fork of https://github.com/oxigraph/rocksdb and https://github.com/facebook/rocksdb for nextgraph and oxigraph
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360 lines
11 KiB
360 lines
11 KiB
// Copyright (c) 2013, 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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//
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#ifndef ROCKSDB_LITE
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#ifndef GFLAGS
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#include <cstdio>
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int main() { fprintf(stderr, "Please install gflags to run tools\n"); }
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#else
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#include <atomic>
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#include <functional>
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#include <memory>
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#include <sstream>
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#include <unordered_map>
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#include "rocksdb/env.h"
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#include "utilities/persistent_cache/block_cache_tier.h"
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#include "utilities/persistent_cache/persistent_cache_tier.h"
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#include "utilities/persistent_cache/volatile_tier_impl.h"
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#include "monitoring/histogram.h"
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#include "port/port.h"
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#include "table/block_builder.h"
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#include "util/gflags_compat.h"
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#include "util/mutexlock.h"
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#include "util/stop_watch.h"
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DEFINE_int32(nsec, 10, "nsec");
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DEFINE_int32(nthread_write, 1, "Insert threads");
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DEFINE_int32(nthread_read, 1, "Lookup threads");
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DEFINE_string(path, "/tmp/microbench/blkcache", "Path for cachefile");
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DEFINE_string(log_path, "/tmp/log", "Path for the log file");
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DEFINE_uint64(cache_size, std::numeric_limits<uint64_t>::max(), "Cache size");
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DEFINE_int32(iosize, 4 * 1024, "Read IO size");
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DEFINE_int32(writer_iosize, 4 * 1024, "File writer IO size");
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DEFINE_int32(writer_qdepth, 1, "File writer qdepth");
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DEFINE_bool(enable_pipelined_writes, false, "Enable async writes");
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DEFINE_string(cache_type, "block_cache",
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"Cache type. (block_cache, volatile, tiered)");
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DEFINE_bool(benchmark, false, "Benchmark mode");
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DEFINE_int32(volatile_cache_pct, 10, "Percentage of cache in memory tier.");
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namespace rocksdb {
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std::unique_ptr<PersistentCacheTier> NewVolatileCache() {
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assert(FLAGS_cache_size != std::numeric_limits<uint64_t>::max());
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std::unique_ptr<PersistentCacheTier> pcache(
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new VolatileCacheTier(FLAGS_cache_size));
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return pcache;
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}
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std::unique_ptr<PersistentCacheTier> NewBlockCache() {
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std::shared_ptr<Logger> log;
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if (!Env::Default()->NewLogger(FLAGS_log_path, &log).ok()) {
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fprintf(stderr, "Error creating log %s \n", FLAGS_log_path.c_str());
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return nullptr;
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}
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PersistentCacheConfig opt(Env::Default(), FLAGS_path, FLAGS_cache_size, log);
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opt.writer_dispatch_size = FLAGS_writer_iosize;
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opt.writer_qdepth = FLAGS_writer_qdepth;
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opt.pipeline_writes = FLAGS_enable_pipelined_writes;
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opt.max_write_pipeline_backlog_size = std::numeric_limits<uint64_t>::max();
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std::unique_ptr<PersistentCacheTier> cache(new BlockCacheTier(opt));
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Status status = cache->Open();
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return cache;
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}
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// create a new cache tier
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// construct a tiered RAM+Block cache
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std::unique_ptr<PersistentTieredCache> NewTieredCache(
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const size_t mem_size, const PersistentCacheConfig& opt) {
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std::unique_ptr<PersistentTieredCache> tcache(new PersistentTieredCache());
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// create primary tier
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assert(mem_size);
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auto pcache =
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std::shared_ptr<PersistentCacheTier>(new VolatileCacheTier(mem_size));
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tcache->AddTier(pcache);
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// create secondary tier
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auto scache = std::shared_ptr<PersistentCacheTier>(new BlockCacheTier(opt));
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tcache->AddTier(scache);
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Status s = tcache->Open();
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assert(s.ok());
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return tcache;
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}
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std::unique_ptr<PersistentTieredCache> NewTieredCache() {
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std::shared_ptr<Logger> log;
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if (!Env::Default()->NewLogger(FLAGS_log_path, &log).ok()) {
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fprintf(stderr, "Error creating log %s \n", FLAGS_log_path.c_str());
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abort();
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}
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auto pct = FLAGS_volatile_cache_pct / static_cast<double>(100);
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PersistentCacheConfig opt(Env::Default(), FLAGS_path,
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(1 - pct) * FLAGS_cache_size, log);
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opt.writer_dispatch_size = FLAGS_writer_iosize;
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opt.writer_qdepth = FLAGS_writer_qdepth;
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opt.pipeline_writes = FLAGS_enable_pipelined_writes;
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opt.max_write_pipeline_backlog_size = std::numeric_limits<uint64_t>::max();
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return NewTieredCache(FLAGS_cache_size * pct, opt);
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}
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//
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// Benchmark driver
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//
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class CacheTierBenchmark {
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public:
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explicit CacheTierBenchmark(std::shared_ptr<PersistentCacheTier>&& cache)
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: cache_(cache) {
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if (FLAGS_nthread_read) {
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fprintf(stdout, "Pre-populating\n");
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Prepop();
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fprintf(stdout, "Pre-population completed\n");
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}
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stats_.Clear();
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// Start IO threads
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std::list<port::Thread> threads;
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Spawn(FLAGS_nthread_write, &threads,
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std::bind(&CacheTierBenchmark::Write, this));
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Spawn(FLAGS_nthread_read, &threads,
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std::bind(&CacheTierBenchmark::Read, this));
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// Wait till FLAGS_nsec and then signal to quit
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StopWatchNano t(Env::Default(), /*auto_start=*/true);
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size_t sec = t.ElapsedNanos() / 1000000000ULL;
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while (!quit_) {
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sec = t.ElapsedNanos() / 1000000000ULL;
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quit_ = sec > size_t(FLAGS_nsec);
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/* sleep override */ sleep(1);
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}
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// Wait for threads to exit
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Join(&threads);
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// Print stats
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PrintStats(sec);
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// Close the cache
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cache_->TEST_Flush();
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cache_->Close();
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}
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private:
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void PrintStats(const size_t sec) {
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std::ostringstream msg;
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msg << "Test stats" << std::endl
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<< "* Elapsed: " << sec << " s" << std::endl
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<< "* Write Latency:" << std::endl
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<< stats_.write_latency_.ToString() << std::endl
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<< "* Read Latency:" << std::endl
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<< stats_.read_latency_.ToString() << std::endl
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<< "* Bytes written:" << std::endl
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<< stats_.bytes_written_.ToString() << std::endl
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<< "* Bytes read:" << std::endl
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<< stats_.bytes_read_.ToString() << std::endl
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<< "Cache stats:" << std::endl
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<< cache_->PrintStats() << std::endl;
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fprintf(stderr, "%s\n", msg.str().c_str());
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}
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//
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// Insert implementation and corresponding helper functions
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//
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void Prepop() {
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for (uint64_t i = 0; i < 1024 * 1024; ++i) {
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InsertKey(i);
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insert_key_limit_++;
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read_key_limit_++;
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}
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// Wait until data is flushed
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cache_->TEST_Flush();
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// warmup the cache
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for (uint64_t i = 0; i < 1024 * 1024; ReadKey(i++)) {
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}
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}
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void Write() {
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while (!quit_) {
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InsertKey(insert_key_limit_++);
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}
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}
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void InsertKey(const uint64_t key) {
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// construct key
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uint64_t k[3];
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Slice block_key = FillKey(k, key);
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// construct value
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auto block = NewBlock(key);
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// insert
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StopWatchNano timer(Env::Default(), /*auto_start=*/true);
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while (true) {
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Status status = cache_->Insert(block_key, block.get(), FLAGS_iosize);
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if (status.ok()) {
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break;
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}
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// transient error is possible if we run without pipelining
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assert(!FLAGS_enable_pipelined_writes);
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}
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// adjust stats
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const size_t elapsed_micro = timer.ElapsedNanos() / 1000;
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stats_.write_latency_.Add(elapsed_micro);
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stats_.bytes_written_.Add(FLAGS_iosize);
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}
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//
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// Read implementation
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//
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void Read() {
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while (!quit_) {
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ReadKey(random() % read_key_limit_);
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}
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}
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void ReadKey(const uint64_t val) {
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// construct key
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uint64_t k[3];
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Slice key = FillKey(k, val);
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// Lookup in cache
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StopWatchNano timer(Env::Default(), /*auto_start=*/true);
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std::unique_ptr<char[]> block;
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size_t size;
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Status status = cache_->Lookup(key, &block, &size);
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if (!status.ok()) {
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fprintf(stderr, "%s\n", status.ToString().c_str());
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}
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assert(status.ok());
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assert(size == (size_t) FLAGS_iosize);
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// adjust stats
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const size_t elapsed_micro = timer.ElapsedNanos() / 1000;
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stats_.read_latency_.Add(elapsed_micro);
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stats_.bytes_read_.Add(FLAGS_iosize);
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// verify content
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if (!FLAGS_benchmark) {
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auto expected_block = NewBlock(val);
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assert(memcmp(block.get(), expected_block.get(), FLAGS_iosize) == 0);
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}
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}
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// create data for a key by filling with a certain pattern
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std::unique_ptr<char[]> NewBlock(const uint64_t val) {
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std::unique_ptr<char[]> data(new char[FLAGS_iosize]);
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memset(data.get(), val % 255, FLAGS_iosize);
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return data;
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}
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// spawn threads
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void Spawn(const size_t n, std::list<port::Thread>* threads,
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const std::function<void()>& fn) {
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for (size_t i = 0; i < n; ++i) {
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threads->emplace_back(fn);
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}
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}
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// join threads
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void Join(std::list<port::Thread>* threads) {
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for (auto& th : *threads) {
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th.join();
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}
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}
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// construct key
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Slice FillKey(uint64_t (&k)[3], const uint64_t val) {
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k[0] = k[1] = 0;
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k[2] = val;
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void* p = static_cast<void*>(&k);
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return Slice(static_cast<char*>(p), sizeof(k));
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}
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// benchmark stats
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struct Stats {
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void Clear() {
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bytes_written_.Clear();
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bytes_read_.Clear();
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read_latency_.Clear();
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write_latency_.Clear();
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}
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HistogramImpl bytes_written_;
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HistogramImpl bytes_read_;
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HistogramImpl read_latency_;
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HistogramImpl write_latency_;
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};
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std::shared_ptr<PersistentCacheTier> cache_; // cache implementation
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std::atomic<uint64_t> insert_key_limit_{0}; // data inserted upto
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std::atomic<uint64_t> read_key_limit_{0}; // data can be read safely upto
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bool quit_ = false; // Quit thread ?
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mutable Stats stats_; // Stats
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};
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} // namespace rocksdb
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//
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// main
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//
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int main(int argc, char** argv) {
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GFLAGS_NAMESPACE::SetUsageMessage(std::string("\nUSAGE:\n") +
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std::string(argv[0]) + " [OPTIONS]...");
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GFLAGS_NAMESPACE::ParseCommandLineFlags(&argc, &argv, false);
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std::ostringstream msg;
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msg << "Config" << std::endl
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<< "======" << std::endl
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<< "* nsec=" << FLAGS_nsec << std::endl
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<< "* nthread_write=" << FLAGS_nthread_write << std::endl
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<< "* path=" << FLAGS_path << std::endl
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<< "* cache_size=" << FLAGS_cache_size << std::endl
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<< "* iosize=" << FLAGS_iosize << std::endl
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<< "* writer_iosize=" << FLAGS_writer_iosize << std::endl
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<< "* writer_qdepth=" << FLAGS_writer_qdepth << std::endl
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<< "* enable_pipelined_writes=" << FLAGS_enable_pipelined_writes
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<< std::endl
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<< "* cache_type=" << FLAGS_cache_type << std::endl
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<< "* benchmark=" << FLAGS_benchmark << std::endl
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<< "* volatile_cache_pct=" << FLAGS_volatile_cache_pct << std::endl;
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fprintf(stderr, "%s\n", msg.str().c_str());
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std::shared_ptr<rocksdb::PersistentCacheTier> cache;
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if (FLAGS_cache_type == "block_cache") {
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fprintf(stderr, "Using block cache implementation\n");
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cache = rocksdb::NewBlockCache();
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} else if (FLAGS_cache_type == "volatile") {
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fprintf(stderr, "Using volatile cache implementation\n");
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cache = rocksdb::NewVolatileCache();
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} else if (FLAGS_cache_type == "tiered") {
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fprintf(stderr, "Using tiered cache implementation\n");
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cache = rocksdb::NewTieredCache();
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} else {
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fprintf(stderr, "Unknown option for cache\n");
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}
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assert(cache);
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if (!cache) {
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fprintf(stderr, "Error creating cache\n");
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abort();
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}
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std::unique_ptr<rocksdb::CacheTierBenchmark> benchmark(
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new rocksdb::CacheTierBenchmark(std::move(cache)));
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return 0;
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}
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#endif // #ifndef GFLAGS
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#else
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int main(int, char**) { return 0; }
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#endif
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