nim-libp2p/examples/tutorial_2_customproto.nim

## # Custom protocol in libp2p
##
## In the [previous tutorial](tutorial_1_connect.md), we've looked at how to create a simple ping program using the `nim-libp2p`.
##
## We'll now look at how to create a custom protocol inside the libp2p
##
## Let's create a `part2.nim`, and import our dependencies:
import chronos
import stew/byteutils

import libp2p
## This is similar to the first tutorial, except we don't need to import the `Ping` protocol.
##
## Next, we'll declare our custom protocol
const TestCodec = "/test/proto/1.0.0"

type TestProto = ref object of LPProtocol

## We've set a [protocol ID](https://docs.libp2p.io/concepts/protocols/#protocol-ids), and created a custom `LPProtocol`. In a more complex protocol, we could use this structure to store interesting variables.
##
## A protocol generally has two part: and handling/server part, and a dialing/client part.
## Theses two parts can be identical, but in our trivial protocol, the server will wait for a message from the client, and the client will send a message, so we have to handle the two cases separately.
##
## Let's start with the server part:

proc new(T: typedesc[TestProto]): T =
  # every incoming connections will in be handled in this closure
  proc handle(conn: Connection, proto: string) {.async, gcsafe.} =
    # Read up to 1024 bytes from this connection, and transform them into
    # a string
    echo "Got from remote - ", string.fromBytes(await conn.readLp(1024))
    # We must close the connections ourselves when we're done with it
    await conn.close()

  return T(codecs: @[TestCodec], handler: handle)

## This is a constructor for our `TestProto`, that will specify our `codecs` and a `handler`, which will be called for each incoming peer asking for this protocol.
## In our handle, we simply read a message from the connection and `echo` it.
##
## We can now create our client part:
proc hello(p: TestProto, conn: Connection) {.async.} =
  await conn.writeLp("Hello p2p!")

## Again, pretty straight-forward, we just send a message on the connection.
##
## We can now create our main procedure:
proc main() {.async, gcsafe.} =
  let
    rng = newRng()
    testProto = TestProto.new()
    switch1 = newStandardSwitch(rng=rng)
    switch2 = newStandardSwitch(rng=rng)

  switch1.mount(testProto)

  await switch1.start()
  await switch2.start()

  let conn = await switch2.dial(switch1.peerInfo.peerId, switch1.peerInfo.addrs, TestCodec)

  await testProto.hello(conn)

  # We must close the connection ourselves when we're done with it
  await conn.close()

  await allFutures(switch1.stop(), switch2.stop()) # close connections and shutdown all transports

## This is very similar to the first tutorial's `main`, the only noteworthy difference is that we use `newStandardSwitch`, which is similar to the `createSwitch` of the first tutorial, but is bundled directly in libp2p
##
## We can now wrap our program by calling our main proc:
waitFor(main())

## And that's it!
## In the [next tutorial](tutorial_3_protobuf.md), we'll create a more complex protocol using Protobuf.
Docs rework (#776) 2022-09-28 08:40:53 +00:00			`## # Custom protocol in libp2p`
			`##`
			## In the [previous tutorial](tutorial_1_connect.md), we've looked at how to create a simple ping program using the `nim-libp2p`.
			`##`
			`## We'll now look at how to create a custom protocol inside the libp2p`
			`##`
			## Let's create a `part2.nim`, and import our dependencies:
			`import chronos`
			`import stew/byteutils`

			`import libp2p`
			## This is similar to the first tutorial, except we don't need to import the `Ping` protocol.
			`##`
			`## Next, we'll declare our custom protocol`
			`const TestCodec = "/test/proto/1.0.0"`

			`type TestProto = ref object of LPProtocol`

			## We've set a [protocol ID](https://docs.libp2p.io/concepts/protocols/#protocol-ids), and created a custom `LPProtocol`. In a more complex protocol, we could use this structure to store interesting variables.
			`##`
			`## A protocol generally has two part: and handling/server part, and a dialing/client part.`
			`## Theses two parts can be identical, but in our trivial protocol, the server will wait for a message from the client, and the client will send a message, so we have to handle the two cases separately.`
			`##`
			`## Let's start with the server part:`

			`proc new(T: typedesc[TestProto]): T =`
			`# every incoming connections will in be handled in this closure`
			`proc handle(conn: Connection, proto: string) {.async, gcsafe.} =`
			`# Read up to 1024 bytes from this connection, and transform them into`
			`# a string`
			`echo "Got from remote - ", string.fromBytes(await conn.readLp(1024))`
			`# We must close the connections ourselves when we're done with it`
			`await conn.close()`

			`return T(codecs: @[TestCodec], handler: handle)`

			## This is a constructor for our `TestProto`, that will specify our `codecs` and a `handler`, which will be called for each incoming peer asking for this protocol.
			## In our handle, we simply read a message from the connection and `echo` it.
			`##`
			`## We can now create our client part:`
			`proc hello(p: TestProto, conn: Connection) {.async.} =`
			`await conn.writeLp("Hello p2p!")`

			`## Again, pretty straight-forward, we just send a message on the connection.`
			`##`
			`## We can now create our main procedure:`
			`proc main() {.async, gcsafe.} =`
			`let`
			`rng = newRng()`
			`testProto = TestProto.new()`
			`switch1 = newStandardSwitch(rng=rng)`
			`switch2 = newStandardSwitch(rng=rng)`

			`switch1.mount(testProto)`

			`await switch1.start()`
			`await switch2.start()`

			`let conn = await switch2.dial(switch1.peerInfo.peerId, switch1.peerInfo.addrs, TestCodec)`

			`await testProto.hello(conn)`

			`# We must close the connection ourselves when we're done with it`
			`await conn.close()`

			`await allFutures(switch1.stop(), switch2.stop()) # close connections and shutdown all transports`

			## This is very similar to the first tutorial's `main`, the only noteworthy difference is that we use `newStandardSwitch`, which is similar to the `createSwitch` of the first tutorial, but is bundled directly in libp2p
			`##`
			`## We can now wrap our program by calling our main proc:`
			`waitFor(main())`

			`## And that's it!`
Protobuf tutorial (#778) 2022-09-29 08:28:58 +00:00			`## In the [next tutorial](tutorial_3_protobuf.md), we'll create a more complex protocol using Protobuf.`