- Overview
- Minimum Recommended Skillset
- Required Reading
- Development Practices
4.1. Share Early, Share Often
4.2. Testing
4.3. Code Documentation and Commenting
4.4. Model Git Commit Messages - Code Approval Process
5.1 Code Review
5.2 Rework Code (if needed)
5.3 Acceptance - Contribution Standards
6.1. Contribution Checklist
6.2. Licensing of Contributions
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), RPC, and websockets. They also represent a radical shift to the current fiscal system and as a result provide an opportunity to help reshape the entire financial system. 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 btcd suite has a formalized and rigorous development process 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.
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.
- A reasonable understanding of bitcoin/blockchain and/or soter/blockdag at a high level (see the Required Reading section for the original white paper)
- 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.
- Effective Go - The entire soterd suite 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.
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.
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
- Incremental development helps ensure you are on the right track with regards to the rest of the community
- 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
One of the major design goals of all core soterd packages is to aim for complete test coverage. This is financial software so bugs and regressions 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 straight forward. 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
- 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
// convert a compact uint32 to big.Int
func CompactToBig(compact uint32) *big.Int {
RIGHT
// CompactToBig converts a compact representation of a whole number N to a
// big integer. The representation is similar to IEEE754 floating point
// numbers.
//
// Like IEEE754 floating point, there are three basic components: the sign,
// the exponent, and the mantissa. They are broken out as follows:
//
// * the most significant 8 bits represent the unsigned base 256 exponent
// * bit 23 (the 24th bit) represents the sign bit
// * the least significant 23 bits represent the mantissa
//
// -------------------------------------------------
// | Exponent | Sign | Mantissa |
// -------------------------------------------------
// | 8 bits [31-24] | 1 bit [23] | 23 bits [22-00] |
// -------------------------------------------------
//
// The formula to calculate N is:
// N = (-1^sign) * mantissa * 256^(exponent-3)
//
// This compact form is only used in bitcoin/soter to encode unsigned 256-bit numbers
// which represent difficulty targets, thus there really is not a need for a
// sign bit, but it is implemented here to stay consistent with bitcoind.
func CompactToBig(compact uint32) *big.Int {
- 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 5460
if amt < 5460 {
return err
}
RIGHT
// Treat transactions with amounts less than the amount which is considered dust
// as non-standard.
if amt < 5460 {
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.
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
Prefix the summary with the subsystem/package when possible. Many other projects make use of the code and this makes it easier for them to tell when something they're using has changed. Have a look at past commits for examples of commit messages.
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 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.
This section describes the code approval process that is used for code contributions. This is how to get your changes into soterd.
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.
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.
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
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.
This process will continue until the code is finally accepted.
Once your code is accepted, it will be integrated with the master branch. Typically it will be rebased and fast-forward merged to master as we prefer to keep a clean commit history over a tangled weave of merge commits. However, regardless of the specific merge method used, the code will be integrated with the master branch and the pull request will be closed.
Rejoice as you will now be listed as a contributor!
- [ ] All changes are Go version 1.3 compliant
- [ ] The code being submitted is commented according to the Code Documentation and Commenting section
- [ ] For new code: Code is accompanied by tests which exercise both the positive and negative (error paths) conditions (if applicable)
- [ ] For bug fixes: Code is accompanied by new tests which trigger the bug being fixed to prevent regressions
- [ ] Any new logging statements use an appropriate subsystem and logging level
- [ ] Code has been formatted with
go fmt
- [ ] Running
go test
does not fail any tests - [ ] Running
go vet
does not report any issues - [ ] Running golint does not report any new issues that did not already exist
All contributions must be licensed with the ISC license. This is the same license as all of the code in the soterd suite.