Core Lightning — Lightning Network implementation focusing on spec compliance and performance
Core Lightning (previously c-lightning) is a lightweight, highly customizable and standard compliant implementation of the Lightning Network protocol.
This implementation has been in production use on the Bitcoin mainnet since early 2018, with the launch of the Blockstream Store.
We recommend getting started by experimenting on testnet
(or regtest
), but the implementation is considered stable and can be safely used on mainnet.
Any help testing the implementation, reporting bugs, or helping with outstanding issues is very welcome.
Don’t hesitate to reach out to us on Build-on-L2, or on the implementation-specific mailing list, or on the Lightning Network-wide mailing list, or on CLN Discord, or on CLN Telegram, or on IRC at dev/gen channel.
Core Lightning only works on Linux and macOS, and requires a locally (or remotely) running bitcoind
(version 25.0 or above) that is fully caught up with the network you’re running on, and relays transactions (ie with blocksonly=0
).
Pruning (prune=n
option in bitcoin.conf
) is partially supported, see here for more details.
There are 3 supported installation options:
lightningd
If you want to experiment with lightningd
, there’s a script to set
up a bitcoind
regtest test network of two local lightning nodes,
which provides a convenient start_ln
helper. See the notes at the top
of the startup_regtest.sh
file for details on how to use it.
. contrib/startup_regtest.sh
To test with real bitcoin, you will need to have a local bitcoind
node running:
bitcoind -daemon
Wait until bitcoind
has synchronized with the network.
Make sure that you do not have walletbroadcast=0
in your ~/.bitcoin/bitcoin.conf
, or you may run into trouble.
Notice that running lightningd
against a pruned node may cause some issues if not managed carefully, see below for more information.
You can start lightningd
with the following command:
lightningd --network=bitcoin --log-level=debug
This creates a .lightning/
subdirectory in your home directory: see man -l doc/lightningd.8
(or https://docs.corelightning.org/docs) for more runtime options.
Core Lightning exposes a JSON-RPC 2.0 interface over a Unix Domain socket; the lightning-cli
tool can be used to access it, or there is a python client library.
You can use lightning-cli help
to print a table of RPC methods; lightning-cli help <command>
will offer specific information on that command.
Useful commands:
Once you’ve started for the first time, there’s a script called
contrib/bootstrap-node.sh
which will connect you to other nodes on
the lightning network.
There are also numerous plugins available for Core Lightning which add
capabilities: in particular there’s a collection at: https://github.com/lightningd/plugins
Including helpme which guides you through setting up
your first channels and customizing your node.
For a less reckless experience, you can encrypt the HD wallet seed:
see HD wallet encryption.
You can also chat to other users at Discord core-lightning;
we are always happy to help you get started!
First you need to transfer some funds to lightningd
so that it can
open a channel:
# Returns an address <address>
lightning-cli newaddr
lightningd
will register the funds once the transaction is confirmed.
Alternatively you can generate a taproot address should your source of funds support it:
# Return a taproot address
lightning-cli newaddr p2tr
Confirm lightningd
got funds by:
# Returns an array of on-chain funds.
lightning-cli listfunds
Once lightningd
has funds, we can connect to a node and open a channel.
Let’s assume the remote node is accepting connections at <ip>
(and optional <port>
, if not 9735) and has the node ID <node_id>
:
lightning-cli connect <node_id> <ip> [<port>]
lightning-cli fundchannel <node_id> <amount_in_satoshis>
This opens a connection and, on top of that connection, then opens a channel.
The funding transaction needs 3 confirmation in order for the channel to be usable, and 6 to be announced for others to use.
You can check the status of the channel using lightning-cli listpeers
, which after 3 confirmations (1 on testnet) should say that state
is CHANNELD_NORMAL
; after 6 confirmations you can use lightning-cli listchannels
to verify that the public
field is now true
.
Payments in Lightning are invoice based.
The recipient creates an invoice with the expected <amount>
in
millisatoshi (or "any"
for a donation), a unique <label>
and a
<description>
the payer will see:
lightning-cli invoice <amount> <label> <description>
This returns some internal details, and a standard invoice string called bolt11
(named after the BOLT #11 lightning spec).
The sender can feed this bolt11
string to the decodepay
command to see what it is, and pay it simply using the pay
command:
lightning-cli pay <bolt11>
Note that there are lower-level interfaces (and more options to these
interfaces) for more sophisticated use.
lightningd
can be configured either by passing options via the command line, or via a configuration file.
Command line options will always override the values in the configuration file.
To use a configuration file, create a file named config
within your top-level lightning directory or network subdirectory
(eg. ~/.lightning/config
or ~/.lightning/bitcoin/config
). See man -l doc/lightningd-config.5
.
A sample configuration file is available at contrib/config-example
.
Core Lightning requires JSON-RPC access to a fully synchronized bitcoind
in order to synchronize with the Bitcoin network.
Access to ZeroMQ is not required and bitcoind
does not need to be run with txindex
like other implementations.
The lightning daemon will poll bitcoind
for new blocks that it hasn’t processed yet, thus synchronizing itself with bitcoind
.
If bitcoind
prunes a block that Core Lightning has not processed yet, e.g., Core Lightning was not running for a prolonged period, then bitcoind
will not be able to serve the missing blocks, hence Core Lightning will not be able to synchronize anymore and will be stuck.
In order to avoid this situation you should be monitoring the gap between Core Lightning’s blockheight using lightning-cli getinfo
and bitcoind
’s blockheight using bitcoin-cli getblockchaininfo
.
If the two blockheights drift apart it might be necessary to intervene.
You can encrypt the hsm_secret
content (which is used to derive the HD wallet’s master key) by passing the --encrypted-hsm
startup argument, or by using the hsmtool
(which you can find in the tool/
directory at the root of this repo) with the encrypt
method. You can unencrypt an encrypted hsm_secret
using the hsmtool
with the decrypt
method.
If you encrypt your hsm_secret
, you will have to pass the --encrypted-hsm
startup option to lightningd
. Once your hsm_secret
is encrypted, you will not be able to access your funds without your password, so please beware with your password management. Also, beware of not feeling too safe with an encrypted hsm_secret
: unlike for bitcoind
where the wallet encryption can restrict the usage of some RPC command, lightningd
always needs to access keys from the wallet which is thus not locked (yet), even with an encrypted BIP32 master seed.
Developers wishing to contribute should start with the developer guide here.