L4/Benchmark/main.cpp

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#include "L4/LocalMemory/HashTableService.h"
#include "L4/Log/PerfCounter.h"
#include <algorithm>
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#include <boost/any.hpp>
#include <boost/program_options.hpp>
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#include <chrono>
#include <condition_variable>
#include <iostream>
#include <string>
#include <thread>
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class Timer {
public:
Timer() : m_start{std::chrono::high_resolution_clock::now()} {}
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void Reset() { m_start = std::chrono::high_resolution_clock::now(); }
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std::chrono::microseconds GetElapsedTime() {
return std::chrono::duration_cast<std::chrono::microseconds>(
std::chrono::high_resolution_clock::now() - m_start);
}
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private:
std::chrono::time_point<std::chrono::steady_clock> m_start;
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};
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class SynchronizedTimer {
public:
SynchronizedTimer() = default;
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void Start() {
if (m_isStarted) {
return;
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}
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m_isStarted = true;
m_startCount =
std::chrono::high_resolution_clock::now().time_since_epoch().count();
}
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void End() {
m_endCount =
std::chrono::high_resolution_clock::now().time_since_epoch().count();
}
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std::chrono::microseconds GetElapsedTime() {
std::chrono::nanoseconds start{m_startCount};
std::chrono::nanoseconds end{m_endCount};
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return std::chrono::duration_cast<std::chrono::microseconds>(end - start);
}
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private:
std::atomic_bool m_isStarted = false;
std::atomic_uint64_t m_startCount;
std::atomic_uint64_t m_endCount;
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};
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struct PerThreadInfoForWriteTest {
std::thread m_thread;
std::size_t m_dataSetSize = 0;
std::chrono::microseconds m_totalTime;
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};
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struct PerThreadInfoForReadTest {
std::thread m_thread;
std::size_t m_dataSetSize = 0;
std::chrono::microseconds m_totalTime;
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};
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struct CommandLineOptions {
static constexpr std::size_t c_defaultDataSetSize = 1000000;
static constexpr std::uint32_t c_defaultNumBuckets = 1000000;
static constexpr std::uint16_t c_defaultKeySize = 16;
static constexpr std::uint32_t c_defaultValueSize = 100;
static constexpr bool c_defaultRandomizeValueSize = false;
static constexpr std::uint32_t c_defaultNumIterationsPerGetContext = 1;
static constexpr std::uint16_t c_defaultNumThreads = 1;
static constexpr std::uint32_t c_defaultEpochProcessingIntervalInMilli = 10;
static constexpr std::uint16_t c_defaultNumActionsQueue = 1;
static constexpr std::uint32_t c_defaultRecordTimeToLiveInSeconds = 300;
static constexpr std::uint64_t c_defaultCacheSizeInBytes = 1024 * 1024 * 1024;
static constexpr bool c_defaultForceTimeBasedEviction = false;
std::string m_module;
std::size_t m_dataSetSize = 0;
std::uint32_t m_numBuckets = 0;
std::uint16_t m_keySize = 0;
std::uint32_t m_valueSize = 0;
bool m_randomizeValueSize = false;
std::uint32_t m_numIterationsPerGetContext = 0;
std::uint16_t m_numThreads = 0;
std::uint32_t m_epochProcessingIntervalInMilli;
std::uint8_t m_numActionsQueue = 0;
// The followings are specific for cache hash tables.
std::uint32_t m_recordTimeToLiveInSeconds = 0U;
std::uint64_t m_cacheSizeInBytes = 0U;
bool m_forceTimeBasedEviction = false;
bool IsCachingModule() const {
static const std::string c_cachingModulePrefix{"cache"};
return m_module.substr(0, c_cachingModulePrefix.size()) ==
c_cachingModulePrefix;
}
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};
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class DataGenerator {
public:
DataGenerator(std::size_t dataSetSize,
std::uint16_t keySize,
std::uint32_t valueSize,
bool randomizeValueSize,
bool isDebugMode = false)
: m_dataSetSize{dataSetSize}, m_keySize{keySize} {
if (isDebugMode) {
std::cout << "Generating data set with size = " << dataSetSize
<< std::endl;
}
Timer timer;
// Populate keys.
m_keys.resize(m_dataSetSize);
m_keysBuffer.resize(m_dataSetSize);
for (std::size_t i = 0; i < m_dataSetSize; ++i) {
m_keysBuffer[i].resize(keySize);
std::generate(m_keysBuffer[i].begin(), m_keysBuffer[i].end(), std::rand);
std::snprintf(reinterpret_cast<char*>(m_keysBuffer[i].data()), keySize,
"%llu", i);
m_keys[i].m_data = m_keysBuffer[i].data();
m_keys[i].m_size = m_keySize;
}
// Populate values buffer. Assumes srand() is already called.
std::generate(m_valuesBuffer.begin(), m_valuesBuffer.end(), std::rand);
// Populate values.
m_values.resize(m_dataSetSize);
std::size_t currentIndex = 0;
for (std::size_t i = 0; i < m_dataSetSize; ++i) {
m_values[i].m_data = &m_valuesBuffer[currentIndex % c_valuesBufferSize];
m_values[i].m_size = randomizeValueSize ? rand() % valueSize : valueSize;
currentIndex += valueSize;
}
if (isDebugMode) {
std::cout << "Finished generating data in "
<< timer.GetElapsedTime().count() << " microseconds"
<< std::endl;
}
}
L4::IReadOnlyHashTable::Key GetKey(std::size_t index) const {
return m_keys[index % m_dataSetSize];
}
L4::IReadOnlyHashTable::Value GetValue(std::size_t index) const {
return m_values[index % m_dataSetSize];
}
private:
std::size_t m_dataSetSize;
std::uint16_t m_keySize;
std::vector<std::vector<std::uint8_t>> m_keysBuffer;
std::vector<L4::IReadOnlyHashTable::Key> m_keys;
std::vector<L4::IReadOnlyHashTable::Value> m_values;
static const std::size_t c_valuesBufferSize = 64 * 1024;
std::array<std::uint8_t, c_valuesBufferSize> m_valuesBuffer;
};
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void PrintHardwareInfo() {
SYSTEM_INFO sysInfo;
GetSystemInfo(&sysInfo);
printf("\n");
printf("Hardware information: \n");
printf("-------------------------------------\n");
printf("%22s | %10u |\n", "OEM ID", sysInfo.dwOemId);
printf("%22s | %10u |\n", "Number of processors",
sysInfo.dwNumberOfProcessors);
printf("%22s | %10u |\n", "Page size", sysInfo.dwPageSize);
printf("%22s | %10u |\n", "Processor type", sysInfo.dwProcessorType);
printf("-------------------------------------\n");
printf("\n");
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}
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void PrintOptions(const CommandLineOptions& options) {
printf("------------------------------------------------------\n");
printf("%39s | %10llu |\n", "Data set size", options.m_dataSetSize);
printf("%39s | %10lu |\n", "Number of hash table buckets",
options.m_numBuckets);
printf("%39s | %10lu |\n", "Key size", options.m_keySize);
printf("%39s | %10lu |\n", "Value type", options.m_valueSize);
printf("%39s | %10lu |\n", "Number of iterations per GetContext()",
options.m_numIterationsPerGetContext);
printf("%39s | %10lu |\n", "Epoch processing interval (ms)",
options.m_epochProcessingIntervalInMilli);
printf("%39s | %10lu |\n", "Number of actions queue",
options.m_numActionsQueue);
if (options.IsCachingModule()) {
printf("%39s | %10lu |\n", "Record time to live (s)",
options.m_recordTimeToLiveInSeconds);
printf("%39s | %10llu |\n", "Cache size in bytes",
options.m_cacheSizeInBytes);
printf("%39s | %10lu |\n", "Force time-based eviction",
options.m_forceTimeBasedEviction);
}
printf("------------------------------------------------------\n\n");
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}
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void PrintHashTableCounters(const L4::HashTablePerfData& perfData) {
printf("HashTableCounter:\n");
printf("----------------------------------------------------\n");
for (auto i = 0;
i < static_cast<std::uint16_t>(L4::HashTablePerfCounter::Count); ++i) {
printf("%35s | %12llu |\n", L4::c_hashTablePerfCounterNames[i],
perfData.Get(static_cast<L4::HashTablePerfCounter>(i)));
}
printf("----------------------------------------------------\n\n");
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}
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L4::HashTableConfig CreateHashTableConfig(const CommandLineOptions& options) {
return L4::HashTableConfig(
"Table1", L4::HashTableConfig::Setting{options.m_numBuckets},
options.IsCachingModule()
? boost::optional<
L4::HashTableConfig::Cache>{L4::HashTableConfig::Cache{
options.m_cacheSizeInBytes,
std::chrono::seconds{options.m_recordTimeToLiveInSeconds},
options.m_forceTimeBasedEviction}}
: boost::none);
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}
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L4::EpochManagerConfig CreateEpochManagerConfig(
const CommandLineOptions& options) {
return L4::EpochManagerConfig(
10000U,
std::chrono::milliseconds(options.m_epochProcessingIntervalInMilli),
options.m_numActionsQueue);
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}
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void ReadPerfTest(const CommandLineOptions& options) {
printf("Performing read-perf which reads all the records inserted:\n");
PrintOptions(options);
auto dataGenerator = std::make_unique<DataGenerator>(
options.m_dataSetSize, options.m_keySize, options.m_valueSize,
options.m_randomizeValueSize);
L4::LocalMemory::HashTableService service(CreateEpochManagerConfig(options));
const auto hashTableIndex =
service.AddHashTable(CreateHashTableConfig(options));
// Insert data set.
auto context = service.GetContext();
auto& hashTable = context[hashTableIndex];
std::vector<std::uint32_t> randomIndices(options.m_dataSetSize);
for (std::uint32_t i = 0U; i < options.m_dataSetSize; ++i) {
randomIndices[i] = i;
}
if (options.m_numThreads > 0) {
// Randomize index only if multiple threads are running
// not to skew the results.
std::random_shuffle(randomIndices.begin(), randomIndices.end());
}
for (int i = 0; i < options.m_dataSetSize; ++i) {
auto key = dataGenerator->GetKey(randomIndices[i]);
auto val = dataGenerator->GetValue(randomIndices[i]);
hashTable.Add(key, val);
}
std::vector<PerThreadInfoForReadTest> allInfo;
allInfo.resize(options.m_numThreads);
SynchronizedTimer overallTimer;
std::mutex mutex;
std::condition_variable cv;
const auto isCachingModule = options.IsCachingModule();
bool isReady = false;
const std::size_t dataSetSizePerThread =
options.m_dataSetSize / options.m_numThreads;
for (std::uint16_t i = 0; i < options.m_numThreads; ++i) {
auto& info = allInfo[i];
std::size_t startIndex = i * dataSetSizePerThread;
info.m_dataSetSize = (i + 1 == options.m_numThreads)
? options.m_dataSetSize - startIndex
: dataSetSizePerThread;
info.m_thread = std::thread([=, &service, &dataGenerator, &info, &mutex,
&cv, &isReady, &overallTimer] {
{
std::unique_lock<std::mutex> lock(mutex);
cv.wait(lock, [&] { return isReady == true; });
}
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overallTimer.Start();
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Timer totalTimer;
Timer getTimer;
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std::size_t iteration = 0;
bool isDone = false;
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while (!isDone) {
auto context = service.GetContext();
auto& hashTable = context[hashTableIndex];
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for (std::uint32_t j = 0;
!isDone && j < options.m_numIterationsPerGetContext; ++j) {
auto key = dataGenerator->GetKey(startIndex + iteration);
L4::IReadOnlyHashTable::Value val;
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if (!hashTable.Get(key, val) && !isCachingModule) {
throw std::runtime_error(
"Look up failure is not allowed in this test.");
}
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isDone = (++iteration == info.m_dataSetSize);
}
}
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overallTimer.End();
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info.m_totalTime = totalTimer.GetElapsedTime();
});
}
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{
std::unique_lock<std::mutex> lock(mutex);
isReady = true;
}
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// Now, start the benchmarking for all threads.
cv.notify_all();
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for (auto& info : allInfo) {
info.m_thread.join();
}
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PrintHashTableCounters(service.GetContext()[hashTableIndex].GetPerfData());
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printf("Result:\n");
printf(" | Total | |\n");
printf(" | micros/op | microseconds | DataSetSize |\n");
printf(" -----------------------------------------------------------\n");
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for (std::size_t i = 0; i < allInfo.size(); ++i) {
const auto& info = allInfo[i];
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printf(" Thread #%llu | %11.3f | %14llu | %13llu |\n", (i + 1),
static_cast<double>(info.m_totalTime.count()) / info.m_dataSetSize,
info.m_totalTime.count(), info.m_dataSetSize);
}
printf(" -----------------------------------------------------------\n");
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printf(" Overall | %11.3f | %14llu | %13llu |\n",
static_cast<double>(overallTimer.GetElapsedTime().count()) /
options.m_dataSetSize,
overallTimer.GetElapsedTime().count(), options.m_dataSetSize);
}
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void WritePerfTest(const CommandLineOptions& options) {
if (options.m_module == "overwrite-perf") {
printf(
"Performing overwrite-perf (writing data with unique keys, then "
"overwrite data with same keys):\n");
} else {
printf("Performing write-perf (writing data with unique keys):\n");
}
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PrintOptions(options);
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auto dataGenerator = std::make_unique<DataGenerator>(
options.m_dataSetSize, options.m_keySize, options.m_valueSize,
options.m_randomizeValueSize);
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L4::LocalMemory::HashTableService service(CreateEpochManagerConfig(options));
const auto hashTableIndex =
service.AddHashTable(CreateHashTableConfig(options));
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if (options.m_module == "overwrite-perf") {
std::vector<std::uint32_t> randomIndices(options.m_dataSetSize);
for (std::uint32_t i = 0U; i < options.m_dataSetSize; ++i) {
randomIndices[i] = i;
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}
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if (options.m_numThreads > 0) {
// Randomize index only if multiple threads are running
// not to skew the results.
std::random_shuffle(randomIndices.begin(), randomIndices.end());
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}
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auto context = service.GetContext();
auto& hashTable = context[hashTableIndex];
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for (int i = 0; i < options.m_dataSetSize; ++i) {
const auto index = randomIndices[i];
auto key = dataGenerator->GetKey(index);
auto val = dataGenerator->GetValue(index);
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hashTable.Add(key, val);
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}
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}
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std::vector<PerThreadInfoForWriteTest> allInfo;
allInfo.resize(options.m_numThreads);
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SynchronizedTimer overallTimer;
std::mutex mutex;
std::condition_variable cv;
bool isReady = false;
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const std::size_t dataSetSizePerThread =
options.m_dataSetSize / options.m_numThreads;
for (std::uint16_t i = 0; i < options.m_numThreads; ++i) {
auto& info = allInfo[i];
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std::size_t startIndex = i * dataSetSizePerThread;
info.m_dataSetSize = (i + 1 == options.m_numThreads)
? options.m_dataSetSize - startIndex
: dataSetSizePerThread;
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info.m_thread = std::thread([=, &service, &dataGenerator, &info, &mutex,
&cv, &isReady, &overallTimer] {
{
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std::unique_lock<std::mutex> lock(mutex);
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cv.wait(lock, [&] { return isReady == true; });
}
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overallTimer.Start();
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Timer totalTimer;
Timer addTimer;
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std::size_t iteration = 0;
bool isDone = false;
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while (!isDone) {
auto context = service.GetContext();
auto& hashTable = context[hashTableIndex];
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for (std::uint32_t j = 0;
!isDone && j < options.m_numIterationsPerGetContext; ++j) {
const auto index = startIndex + iteration;
auto key = dataGenerator->GetKey(index);
auto val = dataGenerator->GetValue(index);
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hashTable.Add(key, val);
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isDone = (++iteration == info.m_dataSetSize);
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}
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}
info.m_totalTime = totalTimer.GetElapsedTime();
overallTimer.End();
});
}
{
std::unique_lock<std::mutex> lock(mutex);
isReady = true;
}
// Now, start the benchmarking for all threads.
cv.notify_all();
for (auto& info : allInfo) {
info.m_thread.join();
}
PrintHashTableCounters(service.GetContext()[hashTableIndex].GetPerfData());
printf("Result:\n");
printf(" | Total | |\n");
printf(" | micros/op | microseconds | DataSetSize |\n");
printf(" -----------------------------------------------------------\n");
for (std::size_t i = 0; i < allInfo.size(); ++i) {
const auto& info = allInfo[i];
printf(" Thread #%llu | %11.3f | %14llu | %13llu |\n", (i + 1),
static_cast<double>(info.m_totalTime.count()) / info.m_dataSetSize,
info.m_totalTime.count(), info.m_dataSetSize);
}
printf(" -----------------------------------------------------------\n");
printf(" Overall | %11.3f | %14llu | %13llu |\n",
static_cast<double>(overallTimer.GetElapsedTime().count()) /
options.m_dataSetSize,
overallTimer.GetElapsedTime().count(), options.m_dataSetSize);
if (options.m_numThreads == 1) {
auto& perfData = service.GetContext()[hashTableIndex].GetPerfData();
std::uint64_t totalBytes =
perfData.Get(L4::HashTablePerfCounter::TotalKeySize) +
perfData.Get(L4::HashTablePerfCounter::TotalValueSize);
auto& info = allInfo[0];
double opsPerSec = static_cast<double>(info.m_dataSetSize) /
info.m_totalTime.count() * 1000000.0;
double MBPerSec =
static_cast<double>(totalBytes) / info.m_totalTime.count();
printf(" %10.3f ops/sec %10.3f MB/sec\n", opsPerSec, MBPerSec);
}
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}
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CommandLineOptions Parse(int argc, char** argv) {
namespace po = boost::program_options;
po::options_description general("General options");
general.add_options()("help", "produce a help message")(
"help-module", po::value<std::string>(),
"produce a help for the following modules:\n"
" write-perf\n"
" overwrite-perf\n"
" read-perf\n"
" cache-read-perf\n"
" cache-write-perf\n")("module", po::value<std::string>(),
"Runs the given module");
po::options_description benchmarkOptions("Benchmark options.");
benchmarkOptions.add_options()("dataSetSize",
po::value<std::size_t>()->default_value(
CommandLineOptions::c_defaultDataSetSize),
"data set size")(
"numBuckets",
po::value<std::uint32_t>()->default_value(
CommandLineOptions::c_defaultNumBuckets),
"number of buckets")("keySize",
po::value<std::uint16_t>()->default_value(
CommandLineOptions::c_defaultKeySize),
"key size in bytes")(
"valueSize",
po::value<std::uint32_t>()->default_value(
CommandLineOptions::c_defaultValueSize),
"value size in bytes")("randomizeValueSize", "randomize value size")(
"numIterationsPerGetContext",
po::value<std::uint32_t>()->default_value(
CommandLineOptions::c_defaultNumIterationsPerGetContext),
"number of iterations per GetContext()")(
"numThreads",
po::value<std::uint16_t>()->default_value(
CommandLineOptions::c_defaultNumThreads),
"number of threads to create")(
"epochProcessingInterval",
po::value<std::uint32_t>()->default_value(
CommandLineOptions::c_defaultEpochProcessingIntervalInMilli),
"epoch processing interval (ms)")(
"numActionsQueue",
po::value<std::uint8_t>()->default_value(
CommandLineOptions::c_defaultNumActionsQueue),
"number of actions queue")(
"recordTimeToLive",
po::value<std::uint32_t>()->default_value(
CommandLineOptions::c_defaultRecordTimeToLiveInSeconds),
"record time to live (s)")(
"cacheSize",
po::value<std::uint64_t>()->default_value(
CommandLineOptions::c_defaultCacheSizeInBytes),
"cache size in bytes")(
"forceTimeBasedEviction",
po::value<bool>()->default_value(
CommandLineOptions::c_defaultForceTimeBasedEviction),
"force time based eviction");
po::options_description all("Allowed options");
all.add(general).add(benchmarkOptions);
po::variables_map vm;
po::store(po::parse_command_line(argc, argv, all), vm);
po::notify(vm);
CommandLineOptions options;
if (vm.count("help")) {
std::cout << all;
} else if (vm.count("module")) {
options.m_module = vm["module"].as<std::string>();
if (vm.count("dataSetSize")) {
options.m_dataSetSize = vm["dataSetSize"].as<std::size_t>();
}
if (vm.count("numBuckets")) {
options.m_numBuckets = vm["numBuckets"].as<std::uint32_t>();
}
if (vm.count("keySize")) {
options.m_keySize = vm["keySize"].as<std::uint16_t>();
}
if (vm.count("valueSize")) {
options.m_valueSize = vm["valueSize"].as<std::uint32_t>();
}
if (vm.count("randomizeValueSize")) {
options.m_randomizeValueSize = true;
}
if (vm.count("numIterationsPerGetContext")) {
options.m_numIterationsPerGetContext =
vm["numIterationsPerGetContext"].as<std::uint32_t>();
}
if (vm.count("numThreads")) {
options.m_numThreads = vm["numThreads"].as<std::uint16_t>();
}
if (vm.count("epochProcessingInterval")) {
options.m_epochProcessingIntervalInMilli =
vm["epochProcessingInterval"].as<std::uint32_t>();
}
if (vm.count("numActionsQueue")) {
options.m_numActionsQueue = vm["numActionsQueue"].as<std::uint8_t>();
}
if (vm.count("recordTimeToLive")) {
options.m_recordTimeToLiveInSeconds =
vm["recordTimeToLive"].as<std::uint32_t>();
}
if (vm.count("cacheSize")) {
options.m_cacheSizeInBytes = vm["cacheSize"].as<std::uint64_t>();
}
if (vm.count("forceTimeBasedEviction")) {
options.m_forceTimeBasedEviction =
vm["forceTimeBasedEviction"].as<bool>();
}
} else {
std::cout << all;
}
return options;
}
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int main(int argc, char** argv) {
auto options = Parse(argc, argv);
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if (options.m_module.empty()) {
return 0;
}
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std::srand(static_cast<unsigned int>(time(NULL)));
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PrintHardwareInfo();
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if (options.m_module == "write-perf" ||
options.m_module == "overwrite-perf" ||
options.m_module == "cache-write-perf") {
WritePerfTest(options);
} else if (options.m_module == "read-perf" ||
options.m_module == "cache-read-perf") {
ReadPerfTest(options);
} else {
std::cout << "Unknown module: " << options.m_module << std::endl;
}
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return 0;
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}