Scala Logging is a convenient and fast logging library wrapping SLF4J.
It's convenient, because you can simply call log methods, without checking whether the respective log level is enabled:
logger.debug(s"Some $expensive message!")
It's fast, because thanks to Scala macros the check-enabled-idiom is applied and the following code is generated:
if (logger.isDebugEnabled) logger.debug(s"Some $expensive message!")
- Java 8 or higher
- Scala 2.11, 2.12, 2.13 or 3.0
- Logging backend compatible with SLF4J
A compatible logging backend is Logback, add it to your sbt build definition:
libraryDependencies += "ch.qos.logback" % "logback-classic" % "1.2.10"
If you are looking for a version compatible with Scala 2.10, check out Scala Logging 2.x.
Scala Logging is published to Sonatype OSS and Maven Central:
- Group id / organization: com.typesafe.scala-logging
- Artifact id / name: scala-logging
sbt users may add this to their build.sbt
:
libraryDependencies += "com.typesafe.scala-logging" %% "scala-logging" % "3.9.4"
The Logger
class from the com.typesafe.scalalogging
package wraps an underlying SLF4J logger.
In order to create a Logger
, you pass a name to the apply
factory method defined in the Logger
companion object:
val logger = Logger("name")
Or, you pass in a SLF4J logger instance:
val logger = Logger(LoggerFactory.getLogger("name"))
Or, you pass in the name of the class into which it is defined:
val logger = Logger(getClass.getName)
Or, you pass in a class:
val logger = Logger(classOf[MyClass])
Or, using the runtime class wrapped by the implicit class tag parameter:
val logger = Logger[MyClass]
The LazyLogging
and StrictLogging
traits from the com.typesafe.scalalogging
package define the logger
member as
a lazy or strict value respectively, whereas the AnyLogging
trait defines an abstract logger
.
It depends on the individual use case which trait to use. However, we have defined some scenarios where you can use these traits:
- Use
LazyLogging
if you are creating lots of objects with this trait repetitively. - Use
StrictLogging
pretty much by default, especially if the class is a singleton, or you know the log methods will always be invoked. - Use
AnyLogging
when writing some trait which needs access to any logger without deciding on a specific implementation.
In case of LazyLogging
and StrictLogging
, the underlying SLF4J logger is named according to the class into which
these traits are mixed:
class LazyLoggingExample extends LazyLogging {
logger.debug("This is Lazy Logging ;-)")
logger.whenDebugEnabled {
println("This would only execute when the debug level is enabled.")
(1 to 10).foreach(x => println("Scala logging is great!"))
}
}
class StrictLoggingExample extends StrictLogging {
logger.debug("This is Strict Logging ;-)")
logger.whenDebugEnabled {
println("This would only execute when the debug level is enabled.")
(1 to 10).foreach(x => println("Scala logging is great!"))
}
}
class AnyLoggingExample extends AnyLogging {
override protected val logger: Logger = Logger("name")
logger.info("This is Any Logging ;-)")
logger.whenInfoEnabled {
println("This would only execute when the info level is enabled.")
(1 to 10).foreach(x => println("Scala logging is great!"))
}
}
LoggerTakingImplicit
provides the same methods as Logger
class, but with additional implicit parameter A
.
During creation of the LoggerTakingImplicit
evidence CanLog[A]
is required.
It may be useful when contextual parameter (e.g. Correlation ID) is being passed around and you would like to include it in the log messages:
case class CorrelationId(value: String)
implicit case object CanLogCorrelationId extends CanLog[CorrelationId] {
override def logMessage(originalMsg: String, a: CorrelationId): String = s"${a.value} $originalMsg"
}
implicit val correlationId = CorrelationId("ID")
val logger = Logger.takingImplicit[CorrelationId]("test")
logger.info("Test") // takes implicit correlationId and logs "ID Test"
If you want to extract the context object associated with your logger i.e. correlationId
here, use getContext
.
val context = logger.canLogEv.getContext()
It's also possible to use MDC
through CanLog
without any troubles with execution context.
case class CorrelationId(value: String)
implicit case object CanLogCorrelationId extends CanLog[CorrelationId] {
override def logMessage(originalMsg: String, a: CorrelationId): String = {
MDC.put("correlationId", a.value)
originalMsg
}
override def afterLog(a: CorrelationId): Unit = {
MDC.remove("correlationId")
}
}
implicit val correlationId = CorrelationId("ID")
val logger = Logger.takingImplicit[CorrelationId]("test")
def serviceMethod(implicit correlationId: CorrelationId): Future[Result] = {
dbCall.map { value =>
logger.trace(s"Received value $value from db") // takes implicit correlationId
toResult(value)
}
}
It is idiomatic to use Scala's string interpolation logger.error(s"log $value")
instead of SLF4J string interpolation logger.error("log {}", value)
.
However there are some tools (such as Sentry) that use the log message format as grouping key. Therefore they do not work well with
Scala's string interpolation.
Scala Logging replaces simple string interpolations with their SLF4J counterparts like this:
logger.error(s"my log message: $arg1 $arg2 $arg3")
logger.error("my log message: {} {} {}", arg1, arg2, arg3)
This has no effect on behavior and performace should be comparable (depends on the underlying logging library).
- Works only when string interpolation is directly used inside the logging statement. That is when the log message is static (available at compile time).
- Works only for the
logger.<level>(message)
andlogger.<level>(marker, message)
logging methods. It does not work if you want to log an exception and use string interpolation too (this is a limitation of the SLF4J API).
Using the sourcecode library, it's possible to add line number information (especially useful for debugging):
def foo(arg: String)(implicit line: sourcecode.Line, file: sourcecode.File) = {
... do something with arg ...
... do something with file.value ...
}
foo("hello") // the implicit sourcecode.File is filled in automatically
This library is community-maintained. It is not supported under the Lightbend subscription.
Contributions via GitHub pull requests are gladly accepted from their original author. Before we can accept pull requests, you will need to agree to the Lightbend Contributor License Agreement online, using your GitHub account.