static void Main(string[] args)
{
var context = default(CacheContext);
var log = Devices.CreateLogDevice(Path.GetTempPath() + "hlog.log", deleteOnClose: true);
var objlog = Devices.CreateLogDevice(Path.GetTempPath() + "hlog.obj.log", deleteOnClose: true);
var logSettings = new LogSettings {
LogDevice = log, ObjectLogDevice = objlog
};
if (useReadCache)
{
logSettings.ReadCacheSettings = new ReadCacheSettings();
}
var h = new FasterKV
<CacheKey, CacheValue, CacheInput, CacheOutput, CacheContext, CacheFunctions>(
1L << 20, new CacheFunctions(), logSettings,
null,
new SerializerSettings <CacheKey, CacheValue> {
keySerializer = () => new CacheKeySerializer(), valueSerializer = () => new CacheValueSerializer()
}
);
h.StartSession();
const int max = 1000000;
Console.WriteLine("Writing keys from 0 to {0} to FASTER", max);
Stopwatch sw = new Stopwatch();
sw.Start();
for (int i = 0; i < max; i++)
{
if (i % 256 == 0)
{
h.Refresh();
if (i % (1 << 19) == 0)
{
long workingSet = Process.GetCurrentProcess().WorkingSet64;
Console.WriteLine($"{i}: {workingSet / 1048576}M");
}
}
var key = new CacheKey(i);
var value = new CacheValue(i);
h.Upsert(ref key, ref value, context, 0);
}
sw.Stop();
Console.WriteLine("Total time to upsert {0} elements: {1:0.000} secs ({2:0.00} inserts/sec)", max, sw.ElapsedMilliseconds / 1000.0, max / (sw.ElapsedMilliseconds / 1000.0));
// Uncomment below to copy entire log to disk, but retain tail of log in memory
// h.Log.Flush(true);
// Uncomment below to move entire log to disk and eliminate data from memory as
// well. This will serve workload entirely from disk using read cache if enabled.
// This will *allow* future updates to the store.
// h.Log.FlushAndEvict(true);
// Uncomment below to move entire log to disk and eliminate data from memory as
// well. This will serve workload entirely from disk using read cache if enabled.
// This will *prevent* future updates to the store.
h.Log.DisposeFromMemory();
Console.Write("Enter read workload type (0 = random reads; 1 = interactive): ");
var workload = int.Parse(Console.ReadLine());
if (workload == 0)
{
RandomReadWorkload(h, max);
}
else
{
InteractiveReadWorkload(h, max);
}
Console.WriteLine("Press <ENTER> to end");
Console.ReadLine();
}
static void Main(string[] args)
{
var context = default(CacheContext);
var log = Devices.CreateLogDevice(Path.GetTempPath() + "hlog.log", deleteOnClose: true);
var objlog = Devices.CreateLogDevice(Path.GetTempPath() + "hlog.obj.log", deleteOnClose: true);
var h = new FasterKV
<CacheKey, CacheValue, CacheInput, CacheOutput, CacheContext, CacheFunctions>(
1L << 20, new CacheFunctions(),
new LogSettings {
LogDevice = log, ObjectLogDevice = objlog
},
null,
new SerializerSettings <CacheKey, CacheValue> {
keySerializer = () => new CacheKeySerializer(), valueSerializer = () => new CacheValueSerializer()
}
);
h.StartSession();
const int max = 1000000;
Console.WriteLine("Writing keys from 0 to {0} to FASTER", max);
Stopwatch sw = new Stopwatch();
sw.Start();
for (int i = 0; i < max; i++)
{
if (i % 256 == 0)
{
h.Refresh();
if (i % (1 << 19) == 0)
{
long workingSet = Process.GetCurrentProcess().WorkingSet64;
Console.WriteLine($"{i}: {workingSet / 1048576}M");
}
}
var key = new CacheKey(i);
var value = new CacheValue(i);
h.Upsert(ref key, ref value, context, 0);
}
sw.Stop();
Console.WriteLine("Total time to upsert {0} elements: {1:0.000} secs ({2:0.00} inserts/sec)", max, sw.ElapsedMilliseconds / 1000.0, max / (sw.ElapsedMilliseconds / 1000.0));
// Uncomment below to copy entire log to disk
// h.ShiftReadOnlyAddress(h.LogTailAddress);
// Uncomment below to move entire log to disk
// and eliminate data from memory as well
// h.ShiftHeadAddress(h.LogTailAddress, true);
Console.Write("Enter read workload type (0 = random reads; 1 = interactive): ");
var workload = int.Parse(Console.ReadLine());
if (workload == 0)
{
RandomReadWorkload(h, max);
}
else
{
InteractiveReadWorkload(h, max);
}
Console.WriteLine("Press <ENTER> to end");
Console.ReadLine();
}
static void Main(string[] args)
{
var context = default(CacheContext);
var log = Devices.CreateLogDevice(Path.GetTempPath() + "hlog.log");
var objlog = Devices.CreateLogDevice(Path.GetTempPath() + "hlog.obj.log");
var h = new FasterKV
<CacheKey, CacheValue, CacheInput, CacheOutput, CacheContext, CacheFunctions>(
1L << 20, new CacheFunctions(),
new LogSettings {
LogDevice = log, ObjectLogDevice = objlog
}
);
h.StartSession();
const int max = 10000000;
Stopwatch sw = new Stopwatch();
sw.Start();
for (int i = 0; i < max; i++)
{
if (i % 256 == 0)
{
h.Refresh();
if (i % (1 << 19) == 0)
{
long workingSet = Process.GetCurrentProcess().WorkingSet64;
Console.WriteLine($"{i}: {workingSet / 1048576}M");
}
}
var key = new CacheKey(i);
var value = new CacheValue(i);
h.Upsert(ref key, ref value, context, 0);
}
sw.Stop();
Console.WriteLine("Total time to upsert {0} elements: {1:0.000} secs ({2:0.00} inserts/sec)", max, sw.ElapsedMilliseconds / 1000.0, max / (sw.ElapsedMilliseconds / 1000.0));
Console.WriteLine("Issuing uniform random read workload");
var rnd = new Random();
int statusPending = 0;
var output = new CacheOutput();
var input = default(CacheInput);
sw.Restart();
for (int i = 0; i < max; i++)
{
long k = rnd.Next(max);
var key = new CacheKey(k);
var status = h.Read(ref key, ref input, ref output, context, 0);
switch (status)
{
case Status.PENDING:
h.CompletePending(true);
statusPending++; break;
case Status.ERROR:
throw new Exception("Error!");
}
if (output.value.value != key.key)
{
throw new Exception("Read error!");
}
}
sw.Stop();
Console.WriteLine("Total time to read {0} elements: {1:0.000} secs ({2:0.00} reads/sec)", max, sw.ElapsedMilliseconds / 1000.0, max / (sw.ElapsedMilliseconds / 1000.0));
Console.WriteLine($"Reads completed with PENDING: {statusPending}");
Console.WriteLine("Done");
Console.ReadLine();
}
static void Main()
{
// This sample shows the use of FASTER as a cache + key-value store for
// C# objects.
// Create files for storing data
// We set deleteOnClose to true, so logs will auto-delete on completion
var log = Devices.CreateLogDevice(Path.GetTempPath() + "hlog.log", deleteOnClose: true);
var objlog = Devices.CreateLogDevice(Path.GetTempPath() + "hlog.obj.log", deleteOnClose: true);
// We use context to store and report latency of async operations
var context = default(CacheContext);
// Define settings for log
var logSettings = new LogSettings {
LogDevice = log, ObjectLogDevice = objlog
};
if (useReadCache)
{
logSettings.ReadCacheSettings = new ReadCacheSettings();
}
var h = new FasterKV
<CacheKey, CacheValue, CacheInput, CacheOutput, CacheContext, CacheFunctions>(
1L << 20, new CacheFunctions(), logSettings,
null, // no checkpoints in this sample
// Provide serializers for key and value types
new SerializerSettings <CacheKey, CacheValue> {
keySerializer = () => new CacheKeySerializer(), valueSerializer = () => new CacheValueSerializer()
}
);
// Thread starts session with FASTER
var s = h.NewSession();
Console.WriteLine("Writing keys from 0 to {0} to FASTER", max);
Stopwatch sw = new Stopwatch();
sw.Start();
for (int i = 0; i < max; i++)
{
if (i % (1 << 19) == 0)
{
long workingSet = Process.GetCurrentProcess().WorkingSet64;
Console.WriteLine($"{i}: {workingSet / 1048576}M");
}
var key = new CacheKey(i);
var value = new CacheValue(i);
s.Upsert(ref key, ref value, context, 0);
}
sw.Stop();
Console.WriteLine("Total time to upsert {0} elements: {1:0.000} secs ({2:0.00} inserts/sec)", max, sw.ElapsedMilliseconds / 1000.0, max / (sw.ElapsedMilliseconds / 1000.0));
// Uncomment below to copy entire log to disk, but retain tail of log in memory
// h.Log.Flush(true);
// Uncomment below to move entire log to disk and eliminate data from memory as
// well. This will serve workload entirely from disk using read cache if enabled.
// This will *allow* future updates to the store.
// h.Log.FlushAndEvict(true);
// Uncomment below to move entire log to disk and eliminate data from memory as
// well. This will serve workload entirely from disk using read cache if enabled.
// This will *prevent* future updates to the store.
h.Log.DisposeFromMemory();
Console.Write("Enter read workload type (0 = random reads; 1 = interactive): ");
var workload = int.Parse(Console.ReadLine());
if (workload == 0)
{
RandomReadWorkload(s, max);
}
else
{
InteractiveReadWorkload(s);
}
// Stop session and clean up
s.Dispose();
h.Dispose();
log.Close();
objlog.Close();
Console.WriteLine("Press <ENTER> to end");
Console.ReadLine();
}
