ClickHouse/dbms/programs/performance-test/PerformanceTest.cpp
2019-12-20 19:53:37 +03:00

356 lines
11 KiB
C++

#include "PerformanceTest.h"
#include <Core/Types.h>
#include <Common/CpuId.h>
#include <Common/quoteString.h>
#include <common/getMemoryAmount.h>
#include <DataStreams/copyData.h>
#include <DataStreams/NullBlockOutputStream.h>
#include <DataStreams/RemoteBlockInputStream.h>
#include <IO/ConnectionTimeouts.h>
#include <IO/ReadBufferFromFile.h>
#include <IO/ReadHelpers.h>
#include <IO/WriteBufferFromFile.h>
#include <filesystem>
#include "executeQuery.h"
namespace DB
{
namespace ErrorCodes
{
extern const int NOT_IMPLEMENTED;
}
namespace
{
void waitQuery(Connection & connection)
{
bool finished = false;
while (true)
{
if (!connection.poll(1000000))
continue;
Packet packet = connection.receivePacket();
switch (packet.type)
{
case Protocol::Server::EndOfStream:
finished = true;
break;
case Protocol::Server::Exception:
throw *packet.exception;
}
if (finished)
break;
}
}
}
namespace fs = std::filesystem;
PerformanceTest::PerformanceTest(
const XMLConfigurationPtr & config_,
Connection & connection_,
const ConnectionTimeouts & timeouts_,
InterruptListener & interrupt_listener_,
const PerformanceTestInfo & test_info_,
Context & context_,
const std::vector<size_t> & queries_to_run_)
: config(config_)
, connection(connection_)
, timeouts(timeouts_)
, interrupt_listener(interrupt_listener_)
, test_info(test_info_)
, context(context_)
, queries_to_run(queries_to_run_)
, log(&Poco::Logger::get("PerformanceTest"))
{
}
bool PerformanceTest::checkPreconditions() const
{
if (!config->has("preconditions"))
return true;
Strings preconditions;
config->keys("preconditions", preconditions);
size_t table_precondition_index = 0;
size_t cpu_precondition_index = 0;
for (const std::string & precondition : preconditions)
{
if (precondition == "flush_disk_cache")
{
if (system(
"(>&2 echo 'Flushing disk cache...') && (sudo sh -c 'echo 3 > /proc/sys/vm/drop_caches') && (>&2 echo 'Flushed.')"))
{
LOG_WARNING(log, "Failed to flush disk cache");
return false;
}
}
if (precondition == "ram_size")
{
size_t ram_size_needed = config->getUInt64("preconditions.ram_size");
size_t actual_ram = getMemoryAmount();
if (!actual_ram)
throw Exception("ram_size precondition not available on this platform", ErrorCodes::NOT_IMPLEMENTED);
if (ram_size_needed > actual_ram)
{
LOG_WARNING(log, "Not enough RAM: need = " << ram_size_needed << ", present = " << actual_ram);
return false;
}
}
if (precondition == "table_exists")
{
std::string precondition_key = "preconditions.table_exists[" + std::to_string(table_precondition_index++) + "]";
std::string table_to_check = config->getString(precondition_key);
std::string query = "EXISTS TABLE " + table_to_check + ";";
size_t exist = 0;
connection.sendQuery(timeouts, query, "", QueryProcessingStage::Complete, &test_info.settings, nullptr, false);
while (true)
{
Packet packet = connection.receivePacket();
if (packet.type == Protocol::Server::Data)
{
for (const ColumnWithTypeAndName & column : packet.block)
{
if (column.name == "result" && column.column->size() > 0)
{
exist = column.column->get64(0);
if (exist)
break;
}
}
}
if (packet.type == Protocol::Server::Exception
|| packet.type == Protocol::Server::EndOfStream)
break;
}
if (!exist)
{
LOG_WARNING(log, "Table " << backQuote(table_to_check) << " doesn't exist");
return false;
}
}
if (precondition == "cpu")
{
std::string precondition_key = "preconditions.cpu[" + std::to_string(cpu_precondition_index++) + "]";
std::string flag_to_check = config->getString(precondition_key);
#define CHECK_CPU_PRECONDITION(OP) \
if (flag_to_check == #OP) \
{ \
if (!Cpu::CpuFlagsCache::have_##OP) \
{ \
LOG_WARNING(log, "CPU doesn't support " << #OP); \
return false; \
} \
} else
CPU_ID_ENUMERATE(CHECK_CPU_PRECONDITION)
{
LOG_WARNING(log, "CPU doesn't support " << flag_to_check);
return false;
}
#undef CHECK_CPU_PRECONDITION
}
}
return true;
}
UInt64 PerformanceTest::calculateMaxExecTime() const
{
UInt64 result = 0;
for (const auto & stop_conditions : test_info.stop_conditions_by_run)
{
UInt64 condition_max_time = stop_conditions.getMaxExecTime();
if (condition_max_time == 0)
return 0;
result += condition_max_time;
}
return result;
}
void PerformanceTest::prepare() const
{
for (const auto & query : test_info.create_and_fill_queries)
{
LOG_INFO(log, "Executing create or fill query \"" << query << '\"');
connection.sendQuery(timeouts, query, "", QueryProcessingStage::Complete, &test_info.settings, nullptr, false);
waitQuery(connection);
LOG_INFO(log, "Query finished");
}
}
void PerformanceTest::finish() const
{
for (const auto & query : test_info.drop_queries)
{
LOG_INFO(log, "Executing drop query \"" << query << '\"');
connection.sendQuery(timeouts, query, "", QueryProcessingStage::Complete, &test_info.settings, nullptr, false);
waitQuery(connection);
LOG_INFO(log, "Query finished");
}
}
std::vector<TestStats> PerformanceTest::execute()
{
std::vector<TestStats> statistics_by_run;
size_t query_count;
if (queries_to_run.empty())
query_count = test_info.queries.size();
else
query_count = queries_to_run.size();
size_t total_runs = test_info.times_to_run * test_info.queries.size();
statistics_by_run.resize(total_runs);
LOG_INFO(log, "Totally will run cases " << test_info.times_to_run * query_count << " times");
UInt64 max_exec_time = calculateMaxExecTime();
if (max_exec_time != 0)
LOG_INFO(log, "Test will be executed for a maximum of " << max_exec_time / 1000. << " seconds");
else
LOG_INFO(log, "Test execution time cannot be determined");
for (size_t number_of_launch = 0; number_of_launch < test_info.times_to_run; ++number_of_launch)
{
QueriesWithIndexes queries_with_indexes;
for (size_t query_index = 0; query_index < test_info.queries.size(); ++query_index)
{
if (queries_to_run.empty() || std::find(queries_to_run.begin(), queries_to_run.end(), query_index) != queries_to_run.end())
{
size_t statistic_index = number_of_launch * test_info.queries.size() + query_index;
queries_with_indexes.push_back({test_info.queries[query_index], statistic_index});
}
else
LOG_INFO(log, "Will skip query " << test_info.queries[query_index] << " by index");
}
if (got_SIGINT)
break;
runQueries(queries_with_indexes, statistics_by_run);
}
if (got_SIGINT)
{
return statistics_by_run;
}
// Pull memory usage data from query log. The log is normally filled in
// background, so we have to flush it synchronously here to see all the
// previous queries.
{
NullBlockOutputStream null_output(Block{});
RemoteBlockInputStream flush_log(connection, "system flush logs",
{} /* header */, context);
copyData(flush_log, null_output);
}
for (auto & statistics : statistics_by_run)
{
if (statistics.query_id.empty())
{
// We have statistics structs for skipped queries as well, so we
// have to filter them out.
continue;
}
// We run some test queries several times, specifying the same query id,
// so this query to the log may return several records. Choose the
// last one, because this is when the query performance has stabilized.
RemoteBlockInputStream log_reader(connection,
"select memory_usage, query_start_time from system.query_log "
"where type = 2 and query_id = '" + statistics.query_id + "' "
"order by query_start_time desc",
{} /* header */, context);
log_reader.readPrefix();
Block block = log_reader.read();
if (block.columns() == 0)
{
LOG_WARNING(log, "Query '" << statistics.query_id << "' is not found in query log.");
continue;
}
auto column = block.getByName("memory_usage").column;
statistics.memory_usage = column->get64(0);
log_reader.readSuffix();
}
return statistics_by_run;
}
void PerformanceTest::runQueries(
const QueriesWithIndexes & queries_with_indexes,
std::vector<TestStats> & statistics_by_run)
{
for (const auto & [query, run_index] : queries_with_indexes)
{
LOG_INFO(log, "[" << run_index<< "] Run query '" << query << "'");
TestStopConditions & stop_conditions = test_info.stop_conditions_by_run[run_index];
TestStats & statistics = statistics_by_run[run_index];
statistics.startWatches();
try
{
executeQuery(connection, query, statistics, stop_conditions, interrupt_listener, context, test_info.settings);
if (test_info.exec_type == ExecutionType::Loop)
{
LOG_INFO(log, "Will run query in loop");
for (size_t iteration = 1; !statistics.got_SIGINT; ++iteration)
{
stop_conditions.reportIterations(iteration);
if (stop_conditions.areFulfilled())
{
LOG_INFO(log, "Stop conditions fullfilled");
break;
}
executeQuery(connection, query, statistics, stop_conditions, interrupt_listener, context, test_info.settings);
}
}
}
catch (const Exception & e)
{
statistics.exception = "Code: " + std::to_string(e.code()) + ", e.displayText() = " + e.displayText();
LOG_WARNING(log, "Code: " << e.code() << ", e.displayText() = " << e.displayText()
<< ", Stack trace:\n\n" << e.getStackTrace().toString());
}
if (!statistics.got_SIGINT)
statistics.ready = true;
else
{
got_SIGINT = true;
LOG_INFO(log, "Got SIGINT, will terminate as soon as possible");
break;
}
}
}
}