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package mill
package scalalib
import coursier.Repository
import coursier.core.Dependency
import coursier.core.Resolution
import coursier.parse.JavaOrScalaModule
import coursier.parse.ModuleParser
import coursier.util.ModuleMatcher
import mainargs.{Flag, arg}
import mill.Agg
import mill.api.{Ctx, JarManifest, MillException, PathRef, Result, internal}
import mill.define.{Command, ModuleRef, Segment, Task, TaskModule}
import mill.scalalib.internal.ModuleUtils
import mill.scalalib.api.CompilationResult
import mill.scalalib.bsp.{BspBuildTarget, BspModule, BspUri, JvmBuildTarget}
import mill.scalalib.publish.Artifact
import mill.util.Jvm
import os.{Path, ProcessOutput}
import scala.annotation.nowarn
/**
* Core configuration required to compile a single Java compilation target
*/
trait JavaModule
extends mill.Module
with WithZincWorker
with TestModule.JavaModuleBase
with TaskModule
with RunModule
with GenIdeaModule
with CoursierModule
with OfflineSupportModule
with BspModule
with SemanticDbJavaModule { outer =>
override def zincWorker: ModuleRef[ZincWorkerModule] = super.zincWorker
@nowarn
type JavaTests = JavaModuleTests
@deprecated("Use JavaTests instead", since = "Mill 0.11.10")
trait JavaModuleTests extends JavaModule with TestModule {
// Run some consistence checks
hierarchyChecks()
override def resources = super[JavaModule].resources
override def moduleDeps: Seq[JavaModule] = Seq(outer)
override def repositoriesTask: Task[Seq[Repository]] = outer.repositoriesTask
override def resolutionCustomizer: Task[Option[coursier.Resolution => coursier.Resolution]] =
outer.resolutionCustomizer
override def javacOptions: T[Seq[String]] = T { outer.javacOptions() }
override def zincWorker: ModuleRef[ZincWorkerModule] = outer.zincWorker
override def skipIdea: Boolean = outer.skipIdea
override def runUseArgsFile: T[Boolean] = T { outer.runUseArgsFile() }
override def sources = T.sources {
for (src <- outer.sources()) yield {
PathRef(this.millSourcePath / src.path.relativeTo(outer.millSourcePath))
}
}
/**
* JavaModule and its derivates define inner test modules.
* To avoid unexpected misbehavior due to the use of the wrong inner test trait
* we apply some hierarchy consistency checks.
* If for some reasons, those are too restrictive to you, you can override this method.
* @throws MillException
*/
protected def hierarchyChecks(): Unit = {
val outerInnerSets = Seq(
("mill.scalajslib.ScalaJSModule", "ScalaJSTests"),
("mill.scalanativelib.ScalaNativeModule", "ScalaNativeTests"),
("mill.scalalib.SbtModule", "SbtModuleTests"),
("mill.scalalib.MavenModule", "MavenModuleTests")
)
for {
(mod, testModShort) <- outerInnerSets
testMod = s"${mod}$$${testModShort}"
}
try {
if (Class.forName(mod).isInstance(outer) && !Class.forName(testMod).isInstance(this))
throw new MillException(
s"$outer is a `${mod}`. $this needs to extend `${testModShort}`."
)
} catch {
case _: ClassNotFoundException => // if we can't find the classes, we certainly are not in a ScalaJSModule
}
}
}
def defaultCommandName(): String = "run"
def resolvePublishDependency: Task[Dep => publish.Dependency] = T.task {
Artifact.fromDepJava(_: Dep)
}
/**
* Allows you to specify an explicit main class to use for the `run` command.
* If none is specified, the classpath is searched for an appropriate main
* class to use if one exists
*/
def mainClass: T[Option[String]] = None
def finalMainClassOpt: T[Either[String, String]] = T {
mainClass() match {
case Some(m) => Right(m)
case None =>
zincWorker().worker().discoverMainClasses(compile()) match {
case Seq() => Left("No main class specified or found")
case Seq(main) => Right(main)
case mains =>
Left(
s"Multiple main classes found (${mains.mkString(",")}) " +
"please explicitly specify which one to use by overriding `mainClass` " +
"or using `runMain <...args>` instead of `run`"
)
}
}
}
def finalMainClass: T[String] = T {
finalMainClassOpt() match {
case Right(main) => Result.Success(main)
case Left(msg) => Result.Failure(msg)
}
}
/**
* Mandatory ivy dependencies that are typically always required and shouldn't be removed by
* overriding [[ivyDeps]], e.g. the scala-library in the [[ScalaModule]].
*/
def mandatoryIvyDeps: T[Agg[Dep]] = T { Agg.empty[Dep] }
/**
* Any ivy dependencies you want to add to this Module, in the format
* ivy"org::name:version" for Scala dependencies or ivy"org:name:version"
* for Java dependencies
*/
def ivyDeps: T[Agg[Dep]] = T { Agg.empty[Dep] }
/**
* Aggregation of mandatoryIvyDeps and ivyDeps.
* In most cases, instead of overriding this Target you want to override `ivyDeps` instead.
*/
def allIvyDeps: T[Agg[Dep]] = T { mandatoryIvyDeps() ++ ivyDeps() }
/**
* Same as `ivyDeps`, but only present at compile time. Useful for e.g.
* macro-related dependencies like `scala-reflect` that doesn't need to be
* present at runtime
*/
def compileIvyDeps: T[Agg[Dep]] = T { Agg.empty[Dep] }
/**
* Additional dependencies, only present at runtime. Useful for e.g.
* selecting different versions of a dependency to use at runtime after your
* code has already been compiled.
*/
def runIvyDeps: T[Agg[Dep]] = T { Agg.empty[Dep] }
/**
* Options to pass to the java compiler
*/
def javacOptions: T[Seq[String]] = T { Seq.empty[String] }
/**
* Additional options for the java compiler derived from other module settings.
*/
def mandatoryJavacOptions: T[Seq[String]] = T { Seq.empty[String] }
/**
* The direct dependencies of this module.
* This is meant to be overridden to add dependencies.
* To read the value, you should use [[moduleDepsChecked]] instead,
* which uses a cached result which is also checked to be free of cycle.
* @see [[moduleDepschecked]]
*/
def moduleDeps: Seq[JavaModule] = Seq.empty
/**
* Same as [[moduleDeps]] but checked to not contain cycles.
* Prefer this over using [[moduleDeps]] directly.
*/
final def moduleDepsChecked: Seq[JavaModule] = {
// trigger initialization to check for cycles
recModuleDeps
moduleDeps
}
/** Should only be called from [[moduleDepsChecked]] */
private lazy val recModuleDeps: Seq[JavaModule] =
ModuleUtils.recursive[JavaModule](
(millModuleSegments ++ Seq(Segment.Label("moduleDeps"))).render,
this,
_.moduleDeps
)
/** The compile-only direct dependencies of this module. */
def compileModuleDeps: Seq[JavaModule] = Seq.empty
/** Same as [[compileModuleDeps]] but checked to not contain cycles. */
final def compileModuleDepsChecked: Seq[JavaModule] = {
// trigger initialization to check for cycles
recCompileModuleDeps
compileModuleDeps
}
/** Should only be called from [[compileModuleDeps]] */
private lazy val recCompileModuleDeps: Seq[JavaModule] =
ModuleUtils.recursive[JavaModule](
(millModuleSegments ++ Seq(Segment.Label("compileModuleDeps"))).render,
this,
_.compileModuleDeps
)
/** The direct and indirect dependencies of this module */
def recursiveModuleDeps: Seq[JavaModule] = {
// moduleDeps.flatMap(_.transitiveModuleDeps).distinct
recModuleDeps
}
/**
* Like `recursiveModuleDeps` but also include the module itself,
* basically the modules whose classpath are needed at runtime
*/
def transitiveModuleDeps: Seq[JavaModule] = Seq(this) ++ recursiveModuleDeps
/**
* All direct and indirect module dependencies of this module, including
* compile-only dependencies: basically the modules whose classpath are needed
* at compile-time.
*
* Note that `compileModuleDeps` are defined to be non-transitive, so we only
* look at the direct `compileModuleDeps` when assembling this list
*/
def transitiveModuleCompileModuleDeps: Seq[JavaModule] = {
(moduleDepsChecked ++ compileModuleDepsChecked).flatMap(_.transitiveModuleDeps).distinct
}
/** The compile-only transitive ivy dependencies of this module and all it's upstream compile-only modules. */
def transitiveCompileIvyDeps: T[Agg[BoundDep]] = T {
// We never include compile-only dependencies transitively, but we must include normal transitive dependencies!
compileIvyDeps().map(bindDependency()) ++
T.traverse(compileModuleDepsChecked)(_.transitiveIvyDeps)().flatten
}
/**
* Show the module dependencies.
* @param recursive If `true` include all recursive module dependencies, else only show direct dependencies.
*/
def showModuleDeps(recursive: Boolean = false): Command[Unit] = T.command {
val normalDeps = if (recursive) recursiveModuleDeps else moduleDepsChecked
val compileDeps =
if (recursive) compileModuleDepsChecked.flatMap(_.transitiveModuleDeps).distinct
else compileModuleDepsChecked
val deps = (normalDeps ++ compileDeps).distinct
val asString =
s"${if (recursive) "Recursive module"
else "Module"} dependencies of ${millModuleSegments.render}:\n\t${deps
.map { dep =>
dep.millModuleSegments.render ++
(if (compileModuleDepsChecked.contains(dep) || !normalDeps.contains(dep)) " (compile)"
else "")
}
.mkString("\n\t")}"
T.log.outputStream.println(asString)
}
/**
* Additional jars, classfiles or resources to add to the classpath directly
* from disk rather than being downloaded from Maven Central or other package
* repositories
*/
def unmanagedClasspath: T[Agg[PathRef]] = T { Agg.empty[PathRef] }
/**
* The transitive ivy dependencies of this module and all it's upstream modules.
* This is calculated from [[ivyDeps]], [[mandatoryIvyDeps]] and recursively from [[moduleDeps]].
*/
def transitiveIvyDeps: T[Agg[BoundDep]] = T {
(ivyDeps() ++ mandatoryIvyDeps()).map(bindDependency()) ++
T.traverse(moduleDepsChecked)(_.transitiveIvyDeps)().flatten
}
/**
* The upstream compilation output of all this module's upstream modules
*/
def upstreamCompileOutput: T[Seq[CompilationResult]] = T {
T.traverse(transitiveModuleCompileModuleDeps)(_.compile)
}
/**
* The transitive version of `localClasspath`
*/
def transitiveLocalClasspath: T[Agg[PathRef]] = T {
T.traverse(transitiveModuleCompileModuleDeps)(_.localClasspath)().flatten
}
/**
* Same as [[transitiveLocalClasspath]], but with all dependencies on [[compile]]
* replaced by their non-compiling [[bspCompileClassesPath]] variants.
*
* Keep in sync with [[transitiveLocalClasspath]]
*/
@internal
def bspTransitiveLocalClasspath: T[Agg[UnresolvedPath]] = T {
T.traverse(transitiveModuleCompileModuleDeps)(_.bspLocalClasspath)().flatten
}
/**
* The transitive version of `compileClasspath`
*/
def transitiveCompileClasspath: T[Agg[PathRef]] = T {
T.traverse(transitiveModuleCompileModuleDeps)(m =>
T.task { m.localCompileClasspath() ++ Agg(m.compile().classes) }
)().flatten
}
/**
* Same as [[transitiveCompileClasspath]], but with all dependencies on [[compile]]
* replaced by their non-compiling [[bspCompileClassesPath]] variants.
*
* Keep in sync with [[transitiveCompileClasspath]]
*/
@internal
def bspTransitiveCompileClasspath: T[Agg[UnresolvedPath]] = T {
T.traverse(transitiveModuleCompileModuleDeps)(m =>
T.task {
m.localCompileClasspath().map(p => UnresolvedPath.ResolvedPath(p.path)) ++
Agg(m.bspCompileClassesPath())
}
)()
.flatten
}
/**
* What platform suffix to use for publishing, e.g. `_sjs` for Scala.js
* projects
*/
def platformSuffix: T[String] = T { "" }
/**
* What shell script to use to launch the executable generated by `assembly`.
* Defaults to a generic "universal" launcher that should work for Windows,
* OS-X and Linux
*/
def prependShellScript: T[String] = T {
finalMainClassOpt().toOption match {
case None => ""
case Some(cls) =>
mill.util.Jvm.launcherUniversalScript(
mainClass = cls,
shellClassPath = Agg("$0"),
cmdClassPath = Agg("%~dpnx0"),
jvmArgs = forkArgs()
)
}
}
/**
* Configuration for the [[assembly]] task: how files and file-conflicts are
* managed when combining multiple jar files into one big assembly jar.
*/
def assemblyRules: Seq[Assembly.Rule] = Assembly.defaultRules
/**
* The folders where the source files for this module live
*/
def sources: T[Seq[PathRef]] = T.sources { millSourcePath / "src" }
/**
* The folders where the resource files for this module live.
* If you need resources to be seen by the compiler, use [[compileResources]].
*/
def resources: T[Seq[PathRef]] = T.sources { millSourcePath / "resources" }
/**
* The folders where the compile time resource files for this module live.
* If your resources files do not necessarily need to be seen by the compiler,
* you should use [[resources]] instead.
*/
def compileResources: T[Seq[PathRef]] = T.sources { millSourcePath / "compile-resources" }
/**
* Folders containing source files that are generated rather than
* hand-written; these files can be generated in this target itself,
* or can refer to files generated from other targets
*/
def generatedSources: T[Seq[PathRef]] = T { Seq.empty[PathRef] }
/**
* The folders containing all source files fed into the compiler
*/
def allSources: T[Seq[PathRef]] = T { sources() ++ generatedSources() }
/**
* All individual source files fed into the Java compiler
*/
def allSourceFiles: T[Seq[PathRef]] = T {
Lib.findSourceFiles(allSources(), Seq("java")).map(PathRef(_))
}
/**
* If `true`, we always show problems (errors, warnings, infos) found in all source files, even when they have not changed since the previous incremental compilation.
* When `false`, we report only problems for files which we re-compiled.
*/
def zincReportCachedProblems: T[Boolean] = T.input {
sys.props.getOrElse(
"mill.scalalib.JavaModule.zincReportCachedProblems",
"false"
).equalsIgnoreCase("true")
}
def zincIncrementalCompilation: T[Boolean] = T {
true
}
/**
* Compiles the current module to generate compiled classfiles/bytecode.
*
* When you override this, you probably also want/need to override [[bspCompileClassesPath]],
* as that needs to point to the same compilation output path.
*
* Keep in sync with [[bspCompileClassesPath]]
*/
def compile: T[mill.scalalib.api.CompilationResult] = T.persistent {
zincWorker()
.worker()
.compileJava(
upstreamCompileOutput = upstreamCompileOutput(),
sources = allSourceFiles().map(_.path),
compileClasspath = compileClasspath().map(_.path),
javacOptions = javacOptions() ++ mandatoryJavacOptions(),
reporter = T.reporter.apply(hashCode),
reportCachedProblems = zincReportCachedProblems(),
incrementalCompilation = zincIncrementalCompilation()
)
}
/**
* The path to the compiled classes by [[compile]] without forcing to actually run the compilation.
* This is safe in an BSP context, as the compilation done later will use the
* exact same compilation settings, so we can safely use the same path.
*
* Keep in sync with [[compile]]
*/
@internal
def bspCompileClassesPath: T[UnresolvedPath] =
if (compile.ctx.enclosing == s"${classOf[JavaModule].getName}#compile") {
T {
T.log.debug(
s"compile target was not overridden, assuming hard-coded classes directory for target ${compile}"
)
UnresolvedPath.DestPath(os.sub / "classes", compile.ctx.segments, compile.ctx.foreign)
}
} else {
T {
T.log.debug(
s"compile target was overridden, need to actually execute compilation to get the compiled classes directory for target ${compile}"
)
UnresolvedPath.ResolvedPath(compile().classes.path)
}
}
/**
* The part of the [[localClasspath]] which is available "after compilation".
*
* Keep in sync with [[bspLocalRunClasspath]]
*/
override def localRunClasspath: T[Seq[PathRef]] = T {
super.localRunClasspath() ++ resources() ++
Agg(compile().classes)
}
/**
* Same as [[localRunClasspath]] but for use in BSP server.
*
* Keep in sync with [[localRunClasspath]]
*/
def bspLocalRunClasspath: T[Agg[UnresolvedPath]] = T {
Agg.from(super.localRunClasspath() ++ resources())
.map(p => UnresolvedPath.ResolvedPath(p.path)) ++
Agg(bspCompileClassesPath())
}
/**
* The *output* classfiles/resources from this module, used for execution,
* excluding upstream modules and third-party dependencies, but including unmanaged dependencies.
*
* This is build from [[localCompileClasspath]] and [[localRunClasspath]]
* as the parts available "before compilation" and "after compiliation".
*
* Keep in sync with [[bspLocalClasspath]]
*/
def localClasspath: T[Seq[PathRef]] = T {
localCompileClasspath().toSeq ++ localRunClasspath()
}
/**
* Same as [[localClasspath]], but with all dependencies on [[compile]]
* replaced by their non-compiling [[bspCompileClassesPath]] variants.
*
* Keep in sync with [[localClasspath]]
*/
@internal
def bspLocalClasspath: T[Agg[UnresolvedPath]] = T {
(localCompileClasspath()).map(p => UnresolvedPath.ResolvedPath(p.path)) ++
bspLocalRunClasspath()
}
/**
* All classfiles and resources from upstream modules and dependencies
* necessary to compile this module.
*
* Keep in sync with [[bspCompileClasspath]]
*/
def compileClasspath: T[Agg[PathRef]] = T {
resolvedIvyDeps() ++ transitiveCompileClasspath() ++ localCompileClasspath()
}
/**
* Same as [[compileClasspath]], but does not trigger compilation targets, if possible.
*
* Keep in sync with [[compileClasspath]]
*/
@internal
def bspCompileClasspath: T[Agg[UnresolvedPath]] = T {
resolvedIvyDeps().map(p => UnresolvedPath.ResolvedPath(p.path)) ++
bspTransitiveCompileClasspath() ++
localCompileClasspath().map(p => UnresolvedPath.ResolvedPath(p.path))
}
/**
* The *input* classfiles/resources from this module, used during compilation,
* excluding upstream modules and third-party dependencies
*/
def localCompileClasspath: T[Agg[PathRef]] = T {
compileResources() ++ unmanagedClasspath()
}
/**
* Resolved dependencies based on [[transitiveIvyDeps]] and [[transitiveCompileIvyDeps]].
*/
def resolvedIvyDeps: T[Agg[PathRef]] = T {
def resolvedIvyDeps0() =
defaultResolver().resolveDeps(transitiveCompileIvyDeps() ++ transitiveIvyDeps())
try resolvedIvyDeps0()
catch {
case e: java.nio.file.AccessDeniedException =>
resolvedIvyDeps0() // this is caused by a coursier race condition on windows, just retry
}
}
/**
* All upstream classfiles and resources necessary to build and executable
* assembly, but without this module's contribution
*/
def upstreamAssemblyClasspath: T[Agg[PathRef]] = T {
resolvedRunIvyDeps() ++ transitiveLocalClasspath()
}
def resolvedRunIvyDeps: T[Agg[PathRef]] = T {
defaultResolver().resolveDeps(runIvyDeps().map(bindDependency()) ++ transitiveIvyDeps())
}
/**
* All classfiles and resources from upstream modules and dependencies
* necessary to run this module's code after compilation
*/
override def runClasspath: T[Seq[PathRef]] = T {
super.runClasspath() ++
resolvedRunIvyDeps().toSeq ++
transitiveLocalClasspath() ++
localClasspath()
}
/**
* Creates a manifest representation which can be modified or replaced
* The default implementation just adds the `Manifest-Version`, `Main-Class` and `Created-By` attributes
*/
def manifest: T[JarManifest] = T {
Jvm.createManifest(finalMainClassOpt().toOption)
}
/**
* Build the assembly for upstream dependencies separate from the current
* classpath
*
* This should allow much faster assembly creation in the common case where
* upstream dependencies do not change
*
* This implementation is deprecated because of it's return value.
* Please use [[upstreamAssembly2]] instead.
*/
@deprecated("Use upstreamAssembly2 instead, which has a richer return value", "Mill 0.11.8")
def upstreamAssembly: T[PathRef] = T {
T.log.error(
s"upstreamAssembly target is deprecated and should no longer used." +
s" Please make sure to use upstreamAssembly2 instead."
)
upstreamAssembly2().pathRef
}
/**
* Build the assembly for upstream dependencies separate from the current
* classpath
*
* This should allow much faster assembly creation in the common case where
* upstream dependencies do not change
*/
def upstreamAssembly2: T[Assembly] = T {
Assembly.create(
destJar = T.dest / "out.jar",
inputPaths = upstreamAssemblyClasspath().map(_.path),
manifest = manifest(),
assemblyRules = assemblyRules
)
}
/**
* An executable uber-jar/assembly containing all the resources and compiled
* classfiles from this module and all it's upstream modules and dependencies
*/
def assembly: T[PathRef] = T {
// detect potential inconsistencies due to `upstreamAssembly` deprecation after 0.11.7
if (
(upstreamAssembly.ctx.enclosing: @nowarn) != s"${classOf[JavaModule].getName}#upstreamAssembly"
) {
T.log.error(
s"${upstreamAssembly.ctx.enclosing: @nowarn} is overriding a deprecated target which is no longer used." +
s" Please make sure to override upstreamAssembly2 instead."
)
}
val prependScript = Option(prependShellScript()).filter(_ != "")
val upstream = upstreamAssembly2()
val created = Assembly.create(
destJar = T.dest / "out.jar",
Agg.from(localClasspath().map(_.path)),
manifest(),
prependScript,
Some(upstream.pathRef.path),
assemblyRules
)
// See https://github.com/com-lihaoyi/mill/pull/2655#issuecomment-1672468284
val problematicEntryCount = 65535
if (
prependScript.isDefined &&
(upstream.addedEntries + created.addedEntries) > problematicEntryCount
) {
Result.Failure(
s"""The created assembly jar contains more than ${problematicEntryCount} ZIP entries.
|JARs of that size are known to not work correctly with a prepended shell script.
|Either reduce the entries count of the assembly or disable the prepended shell script with:
|
| def prependShellScript = ""
|""".stripMargin,
Some(created.pathRef)
)
} else {
Result.Success(created.pathRef)
}
}
/**
* A jar containing only this module's resources and compiled classfiles,
* without those from upstream modules and dependencies
*/
def jar: T[PathRef] = T {
Jvm.createJar(localClasspath().map(_.path).filter(os.exists), manifest())
}
/**
* Additional options to be used by the javadoc tool.
* You should not set the `-d` setting for specifying the target directory,
* as that is done in the [[docJar]] target.
*/
def javadocOptions: T[Seq[String]] = T { Seq[String]() }
/**
* Directories to be processed by the API documentation tool.
*
* Typically includes the source files to generate documentation from.
* @see [[docResources]]
*/
def docSources: T[Seq[PathRef]] = T.sources(allSources())
/**
* Extra directories to be copied into the documentation.
*
* Typically includes static files such as html and markdown, but depends
* on the doc tool that is actually used.
* @see [[docSources]]
*/
def docResources: T[Seq[PathRef]] = T.sources(millSourcePath / "docs")
/**
* Control whether `docJar`-target should use a file to pass command line arguments to the javadoc tool.
* Defaults to `true` on Windows.
* Beware: Using an args-file is probably not supported for very old javadoc versions.
*/
def docJarUseArgsFile: T[Boolean] = T { scala.util.Properties.isWin }
/**
* The documentation jar, containing all the Javadoc/Scaladoc HTML files, for
* publishing to Maven Central
*/
def docJar: T[PathRef] = T[PathRef] {
val outDir = T.dest
val javadocDir = outDir / "javadoc"
os.makeDir.all(javadocDir)
val files = Lib.findSourceFiles(docSources(), Seq("java"))
if (files.nonEmpty) {
val classPath = compileClasspath().iterator.map(_.path).filter(_.ext != "pom").toSeq
val cpOptions =
if (classPath.isEmpty) Seq()
else Seq(
"-classpath",
classPath.mkString(java.io.File.pathSeparator)
)
val options = javadocOptions() ++
Seq("-d", javadocDir.toString) ++
cpOptions ++
files.map(_.toString)
val cmdArgs =
if (docJarUseArgsFile()) {
val content = options.map(s =>
// make sure we properly mask backslashes (path separators on Windows)
s""""${s.replace("\\", "\\\\")}""""
).mkString(" ")
val argsFile = os.temp(
contents = content,
prefix = "javadoc-",
deleteOnExit = false,
dir = outDir
)
T.log.debug(
s"Creating javadoc options file @${argsFile} ..."
)
Seq(s"@${argsFile}")
} else {
options
}
T.log.info("options: " + cmdArgs)
Jvm.runSubprocess(
commandArgs = Seq(Jvm.jdkTool("javadoc")) ++ cmdArgs,
envArgs = Map(),
workingDir = T.dest
)
}
Jvm.createJar(Agg(javadocDir))(outDir)
}
/**
* The source jar, containing only source code for publishing to Maven Central
*/
def sourceJar: T[PathRef] = T {
Jvm.createJar(
(allSources() ++ resources() ++ compileResources()).map(_.path).filter(os.exists),
manifest()
)
}
/**
* Any command-line parameters you want to pass to the forked JVM under `run`,
* `test` or `repl`
*/
override def forkArgs: T[Seq[String]] = T {
// overridden here for binary compatibility (0.11.x)
super.forkArgs()
}
/**
* Any environment variables you want to pass to the forked JVM under `run`,
* `test` or `repl`
*/
override def forkEnv: T[Map[String, String]] = T {
// overridden here for binary compatibility (0.11.x)
super.forkEnv()
}
/**
* Builds a command-line "launcher" file that can be used to run this module's
* code, without the Mill process. Useful for deployment & other places where
* you do not want a build tool running
*/
def launcher = T {
Result.Success(
Jvm.createLauncher(
finalMainClass(),
runClasspath().map(_.path),
forkArgs()
)
)
}
/**
* Task that print the transitive dependency tree to STDOUT.
* NOTE: that when `whatDependsOn` is used with `inverse` it will just
* be ignored since when using `whatDependsOn` the tree _must_ be
* inversed to work, so this will always be set as true.
* @param inverse Invert the tree representation, so that the root is on the bottom.
* @param additionalDeps Additional dependency to be included into the tree.
* @param whatDependsOn possible list of modules to target in the tree in order to see
* where a dependency stems from.
*/
protected def printDepsTree(
inverse: Boolean,
additionalDeps: Task[Agg[BoundDep]],
whatDependsOn: List[JavaOrScalaModule]
): Task[Unit] =
T.task {
val (flattened: Seq[Dependency], resolution: Resolution) = Lib.resolveDependenciesMetadata(
repositoriesTask(),
additionalDeps() ++ transitiveIvyDeps(),
Some(mapDependencies()),
customizer = resolutionCustomizer(),
coursierCacheCustomizer = coursierCacheCustomizer()
)
val roots = whatDependsOn match {
case List() => flattened
case _ =>
// We don't really care what scalaVersions is set as here since the user
// will be passing in `_2.13` or `._3` anyways. Or it may even be a java
// dependency. Looking at the usage upstream, it seems that this is set if
// it can be or else defaults to "". Using it, I haven't been able to see
// any difference whether or not it's set, and by using "" it greatly simplifies
// it.
val matchers = whatDependsOn
.map(module => module.module(scalaVersion = ""))
.map(module => ModuleMatcher(module))
resolution.minDependencies
.filter(dep => matchers.exists(matcher => matcher.matches(dep.module))).toSeq
}
println(
coursier.util.Print.dependencyTree(
resolution = resolution,
roots = roots,
printExclusions = false,
reverse = if (whatDependsOn.isEmpty) inverse else true
)
)
Result.Success(())
}
/**
* Command to print the transitive dependency tree to STDOUT.
*/
def ivyDepsTree(args: IvyDepsTreeArgs = IvyDepsTreeArgs()): Command[Unit] = {
val (invalidModules, validModules) =
args.whatDependsOn.map(ModuleParser.javaOrScalaModule(_)).partitionMap(identity)
if (invalidModules.isEmpty) {
(args.withCompile, args.withRuntime) match {
case (Flag(true), Flag(true)) =>
T.command {
printDepsTree(
args.inverse.value,
T.task {
transitiveCompileIvyDeps() ++ runIvyDeps().map(bindDependency())
},
validModules
)()
}
case (Flag(true), Flag(false)) =>
T.command {
printDepsTree(args.inverse.value, transitiveCompileIvyDeps, validModules)()
}
case (Flag(false), Flag(true)) =>
T.command {
printDepsTree(
args.inverse.value,
T.task { runIvyDeps().map(bindDependency()) },
validModules
)()
}
case _ =>
T.command {
printDepsTree(args.inverse.value, T.task { Agg.empty[BoundDep] }, validModules)()
}
}
} else {
T.command {
val msg = invalidModules.mkString("\n")
Result.Failure[Unit](msg)
}
}
}
override def runUseArgsFile: T[Boolean] = T {
// overridden here for binary compatibility (0.11.x)
super.runUseArgsFile()
}
override def runLocal(args: Task[Args] = T.task(Args())): Command[Unit] = {
// overridden here for binary compatibility (0.11.x)
super.runLocal(args)
}
override def run(args: Task[Args] = T.task(Args())): Command[Unit] = {
// overridden here for binary compatibility (0.11.x)
super.run(args)
}
@deprecated("Binary compat shim, use `.runner().run(..., background=true)`", "Mill 0.12.0")
override protected def doRunBackground(
taskDest: Path,
runClasspath: Seq[PathRef],
zwBackgroundWrapperClasspath: Agg[PathRef],
forkArgs: Seq[String],
forkEnv: Map[String, String],
finalMainClass: String,
forkWorkingDir: Path,
runUseArgsFile: Boolean,
backgroundOutputs: Option[Tuple2[ProcessOutput, ProcessOutput]]
)(args: String*): Ctx => Result[Unit] = {
// overridden here for binary compatibility (0.11.x)
super.doRunBackground(
taskDest,
runClasspath,
zwBackgroundWrapperClasspath,
forkArgs,
forkEnv,
finalMainClass,
forkWorkingDir,
runUseArgsFile,
backgroundOutputs
)(args: _*)
}
override def runBackgroundLogToConsole: Boolean = {
// overridden here for binary compatibility (0.11.x)
super.runBackgroundLogToConsole
}
/**
* Runs this module's code in a background process, until it dies or
* `runBackground` is used again. This lets you continue using Mill while
* the process is running in the background: editing files, compiling, and
* only re-starting the background process when you're ready.
*
* You can also use `-w foo.runBackground` to make Mill watch for changes
* and automatically recompile your code & restart the background process
* when ready. This is useful when working on long-running server processes
* that would otherwise run forever
*/
def runBackground(args: String*): Command[Unit] = {
val task = runBackgroundTask(finalMainClass, T.task { Args(args) })
T.command { task() }
}
/**
* Same as `runBackground`, but lets you specify a main class to run
*/
override def runMainBackground(
@arg(positional = true) mainClass: String,
args: String*
): Command[Unit] = {
// overridden here for binary compatibility (0.11.x)
super.runMainBackground(mainClass, args: _*)
}
/**
* Same as `runLocal`, but lets you specify a main class to run
*/
override def runMainLocal(
@arg(positional = true) mainClass: String,
args: String*
): Command[Unit] = {
// overridden here for binary compatibility (0.11.x)
super.runMainLocal(mainClass, args: _*)
}
/**
* Same as `run`, but lets you specify a main class to run
*/
override def runMain(@arg(positional = true) mainClass: String, args: String*): Command[Unit] = {
// overridden here for binary compatibility (0.11.x)
super.runMain(mainClass, args: _*)
}
/**
* Override this to change the published artifact id.
* For example, by default a scala module foo.baz might be published as foo-baz_2.12 and a java module would be foo-baz.
* Setting this to baz would result in a scala artifact baz_2.12 or a java artifact baz.
*/
def artifactName: T[String] = artifactNameParts().mkString("-")
def artifactNameParts: T[Seq[String]] = millModuleSegments.parts
/**
* The exact id of the artifact to be published. You probably don't want to override this.
* If you want to customize the name of the artifact, override artifactName instead.
* If you want to customize the scala version in the artifact id, see ScalaModule.artifactScalaVersion
*/
def artifactId: T[String] = artifactName() + artifactSuffix()
/**
* The suffix appended to the artifact IDs during publishing
*/
def artifactSuffix: T[String] = platformSuffix()
override def forkWorkingDir: T[Path] = T {
// overridden here for binary compatibility (0.11.x)
super.forkWorkingDir()
}
/**
* Files extensions that need to be managed by Zinc together with class files.
* This means, if zinc needs to remove a class file, it will also remove files
* which match the class file basename and a listed file extension.
*/
def zincAuxiliaryClassFileExtensions: T[Seq[String]] = T { Seq.empty[String] }
/**
* @param all If `true` fetches also source dependencies
*/
override def prepareOffline(all: Flag): Command[Unit] = {
val tasks =
if (all.value) Seq(
T.task {
defaultResolver().resolveDeps(
transitiveCompileIvyDeps() ++ transitiveIvyDeps(),
sources = true
)
},
T.task {
defaultResolver().resolveDeps(
runIvyDeps().map(bindDependency()) ++ transitiveIvyDeps(),
sources = true
)
}
)
else Seq()
T.command {
super.prepareOffline(all)()
resolvedIvyDeps()
zincWorker().prepareOffline(all)()
resolvedRunIvyDeps()
T.sequence(tasks)()
()
}
}
@internal
override def bspBuildTarget: BspBuildTarget = super.bspBuildTarget.copy(
languageIds = Seq(BspModule.LanguageId.Java),
canCompile = true,
canRun = true
)
@internal
override def bspBuildTargetData: Task[Option[(String, AnyRef)]] = T.task {
Some((
JvmBuildTarget.dataKind,
JvmBuildTarget(
javaHome = Option(System.getProperty("java.home")).map(p => BspUri(os.Path(p))),
javaVersion = Option(System.getProperty("java.version"))
)
))
}
}
