We follow the standard GitHub fork & pull approach to pull requests. Just fork the official repo, develop in a branch, and submit a PR!
You're always welcome to submit your PR straight away and start the discussion (without reading the rest of this wonderful doc, or the README.md). The goal of these notes is to make your experience contributing to Akka as smooth and pleasant as possible. We're happy to guide you through the process once you've submitted your PR.
In case of questions about the contribution process or for discussion of specific issues please visit the akka/dev gitter chat.
You may also check out these other resources.
Depending on which version (or sometimes module) you want to work on, you should target a specific branch as explained below:
master
– active development branch of Akka 2.6.xrelease-2.5
– maintenance branch of Akka 2.5.x- similarly
release-2.#
branches contain legacy versions of Akka
Akka uses tags to categorise issues into groups or mark their phase in development.
Most notably many tags start with a t:
prefix (as in topic:
), which categorises issues in terms of which module they relate to. Examples are:
In general all issues are open for anyone working on them, however if you're new to the project and looking for an issue that will be accepted and likely is a nice one to get started you should check out the following tags:
- good first issue - which identifies simple entry level tickets, such as improvements of documentation or tests. If you're not sure how to solve a ticket but would like to work on it feel free to ask in the issue about clarification or tips.
- help wanted - which identifies issues that the core team will likely not have time to work on, or the issue is a nice entry level ticket. If you're not sure how to solve a ticket but would like to work on it feel free to ask in the issue about clarification or tips.
- nice-to-have (low-priority) - are tasks which make sense, however are not very high priority (in face of other very high priority issues). If you see something interesting in this list, a contribution would be really wonderful!
Another group of tickets are those which start from a number. They're used to signal in what phase of development an issue is:
- 0 - new - is assigned when a ticket is unclear on its purpose or if it is valid or not. Sometimes the additional tag
discuss
is used to mark such tickets, if they propose large scale changes and need more discussion before moving into triaged (or being closed as invalid). - 1 - triaged - roughly speaking means "this ticket makes sense". Triaged tickets are safe to pick up for contributing in terms of likeliness of a patch for it being accepted. It is not recommended to start working on a ticket that is not triaged.
- 2 - pick next - used to mark issues which are next up in the queue to be worked on. Sometimes it's also used to mark which PRs are expected to be reviewed/merged for the next release. The tag is non-binding, and mostly used as an organisational helper.
- 3 - in progress - means someone is working on this ticket. If you see a ticket that has the tag, however seems inactive, it could have been an omission with removing the tag, feel free to ping the ticket then if it's still being worked on.
The last group of special tags indicate specific states a ticket is in:
- bug tickets indicate potential production issues. Bugs take priority in being fixed above features. The core team dedicates a number of days to working on bugs each sprint. Bugs which have reproducers are also great for community contributions as they're well-isolated. Sometimes we're not as lucky to have reproducers though, then a bugfix should also include a test reproducing the original error along with the fix.
- failed tickets indicate a Jenkins failure (for example from a nightly build). These tickets usually include a stacktrace + link to the Jenkins failure, and we'll add a comment when we see the same problem again. Since these tickets can either indicate tests with incorrect assumptions or legitimate issues in the production code we look at them periodically. When the same problem isn't seen again over a period of 6 months we assume it to be a rare flaky test or a problem that might have since been fixed, so we close the issue until it pops up again.
Pull request validation states:
validating => [tested | needs-attention]
- signify pull request validation status.
These guidelines apply to all Akka projects, by which we mean both the akka/akka
repository,
as well as any plugins or additional repositories located under the Akka GitHub organisation.
These guidelines are meant to be a living document that should be changed and adapted as needed. We encourage changes that make it easier to achieve our goals in an efficient way.
The steps below describe how to get a patch into a main development branch (e.g. master
).
The steps are exactly the same for everyone involved in the project (be it core team, or first time contributor).
- To avoid duplicated effort, it might be good to check the issue tracker and existing pull requests for existing work.
- If there is no ticket yet, feel free to create one to discuss the problem and the approach you want to take to solve it.
- Fork the project on GitHub. You'll need to create a feature-branch for your work on your fork, as this way you'll be able to submit a pull request against the mainline Akka.
- Create a branch on your fork and work on the feature. For example:
git checkout -b custom-headers-akka-http
- Please make sure to follow the general quality guidelines (specified below) when developing your patch.
- Please write additional tests covering your feature and adjust existing ones if needed before submitting your pull request. The
validatePullRequest
sbt task (explained below) may come in handy to verify your changes are correct.
- Once your feature is complete, prepare the commit following our Creating Commits And Writing Commit Messages. For example, a good commit message would be:
Adding compression support for Manifests #22222
(note the reference to the ticket it aimed to resolve). - If it's a new feature, or a change of behavior, document it on the akka-docs. If the feature was touching Scala or Java DSL, make sure to document both the Scala and Java APIs.
- Now it's finally time to submit the pull request!
- Please make sure to include a reference to the issue you're solving in the comment for the Pull Request, as this will cause the PR to be linked properly with the Issue. Examples of good phrases for this are: "Resolves #1234" or "Refs #1234".
- If you have not already done so, you will be asked by our CLA bot to sign the Lightbend CLA online. CLA stands for Contributor License Agreement and is a way of protecting intellectual property disputes from harming the project.
- A core member will comment
OK TO TEST
on your PR to kick off the build. This is just a sanity check to prevent malicious code from being run on the Jenkins cluster. - Now both committers and interested people will review your code. This process is to ensure the code we merge is of the best possible quality, and that no silly mistakes slip through. You're expected to follow-up these comments by adding new commits to the same branch. The commit messages of those commits can be more loose, for example:
Removed debugging using printline
, as they all will be squashed into one commit before merging into the main branch.- The community and team are really nice people, so don't be afraid to ask follow up questions if you didn't understand some comment, or would like clarification on how to continue with a given feature. We're here to help, so feel free to ask and discuss any kind of questions you might have during review!
- After the review you should fix the issues as needed (pushing a new commit for new review etc.), iterating until the reviewers give their thumbs up–which is signalled usually by a comment saying
LGTM
, which means "Looks Good To Me".- In general a PR is expected to get 2 LGTMs from the team before it is merged. If the PR is trivial, or under special circumstances (such as most of the team being on vacation, a PR was very thoroughly reviewed/tested and surely is correct) one LGTM may be fine as well.
- If the code change needs to be applied to other branches as well (for example a bugfix needing to be backported to a previous version), one of the team will either ask you to submit a PR with the same commit to the old branch, or do this for you.
- Follow the backporting steps below.
- Once everything is said and done, your pull request gets merged 🎉 Your feature will be available with the next “earliest” release milestone (i.e. if back-ported so that it will be in release x.y.z, find the relevant milestone for that release). And of course you will be given credit for the fix in the release stats during the release's announcement. You've made it!
The TL;DR; of the above very precise workflow version is:
- Fork Akka
- Hack and test on your feature (on a branch)
- Document it
- Submit a PR
- Sign the CLA if necessary
- Keep polishing it until received enough LGTM
- Profit!
Backport pull requests such as these are marked using the phrase for validation
in the title to make the purpose clear in the pull request list.
They can be merged once validation passes without additional review (if there are no conflicts).
Using, for example: current.version 2.5.22, previous.version 2.5, milestone.version 2.6.0-M1
- Label this PR with
to-be-backported
- Mark this PR with Milestone
${milestone.version}
- Mark the issue with Milestone
${current.version}
git checkout release-${previous.version}
git pull
- Create wip branch
git cherry-pick <commit>
- Open PR, target
release-${previous.version}
- Label that PR with
backport
- Merge backport PR after validation (no need for full PR reviews)
- Close issue
Akka is using the sbt build system. So the first thing you have to do is to download and install sbt. You can read more about how to do that in the sbt setup documentation.
To compile all the Akka core modules use the compile
command:
sbt compile
You can run all tests with the test
command:
sbt test
If you want to deploy the artifacts to your local Ivy repository (for example,
to use from an sbt project) use the publishLocal
command:
sbt publishLocal
Note that in the examples above we are calling sbt compile
and sbt test
and so on, but sbt also has an interactive mode. If you just run sbt
you
enter the interactive sbt prompt and can enter the commands directly. This saves
starting up a new JVM instance for each command and can be much faster and more
convenient.
For example, building Akka as above is more commonly done like this:
% sbt
[info] Set current project to default (in build file:/.../akka/project/plugins/)
[info] Set current project to akka (in build file:/.../akka/)
> compile
...
> test
...
To run a single multi-jvm test:
sbt
project akka-cluster
multi-jvm:testOnly akka.cluster.SunnyWeather
To format the Scala source code:
sbt
akka-cluster/scalafmtAll
akka-persistence/scalafmtAll
Akka has not been compiled or tested with -optimize
Scala compiler flag. (In sbt, you can specify compiler options in the scalacOptions
key.)
Strange behavior has been reported by users that have tried it.
Akka, like most Scala projects, compiles faster with the Graal JIT enabled. The easiest way to use it for compiling Akka is to:
- Use a JDK > 10
- Use the following JVM options for SBT e.g. by adding them to the
SBT_OPTS
environment variable:-XX:+UnlockExperimentalVMOptions -XX:+EnableJVMCI -XX:+UseJVMCICompiler
The Akka build includes a special task called validatePullRequest
which investigates the changes made as well as dirty
(uncommitted changes) in your local working directory and figures out which projects are impacted by those changes,
then running tests only on those projects.
For example changing something in akka-actor
would cause tests to be run in all projects which depend on it
(e.g. akka-actor-tests
, akka-stream
, akka-docs
etc.).
To use the task simply type validatePullRequest
, and the output should include entries like shown below:
> validatePullRequest
[info] Diffing [HEAD] to determine changed modules in PR...
[info] Detected uncomitted changes in directories (including in dependency analysis): [akka-protobuf,project]
[info] Detected changes in directories: [akka-actor-tests, project, akka-stream, akka-docs, akka-persistence]
By default changes are diffed with the master
branch when working locally, if you want to validate against a different
target PR branch you can do so by setting the PR_TARGET_BRANCH environment variable for sbt:
PR_TARGET_BRANCH=origin/example sbt validatePullRequest
If you have already run all tests and now just need to check that everything is formatted and or mima passes there
are a set of all*
commands aliases for running test:compile
(also formats), mimaReportBinaryIssues
, and validateCompile
(compiles multi-jvm
if enabled for that project). See build.sbt
or use completion to find the most appropriate one
e.g. allCluster
, allTyped
.
Binary compatibility rules and guarantees are described in depth in the Binary Compatibility Rules section of the documentation.
Akka uses MiMa to validate binary compatibility of incoming pull requests. If your PR fails due to binary compatibility issues, you may see an error like this:
[info] akka-stream: found 1 potential binary incompatibilities while checking against com.typesafe.akka:akka-stream_2.12:2.4.2 (filtered 222)
[error] * method foldAsync(java.lang.Object,scala.Function2)akka.stream.scaladsl.FlowOps in trait akka.stream.scaladsl.FlowOps is present only in current version
[error] filter with: ProblemFilters.exclude[ReversedMissingMethodProblem]("akka.stream.scaladsl.FlowOps.foldAsync")
In such situations it's good to consult with a core team member whether the violation can be safely ignored or if it would indeed
break binary compatibility. If the violation can be ignored add exclude statements from the mima output to
a new file named <module>/src/main/mima-filters/<last-version>.backwards.excludes/<pr-or-issue>-<issue-number>-<description>.excludes
,
e.g. akka-actor/src/main/mima-filters/2.6.0.backwards.excludes/pr-12345-rename-internal-classes.excludes
. Make sure to add a comment
in the file that describes briefly why the incompatibility can be ignored.
Situations when it may be fine to ignore a MiMa issued warning include:
- if it is touching any class marked as
private[akka]
,/** INTERNAL API*/
or similar markers - if it is concerning internal classes (often recognisable by package names like
dungeon
,impl
,internal
etc.) - if it is adding API to classes / traits which are only meant for extension by Akka itself, i.e. should not be extended by end-users
- other tricky situations
The binary compatibility of the current changes can be checked by running sbt +mimaReportBinaryIssues
.
Changes to the binary protocol of remoting, cluster and the cluster tools require great care so that it is possible to do rolling upgrades. Note that this may include older nodes communicating with a newer node so compatibility may have to be both ways.
Since during a rolling upgrade nodes producing the 'new' format and nodes producing the 'old' format coexist, a change can require a two-release process: the first change is to add a new binary format but still use the old. A second step then starts actually emitting the new wire format. This ensures users can complete a rolling upgrade first to the intermediate version and then another rolling upgrade to the next version.
All wire protocol changes that may concern rolling upgrades should be documented in the Rolling Update Changelog (found in akka-docs/src/main/paradox/project/rolling-update.md)
Akka includes a shaded version of protobuf 3.9.0
that is used for internal communication. To generate files
run protobufGenerate
. The generated files are put in the src/main/java
of each project and need to be committed.
The generated files are automatically transformed to use the shaded version of protobuf.
Generation depends on protoc 3.9.0
being on the path. Old versions of
protoc can be downloaded from the protobuf release page and built from
source or downloaded from maven central. See
Protobuf.scala for details of how to override
the settings for generation.
For a pull request to be considered at all it has to meet these requirements:
-
Regardless if the code introduces new features or fixes bugs or regressions, it must have comprehensive tests.
-
The code must be well documented in the Lightbend's standard documentation format (see the ‘Documentation’ section below).
-
The commit messages must properly describe the changes, see further below.
-
A pull request must indicate (link to) the issue it is aimed to resolve in the description (or comments) of the PR, in order to establish a link between PR and Issue. This can be achieved by writing "Fixes #1234" or similar in PR description.
-
All Lightbend projects must include Lightbend copyright notices. Each project can choose between one of two approaches:
- All source files in the project must have a Lightbend copyright notice in the file header.
- The Notices file for the project includes the Lightbend copyright notice and no other files contain copyright notices. See http://www.apache.org/legal/src-headers.html for instructions for managing this approach for copyrights.
Akka uses the first choice, having copyright notices in every file header. When absent, these are added automatically during
sbt compile
.
Some additional guidelines regarding source code are:
- Keep the code DRY.
- Apply the Boy Scout Rule whenever you have the chance to.
- Never delete or change existing copyright notices, just add additional info.
- Do not use
@author
tags since it does not encourage Collective Code Ownership.- Contributors , each project should make sure that the contributors gets the credit they deserve—in a text file or page on the project website and in the release notes etc.
All documentation is preferred to be in Lightbend's standard documentation format Paradox, which among other things allows all code in the documentation to be externalized into compiled files and imported into the documentation.
To build the documentation locally:
sbt
akka-docs/paradox
The generated html documentation is in akka-docs/target/paradox/site/main/index.html
.
Alternatively, use akka-docs/paradoxBrowse
to open the generated docs in your default web browser.
Akka Paradox supports directives to link to the Scaladoc- and Javadoc-generated API documentation:
@apidoc[Flow]
searches for the class name and creates links to Scaladoc and Javadoc (see variants in sbt-paradox-apidoc)@scaladoc[Flow](akka.stream.scaladsl.Flow)
(see Paradox docs)@javadoc[Flow](akka.stream.javadsl.Flow)
(see Paradox docs)
Akka generates class diagrams for the API documentation using ScalaDoc.
Links to methods in ScalaDoc comments should be formatted
[[Like#this]]
, because [[this]]
does not work with genjavadoc, and
IntelliJ warns about [[#this]]
.
For further hints on how to disambiguate links in scaladoc comments see
this StackOverflow answer,
though note that this syntax may not correctly render as Javadoc.
The Scaladoc tool needs the dot
command from the Graphviz software package to be installed to avoid errors. You can disable the diagram generation by adding the flag -Dakka.scaladoc.diagrams=false
. After installing Graphviz, make sure you add the toolset to the PATH (definitely on Windows).
Akka generates JavaDoc-style API documentation using the genjavadoc sbt plugin, since the sources are written mostly in Scala.
Generating JavaDoc is not enabled by default, as it's not needed on day-to-day development as it's expected to just work. If you'd like to check if your links and formatting look good in JavaDoc (and not only in ScalaDoc), you can generate it by running:
sbt -Dakka.genjavadoc.enabled=true javaunidoc:doc
Which will generate JavaDoc style docs in ./target/javaunidoc/index.html
. This requires a jdk version 9 or later.
All the external runtime dependencies for the project, including transitive dependencies, must have an open source license that is equal to, or compatible with, Apache 2.
This must be ensured by manually verifying the license for all the dependencies for the project:
- Whenever a committer to the project changes a version of a dependency (including Scala) in the build file.
- Whenever a committer to the project adds a new dependency.
- Whenever a new release is cut (public or private for a customer).
Which licenses are compatible with Apache 2 are defined in this doc, where you can see that the licenses that are listed under Category A
are automatically compatible with Apache 2, while the ones listed under Category B
need additional action:
Each license in this category requires some degree of reciprocity; therefore, additional action must be taken in order to minimize the chance that a user of an Apache product will create a derivative work of a reciprocally-licensed portion of an Apache product without being aware of the applicable requirements.
Each project must also create and maintain a list of all dependencies and their licenses, including all their transitive dependencies. This can be done either in the documentation or in the build file next to each dependency.
Follow these guidelines when creating public commits and writing commit messages.
-
If your work spans multiple local commits (for example; if you do safe point commits while working in a feature branch or work in a branch for a long time doing merges/rebases etc.) then please do not commit it all but rewrite the history by squashing the commits into a single big commit which you write a good commit message for (like discussed in the following sections). For more info read this article: Git Workflow. Every commit should be able to be used in isolation, cherry picked etc.
-
The first line should be a descriptive sentence what the commit is doing, including the ticket number. It should be possible to fully understand what the commit does—but not necessarily how it does it—by just reading this single line. We follow the “imperative present tense” style for commit messages (more info here).
It is not ok to only list the ticket number, type "minor fix" or similar. If the commit is a small fix, then you are done. If not, go to 3.
-
Following the single line description should be a blank line followed by an enumerated list with the details of the commit.
-
You can request review by a specific team member for your commit (depending on the degree of automation we reach, the list may change over time):
Review by @gituser
- if you want to notify someone on the team. The others can, and are encouraged to participate.
Example:
enable Travis CI #1
* Details 1
* Details 2
* Details 3
Akka uses Jenkins GitHub pull request builder plugin that automatically merges the code, builds it, runs the tests and comments on the pull request in GitHub.
Upon a submission of a pull request the GitHub pull request builder plugin will post a following comment:
Can one of the repo owners verify this patch?
This requires a member from a core team to start the pull request validation process by posting a comment consisting only of OK TO TEST
.
From now on, whenever new commits are pushed to the pull request, a validation job will be automatically started and the results of the validation posted to the pull request.
A pull request validation job can be started manually by posting PLS BUILD
comment on the pull request.
In order to speed up PR validation times, the Akka build contains a special sbt task called validatePullRequest
,
which is smart enough to figure out which projects should be built if a PR only has changes in some parts of the project.
For example, if your PR only touches akka-persistence
, no akka-remote
tests need to be run, however the task
will validate all projects that depend on akka-persistence
(including samples).
Also, tests tagged as PerformanceTest
, TimingTest
, LongRunningTest
and all multi-node tests are excluded from PR validation.
You can exclude the same kind of tests in your local build by starting sbt with:
sbt -Dakka.test.tags.exclude=performance,timing,long-running -Dakka.test.multi-in-test=false
In order to force the validatePullRequest
task to build the entire project, regardless of dependency analysis of a PRs
changes one can use the special PLS BUILD ALL
command (typed in a comment on GitHub, on the pull request), which will cause
the validator to test all projects.
Note, that OK TO TEST
will only be picked up when the user asking for it is considered an admin. Public (!) members of the akka organization are automatically considered admins and users manually declared admin in the Jenkins job (currently no one is explicitly listed). PLS BUILD
and PLS BUILD ALL
can be issued by everyone that is an admin or everyone who was whitelisted in the Jenkins Job (whitelisting != declaring someone an admin).
Sometimes it is convenient to place 'internal' classes in their own package. In such situations we prefer 'internal' over 'impl' as a package name.
Akka uses Scalafmt to enforce some of the code style rules.
It's recommended to enable Scalafmt formatting in IntelliJ. Use version 2019.1 or later. In
Preferences > Editor > Code Style > Scala, select Scalafmt as formatter and enable "Reformat on file save".
IntelliJ will then use the same settings and version as defined in .scalafmt.conf
file. Then it's
not needed to use sbt scalafmtAll
when editing with IntelliJ.
PR validation includes checking that the Scala sources are formatted and will fail if they are not.
Akka uses the sbt Java Formatter plugin to format Java sources.
PR validation includes checking that the Java sources are formatted and will fail if they are not.
In addition to formatting the Akka build enforces code discipline through a set of compiler flags. While exploring ideas
the discipline may be more of a hindrance than a help so it is possible to disable it by setting the system property akka.no.discipline
to any non-empty string value when starting up sbt: sbt -Dakka.no.discipline=youbet
PR validation includes the discipline flags and therefore may fail if the flags were disabled during development. Make sure you compile your code at least once with discipline enabled before sending a PR.
Avoid short test timeouts, since Jenkins server may GC heavily causing spurious test failures. GC pause or other hiccups of 2 seconds are common in our CI environment. Please note that usually giving a larger timeout does not slow down the tests, as in an expectMessage
call for example it usually will complete quickly.
There are a number of ways timeouts can be defined in Akka tests. The following ways to use timeouts are recommended (in order of preference):
remaining
is first choice (requireswithin
block)remainingOrDefault
is second choice3.seconds
is third choice if not using testkit- lower timeouts must come with a very good reason (e.g. Awaiting on a known to be "already completed"
Future
)
Special care should be given to expectNoMessage
calls, which indeed will wait the entire timeout before continuing, therefore a shorter timeout should be used in those, for example 200
or 300.millis
. Prefer the method without timeout parameter, which will use the configured expect-no-message-default
timeout.
You can read up on remaining
and friends in TestKit.scala.
For external contributions of entire features, the normal way is to establish it
as a stand-alone feature first, to show that there is a need for the feature. The
next step would be to add it to Akka as an "may change"-feature (in the
akka-contrib subproject) and marking it's public api with the ApiMayChange
annotation,
then when the feature is hardened, well documented and
tested it becomes an officially supported Akka feature.
List of Akka features marked as may change
Akka, aims to keep 100% feature parity between the Java and Scala. Implementing even the API for Java in Scala has proven the most viable way to do it, as long as you keep the following in mind:
-
Keep entry points separated in
javadsl
andscaladsl
unless changing existing APIs which for historical and binary compatibility reasons do not have this subdivision. -
Have methods in the
javadsl
package delegate to the methods in the Scala API, or the common internal implementation. The Akka Stream Scala instances for example have a.asJava
method to convert to theakka.stream.javadsl
counterparts. -
When using Scala
object
instances, offer agetInstance()
method. Seeakka.Done
for an example. -
When the Scala API contains an
apply
method, usecreate
orof
for Java users. -
Do not nest Scala
object
s more than two levels. -
Do not define traits nested in other classes or in objects deeper than one level.
-
Be careful to convert values within data structures (eg. for
scala.Long
vs.java.lang.Long
, usescala.Long.box(value)
) -
Complement any methods with Scala collections with a Java collection version
-
Use the
akka.japi.Pair
class to return tuples -
If the underlying Scala code requires an
ExecutionContext
, make the Java API take anExecutor
and useExecutionContext.fromExecutor(executor)
for conversion. -
Make use of
scala-java8-compat
conversions, see GitHub (eg.scala.compat.java8.FutureConverters
to translate Futures toCompletionStage
s). Note that we cannot upgrade to a newer version scala-java8-compat because of binary compatibility issues. -
Make sure there are Java tests or sample code touching all parts of the API
-
Do not use lower type bounds:
trait[T] { def method[U >: Something]: U }
as they do not work with Java -
Provide
getX
style accessors for values in the Java APIs -
Place classes not part of the public APIs in a shared
internal
package. This package can contain implementations of both Java and Scala APIs. Make such classesprivate[akka]
and also, since that becomespublic
from Java's point of view, annotate with@InternalApi
and add a scaladoc sayingINTERNAL API
-
Traits that are part of the Java API should only be used to define pure interfaces, as soon as there are implementations of methods, prefer
abstract class
. -
Any method definition in a class that will be part of the Java API should not use any default parameters, as they will show up ugly when using them from Java, use plain old method overloading instead.
Scala | Java |
---|---|
scala.Option[T] |
java.util.Optional<T> (OptionalDouble , ...) |
scala.collection.immutable.Seq[T] |
java.util.List<T> |
scala.concurrent.Future[T] |
java.util.concurrent.CompletionStage<T> |
scala.concurrent.Promise[T] |
java.util.concurrent.CompletableFuture<T> |
scala.concurrent.duration.FiniteDuration |
java.time.Duration (use akka.util.JavaDurationConverters ) |
T => Unit |
java.util.function.Consumer<T> |
() => R (scala.Function0[R] ) |
java.util.function.Supplier<R> |
T => R (scala.Function1[T, R] ) |
java.util.function.Function<T, R> |
Documentation of Akka Streams operators is automatically enforced.
If a method exists on Source / Sink / Flow, or any other class listed in project/StreamOperatorsIndexGenerator.scala
,
it must also have a corresponding documentation page under akka-docs/src/main/paradox/streams/operators/...
.
The pages structure is well-defined, and must be the same on all documentation pages, please refer to any neighbouring docs pages in there to see the pattern in action. In general though the page must consist of:
- the title, including where the operator is defined (e.g.
ActorFlow.ask
orSource.map
) - a short explanation of what this operator does, 1 sentence is optimal
- an image explaining the operator more visually (whenever possible)
- a link to the operators' "category" (these are listed in
akka-docs/src/main/paradox/categories
) - the method signature snippet (use the built in directives to generate it)
- a longer explanation about the operator and it's exact semantics (when it pulls, cancels, signals elements)
- at least one usage example
Using this structure, the surrounding infrastructure will generate the index pages, so you do not need to maintain the index or category pages manually.
In case you are adding not only a new operator, but also a new class/object, you need to add it to the
project/StreamOperatorsIndexGenerator.scala
so it can be included in the automatic docs generation and enforcing the
existence of those docs.
If you have found an issue in an Akka project that might have security implications, you can report it to [email protected]. We will make sure those will get handled with priority. Thank you for your responsible disclosure!
Akka currently uses a combination of Jenkins and Travis for Continuous Integration:
- Jenkins runs the tests for each PR
- Jenkins runs a nightly test suite
- Travis checks dependency licenses for all PR's
The Jenkins server farm, sometimes referred to as "the Lausanne cluster", is sponsored by Lightbend.
The cluster is made out of real bare-metal boxes, and maintained by the Akka team (and other very helpful people at Lightbend).