Akka maintains and verifies backwards binary compatibility across versions of modules.
In the rest of this document whenever binary compatibility is mentioned “backwards binary compatibility” is meant (as opposed to forward compatibility).
This means that the new JARs are a drop-in replacement for the old one (but not the other way around) as long as your build does not enable the inliner (Scala-only restriction).
Binary compatibility is maintained between:
- minor and patch versions - please note that the meaning of “minor” has shifted to be more restrictive with Akka
2.4.0, read Change in versioning scheme for details.
Binary compatibility is NOT maintained between:
- major versions
- any versions of may change modules – read Modules marked “May Change” for details
- a few notable exclusions explained below
Specific examples (please read Change in versioning scheme to understand the difference in “before 2.4 era” and “after 2.4 era”):
# [epoch.major.minor] era OK: 2.2.0 --> 2.2.1 --> ... --> 2.2.x NO: 2.2.y --x 2.3.y OK: 2.3.0 --> 2.3.1 --> ... --> 2.3.x OK: 2.3.x --> 2.4.x (special case, migration to new versioning scheme) # [major.minor.patch] era OK: 2.4.0 --> 2.5.x OK: 2.5.0 --> 2.6.x NO: 2.x.y --x 3.x.y OK: 3.0.0 --> 3.0.1 --> ... --> 3.0.n OK: 3.0.n --> 3.1.0 --> ... --> 3.1.n OK: 3.1.n --> 3.2.0 ... ...
If a security vulnerability is reported in Akka or a transient dependency of Akka and it cannot be solved without breaking binary compatibility then fixing the security issue is more important. In such cases binary compatibility might not be retained when releasing a minor version. Such exception is always noted in the release announcement.
Some modules are excluded from the binary compatibility guarantees, such as:
*-testkitmodules - since these are to be used only in tests, which usually are re-compiled and run on demand
*-tckmodules - since they may want to add new tests (or force configuring something), in order to discover possible failures in an existing implementation that the TCK is supposed to be testing. Compatibility here is not guaranteed, however it is attempted to make the upgrade process as smooth as possible.
- all may change modules - which by definition are subject to rapid iteration and change. Read more about that in Modules marked “May Change”
Since the release of Akka
2.4.0 a new versioning scheme is in effect.
Historically, Akka has been following the Java or Scala style of versioning where as the first number would mean “epoch”, the second one would mean major, and third be the minor, thus:
epoch.major.minor (versioning scheme followed until and during
Currently, since Akka
2.4.0, the new versioning applies which is closer to semantic versioning many have come to expect, in which the version number is deciphered as
major.minor.patch. This also means that Akka
2.5.x is binary compatible with the
2.4 series releases (with the exception of “may change” APIs of course).
In addition to that, Akka
2.4.x has been made binary compatible with the
2.3.x series, so there is no reason to remain on Akka 2.3.x, since upgrading is completely compatible (and many issues have been fixed ever since).
Modules that are released together under the Akka project are intended to be upgraded together. For example, it is not legal to mix Akka Actor
2.4.2 with Akka Cluster
2.4.5 even though “Akka
2.4.2” and “Akka
2.4.5” are binary compatible.
This is because modules may assume internals changes across module boundaries, for example some feature in Clustering may have required an internals change in Actor, however it is not public API, thus such change is considered safe.
We recommend keeping an
akkaVersion variable in your build file, and re-use it for all included modules, so when you upgrade you can simply change it in this one place.
May change is used in module descriptions and docs in order to signify that the API that they contain is subject to change without any prior warning and is not covered by the binary compatibility promise. Read more in Modules marked “May Change”.
Akka gives a very strong binary compatibility promise to end-users. However some parts of Akka are excluded from these rules, for example internal or known evolving APIs may be marked as such and shipped as part of an overall stable module. As general rule any breakage is avoided and handled via deprecation and method addition, however certain APIs which are known to not yet be fully frozen (or are fully internal) are marked as such and subject to change at any time (even if best-effort is taken to keep them compatible).
When browsing the source code and/or looking for methods available to be called, especially from Java which does not have as rich of an access protection system as Scala has, you may sometimes find methods or classes annotated with the
/** INTERNAL API */ comment or the
No compatibility guarantees are given about these classes. They may change or even disappear in minor versions, and user code is not supposed to call them.
Side-note on JVM representation details of the Scala
private[akka] pattern that Akka is using extensively in it’s internals: Such methods or classes, which act as “accessible only from the given package” in Scala, are compiled down to
public (!) in raw Java bytecode. The access restriction, that Scala understands is carried along as metadata stored in the classfile. Thus, such methods are safely guarded from being accessed from Scala, however Java users will not be warned about this fact by the
javac compiler. Please be aware of this and do not call into Internal APIs, as they are subject to change without any warning.
In addition to the special internal API marker two annotations exist in Akka and specifically address the following use cases:
@ApiMayChange– which marks APIs which are known to be not fully stable yet. Read more in Modules marked “May Change”
@DoNotInherit– which marks APIs that are designed under a closed-world assumption, and thus must not be extended outside Akka itself (or such code will risk facing binary incompatibilities). E.g. an interface may be marked using this annotation, and while the type is public, it is not meant for extension by user-code. This allows adding new methods to these interfaces without risking to break client code. Examples of such API are the
FlowOpstrait or the Akka HTTP domain model.
Please note that a best-effort approach is always taken when having to change APIs and breakage is avoided as much as possible, however these markers allow to experiment, gather feedback and stabilize the best possible APIs we could build.
Akka uses the Lightbend maintained Migration Manager, called
MiMa for short, for enforcing binary compatibility is kept where it was promised.
All Pull Requests must pass MiMa validation (which happens automatically), and if failures are detected, manual exception overrides may be put in place if the change happened to be in an Internal API for example.
Scala does not maintain serialization compatibility across major versions. This means that if Java serialization is used there is no guarantee objects can be cleanly deserialized if serialized with a different version of Scala.
The internal Akka Protobuf serializers that can be enabled explicitly with
enable-additional-serialization-bindings or implicitly with
akka.actor.allow-java-serialization = off (which is preferable from a security standpoint) does not suffer from this problem.