Spawn IPFS Daemons, JS or Go
- Install
- Notice
- Usage
- Disposable vs non Disposable nodes
- API
- ipfsd-ctl environment variables
- Contribute
- License
- Contribute
$ npm i ipfsd-ctl
Version 1.0.0 changed a bit the api and the options methods take so please read the documentation below.
Please ensure your project also has dependencies on ipfs
, ipfs-http-client
, kubo-rpc-client
, and go-ipfs
.
npm install --save ipfs ipfs-http-client go-ipfs kubo-rpc-client
If you are only going to use the go
implementation of IPFS, you can skip installing the js
implementation and ipfs-http-client
module. (e.g. npm i --save go-ipfs kubo-rpc-client
)
If you are only using the proc
type in-process IPFS node, you can skip installing go-ipfs
and ipfs-http-client
. (e.g. npm i --save ipfs
)
You also need to explicitly defined the options
ipfsBin
,ipfsModule
andipfsHttpModule
according to your needs. Check ControllerOptions and ControllerOptionsOverrides for more information.
This is a shorthand for simpler use cases where factory is not needed.
// No need to create a factory when only a single controller is needed.
// Use createController to spawn it instead.
const Ctl = require('ipfsd-ctl')
const ipfsd = await Ctl.createController({
ipfsHttpModule,
ipfsBin: goIpfsModule.path()
})
const id = await ipfsd.api.id()
console.log(id)
await ipfsd.stop()
Use a factory to spawn multiple controllers based on some common template.
Spawn an IPFS daemon from Node.js
// Create a factory to spawn two test disposable controllers, get access to an IPFS api
// print node ids and clean all the controllers from the factory.
const Ctl = require('ipfsd-ctl')
const factory = Ctl.createFactory(
{
type: 'js',
test: true,
disposable: true,
ipfsHttpModule,
ipfsModule: (await import('ipfs')) // only if you gonna spawn 'proc' controllers
},
{ // overrides per type
js: {
ipfsBin: ipfsModule.path()
},
go: {
ipfsBin: goIpfsModule.path()
}
}
)
const ipfsd1 = await factory.spawn() // Spawns using options from `createFactory`
const ipfsd2 = await factory.spawn({ type: 'go' }) // Spawns using options from `createFactory` but overrides `type` to spawn a `go` controller
console.log(await ipfsd1.api.id())
console.log(await ipfsd2.api.id())
await factory.clean() // Clean all the controllers created by the factory calling `stop` on all of them.
Spawn an IPFS daemon from the Browser using the provided remote endpoint
// Start a remote disposable node, and get access to the api
// print the node id, and stop the temporary daemon
const Ctl = require('ipfsd-ctl')
const port = 9090
const server = Ctl.createServer(port, {
ipfsModule,
ipfsHttpModule
},
{
js: {
ipfsBin: ipfsModule.path()
},
go: {
ipfsBin: goIpfsModule.path()
},
})
const factory = Ctl.createFactory({
ipfsHttpModule,
remote: true,
endpoint: `http://localhost:${port}` // or you can set process.env.IPFSD_CTL_SERVER to http://localhost:9090
})
await server.start()
const ipfsd = await factory.spawn()
const id = await ipfsd.api.id()
console.log(id)
await ipfsd.stop()
await server.stop()
ipfsd-ctl
can spawn disposable
and non-disposable
nodes.
disposable
- Disposable nodes are useful for tests or other temporary use cases, by default they create a temporary repo and automatically initialise and start the node, plus they cleanup everything when stopped.non-disposable
- Non disposable nodes will by default attach to any nodes running on the default or the supplied repo. Requires the user to initialize and start the node, as well as stop and cleanup afterwards.
Creates a factory that can spawn multiple controllers and pre-define options for them.
options
ControllerOptions Controllers options.overrides
ControllerOptionsOverrides Pre-defined options overrides per controller type.
Returns a Factory
Creates a controller.
options
ControllerOptions Factory options.
Returns Promise<Controller>
Create an Endpoint Server. This server is used by a client node to control a remote node. Example: Spawning a go-ipfs node from a browser.
options
[Object] Factory options. Defaults to:{ port: 43134 }
port
number Port to start the server on.
Returns a Server
Controller[] List of all the controllers spawned.
Create a temporary repo to create controllers manually.
Returns Promise<String> - Path to the repo.
Creates a controller for a IPFS node.
options
ControllerOptions Factory options.
Returns Promise<Controller>
Cleans all controllers spawned.
Returns Promise<Factory>
Class controller for a IPFS node.
options
ControllerOptions
String Repo path.
String Executable path.
Object ENV object.
Boolean Flag with the current init state.
Boolean Flag with the current start state.
Boolean Flag with the current clean state.
Multiaddr API address
Multiaddr Gateway address
Object IPFS core interface
Initialises controlled node
initOptions
[Object] IPFS init options https://github.com/ipfs/js-ipfs/blob/master/README.md#optionsinit
Returns Promise<Controller>
Starts controlled node.
Returns Promise<IPFS>
Stops controlled node.
Returns Promise<Controller>
Cleans controlled node, a disposable controller calls this automatically.
Returns Promise<Controller>
Get the pid of the controlled node process if aplicable.
Returns Promise<number>
Get the version of the controlled node.
Returns Promise<string>
Type: [Object]
js
[ControllerOptions] Pre-defined defaults options for JS controllers these are deep merged with options passed toFactory.spawn(options)
.go
[ControllerOptions] Pre-defined defaults options for Go controllers these are deep merged with options passed toFactory.spawn(options)
.proc
[ControllerOptions] Pre-defined defaults options for Proc controllers these are deep merged with options passed toFactory.spawn(options)
.
Type: [Object]
test
[boolean] Flag to activate custom config for tests.remote
[boolean] Use remote endpoint to spawn the nodes. Defaults totrue
when not in node.endpoint
[string] Endpoint URL to manage remote Controllers. (Defaults: 'http://localhost:43134').disposable
[boolean] A new repo is created and initialized for each invocation, as well as cleaned up automatically once the process exits.type
[string] The daemon type, see below the options:- go - spawn go-ipfs daemon
- js - spawn js-ipfs daemon
- proc - spawn in-process js-ipfs node
env
[Object] Additional environment variables, passed to executing shell. Only applies for Daemon controllers.args
[Array] Custom cli args.ipfsHttpModule
[Object] Reference to a IPFS HTTP Client object.ipfsModule
[Object] Reference to a IPFS API object.ipfsBin
[string] Path to a IPFS exectutable.ipfsOptions
[IpfsOptions] Options for the IPFS instance same as https://github.com/ipfs/js-ipfs#ipfs-constructor.proc
nodes receive these options as is, daemon nodes translate the options as far as possible to cli arguments.forceKill
[boolean] - Whether to use SIGKILL to quit a daemon that does not stop after.stop()
is called. (defaulttrue
)forceKillTimeout
[Number] - How long to wait before force killing a daemon in ms. (default5000
)
In additional to the API described in previous sections, ipfsd-ctl
also supports several environment variables. This are often very useful when running in different environments, such as CI or when doing integration/interop testing.
Environment variables precedence order is as follows. Top to bottom, top entry has highest precedence:
- command line options/method arguments
- env variables
- default values
Meaning that, environment variables override defaults in the configuration file but are superseded by options to df.spawn({...})
An alternative way of specifying the executable path for the js-ipfs
or go-ipfs
executable, respectively.
Feel free to join in. All welcome. Open an issue!
This repository falls under the IPFS Code of Conduct.
Licensed under either of
- Apache 2.0, (LICENSE-APACHE / http://www.apache.org/licenses/LICENSE-2.0)
- MIT (LICENSE-MIT / http://opensource.org/licenses/MIT)
Contributions welcome! Please check out the issues.
Also see our contributing document for more information on how we work, and about contributing in general.
Please be aware that all interactions related to this repo are subject to the IPFS Code of Conduct.
Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in the work by you, as defined in the Apache-2.0 license, shall be dual licensed as above, without any additional terms or conditions.