lnd/docs/code_contribution_guidelines.md

Table of Contents

1. Overview
2. Minimum Recommended Skillset
3. Required Reading
4. Development Practices
   1. Share Early, Share Often
   2. Testing
   3. Code Documentation and Commenting
   4. Model Git Commit Messages
   5. Ideal Git Commit Structure
   6. Sign Your Git Commits
   7. Code Spacing and formatting
   8. Pointing to Remote Dependent Branches in Go Modules
   9. Use of Log Levels
   10. Use of Golang submodules
5. Code Approval Process
   1. Code Review
   2. Rework Code (if needed)
   3. Acceptance
   4. Review Bot
6. Contribution Standards
   1. Contribution Checklist
   2. Licensing of Contributions

Overview

Developing cryptocurrencies is an exciting endeavor that touches a wide variety of areas such as wire protocols, peer-to-peer networking, databases, cryptography, language interpretation (transaction scripts), adversarial threat-modeling, and RPC systems. They also represent a radical shift to the current monetary system and as a result provide an opportunity to help reshape the entire financial system. With the advent of the Lightning Network (LN), new layers are being constructed upon the base blockchain layer which have the potential to alleviate many of the limitations and constraints inherent in the design of blockchains. There are few projects that offer this level of diversity and impact all in one code base.

However, as exciting as it is, one must keep in mind that cryptocurrencies represent real money and introducing bugs and security vulnerabilities can have far more dire consequences than in typical projects where having a small bug is minimal by comparison. In the world of cryptocurrencies, even the smallest bug in the wrong area can cost people a significant amount of money. For this reason, the Lightning Network Daemon (lnd) has a formalized and rigorous development process (heavily inspired by btcsuite) which is outlined on this page.

We highly encourage code contributions, however it is imperative that you adhere to the guidelines established on this page.

Minimum Recommended Skillset

The following list is a set of core competencies that we recommend you possess before you really start attempting to contribute code to the project. These are not hard requirements as we will gladly accept code contributions as long as they follow the guidelines set forth on this page. That said, if you don't have the following basic qualifications you will likely find it quite difficult to contribute to the core layers of Lightning. However, there are still a number of low hanging fruit which can be tackled without having full competency in the areas mentioned below.

• A reasonable understanding of bitcoin at a high level (see the Required Reading section for the original white paper)
• A reasonable understanding of the Lightning Network at a high level
• Experience in some type of C-like language
• An understanding of data structures and their performance implications
• Familiarity with unit testing
• Debugging experience
• Ability to understand not only the area you are making a change in, but also the code your change relies on, and the code which relies on your changed code

Building on top of those core competencies, the recommended skill set largely depends on the specific areas you are looking to contribute to. For example, if you wish to contribute to the cryptography code, you should have a good understanding of the various aspects involved with cryptography such as the security and performance implications.

Required Reading

• Effective Go - The entire lnd project follows the guidelines in this document. For your code to be accepted, it must follow the guidelines therein.
• Original Satoshi Whitepaper - This is the white paper that started it all. Having a solid foundation to build on will make the code much more comprehensible.
• Lightning Network Whitepaper - This is the white paper that kicked off the Layer 2 revolution. Having a good grasp of the concepts of Lightning will make the core logic within the daemon much more comprehensible: Bitcoin Script, off-chain blockchain protocols, payment channels, bi-directional payment channels, relative and absolute time-locks, commitment state revocations, and Segregated Witness.
  • The original LN was written for a rather narrow audience, the paper may be a bit unapproachable to many. Thanks to the Bitcoin community, there exist many easily accessible supplemental resources which can help one see how all the pieces fit together from double-spend protection all the way up to commitment state transitions and Hash Time Locked Contracts (HTLCs):
    • Lightning Network Summary
    • Understanding the Lightning Network 3-Part series
    • Deployable Lightning

Note that the core design of the Lightning Network has shifted over time as concrete implementation and design has expanded our knowledge beyond the original white paper. Therefore, specific information outlined in the resources above may be a bit out of date. Many implementers are currently working on an initial Lightning Network Specifications. Once the specification is finalized, it will be the most up-to-date comprehensive document explaining the Lightning Network. As a result, it will be recommended for newcomers to read first in order to get up to speed.

Development Practices

Developers are expected to work in their own trees and submit pull requests when they feel their feature or bug fix is ready for integration into the master branch.

Share Early, Share Often

We firmly believe in the share early, share often approach. The basic premise of the approach is to announce your plans before you start work, and once you have started working, craft your changes into a stream of small and easily reviewable commits.

This approach has several benefits:

• Announcing your plans to work on a feature before you begin work avoids duplicate work
• It permits discussions which can help you achieve your goals in a way that is consistent with the existing architecture
• It minimizes the chances of you spending time and energy on a change that might not fit with the consensus of the community or existing architecture and potentially be rejected as a result
• The quicker your changes are merged to master, the less time you will need to spend rebasing and otherwise trying to keep up with the main code base

Testing

One of the major design goals of all of lnd's packages and the daemon itself is to aim for a high degree of test coverage. This is financial software so bugs and regressions in the core logic can cost people real money. For this reason every effort must be taken to ensure the code is as accurate and bug-free as possible. Thorough testing is a good way to help achieve that goal.

Unless a new feature you submit is completely trivial, it will probably be rejected unless it is also accompanied by adequate test coverage for both positive and negative conditions. That is to say, the tests must ensure your code works correctly when it is fed correct data as well as incorrect data (error paths).

Go provides an excellent test framework that makes writing test code and checking coverage statistics straightforward. For more information about the test coverage tools, see the golang cover blog post.

A quick summary of test practices follows:

• All new code should be accompanied by tests that ensure the code behaves correctly when given expected values, and, perhaps even more importantly, that it handles errors gracefully
• When you fix a bug, it should be accompanied by tests which exercise the bug to both prove it has been resolved and to prevent future regressions
• Changes to publicly exported packages such as brontide should be accompanied by unit tests exercising the new or changed behavior.
• Changes to behavior within the daemon's interaction with the P2P protocol, or RPC's will need to be accompanied by integration tests which use the networkHarnessframework contained within lnd. For example integration tests, see lnd_test.go.
• The itest log files are automatically scanned for [ERR] lines. There shouldn't be any of those in the logs, see Use of Log Levels.

Throughout the process of contributing to lnd, you'll likely also be extensively using the commands within our Makefile. As a result, we recommend perusing the make file documentation.

Code Documentation and Commenting

• At a minimum every function must be commented with its intended purpose and any assumptions that it makes
  • Function comments must always begin with the name of the function per Effective Go
  • Function comments should be complete sentences since they allow a wide variety of automated presentations such as godoc.org
  • The general rule of thumb is to look at it as if you were completely unfamiliar with the code and ask yourself, would this give me enough information to understand what this function does and how I'd probably want to use it?
• Exported functions should also include detailed information the caller of the function will likely need to know and/or understand:
  
  

WRONG

// generates a revocation key
func DeriveRevocationPubkey(commitPubKey *btcec.PublicKey,
	revokePreimage []byte) *btcec.PublicKey {

RIGHT

// DeriveRevocationPubkey derives the revocation public key given the
// counterparty's commitment key, and revocation preimage derived via a
// pseudo-random-function. In the event that we (for some reason) broadcast a
// revoked commitment transaction, then if the other party knows the revocation
// preimage, then they'll be able to derive the corresponding private key to
// this private key by exploiting the homomorphism in the elliptic curve group:
//    * https://en.wikipedia.org/wiki/Group_homomorphism#Homomorphisms_of_abelian_groups
//
// The derivation is performed as follows:
//
//   revokeKey := commitKey + revokePoint
//             := G*k + G*h
//             := G * (k+h)
//
// Therefore, once we divulge the revocation preimage, the remote peer is able to
// compute the proper private key for the revokeKey by computing:
//   revokePriv := commitPriv + revokePreimge mod N
//
// Where N is the order of the sub-group.
func DeriveRevocationPubkey(commitPubKey *btcec.PublicKey,
	revokePreimage []byte) *btcec.PublicKey {

• Comments in the body of the code are highly encouraged, but they should explain the intention of the code as opposed to just calling out the obvious
  
  

WRONG

// return err if amt is less than 546
if amt < 546 {
	return err
}

RIGHT

// Treat transactions with amounts less than the amount which is considered dust
// as non-standard.
if amt < 546 {
	return err
}

NOTE: The above should really use a constant as opposed to a magic number, but it was left as a magic number to show how much of a difference a good comment can make.

Code Spacing and formatting

Code in general (and Open Source code specifically) is read by developers many more times during its lifecycle than it is modified. With this fact in mind, the Golang language was designed for readability (among other goals). While the enforced formatting of go fmt and some best practices already eliminate many discussions, the resulting code can still look and feel very differently among different developers.

We aim to enforce a few additional rules to unify the look and feel of all code in lnd to help improve the overall readability.

Please refer to the code formatting rules document to see the list of additional style rules we enforce.

Model Git Commit Messages

This project prefers to keep a clean commit history with well-formed commit messages. This section illustrates a model commit message and provides a bit of background for it. This content was originally created by Tim Pope and made available on his website, however that website is no longer active, so it is being provided here.

Here’s a model Git commit message:

Short (50 chars or less) summary of changes

More detailed explanatory text, if necessary.  Wrap it to about 72
characters or so.  In some contexts, the first line is treated as the
subject of an email and the rest of the text as the body.  The blank
line separating the summary from the body is critical (unless you omit
the body entirely); tools like rebase can get confused if you run the
two together.

Write your commit message in the present tense: "Fix bug" and not "Fixed
bug."  This convention matches up with commit messages generated by
commands like git merge and git revert.

Further paragraphs come after blank lines.

- Bullet points are okay, too
- Typically a hyphen or asterisk is used for the bullet, preceded by a
  single space, with blank lines in between, but conventions vary here
- Use a hanging indent

Here are some of the reasons why wrapping your commit messages to 72 columns is a good thing.

• git log doesn't do any special wrapping of the commit messages. With the default pager of less -S, this means your paragraphs flow far off the edge of the screen, making them difficult to read. On an 80 column terminal, if we subtract 4 columns for the indent on the left and 4 more for symmetry on the right, we’re left with 72 columns.
• git format-patch --stdout converts a series of commits to a series of emails, using the messages for the message body. Good email netiquette dictates we wrap our plain text emails such that there’s room for a few levels of nested reply indicators without overflow in an 80 column terminal.

In addition to the Git commit message structure adhered to within the daemon all short-commit messages are to be prefixed according to the convention outlined in the Go project. All commits should begin with the subsystem or package primarily affected by the change. In the case of a widespread change, the packages are to be delimited by either a '+' or a ','. This prefix seems minor but can be extremely helpful in determining the scope of a commit at a glance, or when bug hunting to find a commit which introduced a bug or regression.

Ideal Git Commit Structure

Within the project we prefer small, contained commits for a pull request over a single giant commit that touches several files/packages. Ideal commits build on their own, in order to facilitate easy usage of tools like git bisect to git cherry-pick. It's preferred that commits contain an isolated change in a single package. In this case, the commit header message should begin with the prefix of the modified package. For example, if a commit was made to modify the lnwallet package, it should start with lnwallet: .

In the case of changes that only build in tandem with changes made in other packages, it is permitted for a single commit to be made which contains several prefixes such as: lnwallet+htlcswitch. This prefix structure along with the requirement for atomic contained commits (when possible) make things like scanning the set of commits and debugging easier. In the case of changes that touch several packages, and can only compile with the change across several packages, a multi: prefix should be used.

Examples of common patterns w.r.t commit structures within the project:

• It is common that during the work on a PR, existing bugs are found and fixed. If they can be fixed in isolation, they should have their own commit.
• File restructuring like moving a function to another file or changing order of functions: with a separate commit because it is much easier to review the real changes that go on top of the restructuring.
• Preparatory refactorings that are functionally equivalent: own commit.
• Project or package wide file renamings should be in their own commit.
• Ideally if a new package/struct/sub-system is added in a PR, there should be a single commit which adds the new functionality, with follow up individual commits that begin to integrate the functionality within the codebase.
• If a PR only fixes a trivial issue, such as updating documentation on a small scale, fix typos, or any changes that do not modify the code, the commit message should end with [skip ci] to skip the CI checks.

Sign your git commits

When contributing to lnd it is recommended to sign your git commits. This is easy to do and will help in assuring the integrity of the tree. See mailing list entry for more information.

How to sign your commits?

Provide the -S flag (or --gpg-sign) to git commit when you commit your changes, for example

$  git commit -m "Commit message" -S

Optionally you can provide a key id after the -S option to sign with a specific key.

To instruct git to auto-sign every commit, add the following lines to your ~/.gitconfig file:

[commit]
        gpgsign = true

What if I forgot?

You can retroactively sign your previous commit using --amend, for example

$  git commit -S --amend

If you need to go further back, you can use the interactive rebase command with 'edit'. Replace HEAD~3 with the base commit from which you want to start.

$  git rebase -i HEAD~3

Replace 'pick' by 'edit' for the commit that you want to sign and the rebasing will stop after that commit. Then you can amend the commit as above. Afterwards, do

$  git rebase --continue

As this will rewrite history, you cannot do this when your commit is already merged. In that case, too bad, better luck next time.

If you rewrite history for another reason - for example when squashing commits - make sure that you re-sign as the signatures will be lost.

Multiple commits can also be re-signed with git rebase. For example, signing the last three commits can be done with:

$  git rebase --exec 'git commit --amend --no-edit -n -S' -i HEAD~3

How to check if commits are signed?

Use git log with --show-signature,

$  git log --show-signature

You can also pass the --show-signature option to git show to check a single commit.

Pointing to Remote Dependent Branches in Go Modules

It's common that a developer may need to make a change in a dependent project of lnd such as btcd, neutrino, btcwallet, etc. In order to test changes without testing infrastructure, or simply make a PR into lnd that will build without any further work, the go.mod and go.sum files will need to be updated. Luckily, the go mod command has a handy tool to do this automatically so developers don't need to manually edit the go.mod file:

$  go mod edit -replace=IMPORT-PATH-IN-LND@LND-VERSION=DEV-FORK-IMPORT-PATH@DEV-FORK-VERSION

Here's an example replacing the lightning-onion version checked into lnd with a version in roasbeef's fork:

$  go mod edit -replace=github.com/lightningnetwork/lightning-onion@v0.0.0-20180605012408-ac4d9da8f1d6=github.com/roasbeef/lightning-onion@2e5ae87696046298365ab43bcd1cf3a7a1d69695

Use of Log Levels

There are six log levels available: trace, debug, info, warn, error and critical.

Only use error for internal errors that are never expected to happen during normal operation. No event triggered by external sources (rpc, chain backend, etc) should lead to an error log.

Use of Golang submodules

Changes to packages that are their own submodules (e.g. they contain a go.mod and go.sum file, for example tor/go.mod) require a specific process. We want to avoid the use of local replace directives in the root go.mod, therefore changes to a submodule are a bit involved.

The main process for updating and then using code in a submodule is as follows:

• Create a PR for the changes to the submodule itself (e.g. edit something in the tor package)
• Wait for the PR to be merged and a new tag (for example tor/v1.0.x) to be pushed.
• Create a second PR that bumps the updated submodule in the root go.mod and uses the new functionality in the main module.

Of course the two PRs can be opened at the same time and be built on top of each other. But the merge and tag push order should always be maintained.

Code Approval Process

This section describes the code approval process that is used for code contributions. This is how to get your changes into lnd.

Code Review

All code which is submitted will need to be reviewed before inclusion into the master branch. This process is performed by the project maintainers and usually other committers who are interested in the area you are working in as well.

Code Review Timeframe

The timeframe for a code review will vary greatly depending on factors such as the number of other pull requests which need to be reviewed, the size and complexity of the contribution, how well you followed the guidelines presented on this page, and how easy it is for the reviewers to digest your commits. For example, if you make one monolithic commit that makes sweeping changes to things in multiple subsystems, it will obviously take much longer to review. You will also likely be asked to split the commit into several smaller, and hence more manageable, commits.

Keeping the above in mind, most small changes will be reviewed within a few days, while large or far reaching changes may take weeks. This is a good reason to stick with the Share Early, Share Often development practice outlined above.

What is the review looking for?

The review is mainly ensuring the code follows the Development Practices and Code Contribution Standards. However, there are a few other checks which are generally performed as follows:

• The code is stable and has no stability or security concerns
• The code is properly using existing APIs and generally fits well into the overall architecture
• The change is not something which is deemed inappropriate by community consensus

Rework Code (if needed)

After the code review, the change will be accepted immediately if no issues are found. If there are any concerns or questions, you will be provided with feedback along with the next steps needed to get your contribution merged with master. In certain cases the code reviewer(s) or interested committers may help you rework the code, but generally you will simply be given feedback for you to make the necessary changes.

During the process of responding to review comments, we prefer that changes be made with fixup commits. The reason for this is two fold: it makes it easier for the reviewer to see what changes have been made between versions (since Github doesn't easily show prior versions like Critique) and it makes it easier on the PR author as they can set it to auto squash the fix up commits on rebase.

This process will continue until the code is finally accepted.

Acceptance

Before your code is accepted, the release notes we keep in-tree for the next upcoming milestone should be extended to describe the changes contained in your PR. Unless otherwise mentioned by the reviewers of your PR, the description of your changes should live in the document set for the next major release.

Once your code is accepted, it will be integrated with the master branch. After 2+ (sometimes 1) LGTM's (approvals) are given on a PR, it's eligible to land in master. At this final phase, it may be necessary to rebase the PR in order to resolve any conflicts and also squash fix up commits. Ideally, the set of commits by new contributors are PGP signed, although this isn't a strong requirement (but we prefer it!). In order to keep these signatures intact, we prefer using merge commits. PR proposers can use git rebase --signoff to sign and rebase at the same time as a final step.

Rejoice as you will now be listed as a contributor!

Review Bot

In order to keep the review flow going, Lightning Labs uses a bot to remind PR reviewers about their outstanding reviews or to remind authors to address recent reviews. Here are some important things to know about the bot and some controls for adjusting its behaviour:

####🤖 Expected Behaviour:

• The bot will not do anything if your PR is in draft mode.
• It will ping a pending reviewer if they have not reviewed or commented on the PR in x days since the last update or the last time the bot pinged them. (default x = 3)
• It will ping the author of the PR if they have not addressed a review on a PR after x days since last review or the last time the bot pinged them. It will also ping them to remind them to re-request review if needed. (default x = 3)

####🤖 Controls: To control the bot, you need to add a comment on the PR starting with !lightninglabs-deploy followed by the command. There are 2 control types: mute/unmute & cadence. Only the latest comment for each control type will be used. This also means you dont need to keep adding new control comments, just edit the latest comment for that control type.

• !lightninglabs-deploy mute will mute the bot on the PR completely.
• !lightninglabs-deploy mute 72h30m will mute the bot for the given duration.
• !lightninglabs-deploy mute 2022-Feb-02 will mute the bot until the given date (must be in this format!).
• !lightninglabs-deploy mute #4 will mute the bot until the given PR of the same repo has been merged.
• !lightninglabs-deploy unmute will unmute the bot (or just delete the comment that was muting it)
• !lightninglabs-deploy cadence 60h change the cadence of the bot from the default of 3 days to the given duration.
• it will auto-mute if the PR is in Draft mode

Contribution Standards

Contribution Checklist

See template.

Licensing of Contributions

---

All contributions must be licensed with the MIT license. This is the same license as all of the code found within lnd.

Acknowledgements

This document was heavily inspired by a similar document outlining the code contribution guidelines for btcd.