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# Developing Oragono
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Most development happens on the `develop` branch, which is occasionally rebased + merged into `master` when it's not incredibly broken. When this happens, the `develop` branch is usually pruned until I feel like making 'unsafe' changes again.
2017-01-17 22:30:48 +01:00
I may also name the branch `develop+feature` if I'm developing multiple, or particularly unstable, features.
The intent is to keep `master` relatively stable.
## Releasing a new version
1. Ensure dependencies are up-to-date.
2. Run [`irctest`]() over it to make sure nothing's severely broken.
3. Remove `-unreleased` from the version number in `irc/constants.go`.
4. Update the changelog with new changes.
5. Remove unused sections from the changelog, change the date/version number and write release notes.
6. Commit the new changelog and constants change.
7. Tag the release with `git tag v0.0.0 -m "Release v0.0.0"` (`0.0.0` replaced with the real ver number).
8. Build binaries using the Makefile, upload release to Github including the changelog and binaries.
Once it's built and released, you need to setup the new development version. To do so:
1. In `irc/constants.go`, update the version number to `0.0.1-unreleased`, where `0.0.1` is the previous release number with the minor field incremented by one (for instance, `0.9.2` -> `0.9.3-unreleased`).
2. At the top of the changelog, paste a new section with the content below.
3. Commit the new version number and changelog with the message `"Setup v0.0.1-unreleased devel ver"`.
**Unreleased changelog content**
```md
## Unreleased
New release of Oragono!
### Config Changes
### Security
### Added
### Changed
### Removed
### Fixed
```
## Updating `vendor/`
The `vendor/` directory holds our dependencies. When we import new repos, we need to update this folder to contain these new deps. This is something that I'll mostly be handling.
To update this folder:
1. Install https://github.com/golang/dep
2. `cd` to Oragono folder
3. `dep ensure -update`
4. `cd vendor`
5. Commit the changes with the message `"Updated packages"`
6. `cd ..`
4. Commit the result with the message `"vendor: Updated submodules"`
This will make sure things stay nice and up-to-date for users.
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## Fuzzing and Testing
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Fuzzing can be useful. We don't have testing done inside the IRCd itself, but this fuzzer I've written works alright and has helped shake out various bugs: [irc_fuzz.py](https://gist.github.com/DanielOaks/63ae611039cdf591dfa4).
In addition, I've got the beginnings of a stress-tester here which is useful:
https://github.com/DanielOaks/irc-stress-test
As well, there's a decent set of 'tests' here, which I like to run Oragono through now and then:
https://github.com/DanielOaks/irctest
## Debugging Hangs
To debug a hang, the best thing to do is to get a stack trace. Go's nice, and you can do so by running this:
$ kill -ABRT <procid>
This will kill Oragono and print out a stack trace for you to take a look at.
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## Concurrency design
Oragono involves a fair amount of shared state. Here are some of the main points:
1. Each client has a separate goroutine that listens for incoming messages and synchronously processes them.
1. All sends to clients are asynchronous; `client.Send` appends the message to a queue, which is then processed on a separate goroutine. It is always safe to call `client.Send`.
1. The server has a few of its own goroutines, for listening on sockets and handing off new client connections to their dedicated goroutines.
1. A few tasks are done asynchronously in ad-hoc goroutines.
In consequence, there is a lot of state (in particular, server and channel state) that can be read and written from multiple goroutines. This state is protected with mutexes. To avoid deadlocks, mutexes are arranged in "tiers"; while holding a mutex of one tier, you're only allowed to acquire mutexes of a strictly *higher* tier. The tiers are:
1. Tier 1 mutexes: these are the "innermost" mutexes. They typically protect getters and setters on objects, or invariants that are local to the state of a single object. Example: `Channel.stateMutex`.
1. Tier 2 mutexes: these protect some invariants of their own, but also need to access fields on other objects that themselves require synchronization. Example: `ChannelManager.RWMutex`.
1. Tier 3 mutexes: these protect macroscopic operations, where it doesn't make sense for more than one to occur concurrently. Example; `Server.rehashMutex`, which prevents rehashes from overlapping.
There are some mutexes that are "tier 0": anything in a subpackage of `irc` (e.g., `irc/logger` or `irc/connection_limits`) shouldn't acquire mutexes defined in `irc`.
We are using `buntdb` for persistence; a `buntdb.DB` has an `RWMutex` inside it, with read-write transactions getting the `Lock()` and read-only transactions getting the `RLock()`. We haven't completely decided where this lock fits into the overall lock model. For now, it's probably better to err on the side of caution: if possible, don't acquire new locks inside the `buntdb` transaction, and be careful about what locks are held around the transaction as well.