npm install --save mutex-server
Critical sections in the network level.
The mutex-server
is an npm module that can be used for building a mutex server. When you need to control a critical section on the entire system level, like distributed processing system using the network communications, this mutex-server
can be a good solution.
Installs and opens a mutex-server
and let clients to connect to the server. The clients who're connecting to the mutex-server
can utilize remote critical section components like mutex or semaphore.
Also, mutex-server
has a safety device for network disconnections. When a client has been suddenly disconnected, all of the locks had acquired or tried by the client would be automatically unlocked or cancelled. Therefore, you don't worry about any network disconnection accident and just enjoy the mutex-server
with confidence.
When you want to open a mutex-server
, utilize the MutexServer
class and accept or reject connections from the remote clients by using the MutexAcceptor
class. Otherwise, you want to connect to a remote mutex-server
as a client, utilize the MutexConnector
class.
If you succeeded to connect to a mutex-server
, as a client through the MutexConnector
class, you can utilize lots of remote critical section components like below. For reference, all of those critical section components are following the STL (Standard Template Library) design.
Also, std.UniqueLock
and std.SharedLock
can be a good choice for safe development. They always ensure that acquired lock to be automatically unlocked, in any circumstance, even if an error occurs in your business code.
- Solid Components
- Adaptor Components
- Safety Helpers
Let's learn how to use the mutex-server
through a sample project. I'll open a server and let
4 clients to connect to the server. After those 4 clients' connections, they'll monopoly a critical section through RemoteMutex.lock()
method and start printing a line very slowly.
After printing has been completed, each client will act one of them randomly: unlock the mutex or close the connection without the unlock. As you know and as I've mentioned, if a client has been disconnected without returning locks that it had been acquired, the mutex-server
will automatically release them.
Therefore, two random actions would be confirmed to the same result: RemoteMutex.unlock()
.
import msv from "mutex-server";
import std from "tstl";
const PASSWORD = "qweqwe123!";
const PORT = 37119;
async function client(index: number, character: string): Promise<void>
{
// CONNECT TO THE SERVER
let connector: msv.MutexConnector<string, null> = new msv.MutexConnector(PASSWORD, null);
await connector.connect(`ws://127.0.0.1:${PORT}`);
// GET LOCK
let mutex: msv.RemoteMutex = await connector.getMutex("printer");
await mutex.lock();
// PRINTS A LINE VERY SLOWLY MONOPOLYING THE MUTEX
process.stdout.write(`Connector #${index} is monopolying a mutex: `);
for (let i: number = 0; i < 20; ++i)
{
process.stdout.write(character);
await std.sleep_for(50);
}
process.stdout.write("\n");
// ALTHOUGH THE CLIENT DOES NOT RELEASE THE LOCK
if (Math.random() < 0.5)
await mutex.unlock();
else // SERVER WILL UNLOCK IT AUTOMATICALLY AFTER THE DISCONNECTION
await connector.close();
}
async function main(): Promise<void>
{
// OPEN SERVER
let server: msv.MutexServer<string, null> = new msv.MutexServer();
await server.open(PORT, async acceptor =>
{
if (acceptor.header === PASSWORD)
await acceptor.accept(null);
else
await acceptor.reject();
});
// CREATE 10 CLIENTS LOCKING MUTEX
let promises: Promise<void>[] = [];
for (let i: number = 0; i < 4; ++i)
{
let character: string = std.randint(0, 9).toString();
promises.push( client(i + 1, character) );
}
// WAIT THE CLIENTS TO BE DISCONNCTED AND CLOSE SERVER
await Promise.all(promises);
await server.close();
}
main();
mutex-server
is an open source project following the MIT license.
- Github: https://github.com/samchon/mutex
- NPM: https://www.npmjs.com/package/mutex-server
Someone who wants to know more about this mutex-server
, I've prepared the API documents. Through the API documents, you can travel all of the features defined in this mutex-server
.
Also, I'm planning to write the guide documents providing detailed learning course and lots of example projects handling network level critical sections. When the guide documents has been published, its URL address would be https://samchon.github.io/mutex and it would form like the TGrid's.
- API Documents: https://samchon.github.io/mutex/api
- Guide Documents: not yet, but soon.
4.3.1. TypeScript
I've developed this mutex-server
with the TypeScript.
Also, I hope all users of this mutex-server
to use the TypeScript too, for the safe development. As this mutex-server
is designed to handling critical section in the network level, a tiny mistake like mis-typing can be a critical damage on the entire network system.
It's the reason why I recommend you to use the TypeScript when using this mutex-server
.
4.3.2. TSTL
This mutex-server
is an extension module of the TSTL.
TSTL is an open source project migrating C++ STL (Standrad Template Library) to the TypeScript. Therefore, TSTL is following designs from the C++ standard committee and providing many modules like containers, iterators, algorithms and functors following the standard.
However, TypeScript is not C++ and it's development environment is different with the C++, either. Therefore, there're some STL features that are not suitable for the TypeScript development. Also, there can be a feature not supported by STL, but it's an important one in the TypeScript development environment, too.
To resolve such problems, TSTL is providing extension modules. This mutex-server
is one of those extension module from the TSTL, designed to support the network level critical sections: tstl#74.
4.3.3. TGrid
TGrid is also an extension module of the TSTL, designed to support the thread and network, too.
The TGrid has implemented thread and network by inventing a new concept; RFC (Remote Function Call). Also, this mutex-server
has realized its remote, network level critical section, components by utilizing the RFC concepts invented by the TGrid.