter : {false, true}) {
for (bool mmap : {false, true}) {
for (int compression_type :
{kNoCompression /* 0x0 */, kZSTD /* 0x7 */}) {
for (bool compression_checksum : {false, true}) {
for (bool no_blockcache : {false, true}) {
b->Args({comp_style, max_data, per_key_size,
enable_statistics, negative_query, enable_filter,
mmap, compression_type, compression_checksum,
no_blockcache});
}
}
}
}
}
}
}
}
}
}
b->ArgNames({"comp_style", "max_data", "per_key_size", "enable_statistics",
"negative_query", "enable_filter", "mmap", "compression_type",
"compression_checksum", "no_blockcache"});
}
static const uint64_t DBGetNum = 10000l;
BENCHMARK(DBGet)->Threads(1)->Iterations(DBGetNum)->Apply(DBGetArguments);
BENCHMARK(DBGet)->Threads(8)->Iterations(DBGetNum / 8)->Apply(DBGetArguments);
static void SimpleGetWithPerfContext(benchmark::State& state) {
// setup DB
static std::unique_ptr<DB> db;
std::string db_name;
Options options;
options.create_if_missing = true;
options.arena_block_size = 8 << 20;
auto rnd = Random(301 + state.thread_index());
KeyGenerator kg(&rnd, 1024);
if (state.thread_index() == 0) {
auto env = Env::Default();
std::string db_path;
Status s = env->GetTestDirectory(&db_path);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
return;
}
db_name = db_path + "/simple_get_" + std::to_string(getpid());
DestroyDB(db_name, options);
{
DB* db_ptr = nullptr;
s = DB::Open(options, db_name, &db_ptr);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
return;
}
db.reset(db_ptr);
}
// load db
auto wo = WriteOptions();
wo.disableWAL = true;
for (uint64_t i = 0; i < 1024; i++) {
s = db->Put(wo, kg.Next(), rnd.RandomString(1024));
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
auto db_full = static_cast_with_check<DBImpl>(db.get());
s = db_full->WaitForCompact(WaitForCompactOptions());
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
return;
}
FlushOptions fo;
s = db->Flush(fo);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
auto ro = ReadOptions();
size_t not_found = 0;
uint64_t user_key_comparison_count = 0;
uint64_t block_read_time = 0;
uint64_t block_read_cpu_time = 0;
uint64_t block_checksum_time = 0;
uint64_t get_snapshot_time = 0;
uint64_t get_post_process_time = 0;
uint64_t get_from_output_files_time = 0;
uint64_t new_table_block_iter_nanos = 0;
uint64_t block_seek_nanos = 0;
uint64_t get_cpu_nanos = 0;
uint64_t get_from_table_nanos = 0;
SetPerfLevel(kEnableTime);
get_perf_context()->EnablePerLevelPerfContext();
for (auto _ : state) {
std::string val;
get_perf_context()->Reset();
Status s = db->Get(ro, kg.NextNonExist(), &val);
if (s.IsNotFound()) {
not_found++;
}
user_key_comparison_count += get_perf_context()->user_key_comparison_count;
block_read_time += get_perf_context()->block_read_time;
block_read_cpu_time += get_perf_context()->block_read_cpu_time;
block_checksum_time += get_perf_context()->block_checksum_time;
get_snapshot_time += get_perf_context()->get_snapshot_time;
get_post_process_time += get_perf_context()->get_post_process_time;
get_from_output_files_time +=
get_perf_context()->get_from_output_files_time;
new_table_block_iter_nanos +=
get_perf_context()->new_table_block_iter_nanos;
block_seek_nanos += get_perf_context()->block_seek_nanos;
get_cpu_nanos += get_perf_context()->get_cpu_nanos;
get_from_table_nanos +=
(*(get_perf_context()->level_to_perf_context))[0].get_from_table_nanos;
}
state.counters["neg_qu_pct"] = benchmark::Counter(
static_cast<double>(not_found * 100), benchmark::Counter::kAvgIterations);
state.counters["user_key_comparison_count"] =
benchmark::Counter(static_cast<double>(user_key_comparison_count),
benchmark::Counter::kAvgIterations);
state.counters["block_read_time"] = benchmark::Counter(
static_cast<double>(block_read_time), benchmark::Counter::kAvgIterations);
state.counters["block_read_cpu_time"] =
benchmark::Counter(static_cast<double>(block_read_cpu_time),
benchmark::Counter::kAvgIterations);
state.counters["block_checksum_time"] =
benchmark::Counter(static_cast<double>(block_checksum_time),
benchmark::Counter::kAvgIterations);
state.counters["get_snapshot_time"] =
benchmark::Counter(static_cast<double>(get_snapshot_time),
benchmark::Counter::kAvgIterations);
state.counters["get_post_process_time"] =
benchmark::Counter(static_cast<double>(get_post_process_time),
benchmark::Counter::kAvgIterations);
state.counters["get_from_output_files_time"] =
benchmark::Counter(static_cast<double>(get_from_output_files_time),
benchmark::Counter::kAvgIterations);
state.counters["new_table_block_iter_nanos"] =
benchmark::Counter(static_cast<double>(new_table_block_iter_nanos),
benchmark::Counter::kAvgIterations);
state.counters["block_seek_nanos"] =
benchmark::Counter(static_cast<double>(block_seek_nanos),
benchmark::Counter::kAvgIterations);
state.counters["get_cpu_nanos"] = benchmark::Counter(
static_cast<double>(get_cpu_nanos), benchmark::Counter::kAvgIterations);
state.counters["get_from_table_nanos"] =
benchmark::Counter(static_cast<double>(get_from_table_nanos),
benchmark::Counter::kAvgIterations);
if (state.thread_index() == 0) {
TeardownDB(state, db, options, kg);
}
}
BENCHMARK(SimpleGetWithPerfContext)->Iterations(1000000);
static void DBGetMergeOperandsInMemtable(benchmark::State& state) {
const uint64_t kDataLen = 16 << 20; // 16MB
const uint64_t kValueLen = 64;
const uint64_t kNumEntries = kDataLen / kValueLen;
const uint64_t kNumEntriesPerKey = state.range(0);
const uint64_t kNumKeys = kNumEntries / kNumEntriesPerKey;
// setup DB
static std::unique_ptr<DB> db;
Options options;
options.merge_operator = MergeOperators::CreateStringAppendOperator();
// Make memtable large enough that automatic flush will not be triggered.
options.write_buffer_size = 2 * kDataLen;
KeyGenerator sequential_key_gen(kNumKeys);
auto rnd = Random(301 + state.thread_index());
if (state.thread_index() == 0) {
SetupDB(state, options, &db, "DBGetMergeOperandsInMemtable");
// load db
auto write_opts = WriteOptions();
write_opts.disableWAL = true;
for (uint64_t i = 0; i < kNumEntries; i++) {
Status s = db->Merge(write_opts, sequential_key_gen.Next(),
rnd.RandomString(static_cast<int>(kValueLen)));
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
}
KeyGenerator random_key_gen(kNumKeys);
std::vector<PinnableSlice> value_operands;
value_operands.resize(kNumEntriesPerKey);
GetMergeOperandsOptions get_merge_ops_opts;
get_merge_ops_opts.expected_max_number_of_operands =
static_cast<int>(kNumEntriesPerKey);
for (auto _ : state) {
int num_value_operands = 0;
Status s = db->GetMergeOperands(
ReadOptions(), db->DefaultColumnFamily(), random_key_gen.Next(),
value_operands.data(), &get_merge_ops_opts, &num_value_operands);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
if (num_value_operands != static_cast<int>(kNumEntriesPerKey)) {
state.SkipWithError("Unexpected number of merge operands found for key");
}
for (auto& value_operand : value_operands) {
value_operand.Reset();
}
}
if (state.thread_index() == 0) {
TeardownDB(state, db, options, random_key_gen);
}
}
static void DBGetMergeOperandsInSstFile(benchmark::State& state) {
const uint64_t kDataLen = 16 << 20; // 16MB
const uint64_t kValueLen = 64;
const uint64_t kNumEntries = kDataLen / kValueLen;
const uint64_t kNumEntriesPerKey = state.range(0);
const uint64_t kNumKeys = kNumEntries / kNumEntriesPerKey;
const bool kMmap = state.range(1);
// setup DB
static std::unique_ptr<DB> db;
BlockBasedTableOptions table_options;
if (kMmap) {
table_options.no_block_cache = true;
} else {
// Make block cache large enough that eviction will not be triggered.
table_options.block_cache = NewLRUCache(2 * kDataLen);
}
Options options;
if (kMmap) {
options.allow_mmap_reads = true;
}
options.compression = kNoCompression;
options.merge_operator = MergeOperators::CreateStringAppendOperator();
options.table_factory.reset(NewBlockBasedTableFactory(table_options));
// Make memtable large enough that automatic flush will not be triggered.
options.write_buffer_size = 2 * kDataLen;
KeyGenerator sequential_key_gen(kNumKeys);
auto rnd = Random(301 + state.thread_index());
if (state.thread_index() == 0) {
SetupDB(state, options, &db, "DBGetMergeOperandsInBlockCache");
// load db
//
// Take a snapshot after each cycle of merges to ensure flush cannot
// merge any entries.
std::vector<const Snapshot*> snapshots;
snapshots.resize(kNumEntriesPerKey);
auto write_opts = WriteOptions();
write_opts.disableWAL = true;
for (uint64_t i = 0; i < kNumEntriesPerKey; i++) {
for (uint64_t j = 0; j < kNumKeys; j++) {
Status s = db->Merge(write_opts, sequential_key_gen.Next(),
rnd.RandomString(static_cast<int>(kValueLen)));
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
snapshots[i] = db->GetSnapshot();
}
// Flush to an L0 file; read back to prime the cache/mapped memory.
db->Flush(FlushOptions());
for (uint64_t i = 0; i < kNumKeys; ++i) {
std::string value;
Status s = db->Get(ReadOptions(), sequential_key_gen.Next(), &value);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
if (state.thread_index() == 0) {
for (uint64_t i = 0; i < kNumEntriesPerKey; ++i) {
db->ReleaseSnapshot(snapshots[i]);
}
}
}
KeyGenerator random_key_gen(kNumKeys);
std::vector<PinnableSlice> value_operands;
value_operands.resize(kNumEntriesPerKey);
GetMergeOperandsOptions get_merge_ops_opts;
get_merge_ops_opts.expected_max_number_of_operands =
static_cast<int>(kNumEntriesPerKey);
for (auto _ : state) {
int num_value_operands = 0;
ReadOptions read_opts;
read_opts.verify_checksums = false;
Status s = db->GetMergeOperands(
read_opts, db->DefaultColumnFamily(), random_key_gen.Next(),
value_operands.data(), &get_merge_ops_opts, &num_value_operands);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
if (num_value_operands != static_cast<int>(kNumEntriesPerKey)) {
state.SkipWithError("Unexpected number of merge operands found for key");
}
for (auto& value_operand : value_operands) {
value_operand.Reset();
}
}
if (state.thread_index() == 0) {
TeardownDB(state, db, options, random_key_gen);
}
}
static void DBGetMergeOperandsInMemtableArguments(
benchmark::internal::Benchmark* b) {
for (int entries_per_key : {1, 32, 1024}) {
b->Args({entries_per_key});
}
b->ArgNames({"entries_per_key"});
}
static void DBGetMergeOperandsInSstFileArguments(
benchmark::internal::Benchmark* b) {
for (int entries_per_key : {1, 32, 1024}) {
for (bool mmap : {false, true}) {
b->Args({entries_per_key, mmap});
}
}
b->ArgNames({"entries_per_key", "mmap"});
}
BENCHMARK(DBGetMergeOperandsInMemtable)
->Threads(1)
->Apply(DBGetMergeOperandsInMemtableArguments);
BENCHMARK(DBGetMergeOperandsInMemtable)
->Threads(8)
->Apply(DBGetMergeOperandsInMemtableArguments);
BENCHMARK(DBGetMergeOperandsInSstFile)
->Threads(1)
->Apply(DBGetMergeOperandsInSstFileArguments);
BENCHMARK(DBGetMergeOperandsInSstFile)
->Threads(8)
->Apply(DBGetMergeOperandsInSstFileArguments);
std::string GenerateKey(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);
}
return k;
}
void GenerateRandomKVs(std::vector<std::string>* keys,
std::vector<std::string>* 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 share the prefix
for (int j = 0; j < keys_share_prefix; ++j) {
keys->emplace_back(GenerateKey(i, j, padding_size, &rnd));
// 100 bytes values
values->emplace_back(rnd.RandomString(100));
}
}
}
// TODO: move it to different files, as it's testing an internal API
static void DataBlockSeek(benchmark::State& state) {
Random rnd(301);
Options options = Options();
BlockBuilder builder(16, true, false,
BlockBasedTableOptions::kDataBlockBinarySearch);
int num_records = 500;
std::vector<std::string> keys;
std::vector<std::string> values;
GenerateRandomKVs(&keys, &values, 0, num_records);
for (int i = 0; i < num_records; i++) {
std::string ukey(keys[i] + "1");
InternalKey ikey(ukey, 0, kTypeValue);
builder.Add(ikey.Encode().ToString(), values[i]);
}
Slice rawblock = builder.Finish();
BlockContents contents;
contents.data = rawblock;
Block reader(std::move(contents));
SetPerfLevel(kEnableTime);
uint64_t total = 0;
for (auto _ : state) {
DataBlockIter* iter = reader.NewDataIterator(options.comparator,
kDisableGlobalSequenceNumber);
uint32_t index = rnd.Uniform(static_cast<int>(num_records));
std::string ukey(keys[index] + "1");
InternalKey ikey(ukey, 0, kTypeValue);
get_perf_context()->Reset();
bool may_exist = iter->SeekForGet(ikey.Encode().ToString());
if (!may_exist) {
state.SkipWithError("key not found");
}
total += get_perf_context()->block_seek_nanos;
delete iter;
}
state.counters["seek_ns"] = benchmark::Counter(
static_cast<double>(total), benchmark::Counter::kAvgIterations);
}
BENCHMARK(DataBlockSeek)->Iterations(1000000);
static void IteratorSeek(benchmark::State& state) {
auto compaction_style = static_cast<CompactionStyle>(state.range(0));
uint64_t max_data = state.range(1);
uint64_t per_key_size = state.range(2);
bool enable_statistics = state.range(3);
bool negative_query = state.range(4);
bool enable_filter = state.range(5);
uint64_t key_num = max_data / per_key_size;
// setup DB
static std::unique_ptr<DB> db;
Options options;
if (enable_statistics) {
options.statistics = CreateDBStatistics();
}
options.compaction_style = compaction_style;
if (enable_filter) {
BlockBasedTableOptions table_options;
table_options.filter_policy.reset(NewBloomFilterPolicy(10, false));
options.table_factory.reset(NewBlockBasedTableFactory(table_options));
}
auto rnd = Random(301 + state.thread_index());
KeyGenerator kg(&rnd, key_num);
if (state.thread_index() == 0) {
SetupDB(state, options, &db, "IteratorSeek");
// load db
auto wo = WriteOptions();
wo.disableWAL = true;
for (uint64_t i = 0; i < key_num; i++) {
Status s = db->Put(wo, kg.Next(),
rnd.RandomString(static_cast<int>(per_key_size)));
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
FlushOptions fo;
Status s = db->Flush(fo);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
auto db_full = static_cast_with_check<DBImpl>(db.get());
s = db_full->WaitForCompact(WaitForCompactOptions());
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
return;
}
}
for (auto _ : state) {
std::unique_ptr<Iterator> iter{nullptr};
state.PauseTiming();
if (!iter) {
iter.reset(db->NewIterator(ReadOptions()));
}
Slice key = negative_query ? kg.NextNonExist() : kg.Next();
if (!iter->status().ok()) {
state.SkipWithError(iter->status().ToString().c_str());
return;
}
state.ResumeTiming();
iter->Seek(key);
}
if (state.thread_index() == 0) {
TeardownDB(state, db, options, kg);
}
}
static void IteratorSeekArguments(benchmark::internal::Benchmark* b) {
for (int comp_style : {kCompactionStyleLevel, kCompactionStyleUniversal,
kCompactionStyleFIFO}) {
for (int64_t max_data : {128l << 20, 512l << 20}) {
for (int64_t per_key_size : {256, 1024}) {
for (bool enable_statistics : {false, true}) {
for (bool negative_query : {false, true}) {
for (bool enable_filter : {false, true}) {
b->Args({comp_style, max_data, per_key_size, enable_statistics,
negative_query, enable_filter});
}
}
}
}
}
}
b->ArgNames({"comp_style", "max_data", "per_key_size", "enable_statistics",
"negative_query", "enable_filter"});
}
static constexpr uint64_t kDBSeekNum = 10l << 10;
BENCHMARK(IteratorSeek)
->Threads(1)
->Iterations(kDBSeekNum)
->Apply(IteratorSeekArguments);
BENCHMARK(IteratorSeek)
->Threads(8)
->Iterations(kDBSeekNum / 8)
->Apply(IteratorSeekArguments);
static void IteratorNext(benchmark::State& state) {
auto compaction_style = static_cast<CompactionStyle>(state.range(0));
uint64_t max_data = state.range(1);
uint64_t per_key_size = state.range(2);
uint64_t key_num = max_data / per_key_size;
// setup DB
static std::unique_ptr<DB> db;
Options options;
options.compaction_style = compaction_style;
auto rnd = Random(301 + state.thread_index());
KeyGenerator kg(&rnd, key_num);
if (state.thread_index() == 0) {
SetupDB(state, options, &db, "IteratorNext");
// load db
auto wo = WriteOptions();
wo.disableWAL = true;
for (uint64_t i = 0; i < key_num; i++) {
Status s = db->Put(wo, kg.Next(),
rnd.RandomString(static_cast<int>(per_key_size)));
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
FlushOptions fo;
Status s = db->Flush(fo);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
auto db_full = static_cast_with_check<DBImpl>(db.get());
s = db_full->WaitForCompact(WaitForCompactOptions());
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
return;
}
}
for (auto _ : state) {
std::unique_ptr<Iterator> iter{nullptr};
state.PauseTiming();
if (!iter) {
iter.reset(db->NewIterator(ReadOptions()));
}
while (!iter->Valid()) {
iter->Seek(kg.Next());
if (!iter->status().ok()) {
state.SkipWithError(iter->status().ToString().c_str());
}
}
state.ResumeTiming();
iter->Next();
}
if (state.thread_index() == 0) {
TeardownDB(state, db, options, kg);
}
}
static void IteratorNextArguments(benchmark::internal::Benchmark* b) {
for (int comp_style : {kCompactionStyleLevel, kCompactionStyleUniversal,
kCompactionStyleFIFO}) {
for (int64_t max_data : {128l << 20, 512l << 20}) {
for (int64_t per_key_size : {256, 1024}) {
b->Args({comp_style, max_data, per_key_size});
}
}
}
b->ArgNames({"comp_style", "max_data", "per_key_size"});
}
static constexpr uint64_t kIteratorNextNum = 10l << 10;
BENCHMARK(IteratorNext)
->Iterations(kIteratorNextNum)
->Apply(IteratorNextArguments);
static void IteratorNextWithPerfContext(benchmark::State& state) {
// setup DB
static std::unique_ptr<DB> db;
Options options;
auto rnd = Random(301 + state.thread_index());
KeyGenerator kg(&rnd, 1024);
if (state.thread_index() == 0) {
SetupDB(state, options, &db, "IteratorNextWithPerfContext");
// load db
auto wo = WriteOptions();
wo.disableWAL = true;
for (uint64_t i = 0; i < 1024; i++) {
Status s = db->Put(wo, kg.Next(), rnd.RandomString(1024));
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
auto db_full = static_cast_with_check<DBImpl>(db.get());
Status s = db_full->WaitForCompact(WaitForCompactOptions());
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
return;
}
FlushOptions fo;
s = db->Flush(fo);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
uint64_t user_key_comparison_count = 0;
uint64_t internal_key_skipped_count = 0;
uint64_t find_next_user_entry_time = 0;
uint64_t iter_next_cpu_nanos = 0;
SetPerfLevel(kEnableTime);
get_perf_context()->EnablePerLevelPerfContext();
for (auto _ : state) {
std::unique_ptr<Iterator> iter{nullptr};
state.PauseTiming();
if (!iter) {
iter.reset(db->NewIterator(ReadOptions()));
}
while (!iter->Valid()) {
iter->Seek(kg.Next());
if (!iter->status().ok()) {
state.SkipWithError(iter->status().ToString().c_str());
}
}
get_perf_context()->Reset();
state.ResumeTiming();
iter->Next();
user_key_comparison_count += get_perf_context()->user_key_comparison_count;
internal_key_skipped_count +=
get_perf_context()->internal_key_skipped_count;
find_next_user_entry_time += get_perf_context()->find_next_user_entry_time;
iter_next_cpu_nanos += get_perf_context()->iter_next_cpu_nanos;
}
state.counters["user_key_comparison_count"] =
benchmark::Counter(static_cast<double>(user_key_comparison_count),
benchmark::Counter::kAvgIterations);
state.counters["internal_key_skipped_count"] =
benchmark::Counter(static_cast<double>(internal_key_skipped_count),
benchmark::Counter::kAvgIterations);
state.counters["find_next_user_entry_time"] =
benchmark::Counter(static_cast<double>(find_next_user_entry_time),
benchmark::Counter::kAvgIterations);
state.counters["iter_next_cpu_nanos"] =
benchmark::Counter(static_cast<double>(iter_next_cpu_nanos),
benchmark::Counter::kAvgIterations);
if (state.thread_index() == 0) {
TeardownDB(state, db, options, kg);
}
}
BENCHMARK(IteratorNextWithPerfContext)->Iterations(100000);
static void IteratorPrev(benchmark::State& state) {
auto compaction_style = static_cast<CompactionStyle>(state.range(0));
uint64_t max_data = state.range(1);
uint64_t per_key_size = state.range(2);
uint64_t key_num = max_data / per_key_size;
// setup DB
static std::unique_ptr<DB> db;
std::string db_name;
Options options;
options.compaction_style = compaction_style;
auto rnd = Random(301 + state.thread_index());
KeyGenerator kg(&rnd, key_num);
if (state.thread_index() == 0) {
SetupDB(state, options, &db, "IteratorPrev");
// load db
auto wo = WriteOptions();
wo.disableWAL = true;
for (uint64_t i = 0; i < key_num; i++) {
Status s = db->Put(wo, kg.Next(),
rnd.RandomString(static_cast<int>(per_key_size)));
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
FlushOptions fo;
Status s = db->Flush(fo);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
auto db_full = static_cast_with_check<DBImpl>(db.get());
s = db_full->WaitForCompact(WaitForCompactOptions());
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
return;
}
}
for (auto _ : state) {
std::unique_ptr<Iterator> iter{nullptr};
state.PauseTiming();
if (!iter) {
iter.reset(db->NewIterator(ReadOptions()));
}
while (!iter->Valid()) {
iter->Seek(kg.Next());
if (!iter->status().ok()) {
state.SkipWithError(iter->status().ToString().c_str());
}
}
state.ResumeTiming();
iter->Prev();
}
if (state.thread_index() == 0) {
TeardownDB(state, db, options, kg);
}
}
static void IteratorPrevArguments(benchmark::internal::Benchmark* b) {
for (int comp_style : {kCompactionStyleLevel, kCompactionStyleUniversal,
kCompactionStyleFIFO}) {
for (int64_t max_data : {128l << 20, 512l << 20}) {
for (int64_t per_key_size : {256, 1024}) {
b->Args({comp_style, max_data, per_key_size});
}
}
}
b->ArgNames({"comp_style", "max_data", "per_key_size"});
}
static constexpr uint64_t kIteratorPrevNum = 10l << 10;
BENCHMARK(IteratorPrev)
->Iterations(kIteratorPrevNum)
->Apply(IteratorPrevArguments);
static void PrefixSeek(benchmark::State& state) {
auto compaction_style = static_cast<CompactionStyle>(state.range(0));
uint64_t max_data = state.range(1);
uint64_t per_key_size = state.range(2);
bool enable_statistics = state.range(3);
bool enable_filter = state.range(4);
uint64_t key_num = max_data / per_key_size;
// setup DB
static std::unique_ptr<DB> db;
Options options;
if (enable_statistics) {
options.statistics = CreateDBStatistics();
}
options.compaction_style = compaction_style;
options.prefix_extractor.reset(NewFixedPrefixTransform(4));
if (enable_filter) {
BlockBasedTableOptions table_options;
table_options.filter_policy.reset(NewBloomFilterPolicy(10, false));
options.table_factory.reset(NewBlockBasedTableFactory(table_options));
}
auto rnd = Random(301 + state.thread_index());
KeyGenerator kg(&rnd, key_num, key_num / 100);
if (state.thread_index() == 0) {
SetupDB(state, options, &db, "PrefixSeek");
// load db
auto wo = WriteOptions();
wo.disableWAL = true;
for (uint64_t i = 0; i < key_num; i++) {
Status s = db->Put(wo, kg.Next(),
rnd.RandomString(static_cast<int>(per_key_size)));
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
FlushOptions fo;
Status s = db->Flush(fo);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
auto db_full = static_cast_with_check<DBImpl>(db.get());
s = db_full->WaitForCompact(WaitForCompactOptions());
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
return;
}
}
for (auto _ : state) {
std::unique_ptr<Iterator> iter{nullptr};
state.PauseTiming();
if (!iter) {
iter.reset(db->NewIterator(ReadOptions()));
}
state.ResumeTiming();
iter->Seek(kg.NextPrefix());
if (!iter->status().ok()) {
state.SkipWithError(iter->status().ToString().c_str());
return;
}
}
if (state.thread_index() == 0) {
TeardownDB(state, db, options, kg);
}
}
static void PrefixSeekArguments(benchmark::internal::Benchmark* b) {
for (int comp_style : {kCompactionStyleLevel, kCompactionStyleUniversal,
kCompactionStyleFIFO}) {
for (int64_t max_data : {128l << 20, 512l << 20}) {
for (int64_t per_key_size : {256, 1024}) {
for (bool enable_statistics : {false, true}) {
for (bool enable_filter : {false, true}) {
b->Args({comp_style, max_data, per_key_size, enable_statistics,
enable_filter});
}
}
}
}
}
b->ArgNames({"comp_style", "max_data", "per_key_size", "enable_statistics",
"enable_filter"});
}
static constexpr uint64_t kPrefixSeekNum = 10l << 10;
BENCHMARK(PrefixSeek)->Iterations(kPrefixSeekNum)->Apply(PrefixSeekArguments);
BENCHMARK(PrefixSeek)
->Threads(8)
->Iterations(kPrefixSeekNum / 8)
->Apply(PrefixSeekArguments);
// TODO: move it to different files, as it's testing an internal API
static void RandomAccessFileReaderRead(benchmark::State& state) {
bool enable_statistics = state.range(0);
constexpr int kFileNum = 10;
auto env = Env::Default();
auto fs = env->GetFileSystem();
std::string db_path;
Status s = env->GetTestDirectory(&db_path);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
return;
}
// Setup multiple `RandomAccessFileReader`s with different parameters to be
// used for test
Random rand(301);
std::string fname_base =
db_path + kFilePathSeparator + "random-access-file-reader-read";
std::vector<std::unique_ptr<RandomAccessFileReader>> readers;
auto statistics_share = CreateDBStatistics();
Statistics* statistics = enable_statistics ? statistics_share.get() : nullptr;
for (int i = 0; i < kFileNum; i++) {
std::string fname = fname_base + std::to_string(i);
std::string content = rand.RandomString(kDefaultPageSize);
std::unique_ptr<WritableFile> tgt_file;
env->NewWritableFile(fname, &tgt_file, EnvOptions());
tgt_file->Append(content);
tgt_file->Close();
std::unique_ptr<FSRandomAccessFile> f;
fs->NewRandomAccessFile(fname, FileOptions(), &f, nullptr);
int rand_num = rand.Next() % 3;
auto temperature = rand_num == 0 ? Temperature::kUnknown
: rand_num == 1 ? Temperature::kWarm
: Temperature::kCold;
readers.emplace_back(new RandomAccessFileReader(
std::move(f), fname, env->GetSystemClock().get(), nullptr, statistics,
Histograms::HISTOGRAM_ENUM_MAX, nullptr, nullptr, {}, temperature,
rand_num == 1));
}
IOOptions io_options;
std::unique_ptr<char[]> scratch(new char[2048]);
Slice result;
uint64_t idx = 0;
for (auto _ : state) {
s = readers[idx++ % kFileNum]->Read(io_options, 0, kDefaultPageSize / 3,
&result, scratch.get(), nullptr);
if (!s.ok()) {
state.SkipWithError(s.ToString().c_str());
}
}
// clean up
for (int i = 0; i < kFileNum; i++) {
std::string fname = fname_base + std::to_string(i);
env->DeleteFile(fname); // ignore return, okay to fail cleanup
}
}
BENCHMARK(RandomAccessFileReaderRead)
->Iterations(1000000)
->Arg(0)
->Arg(1)
->ArgName("enable_statistics");
} // namespace ROCKSDB_NAMESPACE
BENCHMARK_MAIN();
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