Pure Scala Artifact Fetching
A Scala library to fetch dependencies from Maven / Ivy repositories
coursier is a dependency resolver / fetcher à la Maven / Ivy, entirely
rewritten from scratch in Scala. It aims at being fast and easy to embed
in other contexts. Its very core (core
module) aims at being
extremely pure, and only requires to be fed external data (Ivy / Maven metadata) via a monad.
The cache
module handles caching of the metadata and artifacts themselves,
and is less so pure than the core
module, in the sense that it happily
does IO as a side-effect (always wrapped in Task
, and naturally favoring immutability for all
that's kept in memory).
It handles fancy Maven features like
and is able to fetch metadata and artifacts from both Maven and Ivy repositories.
Compared to the default dependency resolution of SBT, it adds:
- downloading of artifacts in parallel,
- better offline mode - one can safely work with snapshot dependencies if these are in cache (SBT tends to try and fail if it cannot check for updates),
- non obfuscated cache (cache structure just mimics the URL it caches),
- no global lock (no "Waiting for ~/.ivy2/.sbt.ivy.lock to be available").
From the command-line, it also has:
- a launcher, able to launch apps distributed via Maven / Ivy repositories,
- a bootstrap generator, able to generate stripped launchers of these apps.
Lastly, it can be used programmatically via its API and has a Scala JS demo.
- Quick start
- Why
- Usage
- Extra features
- Limitations
- FAQ
- Development tips
- Contributors
- Projects using coursier
Enable the SBT plugin by adding
addSbtPlugin("io.get-coursier" % "sbt-coursier" % "1.0.3")
to ~/.sbt/0.13/plugins/build.sbt
(enables it globally), or to the project/plugins.sbt
file
of an SBT project. Tested with SBT 0.13.8 / 0.13.9 / 0.13.11 / 0.13.12 / 0.13.13 / 0.13.15 / 0.13.16-M1 / 1.0.1-M5.
Download and run its launcher with
$ curl -L -o coursier https://git.io/vgvpD && chmod +x coursier && ./coursier --help
Alternatively on OS X, install it via homebrew,
$ brew install --HEAD coursier/formulas/coursier
Or on Archlinux, install it from AUR,
$ pacaur -S coursier
Run an application distributed via artifacts with
$ ./coursier launch com.lihaoyi:ammonite_2.11.8:0.7.0
Download and list the classpath of one or several dependencies with
$ ./coursier fetch org.apache.spark:spark-sql_2.11:1.6.1 com.twitter:algebird-spark_2.11:0.12.0
/path/to/.coursier/cache/v1/https/repo1.maven.org/maven2/com/twitter/algebird-spark_2.11/0.12.0/algebird-spark_2.11-0.12.0.jar
/path/to/.coursier/cache/v1/https/repo1.maven.org/maven2/com/twitter/algebird-core_2.11/0.12.0/algebird-core_2.11-0.12.0.jar
/path/to/.coursier/cache/v1/https/repo1.maven.org/maven2/org/apache/hadoop/hadoop-annotations/2.2.0/hadoop-annotations-2.2.0.jar
/path/to/.coursier/cache/v1/https/repo1.maven.org/maven2/org/tukaani/xz/1.0/xz-1.0.jar
...
If you use ZSH, simple tab-completions are available by copying the
scripts/_coursier
file into your completions directory, if you have one. If
you do not, then you can install the completions with,
mkdir -p ~/.zsh/completion
cp scripts/_coursier ~/.zsh/completion/
echo 'fpath=(~/.zsh/completion $fpath)' >> ~/.zshrc
echo 'autoload -Uz compinit ; compinit' >> ~/.zshrc
Add to your build.sbt
libraryDependencies ++= Seq(
"io.get-coursier" %% "coursier" % "1.0.3",
"io.get-coursier" %% "coursier-cache" % "1.0.3"
)
Note that the examples below are validated against the current sources of coursier. You may want to read the documentation of the latest release of coursier instead.
Add an import for coursier,
import coursier._
To resolve dependencies, first create a Resolution
case class with your dependencies in it,
val start = Resolution(
Set(
Dependency(
Module("org.scalaz", "scalaz-core_2.11"), "7.2.3"
),
Dependency(
Module("org.typelevel", "cats-core_2.11"), "0.6.0"
)
)
)
Create a fetch function able to get things from a few repositories via a local cache,
import coursier.util.Task
val repositories = Seq(
Cache.ivy2Local,
MavenRepository("https://repo1.maven.org/maven2")
)
val fetch = Fetch.from(repositories, Cache.fetch[Task]())
Then run the resolution per-se,
import scala.concurrent.ExecutionContext.Implicits.global
val resolution = start.process.run(fetch).unsafeRun()
That will fetch and use metadata.
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.
Then 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()
The default global cache used by coursier is ~/.coursier/cache/v1
. E.g. the artifact at
https://repo1.maven.org/maven2/org/scala-lang/scala-library/2.11.8/scala-library-2.11.8.jar
will land in ~/.coursier/cache/v1/https/repo1.maven.org/maven2/org/scala-lang/scala-library/2.11.8/scala-library-2.11.8.jar
.
From the SBT plugin, the default repositories are the ones provided by SBT (typically Central or JFrog, and ~/.ivy2/local
).
From the CLI tools, these are Central (https://repo1.maven.org/maven2
) and ~/.ivy2/local
.
From the API, these are specified manually - you are encouraged to use those too.
The current state of dependency management in Scala suffers several flaws, that prevent applications to fully profit from and rely on dependency management. Coursier aims at addressing these by making it easy to:
- resolve / download dependencies programmatically,
- launch applications distributed via Maven / Ivy artifacts from the command-line,
- work offline with artifacts,
- sandbox dependency management between projects.
As its API illustrates, getting artifacts of dependencies is just a matter of specifying these along with a few repositories. You can then straightforwardly get the corresponding artifacts, easily getting precise feedback about what goes on during the resolution.
Launching an application distributed via Maven artifacts is just a command away with the launcher of coursier. In most cases, just specifying the corresponding main dependency is enough to launch the corresponding application.
If all your dependencies are in cache, chances are coursier will not even try to connect to remote repositories. This also applies to snapshot dependencies of course - these are only updated on demand, not getting constantly in your way like is currently the case by default with SBT.
When using coursier from the command-line or via its SBT plugin, sandboxing is just one command away. Just do
export COURSIER_CACHE="$(pwd)/.coursier-cache"
, and the cache will become .coursier-cache
from the current
directory instead of the default global ~/.coursier/cache/v1
. This allows for example to quickly inspect the content
of the cache used by a particular project, in case you have any doubt about what's in it.
Enable the SBT plugin globally by adding
addSbtPlugin("io.get-coursier" % "sbt-coursier" % "1.0.3")
to ~/.sbt/0.13/plugins/build.sbt
To enable it on a per-project basis, add it only to the project/plugins.sbt
of an SBT project.
The SBT plugin has been tested only with SBT 0.13.8 / 0.13.9 / 0.13.11 / 0.13.12 / 0.13.13. It doesn't currently work with the SBT 1.0 milestones.
Once enabled, the update
, updateClassifiers
, and updateSbtClassifiers
commands are taken care of by coursier. These
provide more output about what's going on than their default implementations do.
Download and run its launcher with
$ curl -L -o coursier https://git.io/vgvpD && chmod +x coursier && ./coursier --help
The launcher itself weighs only 30 kB and can be easily embedded as is in other projects. It downloads the artifacts required to launch coursier on the first run.
Alternatively on OS X, install it via homebrew, that puts the coursier
launcher directly in your PATH,
$ brew install --HEAD coursier/formulas/coursier
$ ./coursier --help
lists the available coursier commands. The most notable ones are launch
, and fetch
. Type
$ ./coursier command --help
to get a description of the various options the command command
(replace with one
of the above command) accepts.
Both commands below can be given repositories with the -r
or --repository
option, like
-r central
-r https://oss.sonatype.org/content/repositories/snapshots
-r "ivy:https://repo.typesafe.com/typesafe/ivy-releases/[organisation]/[module]/(scala_[scalaVersion]/)(sbt_[sbtVersion]/)[revision]/[type]s/[artifact](-[classifier]).[ext]"
central
and ivy2local
correspond to Maven Central and ~/.ivy2/local
. These are used by default
unless the --no-default
option is specified.
Repositories starting with ivy:
are assumed to be Ivy repositories, specified with an Ivy pattern, like ivy:https://repo.typesafe.com/typesafe/ivy-releases/[organisation]/[module]/(scala_[scalaVersion]/)(sbt_[sbtVersion]/)[revision]/[type]s/[artifact](-[classifier]).[ext]
.
Else, a Maven repository is assumed.
To set credentials for a repository, pass a user and password in its URL, like
-r https://user:[email protected]/content/repositories/releases
The launch
command fetches a set of Maven coordinates it is given, along
with their transitive dependencies, then launches the "main main
class" from
it if it can find one (typically from the manifest of the first coordinates).
The main class to launch can also be manually specified with the -M
option.
For example, it can launch:
- Ammonite (enhanced Scala REPL),
$ ./coursier launch com.lihaoyi:ammonite_2.11.8:0.7.0
along with the REPLs of various JVM languages like
- Frege,
$ ./coursier launch -r central -r https://oss.sonatype.org/content/groups/public \
org.frege-lang:frege-repl-core:1.3 -M frege.repl.FregeRepl
- clojure,
$ ./coursier launch org.clojure:clojure:1.7.0 -M clojure.main
- jruby,
$ wget https://raw.githubusercontent.com/jruby/jruby/master/bin/jirb && \
./coursier launch org.jruby:jruby:9.0.4.0 -M org.jruby.Main -- -- jirb
- jython,
$ ./coursier launch org.python:jython-standalone:2.7.0 -M org.python.util.jython
- Groovy,
$ ./coursier launch org.codehaus.groovy:groovy-groovysh:2.4.5 -M org.codehaus.groovy.tools.shell.Main \
commons-cli:commons-cli:1.3.1
etc.
and various programs, like
- ProGuard and its utility Retrace,
$ ./coursier launch net.sf.proguard:proguard-base:5.2.1 -M proguard.ProGuard
$ ./coursier launch net.sf.proguard:proguard-retrace:5.2.1 -M proguard.retrace.ReTrace
- Wiremock,
./coursier launch com.github.tomakehurst:wiremock:1.57 -- \
--proxy-all="http://search.twitter.com" --record-mappings --verbose
- SQLLine,
$ ./coursier launch \
sqlline:sqlline:1.3.0 \
org.postgresql:postgresql:42.1.4 \
-M sqlline.SqlLine -- \
-d org.postgresql.Driver \
-n USERNAME \
-p PASSWORD \
-u jdbc:postgresql://HOST:PORT/DATABASE
If you wish to pass additional argument to the artifact being launched, separate them from the coursier's parameters list with the "--", just like in the Wiremock example above.
The fetch
command simply fetches a set of dependencies, along with their
transitive dependencies, then prints the local paths of all their artifacts.
Example
$ ./coursier fetch org.apache.spark:spark-sql_2.11:1.6.1
/path/to/.coursier/cache/v1/https/repo1.maven.org/maven2/org/apache/hadoop/hadoop-annotations/2.2.0/hadoop-annotations-2.2.0.jar
/path/to/.coursier/cache/v1/https/repo1.maven.org/maven2/org/tukaani/xz/1.0/xz-1.0.jar
/path/to/.coursier/cache/v1/https/repo1.maven.org/maven2/org/tachyonproject/tachyon-underfs-s3/0.8.2/tachyon-underfs-s3-0.8.2.jar
/path/to/.coursier/cache/v1/https/repo1.maven.org/maven2/org/glassfish/grizzly/grizzly-http/2.1.2/grizzly-http-2.1.2.jar
...
By adding the -p
option, these paths can be handed over directly to
java -cp
, like
$ java -cp "$(./coursier fetch -p com.lihaoyi:ammonite_2.11.8:0.7.0)" ammonite.Main
Loading...
Welcome to the Ammonite Repl 0.7.0
(Scala 2.11.8 Java 1.8.0_60)
@
Fetch with module level attributes, as opposed to e.g. --classifier
is applied globally.
$ ./coursier fetch org.apache.avro:avro:1.7.4,classifier=tests --artifact-type test-jar,jar
Fetch and generate a machine readable json report. Json Report Documentation
$ ./coursier fetch org.apache.avro:avro:1.7.4 --json-output-file report.json
The bootstrap
command generates tiny bootstrap launchers, able to pull their dependencies from
repositories on first launch. For example, the launcher of coursier is generated with a command like
$ ./coursier bootstrap \
io.get-coursier:coursier-cli_2.11:1.0.3 \
-f -o coursier
See ./coursier bootstrap --help
for a list of the available options.
The bootstrap
command can also generate scala-native executables. This requires the corresponding scala-native app to publish its JARs, on Maven Central for example, and your environment to be set up for scala-native. One can then generate executables with a command like
$ ./coursier bootstrap \
--native \
io.get-coursier:echo_native0.3_2.11:1.0.2 \
-o echo-native
[info] Linking (2354 ms)
[info] Discovered 1291 classes and 9538 methods
…
$ ./echo-native hey
hey
Add to your build.sbt
libraryDependencies ++= Seq(
"io.get-coursier" %% "coursier" % "1.0.3",
"io.get-coursier" %% "coursier-cache" % "1.0.3"
)
Note that the examples below are validated against the current sources of coursier. You may want to read the documentation of the latest release of coursier instead.
The first module, "io.get-coursier" %% "coursier" % "1.0.3"
, mainly depends on
scalaz-core
(and only it, not scalaz-concurrent
for example). It contains among others,
definitions,
mainly in Definitions.scala
,
Resolution
, representing a particular state of the resolution,
and ResolutionProcess
,
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" % "1.0.3"
, is precisely in charge of fetching
these input metadata. It uses scalaz.concurrent.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,
import coursier._
Resolving dependencies involves create an initial resolution state, with all the initial dependencies in it, like
val start = Resolution(
Set(
Dependency(
Module("org.typelevel", "cats-core_2.11"), "0.6.0"
),
Dependency(
Module("org.scalaz", "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 Resolution
s, until the final one.
start
above is only the initial state - it is far from over, as the isDone
method on it tells,
scala> start.isDone
res0: Boolean = false
In order for the resolution to go on, we'll need things from a few repositories,
scala> val repositories = Seq(
| Cache.ivy2Local,
| MavenRepository("https://repo1.maven.org/maven2")
| )
repositories: Seq[coursier.core.Repository] = List(IvyRepository(Pattern(List(Const(file://), Var(user.home), Const(/local/), Var(organisation), Const(/), Var(module), Const(/), Opt(WrappedArray(Const(scala_), Var(scalaVersion), Const(/))), Opt(WrappedArray(Const(sbt_), Var(sbtVersion), Const(/))), Var(revision), Const(/), Var(type), Const(s/), Var(artifact), Opt(WrappedArray(Const(-), Var(classifier))), Const(.), Var(ext))),None,None,true,true,true,true,None), MavenRepository(https://repo1.maven.org/maven2,None,true,None))
The first one, Cache.ivy2Local
, is defined in coursier.Cache
, itself from the coursier-cache
module that
we added above. As we can see, it is an IvyRepository
, picking things under ~/.ivy2/local
. An IvyRepository
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
this one.
Both IvyRepository
and MavenRepository
are case classes, so that it's straightforward to specify one's own
repositories.
To set credentials for a MavenRepository
or IvyRepository
, set their authentication
field, like
scala> import coursier.core.Authentication
import coursier.core.Authentication
scala> MavenRepository(
| "https://nexus.corp.com/content/repositories/releases",
| authentication = Some(Authentication("user", "pass"))
| )
res2: coursier.maven.MavenRepository = MavenRepository(https://nexus.corp.com/content/repositories/releases,None,true,Some(Authentication(user, *******)))
Now that we have repositories, we're going to mix these with things from the coursier-cache
module,
for resolution to happen via the cache. We'll create a function
of type 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 ((Artifact.Source, Project)
),
wrapping the whole in a monad F
.
val fetch = Fetch.from(repositories, Cache.fetch[Task]())
The monad used by Fetch.from
is scalaz.concurrent.Task
, but the resolution process is not tied to a particular
monad - any stack-safe monad would do.
With this fetch
method, we can now go on with the resolution. Calling process
on start
above gives a
ResolutionProcess
,
that drives the resolution. It is loosely inspired by the Process
of scalaz-stream.
It is an immutable structure, that represents the various states the resolution process can be in.
Its method current
gives the current Resolution
. Calling isDone
on the latter says whether the
resolution is done or not.
The 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.
Lastly, the 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 (isDone
) -
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.default
method above
a Cache.Logger
.
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 Cache.default
.
Now that the resolution is done, we can check for errors in
val errors: Seq[((Module, String), Seq[String])] = resolution.metadataErrors
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.
coursier is also compiled to Scala JS, and can be tested in the browser via its demo.
Changing things in cache are given a time-to-live (TTL) of 24 hours by default. Changing things are artifacts for versions ending with -SNAPSHOT
, Maven metadata files listing available versions, etc.
The most straightforward way of changing that consists in setting COURSIER_TTL
in the environment. It's parsed with scala.concurrent.duration.Duration
, so that things like 24 hours
, 5 min
, 10s
, or 0s
, are fine, and it accepts infinity (Inf
) as a duration.
E.g. to print the dependency tree of io.circe:circe-core:0.4.1
,
$ coursier resolve -t io.circe:circe-core_2.11:0.4.1
Result:
└─ io.circe:circe-core_2.11:0.4.1
├─ io.circe:circe-numbers_2.11:0.4.1
| └─ org.scala-lang:scala-library:2.11.8
├─ org.scala-lang:scala-library:2.11.8
└─ org.typelevel:cats-core_2.11:0.4.1
├─ com.github.mpilquist:simulacrum_2.11:0.7.0
| ├─ org.scala-lang:scala-library:2.11.7 -> 2.11.8
| └─ org.typelevel:macro-compat_2.11:1.1.0
| └─ org.scala-lang:scala-library:2.11.7 -> 2.11.8
...
From SBT, with sbt-coursier enabled, the command coursierDependencyTree
prints the dependency tree of the various sub-projects,
> coursierDependencyTree
io.get-coursier:coursier_2.11:1.0.1-SNAPSHOT
├─ com.lihaoyi:fastparse_2.11:0.3.7
| ├─ com.lihaoyi:fastparse-utils_2.11:0.3.7
| | ├─ com.lihaoyi:sourcecode_2.11:0.1.1
| | | └─ org.scala-lang:scala-library:2.11.7 -> 2.11.8
| | └─ org.scala-lang:scala-library:2.11.7 -> 2.11.8
| ├─ com.lihaoyi:sourcecode_2.11:0.1.1
| | └─ org.scala-lang:scala-library:2.11.7 -> 2.11.8
| └─ org.scala-lang:scala-library:2.11.7 -> 2.11.8
├─ org.jsoup:jsoup:1.9.2
...
Note that this command can be scoped to sub-projects, like proj/coursierDependencyTree
.
The printed trees highlight version bumps, that only change the patch number, in yellow. The 2.11.7 -> 2.11.8
above mean that the parent dependency wanted version 2.11.7
, but version 2.11.8
landed in the classpath, pulled in this version by other dependencies.
They highlight in red version bumps that may not be binary compatible, changing major or minor version number.
The coursier bootstrap
command generates tiny bootstrap launchers (~30 kB). These are able to download their dependencies upon first launch, then launch the corresponding application. E.g. to generate a launcher for scalafmt,
$ coursier bootstrap com.geirsson:scalafmt-cli_2.11:0.2.3 -o scalafmt
This generates a scalafmt
file, which is a tiny JAR, corresponding to the bootstrap
sub-project of coursier. It contains resource files, with the URLs of the various dependencies of scalafmt. On first launch, these are downloaded under ~/.coursier/bootstrap/com.geirsson/scalafmt-cli_2.11
(following the organization and name of the first dependency - note that this directory can be changed with the -D
option). Nothing needs to be downloaded once all the dependencies are there, and the application is then launched straightaway.
To use artifacts from repositories requiring credentials, pass the user and password via the repository URL, like
$ coursier fetch -r https://user:[email protected]/repo com.company:lib:0.1.0
From SBT, add the setting coursierUseSbtCredentials := true
for sbt-coursier to use the credentials set via the credentials
key. This manual step was added in order for the credentials
setting not to be checked if not needed, as it seems to acquire some (good ol') global lock when checked, which sbt-coursier aims at avoiding.
By default, coursier and sbt-coursier handle the http://
, https://
, and file://
protocols. It should also be fine
by protocols supported by java.net.URL
(not thoroughly tested). Support for other protocols can be added via plugins. coursier-s3, a plugin for S3, is under development, and illustrates how to write such plugins.
The minimum was made for SBT plugins to be resolved fine (including dependencies between plugins, the possibility that some of them come from Maven repositories, with a peculiarities, classifiers - sources, javadoc - should be fine too). So it is likely that projects relying more heavily on Ivy features could run into the limitations of the current implementation.
Any issue report related to that, illustrated with public Ivy repositories if possible, would be greatly appreciated.
SBT seems to require the update
command to generate a few metadata files
later used by publish
. If ever there's an issue with these, this might
add discrepancies in the artifacts published with publish
or publishLocal
.
Should you want to use the coursier SBT plugin while publishing artifacts at the
same time, I'd recommend an extreme caution at first, like manually inspecting
the metadata files and compare with previous ones, to ensure everything's fine.
coursier publishes its artifacts with its own plugin enabled since version
1.0.0-M2
though, without any apparent problem.
If ever resolution or artifact downloading stumbles upon a locked metadata or artifact in the cache, it will just fail, instead of waiting for the lock to be freed.
Plus the inherent amount of bugs arising in a young project :-)
Even though the coursier SBT plugin is enabled and some coursier*
keys can be found from the SBT prompt, dependency resolution seems still to be handled by SBT itself. Why?
Check that the default SBT settings (sbt.Defaults.defaultSettings
) are not manually added to your project.
These define commands that the coursier SBT plugin overrides. Adding them again erases these overrides,
effectively disabling coursier.
This error originates from the org.jboss.netty:netty:3.2.2.Final
dependency to be put in the classpath.
Exclude it from your spark dependencies with the exclusion org.jboss.netty:netty
.
Coursier tries to follow the Maven documentation to build the full dependency set, in particular
some points about dependency exclusion.
Inspecting the org.apache.spark:spark-core_2.11:1.5.2
dependency graph shows that spark-core
depends on org.jboss.netty:netty:3.2.2.Final
via the following path: org.apache.spark:spark-core_2.11:1.5.2
->
org.tachyonproject:tachyon-client:0.7.1
-> org.apache.curator:curator-framework:2.4.0
->
org.apache.zookeeper:zookeeper:3.4.5
-> org.jboss.netty:netty:3.2.2.Final
. Even though
spark-core tries to exclude org.jboss.netty:netty
to land in its classpath via some other dependencies
(e.g. it excludes it via its dependencies towards org.apache.hadoop:hadoop-client
and org.apache.curator:curator-recipes
),
it does not via the former path. So it depends on it according to the
Maven documentation.
This is likely unintended, as it leads to exceptions like
java.lang.VerifyError: (class: org/jboss/netty/channel/socket/nio/NioWorkerPool, method: createWorker signature: (Ljava/util/concurrent/Executor;)Lorg/jboss/netty/channel/socket/nio/AbstractNioWorker;) Wrong return type in function
Excluding org.jboss.netty:netty
from the spark dependencies fixes it.
On first launch, the coursier launcher downloads a 1.5+ MB JAR. Is it possible to have a standalone launcher, that would not need to download things on first launch?
Run scripts/generate-launcher.sh -s
from the root of the coursier sources. That will generate a new (bigger) coursier
launcher, that needs not to download anything on first launch.
Download it from the same link as the command above. Then run from a console, in the directory where the coursier
launcher is,
> java -noverify -jar coursier
The -noverify
option seems to be required after the proguarding step of the main JAR of coursier.
Set the COURSIER_CACHE
prior to running coursier
or SBT, like
$ COURSIER_CACHE=$(pwd)/.coursier-cache coursier
or
$ COURSIER_CACHE=$(pwd)/.coursier-cache sbt
In general, as coursier has a few modules that target either only scala 2.10 or 2.11, it is recommended
to systematically force the scala version, with the ++2.11.8
or ++2.10.6
commands. The cli
module
in particular is only built in 2.11, and the plugin
one only in 2.10.
Set scalaVersion
to 2.10.6
in build.sbt
. Then re-open / reload the coursier project.
They require npm install
to have been run once from the coursier
directory or a subdirectory of
it. They can then be run with sbt testsJS/test
.
Run
$ sbt "~cli/pack"
This generates and updates a runnable distribution of coursier in target/pack
, via
the sbt-pack plugin.
It can be run from another terminal with
$ cli/target/pack/bin/coursier
See the up-to-date list of contributors on GitHub.
Don't hesitate to pick an issue to contribute, and / or ask for help for how to proceed on the Gitter channel.
- Lars Hupel's libisabelle fetches some of its requirements via coursier,
- jupyter-scala is launched and allows to add dependencies in its sessions with coursier (initial motivation for writing coursier),
- Apache Toree - formerly known as spark-kernel, is now using coursier to add dependencies on-the-fly (#4),
- Quill is using coursier for faster dependency resolution (#591),
- vscode-scala uses coursier to fetch and launch its ensime-based server,
- Ammonite uses coursier to fetch user-added dependencies since version
0.9.0
, - ensime-sbt uses coursier to get the ensime server classpath,
- scalafmt relies on coursier for its CLI installation,
- scalafiddle uses coursier to fetch user-added dependencies,
- Your project here :-)
Thanks to JProfiler for having kindly granted an Open Source license to help for the development of coursier.
Released under the Apache license, v2.