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https://github.com/perlin-network/noise

A decentralized P2P networking stack written in Go.
https://github.com/perlin-network/noise

cryptography golang network p2p peer-discovery

Last synced: 25 days ago
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A decentralized P2P networking stack written in Go.

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README

        

# noise

[![GoDoc][1]][2] [![Discord][7]][8] [![MIT licensed][5]][6] ![Build Status][9] [![Go Report Card][11]][12] [![Coverage Status][13]][14]

[1]: https://godoc.org/github.com/perlin-network/noise?status.svg
[2]: https://godoc.org/github.com/perlin-network/noise
[5]: https://img.shields.io/badge/license-MIT-blue.svg
[6]: LICENSE
[7]: https://img.shields.io/discord/458332417909063682.svg
[8]: https://discord.gg/dMYfDPM
[9]: https://github.com/perlin-network/noise/workflows/CI/badge.svg
[11]: https://goreportcard.com/badge/github.com/perlin-network/noise
[12]: https://goreportcard.com/report/github.com/perlin-network/noise
[13]: https://codecov.io/gh/perlin-network/noise/branch/master/graph/badge.svg
[14]: https://codecov.io/gh/perlin-network/noise

**noise** is an opinionated, easy-to-use P2P network stack for decentralized applications, and cryptographic protocols written in Go.

**noise** is made to be minimal, robust, developer-friendly, performant, secure, and cross-platform across multitudes of devices by making use of a small amount of well-tested, production-grade dependencies.

## Features

- Listen for incoming peers, query peers, and ping peers.
- Request for/respond to messages, fire-and-forget messages, and optionally automatically serialize/deserialize messages across peers.
- Optionally cancel/timeout pinging peers, sending messages to peers, receiving messages from peers, or requesting messages from peers via `context` support.
- Fine-grained control over a node and peers lifecycle and goroutines and resources (synchronously/asynchronously/gracefully start listening for new peers, stop listening for new peers, send messages to a peer, disconnect an existing peer, wait for a peer to be ready, wait for a peer to have disconnected).
- Limit resource consumption by pooling connections and specifying the max number of inbound/outbound connections allowed at any given time.
- Reclaim resources exhaustively by timing out idle peers with a configurable timeout.
- Establish a shared secret by performing an Elliptic-Curve Diffie-Hellman Handshake over Curve25519.
- Establish an encrypted session amongst a pair of peers via authenticated-encryption-with-associated-data (AEAD). Built-in support for AES 256-bit Galois Counter Mode (GCM).
- Peer-to-peer routing, discovery, identities, and handshake protocol via Kademlia overlay network protocol.

## Defaults

- No logs are printed by default. Set a logger via `noise.WithNodeLogger(*zap.Logger)`.
- A random Ed25519 key pair is generated for a new node.
- Peers attempt to be dialed at most three times.
- A total of 128 outbound connections are allowed at any time.
- A total of 128 inbound connections are allowed at any time.
- Peers may send in a single message, at most, 4MB worth of data.
- Connections timeout after 10 seconds if no reads/writes occur.

## Dependencies

- Logging is handled by [uber-go/zap](https://github.com/uber-go/zap).
- Unit tests are handled by [stretchr/testify](https://github.com/stretchr/testify).
- X25519 handshaking and Curve25519 encryption/decryption and Ed25519 signatures are handled by [oasislabs/ed25519](https://github.com/oasislabs/ed25519).

## Setup

**noise** was intended to be used in Go projects that utilize Go modules. You may incorporate noise into your project as a library dependency by executing the following:

```shell
% go get -u github.com/perlin-network/noise
```

## Example

```go
package main

import (
"context"
"fmt"
"github.com/perlin-network/noise"
)

func check(err error) {
if err != nil {
panic(err)
}
}

// This example demonstrates how to send/handle RPC requests across peers, how to listen for incoming
// peers, how to check if a message received is a request or not, how to reply to a RPC request, and
// how to cleanup node instances after you are done using them.
func main() {
// Let there be nodes Alice and Bob.

alice, err := noise.NewNode()
check(err)

bob, err := noise.NewNode()
check(err)

// Gracefully release resources for Alice and Bob at the end of the example.

defer alice.Close()
defer bob.Close()

// When Bob gets a message from Alice, print it out and respond to Alice with 'Hi Alice!'

bob.Handle(func(ctx noise.HandlerContext) error {
if !ctx.IsRequest() {
return nil
}

fmt.Printf("Got a message from Alice: '%s'\n", string(ctx.Data()))

return ctx.Send([]byte("Hi Alice!"))
})

// Have Alice and Bob start listening for new peers.

check(alice.Listen())
check(bob.Listen())

// Have Alice send Bob a request with the message 'Hi Bob!'

res, err := alice.Request(context.TODO(), bob.Addr(), []byte("Hi Bob!"))
check(err)

// Print out the response Bob got from Alice.

fmt.Printf("Got a message from Bob: '%s'\n", string(res))

// Output:
// Got a message from Alice: 'Hi Bob!'
// Got a message from Bob: 'Hi Alice!'
}
```

For documentation and more examples, refer to noise's godoc [here](https://godoc.org/github.com/perlin-network/noise).

## Benchmarks

Benchmarks measure CPU time and allocations of a single node sending messages, requests, and responses to/from itself over 8 logical cores on a loopback adapter.

Take these benchmark numbers with a grain of salt.

```shell
% cat /proc/cpuinfo | grep 'model name' | uniq
model name : Intel(R) Core(TM) i7-7700HQ CPU @ 2.80GHz

% go test -bench=. -benchtime=30s -benchmem
goos: linux
goarch: amd64
pkg: github.com/perlin-network/noise
BenchmarkRPC-8 4074007 9967 ns/op 272 B/op 7 allocs/op
BenchmarkSend-8 31161464 1051 ns/op 13 B/op 2 allocs/op
PASS
ok github.com/perlin-network/noise 84.481s
```

## Versioning

**noise** is currently in its initial development phase and therefore does not promise that subsequent releases will not comprise of breaking changes. Be aware of this should you choose to utilize Noise for projects that are in production.

Releases are marked with a version number formatted as MAJOR.MINOR.PATCH. Major breaking changes involve a bump in MAJOR, minor backward-compatible changes involve a bump in MINOR, and patches and bug fixes involve a bump in PATCH starting from v2.0.0.

Therefore, **noise** _mostly_ respects semantic versioning.

The rationale behind this is due to improper tagging of prior releases (v0.1.0, v1.0.0, v1.1.0, and v1.1.1), which has caused for the improper caching of module information on _proxy.golang.org_ and _sum.golang.org_.

As a result, _noise's initial development phase starts from v1.1.2_. Until Noise's API is stable, subsequent releases will only comprise of bumps in MINOR and PATCH.

## License

**noise**, and all of its source code is released under the MIT [License](https://github.com/perlin-network/noise/blob/master/LICENSE).