For an introduction of remoting capabilities of Akka please see @ref:Location Transparency.
@@@ note
As explained in that chapter Akka remoting is designed for communication in a peer-to-peer fashion and it has limitations for client-server setups. In particular Akka Remoting does not work transparently with Network Address Translation, Load Balancers, or in Docker containers. For symmetric communication in these situations network and/or Akka configuration will have to be changed as described in Akka behind NAT or in a Docker container.
@@@
The Akka remoting is a separate jar file. Make sure that you have the following dependency in your project:
@@@vars sbt : ``` "com.typesafe.akka" %% "akka-remote" % "$akka.version$"
Maven
: ```
<dependency>
<groupId>com.typesafe.akka</groupId>
<artifactId>akka-remote_$scala.binary_version$</artifactId>
<version>$akka.version$</version>
</dependency>
@@@
To enable remote capabilities in your Akka project you should, at a minimum, add the following changes
to your application.conf
file:
akka {
actor {
provider = remote
}
remote {
enabled-transports = ["akka.remote.netty.tcp"]
netty.tcp {
hostname = "127.0.0.1"
port = 2552
}
}
}
As you can see in the example above there are four things you need to add to get started:
- Change provider from
local
toremote
- Add host name - the machine you want to run the actor system on; this host name is exactly what is passed to remote systems in order to identify this system and consequently used for connecting back to this system if need be, hence set it to a reachable IP address or resolvable name in case you want to communicate across the network.
- Add port number - the port the actor system should listen on, set to 0 to have it chosen automatically
@@@ note
The port number needs to be unique for each actor system on the same machine even if the actor systems have different names. This is because each actor system has its own networking subsystem listening for connections and handling messages as not to interfere with other actor systems.
@@@
The example above only illustrates the bare minimum of properties you have to add to enable remoting. All settings are described in Remote Configuration.
Akka has two ways of using remoting:
- Lookup : used to look up an actor on a remote node with
actorSelection(path)
- Creation : used to create an actor on a remote node with
actorOf(Props(...), actorName)
In the next sections the two alternatives are described in detail.
actorSelection(path)
will obtain an ActorSelection
to an Actor on a remote node, e.g.:
Scala : ``` val selection = context.actorSelection("akka.tcp://actorSystemName@10.0.0.1:2552/user/actorName")
Java
: ```
ActorSelection selection =
context.actorSelection("akka.tcp://app@10.0.0.1:2552/user/serviceA/worker");
As you can see from the example above the following pattern is used to find an actor on a remote node:
akka.<protocol>://<actor system name>@<hostname>:<port>/<actor path>
Once you obtained a selection to the actor you can interact with it in the same way you would with a local actor, e.g.:
Scala : ``` selection ! "Pretty awesome feature"
Java
: ```
selection.tell("Pretty awesome feature", getSelf());
To acquire an ActorRef
for an ActorSelection
you need to
send a message to the selection and use the sender
reference of the reply from
the actor. There is a built-in Identify
message that all Actors will understand
and automatically reply to with a ActorIdentity
message containing the
ActorRef
. This can also be done with the @scala[resolveOne
]@java[resolveOneCS
] method of
the ActorSelection
, which returns a @scala[Future
]@java[CompletionStage
] of the matching
ActorRef
.
@@@ note
For more details on how actor addresses and paths are formed and used, please refer to @ref:Actor References, Paths and Addresses.
@@@
@@@ note
Message sends to actors that are actually in the sending actor system do not get delivered via the remote actor ref provider. They're delivered directly, by the local actor ref provider.
Aside from providing better performance, this also means that if the hostname you configure remoting to listen as cannot actually be resolved from within the very same actor system, such messages will (perhaps counterintuitively) be delivered just fine.
@@@
If you want to use the creation functionality in Akka remoting you have to further amend the
application.conf
file in the following way (only showing deployment section):
akka {
actor {
deployment {
/sampleActor {
remote = "akka.tcp://sampleActorSystem@127.0.0.1:2553"
}
}
}
}
The configuration above instructs Akka to react when an actor with path /sampleActor
is created, i.e.
using @scala[system.actorOf(Props(...), "sampleActor")
]@java[system.actorOf(new Props(...), "sampleActor")
]. This specific actor will not be directly instantiated,
but instead the remote daemon of the remote system will be asked to create the actor,
which in this sample corresponds to sampleActorSystem@127.0.0.1:2553
.
Once you have configured the properties above you would do the following in code:
Scala : @@snip RemoteDeploymentDocSpec.scala { #sample-actor }
Java : @@snip RemoteDeploymentDocTest.java { #sample-actor }
The actor class SampleActor
has to be available to the runtimes using it, i.e. the classloader of the
actor systems has to have a JAR containing the class.
@@@ note
In order to ensure serializability of Props
when passing constructor
arguments to the actor being created, do not make the factory @scala[an]@java[a non-static] inner class:
this will inherently capture a reference to its enclosing object, which in
most cases is not serializable. It is best to @scala[create a factory method in the
companion object of the actor’s class]@java[make a static
inner class which implements Creator<T extends Actor>
].
Serializability of all Props can be tested by setting the configuration item
akka.actor.serialize-creators=on
. Only Props whose deploy
has
LocalScope
are exempt from this check.
@@@
@@@ note
You can use asterisks as wildcard matches for the actor path sections, so you could specify:
/*/sampleActor
and that would match all sampleActor
on that level in the hierarchy.
You can also use wildcard in the last position to match all actors at a certain level:
/someParent/*
. Non-wildcard matches always have higher priority to match than wildcards, so:
/foo/bar
is considered more specific than /foo/*
and only the highest priority match is used.
Please note that it cannot be used to partially match section, like this: /foo*/bar
, /f*o/bar
etc.
@@@
To allow dynamically deployed systems, it is also possible to include
deployment configuration in the Props
which are used to create an
actor: this information is the equivalent of a deployment section from the
configuration file, and if both are given, the external configuration takes
precedence.
With these imports:
Scala : @@snip RemoteDeploymentDocSpec.scala { #import }
Java : @@snip RemoteDeploymentDocTest.java { #import }
and a remote address like this:
Scala : @@snip RemoteDeploymentDocSpec.scala { #make-address }
Java : @@snip RemoteDeploymentDocTest.java { #make-address }
you can advise the system to create a child on that remote node like so:
Scala : @@snip RemoteDeploymentDocSpec.scala { #deploy }
Java : @@snip RemoteDeploymentDocTest.java { #deploy }
As remote deployment can potentially be abused by both users and even attackers a whitelist feature is available to guard the ActorSystem from deploying unexpected actors. Please note that remote deployment is not remote code loading, the Actors class to be deployed onto a remote system needs to be present on that remote system. This still however may pose a security risk, and one may want to restrict remote deployment to only a specific set of known actors by enabling the whitelist feature.
To enable remote deployment whitelisting set the akka.remote.deployment.enable-whitelist
value to on
.
The list of allowed classes has to be configured on the "remote" system, in other words on the system onto which
others will be attempting to remote deploy Actors. That system, locally, knows best which Actors it should or
should not allow others to remote deploy onto it. The full settings section may for example look like this:
@@snip RemoteDeploymentWhitelistSpec.scala { #whitelist-config }
Actor classes not included in the whitelist will not be allowed to be remote deployed onto this system.
Each link with a remote system can be in one of the four states as illustrated above. Before any communication
happens with a remote system at a given Address
the state of the association is Idle
. The first time a message
is attempted to be sent to the remote system or an inbound connection is accepted the state of the link transitions to
Active
denoting that the two systems has messages to send or receive and no failures were encountered so far.
When a communication failure happens and the connection is lost between the two systems the link becomes Gated
.
In this state the system will not attempt to connect to the remote host and all outbound messages will be dropped. The time
while the link is in the Gated
state is controlled by the setting akka.remote.retry-gate-closed-for
:
after this time elapses the link state transitions to Idle
again. Gate
is one-sided in the
sense that whenever a successful inbound connection is accepted from a remote system during Gate
it automatically
transitions to Active
and communication resumes immediately.
In the face of communication failures that are unrecoverable because the state of the participating systems are inconsistent,
the remote system becomes Quarantined
. Unlike Gate
, quarantining is permanent and lasts until one of the systems
is restarted. After a restart communication can be resumed again and the link can become Active
again.
Watching a remote actor is not different than watching a local actor, as described in @ref:Lifecycle Monitoring aka DeathWatch.
Under the hood remote death watch uses heartbeat messages and a failure detector to generate Terminated
message from network failures and JVM crashes, in addition to graceful termination of watched
actor.
The heartbeat arrival times is interpreted by an implementation of The Phi Accrual Failure Detector.
The suspicion level of failure is given by a value called phi. The basic idea of the phi failure detector is to express the value of phi on a scale that is dynamically adjusted to reflect current network conditions.
The value of phi is calculated as:
phi = -log10(1 - F(timeSinceLastHeartbeat))
where F is the cumulative distribution function of a normal distribution with mean and standard deviation estimated from historical heartbeat inter-arrival times.
In the Remote Configuration you can adjust the akka.remote.watch-failure-detector.threshold
to define when a phi value is considered to be a failure.
A low threshold
is prone to generate many false positives but ensures
a quick detection in the event of a real crash. Conversely, a high threshold
generates fewer mistakes but needs more time to detect actual crashes. The
default threshold
is 10 and is appropriate for most situations. However in
cloud environments, such as Amazon EC2, the value could be increased to 12 in
order to account for network issues that sometimes occur on such platforms.
The following chart illustrates how phi increase with increasing time since the previous heartbeat.
Phi is calculated from the mean and standard deviation of historical inter arrival times. The previous chart is an example for standard deviation of 200 ms. If the heartbeats arrive with less deviation the curve becomes steeper, i.e. it is possible to determine failure more quickly. The curve looks like this for a standard deviation of 100 ms.
To be able to survive sudden abnormalities, such as garbage collection pauses and
transient network failures the failure detector is configured with a margin,
akka.remote.watch-failure-detector.acceptable-heartbeat-pause
. You may want to
adjust the Remote Configuration of this depending on you environment.
This is how the curve looks like for acceptable-heartbeat-pause
configured to
3 seconds.
When using remoting for actors you must ensure that the props
and messages
used for
those actors are serializable. Failing to do so will cause the system to behave in an unintended way.
For more information please see @ref:Serialization.
Since the 2.4.11
release of Akka it is possible to entirely disable the default Java Serialization mechanism.
Please note that @ref:new remoting implementation (codename Artery) does not use Java
serialization for internal messages by default. For compatibility reasons, the current remoting still uses Java
serialization for some classes, however you can disable it in this remoting implementation as well by following
the steps below.
The first step is to enable some additional serializers that replace previous Java serialization of some internal messages. This is recommended also when you can't disable Java serialization completely. Those serializers are enabled with this configuration:
akka.actor {
# Set this to on to enable serialization-bindings define in
# additional-serialization-bindings. Those are by default not included
# for backwards compatibility reasons. They are enabled by default if
# akka.remote.artery.enabled=on.
enable-additional-serialization-bindings = on
}
The reason these are not enabled by default is wire-level compatibility between any 2.4.x Actor Systems. If you roll out a new cluster, all on the same Akka version that can enable these serializers it is recommended to enable this setting. When using @ref:Remoting (codename Artery) these serializers are enabled by default.
@@@ warning
Please note that when enabling the additional-serialization-bindings when using the old remoting, you must do so on all nodes participating in a cluster, otherwise the mis-aligned serialization configurations will cause deserialization errors on the receiving nodes.
@@@
Java serialization is known to be slow and prone to attacks
of various kinds - it never was designed for high throughput messaging after all. However, it is very
convenient to use, thus it remained the default serialization mechanism that Akka used to
serialize user messages as well as some of its internal messages in previous versions.
Since the release of Artery, Akka internals do not rely on Java serialization anymore (one exception being java.lang.Throwable
).
@@@ warning
Please note Akka 2.5 by default does not use any Java Serialization for its own internal messages, unlike 2.4 where
by default it sill did for a few of the messages. If you want an 2.4.x system to communicate with a 2.5.x series, for
example during a rolling deployment you should first enable additional-serialization-bindings
on the old systems.
You must do so on all nodes participating in a cluster, otherwise the mis-aligned serialization
configurations will cause deserialization errors on the receiving nodes. These additional serialization bindings are
enabled by default in Akka 2.5.x.
@@@
@@@ note
When using the new remoting implementation (codename Artery), Akka does not use Java Serialization for any of its internal messages. It is highly encouraged to disable java serialization, so please plan to do so at the earliest possibility you have in your project.
One may think that network bandwidth and latency limit the performance of remote messaging, but serialization is a more typical bottleneck.
@@@
For user messages, the default serializer, implemented using Java serialization, remains available and enabled. We do however recommend to disable it entirely and utilise a proper serialization library instead in order effectively utilise the improved performance and ability for rolling deployments using Artery. Libraries that we recommend to use include, but are not limited to, Kryo by using the akka-kryo-serialization library or Google Protocol Buffers if you want more control over the schema evolution of your messages.
In order to completely disable Java Serialization in your Actor system you need to add the following configuration to
your application.conf
:
akka.actor.allow-java-serialization = off
This will completely disable the use of akka.serialization.JavaSerialization
by the
Akka Serialization extension, instead DisabledJavaSerializer
will
be inserted which will fail explicitly if attempts to use java serialization are made.
It will also enable the above mentioned enable-additional-serialization-bindings
.
The log messages emitted by such serializer SHOULD be treated as potential attacks which the serializer prevented, as they MAY indicate an external operator attempting to send malicious messages intending to use java serialization as attack vector. The attempts are logged with the SECURITY marker.
Please note that this option does not stop you from manually invoking java serialization.
Please note that this means that you will have to configure different serializers which will able to handle all of your remote messages. Please refer to the @ref:Serialization documentation as well as @ref:ByteBuffer based serialization to learn how to do this.
It is absolutely feasible to combine remoting with @ref:Routing.
A pool of remote deployed routees can be configured as:
@@snip RouterDocSpec.scala { #config-remote-round-robin-pool }
This configuration setting will clone the actor defined in the Props
of the remotePool
10
times and deploy it evenly distributed across the two given target nodes.
A group of remote actors can be configured as:
@@snip RouterDocSpec.scala { #config-remote-round-robin-group }
This configuration setting will send messages to the defined remote actor paths. It requires that you create the destination actors on the remote nodes with matching paths. That is not done by the router.
You can download a ready to run @scala[@extrefremoting sample]@java[@extrefremoting sample] together with a tutorial for a more hands-on experience. The source code of this sample can be found in the @scala[@extrefAkka Samples Repository]@java[@extrefAkka Samples Repository].
It is possible to listen to events that occur in Akka Remote, and to subscribe/unsubscribe to these events
you simply register as listener to the below described types in on the ActorSystem.eventStream
.
@@@ note
To subscribe to any remote event, subscribe to
RemotingLifecycleEvent
. To subscribe to events related only to
the lifecycle of associations, subscribe to
akka.remote.AssociationEvent
.
@@@
@@@ note
The use of term "Association" instead of "Connection" reflects that the remoting subsystem may use connectionless transports, but an association similar to transport layer connections is maintained between endpoints by the Akka protocol.
@@@
By default an event listener is registered which logs all of the events described below. This default was chosen to help setting up a system, but it is quite common to switch this logging off once that phase of the project is finished.
@@@ note
In order to switch off the logging, set
akka.remote.log-remote-lifecycle-events = off
in your
application.conf
.
@@@
To be notified when an association is over ("disconnected") listen to DisassociatedEvent
which
holds the direction of the association (inbound or outbound) and the addresses of the involved parties.
To be notified when an association is successfully established ("connected") listen to AssociatedEvent
which
holds the direction of the association (inbound or outbound) and the addresses of the involved parties.
To intercept errors directly related to associations, listen to AssociationErrorEvent
which
holds the direction of the association (inbound or outbound), the addresses of the involved parties and the
Throwable
cause.
To be notified when the remoting subsystem is ready to accept associations, listen to RemotingListenEvent
which
contains the addresses the remoting listens on.
To be notified when the current system is quarantined by the remote system, listen to ThisActorSystemQuarantinedEvent
,
which includes the addresses of local and remote ActorSystems.
To be notified when the remoting subsystem has been shut down, listen to RemotingShutdownEvent
.
To intercept generic remoting related errors, listen to RemotingErrorEvent
which holds the Throwable
cause.
An ActorSystem
should not be exposed via Akka Remote over plain TCP to an untrusted network (e.g. internet).
It should be protected by network security, such as a firewall. If that is not considered as enough protection
TLS with mutual authentication should be enabled.
Best practice is that Akka remoting nodes should only be accessible from the adjacent network. Note that if TLS is enabled with mutual authentication there is still a risk that an attacker can gain access to a valid certificate by compromising any node with certificates issued by the same internal PKI tree.
It is also security best-practice to disable the Java serializer because of its multiple known attack surfaces.
SSL can be used as the remote transport by adding akka.remote.netty.ssl
to the enabled-transport
configuration section.
An example of setting up the default Netty based SSL driver as default:
akka {
remote {
enabled-transports = [akka.remote.netty.ssl]
}
}
Next the actual SSL/TLS parameters have to be configured:
akka {
remote {
netty.ssl {
hostname = "127.0.0.1"
port = "3553"
security {
key-store = "/example/path/to/mykeystore.jks"
trust-store = "/example/path/to/mytruststore.jks"
key-store-password = "changeme"
key-password = "changeme"
trust-store-password = "changeme"
protocol = "TLSv1.2"
enabled-algorithms = [TLS_DHE_RSA_WITH_AES_128_GCM_SHA256]
random-number-generator = "AES128CounterSecureRNG"
}
}
}
}
According to RFC 7525 the recommended algorithms to use with TLS 1.2 (as of writing this document) are:
- TLS_DHE_RSA_WITH_AES_128_GCM_SHA256
- TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256
- TLS_DHE_RSA_WITH_AES_256_GCM_SHA384
- TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384
You should always check the latest information about security and algorithm recommendations though before you configure your system.
Creating and working with keystores and certificates is well documented in the Generating X.509 Certificates section of Lightbend's SSL-Config library.
Since an Akka remoting is inherently @ref:peer-to-peer both the key-store as well as trust-store need to be configured on each remoting node participating in the cluster.
The official Java Secure Socket Extension documentation as well as the Oracle documentation on creating KeyStore and TrustStores are both great resources to research when setting up security on the JVM. Please consult those resources when troubleshooting and configuring SSL.
Since Akka 2.5.0 mutual authentication between TLS peers is enabled by default.
Mutual authentication means that the the passive side (the TLS server side) of a connection will also request and verify a certificate from the connecting peer. Without this mode only the client side is requesting and verifying certificates. While Akka is a peer-to-peer technology, each connection between nodes starts out from one side (the "client") towards the other (the "server").
Note that if TLS is enabled with mutual authentication there is still a risk that an attacker can gain access to a valid certificate by compromising any node with certificates issued by the same internal PKI tree.
See also a description of the settings in the @ref:Remote Configuration section.
@@@ note
When using SHA1PRNG on Linux it's recommended specify -Djava.security.egd=file:/dev/urandom
as argument
to the JVM to prevent blocking. It is NOT as secure because it reuses the seed.
@@@
As soon as an actor system can connect to another remotely, it may in principle
send any possible message to any actor contained within that remote system. One
example may be sending a PoisonPill
to the system guardian, shutting
that system down. This is not always desired, and it can be disabled with the
following setting:
akka.remote.untrusted-mode = on
This disallows sending of system messages (actor life-cycle commands,
DeathWatch, etc.) and any message extending PossiblyHarmful
to the
system on which this flag is set. Should a client send them nonetheless they
are dropped and logged (at DEBUG level in order to reduce the possibilities for
a denial of service attack). PossiblyHarmful
covers the predefined
messages like PoisonPill
and Kill
, but it can also be added
as a marker trait to user-defined messages.
@@@ warning
Untrusted mode does not give full protection against attacks by itself. It makes it slightly harder to perform malicious or unintended actions but it should be complemented with disabled Java serializer. Additional protection can be achieved when running in an untrusted network by network security (e.g. firewalls) and/or enabling TLS with mutual authentication.
@@@
Messages sent with actor selection are by default discarded in untrusted mode, but permission to receive actor selection messages can be granted to specific actors defined in configuration:
akka.remote.trusted-selection-paths = ["/user/receptionist", "/user/namingService"]
The actual message must still not be of type PossiblyHarmful
.
In summary, the following operations are ignored by a system configured in untrusted mode when incoming via the remoting layer:
- remote deployment (which also means no remote supervision)
- remote DeathWatch
system.stop()
,PoisonPill
,Kill
- sending any message which extends from the
PossiblyHarmful
marker interface, which includesTerminated
- messages sent with actor selection, unless destination defined in
trusted-selection-paths
.
@@@ note
Enabling the untrusted mode does not remove the capability of the client to
freely choose the target of its message sends, which means that messages not
prohibited by the above rules can be sent to any actor in the remote system.
It is good practice for a client-facing system to only contain a well-defined
set of entry point actors, which then forward requests (possibly after
performing validation) to another actor system containing the actual worker
actors. If messaging between these two server-side systems is done using
local ActorRef
(they can be exchanged safely between actor systems
within the same JVM), you can restrict the messages on this interface by
marking them PossiblyHarmful
so that a client cannot forge them.
@@@
There are lots of configuration properties that are related to remoting in Akka. We refer to the @ref:reference configuration for more information.
@@@ note
Setting properties like the listening IP and port number programmatically is best done by using something like the following:
@@snip RemoteDeploymentDocTest.java { #programmatic }
@@@
In setups involving Network Address Translation (NAT), Load Balancers or Docker containers the hostname and port pair that Akka binds to will be different than the "logical" host name and port pair that is used to connect to the system from the outside. This requires special configuration that sets both the logical and the bind pairs for remoting.
akka {
remote {
netty.tcp {
hostname = my.domain.com # external (logical) hostname
port = 8000 # external (logical) port
bind-hostname = local.address # internal (bind) hostname
bind-port = 2552 # internal (bind) port
}
}
}
Keep in mind that local.address will most likely be in one of private network ranges:
- 10.0.0.0 - 10.255.255.255 (network class A)
- 172.16.0.0 - 172.31.255.255 (network class B)
- 192.168.0.0 - 192.168.255.255 (network class C)