Direct former README import (possibly not up-to-date)
Add to your
libraryDependencies ++= Seq( "io.get-coursier" %% "coursier-core" % "1.1.0-M11", "io.get-coursier" %% "coursier-cache" % "1.1.0-M11" )
libraryDependencies += "io.get-coursier" %% "coursier" % "1.1.0-M11"
The first module,
"io.get-coursier" %% "coursier" % "1.1.0-M11", contains among others,
Resolution, representing a particular state of the resolution,
that expects to be given metadata, wrapped in any
Monad, then feeds these to
Resolution, and at the end gives
you the final
Resolution, wrapped in the same
Monad it was given input. This final
Resolution has all the dependencies,
including the transitive ones.
The second module,
"io.get-coursier" %% "coursier-cache" % "1.1.0-M11", is precisely in charge of fetching
these input metadata. It uses its own
coursier.util.Task as a
Monad to wrap them. It also fetches artifacts (JARs, etc.).
It caches all of these (metadata and artifacts) on disk, and validates checksums too.
In the code below, we'll assume some imports are around,
Resolving dependencies involves create an initial resolution state, with all the initial dependencies in it, like
val start = Resolution( Seq( Dependency( Module(org"org.typelevel", name"cats-core_2.11"), "0.6.0" ), Dependency( Module(org"org.scalaz", name"scalaz-core_2.11"), "7.2.3" ) ) )
It goes without saying that a
Resolution is immutable, as are all the classes defined in the core module.
The resolution process will go on by giving successive
Resolutions, until the final one.
start above is only the initial state - it is far from over, as the
isDone method on it tells,
start.isDone // res0: Boolean = false
In order for the resolution to go on, we'll need things from a few repositories,
val repositories = Seq( coursier.cache.LocalRepositories.ivy2Local, MavenRepository("https://repo1.maven.org/maven2") )
The first one,
Cache.ivy2Local, is defined in
coursier.Cache, itself from the
coursier-cache module that
we added above. It is an
IvyRepository, picking things under
is related to the Ivy build tool. This kind of repository involves a so-called pattern, with
various properties. These are not of very common use in Scala, although SBT uses them a bit.
The second repository is a
MavenRepository. These are simpler than the Ivy repositories. They're the ones
we're the most used to in Scala. Common ones like Central like here, or the repositories
from Sonatype, are Maven repositories. These originate
from the Maven build tool. Unlike the Ivy repositories which involve customisable patterns to point
to the underlying metadata and artifacts, the paths of these for Maven repositories all look alike,
like for any particular version of the standard library, under paths like
MavenRepository are case classes, so that it's straightforward to specify one's own
To set credentials for a
IvyRepository, set their
authentication field, like
import coursier.core.Authentication MavenRepository( "https://nexus.corp.com/content/repositories/releases", authentication = Some(Authentication("user", "pass")) )
Now that we have repositories, we're going to mix these with things from the
for resolution to happen via the cache. We'll create a function
Seq[(Module, String)] => F[Seq[((Module, String), Either[Seq[String], (Artifact.Source, Project)])]].
Given a sequence of dependencies, designated by their
Module (organisation and name in most cases)
and version (just a
String), it gives either errors (
Seq[String]) or metadata (
wrapping the whole in a monad
import coursier.util.Task val fetch = ResolutionProcess.fetch(repositories, Cache.fetch[Task]())
The monad used by
coursier.util.Task, but the resolution process is not tied to a particular
monad - any stack-safe monad would do.
fetch method, we can now go on with the resolution. Calling
start above gives a
that drives the resolution. It is loosely inspired by the
Process of fs2 (formerly scalaz-stream).
It is an immutable structure, that represents the various states the resolution process can be in.
current gives the current
isDone on the latter says whether the
resolution is done or not.
next method, that expects a
fetch method like the one above, gives
the "next" state of the resolution process, wrapped in the monad of the
fetch method. It allows to do
one resolution step.
run method runs the whole resolution until its end. It expects a
fetch method too,
and will make at most
maxIterations steps (50 by default), and return the "final" resolution state,
wrapped in the monad of
fetch. One should check that the
Resolution it returns is done (
the contrary means that
maxIterations were reached, likely signaling an issue, unless the underlying
resolution is particularly complex, in which case
maxIterations could be increased.
Let's run the whole resolution,
import scala.concurrent.ExecutionContext.Implicits.global val resolution = start.process.run(fetch).unsafeRun()
To get additional feedback during the resolution, we can give the
Cache.fetch method above
By default, downloads happen in a global fixed thread pool (with 6 threads, allowing for 6 parallel downloads), but
you can supply your own thread pool to
Now that the resolution is done, we can check for errors in
val errors: Seq[((Module, String), Seq[String])] = resolution.errors
These would mean that the resolution wasn't able to get metadata about some dependencies.
We can also check for version conflicts, in
val conflicts: Set[Dependency] = resolution.conflicts
which are dependencies whose versions could not be unified.
Then, if all went well, we can fetch and get local copies of the artifacts themselves (the JARs) with
import java.io.File import coursier.util.Gather val localArtifacts: Seq[Either[FileError, File]] = Gather[Task].gather( resolution.artifacts().map(Cache.file[Task](_).run) ).unsafeRun()
We're using the
Cache.file method, that can also be given a
Logger (for more feedback) and a custom thread pool.