public static void Main(string[] args)
{
try
{
BenchController.Run(args);
}
catch (Exception ex)
{
BencherUtils.DisplayException(ex);
}
}
private static void WarmupDB()
{
IBencher dbWarmer = new DataTableBencher()
{
CommandText = SqlSelectCommandText, ConnectionStringToUse = ConnectionString
};
Console.WriteLine("\nWarming up DB, DB client code and CLR");
Console.WriteLine("====================================================================");
BenchController.DisplayBencherInfo(dbWarmer);
for (int i = 0; i < LoopAmount; i++)
{
var result = dbWarmer.PerformSetBenchmark();
BenchController.ReportSetResult(result);
}
}
private static void DisplayHeader()
{
bool releaseBuild = true;
#if DEBUG
releaseBuild = false;
#endif
var conBuilder = new SqlConnectionStringBuilder(ConnectionString);
string sqlServerVersion = "Unknown";
using (var conForHeader = new SqlConnection(ConnectionString))
{
conForHeader.Open();
sqlServerVersion = conForHeader.ServerVersion;
conForHeader.Close();
}
Console.WriteLine("+-------------------------------------------------------------------------------------------");
Console.WriteLine("| Raw Data Access / ORM Benchmarks.");
Console.WriteLine(@"| Code available at : https://github.com/FransBouma/RawDataAccessBencher");
Console.WriteLine("| Benchmarks run on : {0}", DateTime.Now.ToString("F"));
Console.WriteLine("| Registered benchmarks :");
foreach (var bencher in RegisteredBenchers)
{
BenchController.DisplayBencherInfo(bencher, "| \t", suffixWithDashLine: false);
}
Console.WriteLine("| Run set benchmarks : {0}", PerformSetBenchmarks);
Console.WriteLine("| Run individual fetch benchmarks: {0}", PerformIndividualBenchMarks);
Console.WriteLine("| Number of set fetches : {0}", LoopAmount);
Console.WriteLine("| Number of individual keys : {0}", IndividualKeysAmount);
Console.WriteLine("| Release build : {0}", releaseBuild);
Console.WriteLine("| Client OS : {0} ({1}bit)", Environment.OSVersion, Environment.Is64BitOperatingSystem ? "64" : "32");
Console.WriteLine("| Bencher runs as 64bit : {0}", Environment.Is64BitProcess);
#if NETCOREAPP
Console.WriteLine("| .NET Type : .NET Core");
Console.WriteLine("| CLR version : {0} {1}", PlatformServices.Default.Application.RuntimeFramework.Identifier,
PlatformServices.Default.Application.RuntimeFramework.Version);
#else
Console.WriteLine("| .NET Type : .NET Full");
Console.WriteLine("| CLR version : {0}", Environment.Version);
#endif
Console.WriteLine("| Number of CPUs : {0}", Environment.ProcessorCount);
Console.WriteLine("| Server used : {0}", conBuilder.DataSource);
Console.WriteLine("| Catalog used : {0}", conBuilder.InitialCatalog);
Console.WriteLine("| SQL Server version used : {0}", sqlServerVersion);
Console.WriteLine("+-------------------------------------------------------------------------------------------\n");
}
private static void RunRegisteredBenchers()
{
Console.WriteLine("\nStarting benchmarks.");
Console.WriteLine("====================================================================");
foreach (var bencher in RegisteredBenchers)
{
BenchController.DisplayBencherInfo(bencher);
try
{
BenchController.RunBencher(bencher);
}
catch (Exception ex)
{
BencherUtils.DisplayException(ex);
}
}
Console.WriteLine("\nPerforming memory measurement runs.");
Console.WriteLine("====================================================================");
#if !NETCOREAPP
AppDomain.MonitoringIsEnabled = true;
#endif
foreach (var bencher in RegisteredBenchers)
{
BenchController.DisplayBencherInfo(bencher);
bencher.CollectMemoryAllocated = true;
try
{
BenchController.RunMemoryAnalysisForBencher(bencher);
}
catch (Exception ex)
{
BencherUtils.DisplayException(ex);
}
bencher.CollectMemoryAllocated = false;
}
}
private static void DisplayBencherInfo(IBencher bencher)
{
BenchController.DisplayBencherInfo(bencher, "\n", suffixWithDashLine: true);
}
public static void Run(string[] args)
{
bool autoExit = false;
if (args.Length > 0)
{
autoExit = args[0] == "/a";
}
BenchController.InitConnectionString();
CacheController.RegisterCache(ConnectionString, new ResultsetCache());
RegisteredBenchers.Add(new HandCodedBencher()
{
CommandText = SqlSelectCommandText, ConnectionStringToUse = ConnectionString
});
RegisteredBenchers.Add(new HandCodedBencherUsingGetFieldValue()
{
CommandText = SqlSelectCommandText, ConnectionStringToUse = ConnectionString
});
RegisteredBenchers.Add(new RepoDbRawSqlBencher()
{
ConnectionStringToUse = ConnectionString, CommandText = SqlSelectCommandText
});
RegisteredBenchers.Add(new RepoDbPocoBencher()
{
ConnectionStringToUse = ConnectionString, CommandText = SqlSelectCommandText
});
RegisteredBenchers.Add(new HandCodedBencherUsingBoxing()
{
CommandText = SqlSelectCommandText, ConnectionStringToUse = ConnectionString
});
RegisteredBenchers.Add(new HandCodedBencherUsingBoxingGetValue()
{
CommandText = SqlSelectCommandText, ConnectionStringToUse = ConnectionString
});
RegisteredBenchers.Add(new RawDbDataReaderBencher()
{
CommandText = SqlSelectCommandText, ConnectionStringToUse = ConnectionString
});
RegisteredBenchers.Add(new NPocoBencher()
{
CommandText = SqlSelectCommandText, ConnectionStringToUse = ConnectionString
});
RegisteredBenchers.Add(new LINQ2DBCompiledBencher(ConnectionString));
RegisteredBenchers.Add(new LINQ2DBNormalBencher(ConnectionString));
RegisteredBenchers.Add(new LLBLGenProNoChangeTrackingRawSQLPocoBencher(ConnectionString)
{
CommandText = SqlSelectCommandText
});
RegisteredBenchers.Add(new LLBLGenProNoChangeTrackingQuerySpecPocoBencher(ConnectionString));
RegisteredBenchers.Add(new LLBLGenProNoChangeTrackingLinqPocoBencher(ConnectionString));
RegisteredBenchers.Add(new LLBLGenProNoChangeTrackingBencher(ConnectionString));
RegisteredBenchers.Add(new LLBLGenProResultsetCachingBencher(ConnectionString));
RegisteredBenchers.Add(new LLBLGenProNormalBencher(ConnectionString));
RegisteredBenchers.Add(new LLBLGenProDTOBencher(ConnectionString));
RegisteredBenchers.Add(new DapperBencher()
{
CommandText = SqlSelectCommandText, ConnectionStringToUse = ConnectionString
});
RegisteredBenchers.Add(new ChainBencher()
{
CommandText = SqlSelectCommandText, ConnectionStringToUse = ConnectionString
});
RegisteredBenchers.Add(new OrmLiteBencher()
{
CommandText = SqlSelectCommandText, ConnectionStringToUse = ConnectionString
});
RegisteredBenchers.Add(new DataTableBencher()
{
CommandText = SqlSelectCommandText, ConnectionStringToUse = ConnectionString
});
RegisteredBenchers.Add(new ChainCompiledBencher()
{
CommandText = SqlSelectCommandText, ConnectionStringToUse = ConnectionString
});
#if NETCOREAPP
// EF Core 3.x does support netstandard 2.0 but the benchers fail to build on .NET 4.8 so we'll skip them on netfx
RegisteredBenchers.Add(new EntityFrameworkCoreNoChangeTrackingBencher()
{
ConnectionStringToUse = ConnectionString
});
RegisteredBenchers.Add(new EntityFrameworkCoreNormalBencher()
{
ConnectionStringToUse = ConnectionString
});
RegisteredBenchers.Add(new EntityFrameworkCoreDTOBencher()
{
ConnectionStringToUse = ConnectionString
});
#else
RegisteredBenchers.Add(new MassiveBencher());
RegisteredBenchers.Add(new NHibernateNormalBencher());
RegisteredBenchers.Add(new LinqToSqlNoChangeTrackingBencher());
RegisteredBenchers.Add(new LinqToSqlNormalBencher());
RegisteredBenchers.Add(new EntityFrameworkNoChangeTrackingBencher());
RegisteredBenchers.Add(new EntityFrameworkNormalBencher());
RegisteredBenchers.Add(new PetaPocoBencher()
{
CommandText = SqlSelectCommandText, ConnectionStringToUse = ConnectionString
});
RegisteredBenchers.Add(new PetaPocoFastBencher()
{
CommandText = SqlSelectCommandText, ConnectionStringToUse = ConnectionString
});
#endif
BenchController.DisplayHeader();
BenchController.WarmupDB();
BenchController.FetchKeysForIndividualFetches();
// Uncomment the line below if you want to profile a bencher. Specify the bencher instance and follow the guides on the screen.
//ProfileBenchers(RegisteredBenchers.FirstOrDefault(b => b.GetType() == typeof(LINQ2DBNormalBencher)));
BenchController.RunRegisteredBenchers();
BenchController.ReportResultStatistics(autoExit);
}
private static void RunBencher(IBencher bencher)
{
bencher.ResetResults();
Console.WriteLine("First one warm-up run of each bench type to initialize constructs. Results will not be collected.");
BenchResult result = null;
if (PerformSetBenchmarks && bencher.SupportsSetFetch)
{
result = bencher.PerformSetBenchmark(discardResults: true);
BenchController.ReportSetResult(result);
}
if (bencher.SupportsEagerLoading)
{
result = bencher.PerformEagerLoadBenchmark(discardResults: true);
BenchController.ReportEagerLoadResult(result);
if (PerformAsyncBenchmarks && bencher.SupportsAsync)
{
result = bencher.PerformAsyncEagerLoadBenchmark(discardResults: true);
BenchController.ReportEagerLoadResult(result);
}
}
if (PerformIndividualBenchMarks && bencher.SupportsIndividualFetch)
{
result = bencher.PerformIndividualBenchMark(KeysForIndividualFetches, discardResults: true);
BenchController.ReportIndividualResult(result);
}
if (PerformSetInsertBenchmarks && bencher.SupportsInserts)
{
result = bencher.PerformInsertSetBenchmark(InsertSetSize, InsertBatchSizeDefault, discardResults: true);
BenchController.ReportInsertSetResult(result);
}
Console.WriteLine("Doing a GC collect...");
BenchController.ForceGCCollect();
Console.WriteLine("Done.");
Console.WriteLine("\nStarting bench runs...");
if (PerformSetBenchmarks && bencher.SupportsSetFetch)
{
// set benches
Console.WriteLine("Set fetches");
Console.WriteLine("-------------------------");
for (int i = 0; i < LoopAmount; i++)
{
result = bencher.PerformSetBenchmark();
BenchController.ReportSetResult(result);
// avoid having the GC collect in the middle of a run.
BenchController.ForceGCCollect();
}
}
if (PerformIndividualBenchMarks && bencher.SupportsIndividualFetch)
{
// individual benches
Console.WriteLine("\nSingle element fetches");
Console.WriteLine("-------------------------");
for (int i = 0; i < LoopAmount; i++)
{
result = bencher.PerformIndividualBenchMark(KeysForIndividualFetches);
BenchController.ReportIndividualResult(result);
// avoid having the GC collect in the middle of a run.
BenchController.ForceGCCollect();
if (ApplyAntiFloodForVMUsage)
{
// sleep is to avoid hammering the network layer on the target server. If the target server is a VM, it might stall once or twice
// during benching, which is not what we want at it can skew the results a lot. In a very short time, a lot of queries are executed
// on the target server (LoopAmount * IndividualKeysAmount), which will hurt performance on VMs with very fast frameworks in some
// cases in some runs (so more than 2 runs are slow).
#pragma warning disable CS0162
Thread.Sleep(400);
#pragma warning restore CS0162
}
}
}
if (PerformEagerLoadBenchmarks && bencher.SupportsEagerLoading)
{
// eager load benches
Console.WriteLine("\nEager Load fetches");
Console.WriteLine("-------------------------");
for (int i = 0; i < LoopAmount; i++)
{
result = bencher.PerformEagerLoadBenchmark();
BenchController.ReportEagerLoadResult(result);
// avoid having the GC collect in the middle of a run.
BenchController.ForceGCCollect();
}
}
if (PerformAsyncBenchmarks && bencher.SupportsEagerLoading && bencher.SupportsAsync)
{
// eager load benches
Console.WriteLine("\nAsync eager Load fetches");
Console.WriteLine("-------------------------");
for (int i = 0; i < LoopAmount; i++)
{
result = bencher.PerformAsyncEagerLoadBenchmark(discardResults: false);
BenchController.ReportEagerLoadResult(result);
// avoid having the GC collect in the middle of a run.
BenchController.ForceGCCollect();
}
}
if (PerformSetInsertBenchmarks && bencher.SupportsInserts)
{
// set insert benches
Console.WriteLine("\nSet Inserts");
Console.WriteLine("-------------------------");
for (int i = 0; i < LoopAmount; i++)
{
result = bencher.PerformInsertSetBenchmark(InsertSetSize, InsertBatchSizeDefault);
BenchController.ReportInsertSetResult(result);
// avoid having the GC collect in the middle of a run.
BenchController.ForceGCCollect();
}
}
}
private static void RunMemoryAnalysisForBencher(IBencher bencher)
{
Console.WriteLine("\nStarting bench runs...");
BenchResult result;
if (PerformSetBenchmarks && bencher.SupportsSetFetch)
{
// set benches
Console.WriteLine("Set fetches");
Console.WriteLine("-------------------------");
result = bencher.PerformSetBenchmark(discardResults: true);
BenchController.ReportMemoryUsageSetResult(result);
bencher.MemorySetBenchmarks = result.NumberOfBytesAllocated;
// avoid having the GC collect in the middle of a run.
BenchController.ForceGCCollect();
}
if (PerformIndividualBenchMarks && bencher.SupportsIndividualFetch)
{
// individual benches
Console.WriteLine("\nSingle element fetches");
Console.WriteLine("-------------------------");
result = bencher.PerformIndividualBenchMark(KeysForIndividualFetches, discardResults: true);
BenchController.ReportMemoryUsageIndividualResult(result);
bencher.MemoryIndividualBenchmarks = result.NumberOfBytesAllocated;
// avoid having the GC collect in the middle of a run.
BenchController.ForceGCCollect();
if (ApplyAntiFloodForVMUsage)
{
// sleep is to avoid hammering the network layer on the target server. If the target server is a VM, it might stall once or twice
// during benching, which is not what we want at it can skew the results a lot. In a very short time, a lot of queries are executed
// on the target server (LoopAmount * IndividualKeysAmount), which will hurt performance on VMs with very fast frameworks in some
// cases in some runs (so more than 2 runs are slow).
#pragma warning disable CS0162
Thread.Sleep(400);
#pragma warning restore CS0162
}
}
if (PerformEagerLoadBenchmarks && bencher.SupportsEagerLoading)
{
// eager load benches
Console.WriteLine("\nEager Load fetches");
Console.WriteLine("-------------------------");
result = bencher.PerformEagerLoadBenchmark(discardResults: true);
BenchController.ReportMemoryUsageEagerLoadResult(result);
bencher.MemoryEagerLoadBenchmarks = result.NumberOfBytesAllocated;
// avoid having the GC collect in the middle of a run.
BenchController.ForceGCCollect();
}
if (PerformAsyncBenchmarks && bencher.SupportsEagerLoading && bencher.SupportsAsync)
{
// eager load benches
Console.WriteLine("\nAsync eager Load fetches");
Console.WriteLine("-------------------------");
result = bencher.PerformAsyncEagerLoadBenchmark(discardResults: true);
BenchController.ReportMemoryUsageEagerLoadResult(result);
bencher.MemoryAsyncEagerLoadBenchmarks = result.NumberOfBytesAllocated;
// avoid having the GC collect in the middle of a run.
BenchController.ForceGCCollect();
}
if (PerformSetInsertBenchmarks && bencher.SupportsInserts)
{
// set inserts
Console.WriteLine("\nSet inserts");
Console.WriteLine("-------------------------");
result = bencher.PerformInsertSetBenchmark(InsertSetSize, InsertBatchSizeDefault, discardResults: true);
BenchController.ReportMemoryUsageInsertSetResult(result);
bencher.MemorySetInsertBenchmarks = result.NumberOfBytesAllocated;
// avoid having the GC collect in the middle of a run.
BenchController.ForceGCCollect();
}
}
