mirror of https://github.com/vacp2p/nim-libp2p.git
96 lines
5.0 KiB
Nim
96 lines
5.0 KiB
Nim
## # Simple ping tutorial
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##
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## Hi all, welcome to the first nim-libp2p tutorial!
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##
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## !!! tips ""
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## This tutorial is for everyone who is interested in building peer-to-peer applications. No Nim programming experience is needed.
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##
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## To give you a quick overview, **Nim** is the programming language we are using and **nim-libp2p** is the Nim implementation of [libp2p](https://libp2p.io/), a modular library that enables the development of peer-to-peer network applications.
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##
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## Hope you'll find it helpful in your journey of learning. Happy coding! ;)
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##
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## ## Before you start
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## The only prerequisite here is [Nim](https://nim-lang.org/), the programming language with a Python-like syntax and a performance similar to C. Detailed information can be found [here](https://nim-lang.org/docs/tut1.html).
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##
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## Install Nim via their [official website](https://nim-lang.org/install.html).
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## Check Nim's installation via `nim --version` and its package manager Nimble via `nimble --version`.
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##
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## You can now install the latest version of `nim-libp2p`:
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## ```bash
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## nimble install libp2p@#master
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## ```
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##
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## ## A simple ping application
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## We'll start by creating a simple application, which is starting two libp2p [switch](https://docs.libp2p.io/concepts/stream-multiplexing/#switch-swarm), and pinging each other using the [Ping](https://docs.libp2p.io/concepts/protocols/#ping) protocol.
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##
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## !!! tips ""
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## You can find the source of this tutorial (and other tutorials) in the [libp2p/examples](https://github.com/status-im/nim-libp2p/tree/master/examples) folder!
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##
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## Let's create a `part1.nim`, and import our dependencies:
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import chronos
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import libp2p
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import libp2p/protocols/ping
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## [chronos](https://github.com/status-im/nim-chronos) the asynchronous framework used by `nim-libp2p`
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##
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## Next, we'll create an helper procedure to create our switches. A switch needs a bit of configuration, and it will be easier to do this configuration only once:
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proc createSwitch(ma: MultiAddress, rng: ref HmacDrbgContext): Switch =
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var switch = SwitchBuilder
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.new()
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.withRng(rng) # Give the application RNG
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.withAddress(ma) # Our local address(es)
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.withTcpTransport() # Use TCP as transport
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.withMplex() # Use Mplex as muxer
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.withNoise() # Use Noise as secure manager
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.build()
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return switch
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## This will create a switch using [Mplex](https://docs.libp2p.io/concepts/stream-multiplexing/) as a multiplexer, Noise to secure the communication, and TCP as an underlying transport.
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##
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## You can of course tweak this, to use a different or multiple transport, or tweak the configuration of Mplex and Noise, but this is some sane defaults that we'll use going forward.
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##
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##
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## Let's now start to create our main procedure:
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proc main() {.async.} =
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let
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rng = newRng()
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localAddress = MultiAddress.init("/ip4/0.0.0.0/tcp/0").tryGet()
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pingProtocol = Ping.new(rng=rng)
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## We created some variables that we'll need for the rest of the application: the global `rng` instance, our `localAddress`, and an instance of the `Ping` protocol.
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## The address is in the [MultiAddress](https://github.com/multiformats/multiaddr) format. The port `0` means "take any port available".
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##
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## `tryGet` is procedure which is part of [nim-result](https://github.com/arnetheduck/nim-result/), that will throw an exception if the supplied MultiAddress is invalid.
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##
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## We can now create our two switches:
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let
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switch1 = createSwitch(localAddress, rng)
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switch2 = createSwitch(localAddress, rng)
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switch1.mount(pingProtocol)
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await switch1.start()
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await switch2.start()
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## We've **mounted** the `pingProtocol` on our first switch. This means that the first switch will actually listen for any ping requests coming in, and handle them accordingly.
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##
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## Now that we've started the nodes, they are listening for incoming peers.
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## We can find out which port was attributed, and the resulting local addresses, by using `switch1.peerInfo.addrs`.
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##
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## We'll **dial** the first switch from the second one, by specifying it's **Peer ID**, it's **MultiAddress** and the **`Ping` protocol codec**:
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let conn = await switch2.dial(switch1.peerInfo.peerId, switch1.peerInfo.addrs, PingCodec)
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## We now have a `Ping` connection setup between the second and the first switch, we can use it to actually ping the node:
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# ping the other node and echo the ping duration
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echo "ping: ", await pingProtocol.ping(conn)
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# We must close the connection ourselves when we're done with it
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await conn.close()
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## And that's it! Just a little bit of cleanup: shutting down the switches, waiting for them to stop, and we'll call our `main` procedure:
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await allFutures(switch1.stop(), switch2.stop()) # close connections and shutdown all transports
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waitFor(main())
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## You can now run this program using `nim c -r part1.nim`, and you should see the dialing sequence, ending with a ping output.
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##
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## In the [next tutorial](tutorial_2_customproto.md), we'll look at how to create our own custom protocol.
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