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ScyllaDB Java Driver is available under the Apache v2 License. ScyllaDB Java Driver is a fork of DataStax Java Driver. See Copyright here.
The driver is a highly concurrent environment. We try to use thread confinement to simplify the code, when that does not impact performance.
The hot path is everything that happens for a session.execute
call. In a typical client
application, this is where the driver will likely spend the majority of its time, so it must be
fast.
Write path:
convert the statement into a protocol-level Message
(CqlRequestHandler
constructor);
find a node and a connection, and write the message to it (CqlRequestHandler.sendRequest
);
assign a stream id and wrap the message into a frame (InflightHandler.write
);
encode the frame into a binary payload (FrameEncoder
).
Read path:
decode the binary payload into a frame (FrameDecoder
);
find the handler that corresponds to the stream id (InFlightHandler.channelRead
);
complete the client’s future (CqlRequestHandler.NodeResponseCallback.onResponse
).
Various policies are also invoked along the way (load balancing, retry, speculative execution, timestamp generator…), they are considered on the hot path too.
Steps 1 and 2 of the write path happen on the client thread, and 3 and 4 on the Netty I/O thread
(which is one of the threads in NettyOptions.ioEventLoopGroup()
).
On the read path, everything happens on the Netty I/O thread. Beyond that, we want to avoid context
switches for performance reasons: in early prototypes, we tried confining CqlRequestHandler
to a
particular thread, but that did not work well; so you will find that the code is fairly similar to
driver 3 in terms of concurrency control (reliance on atomic structures, volatile fields, etc).
Note: code on the hot path should prefer the TRACE
log level.
The cold path is everything else: initialization and shutdown, metadata refreshes, tracking node states, etc. They will typically be way less frequent than user requests, so we can tolerate a small performance hit in order to make concurrency easier to handle.
One pattern we use a lot is a confined inner class:
public class ControlConnection {
// some content omitted for brevity
private final EventExecutor adminExecutor;
private final SingleThreaded singleThreaded;
// Called from other components, from any thread
public void reconnectNow() {
RunOrSchedule.on(adminExecutor, singleThreaded::reconnectNow);
}
private class SingleThreaded {
private void reconnectNow() {
assert adminExecutor.inEventLoop();
// this method is only ever called from one thread, much easier to handle concurrency
}
}
}
Public outer methods such as reconnectNow()
are called concurrently. But they delegate to a method
of the internal class, that always runs on the same adminExecutor
thread. RunOrSchedule.on
calls
the method directly if we’re already on the target thread, otherwise it schedules a task. If we need
to propagate a result, the outer method injects a future that the inner method completes.
adminExecutor
is picked randomly from NettyOptions.adminEventExecutorGroup()
at construction
time.
Confining SingleThreaded
simplifies the code tremendously: we can use regular, non-volatile
fields, and methods are guaranteed to always run in isolation, eliminating subtle race conditions
(this idea was borrowed from actor systems).
Whether on the hot or cold path, internal code is almost 100% lock-free. The driver guarantees on lock-freedom are detailed in the core manual.
If an internal component needs to execute a query, it does so asynchronously, and registers
callbacks to process the results. Examples of this can be found in ReprepareOnUp
and
DefaultTopologyMonitor
(among others).
The only place where the driver blocks is when using the synchronous API (methods declared in
SyncCqlSession
), and when calling other synchronous wrapper methods in the public API, for
example, ExecutionInfo.getQueryTrace()
:
public interface ExecutionInfo {
// some content omitted for brevity
default QueryTrace getQueryTrace() {
BlockingOperation.checkNotDriverThread();
return CompletableFutures.getUninterruptibly(getQueryTraceAsync());
}
}
When a public API method is blocking, this is generally clearly stated in its javadocs.
BlockingOperation
is a utility to check that those methods aren’t called on I/O threads, which
could introduce deadlocks.
Keeping the internals fully asynchronous is another major improvement over driver 3, where internal requests were synchronous, and required multiple internal executors to avoid deadlocks.
In driver 4, there are only two executors: NettyOptions.ioEventLoopGroup()
and
NettyOptions.adminEventLoopGroup()
, that are guaranteed to never run blocking tasks. They can be
shared with application code, or across multiple sessions, or can even be one and the same (in
theory, it’s possible to use a single 1-thread executor, although there’s probably no practical
reason to do that).
To be exhaustive, NettyOptions.getTimer()
also uses its own thread; we tried scheduling request
timeouts and speculative executions on I/O threads in early alphas, but that didn’t perform as well
as Netty’s HashedWheelTimer
.
So the total number of threads created by a session is
advanced.netty.io-group.size + advanced.netty.admin-group.size + 1
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ScyllaDB Java Driver is available under the Apache v2 License. ScyllaDB Java Driver is a fork of DataStax Java Driver. See Copyright here.
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