Modules
Mill modules are object
s extending mill.Module
, and let you group related
tasks together to keep things neat and organized. Mill’s comes with built in
modules such as mill.scalalib.ScalaModule
and mill.scalalib.CrossSbtModule
,
but you can use modules for other purposes as well.
Using Modules
The path to a Mill module from the root of your build file corresponds to the path you would use to run tasks within that module from the command line. e.g. for the following build:
object foo extends mill.Module {
def bar = T { "hello" }
object baz extends mill.Module {
def qux = T { "world" }
}
}
You would be able to run the two targets via mill foo.bar
or mill
foo.baz.qux
. You can use mill show foo.bar
or mill show foo.baz.qux
to
make Mill echo out the string value being returned by each Target. The two
targets will store their output metadata & files at ./out/foo/bar
and
./out/foo/baz/qux
respectively.
Modules also provide a way to define and re-use common collections of tasks, via
Scala trait
s. For example, you can define your own FooModule
trait:
trait FooModule extends mill.Module {
def bar = T { "hello" }
def baz = T { "world" }
}
And use it to define multiple modules with the same bar
and baz
targets,
along with any other customizations such as qux
:
object foo1 extends FooModule
object foo2 extends FooModule {
def qux = T { "I am Cow" }
}
This would make the following targets available from the command line
-
mill show foo1.bar
-
mill show foo1.baz
-
mill show foo2.bar
-
mill show foo2.baz
-
mill show foo2.qux
The built-in mill.scalalib
package uses this to define
mill.scalalib.ScalaModule
, mill.scalalib.SbtModule
and
mill.scalalib.TestScalaModule
, all of which contain a set of "standard"
operations such as compile
, jar
or assembly
that you may expect from a
typical Scala module.
When defining your own module abstractions, in general you should use trait
s
and not `class`es, except in the case of
Cross Builds.
Overriding Targets
trait BaseModule extends Module {
def foo = T { Seq("base") }
def cmd(i: Int) = T.command { Seq("base" + i) }
}
object canOverrideSuper with BaseModule {
def foo = T { super.foo() ++ Seq("object") }
def cmd(i: Int) = T.command { super.cmd(i)() ++ Seq("object" + i) }
}
You can override targets and commands to customize them or change what they do.
The overridden version is available via super
. You can omit the override
keyword in Mill builds.
millSourcePath
Each Module has a millSourcePath
field that corresponds to the path that module
expects its input files to be on disk. Re-visiting our examples above:
object foo extends mill.Module {
def bar = T { "hello" }
object baz extends mill.Module {
def qux = T { "world" }
}
}
The foo
module has a millSourcePath
of ./foo
, while the foo.baz
module has a
millSourcePath
of ./foo/baz
.
You can use millSourcePath
to automatically set the source folders of your
modules to match the build structure. You are not forced to rigidly use
millSourcePath
to define the source folders of all your code, but it can simplify
the common case where you probably want your build-layout and on-disk-layout to
be the same.
E.g. for mill.scalalib.ScalaModule
, the Scala source code is assumed by
default to be in millSourcePath / "src"
while resources are automatically assumed to
be in millSourcePath / "resources"
.
You can override millSourcePath
:
build.sc
object foo extends mill.Module {
def millSourcePath = super.millSourcePath / "lols"
def bar = T { "hello" }
object baz extends mill.Module {
def qux = T { "world" }
}
}
And any overrides propagate down to the module’s children: in the above example,
module foo
would have its millSourcePath
be ./foo/lols
while module`foo.baz`
would have its millSourcePath
be ./foo/lols/baz
.
Note that millSourcePath
is generally only used for a module’s input source files.
Output is always in the out/
folder and cannot be changed, e.g. even with the
overridden millSourcePath
the output paths are still the default ./out/foo/bar
and
./out/foo/baz/qux
folders.
External Modules
Libraries for use in Mill can define ExternalModule
s: Module
s which are
shared between all builds which use that library:
package foo
import mill._
object Bar extends mill.define.ExternalModule {
def baz = T { 1 }
def qux() = T.command { println(baz() + 1) }
lazy val millDiscover = mill.define.Discover[this.type]
}
In the above example, foo.Bar
is an ExternalModule
living within the foo
Java package, containing the baz
target and qux
command. Those can be run
from the command line via:
mill foo.Bar/baz
mill foo.Bar/qux
ExternalModule
s are useful for someone providing a library for use with Mill
that is shared by the entire build: for example,
mill.scalalib.ZincWorkerApi/zincWorker
provides a shared Scala compilation
service & cache that is shared between all ScalaModule
s, and
mill.scalalib.GenIdea/idea
lets you generate IntelliJ projects without
needing to define your own T.command
in your build.sc
file
Foreign Modules
Mill can load other mill projects from external (or sub) folders,
using Ammonite’s $file
magic import, allowing to depend on foreign modules.
This allows, for instance, to depend on other projects' sources, or split
your build logic into smaller files.
For instance, assuming the following structure :
foo/
build.sc
bar/
build.sc
baz/
build.sc
you can write the following in foo/build.sc
:
import $file.bar.build
import $file.^.baz.build
import mill._
def someFoo = T {
^.baz.build.someBaz(...)
bar.build.someBar(...)
...
}
The output of the foreign tasks will be cached under foo/out/foreign-modules/
.