Package

com.thoughtworks

feature

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package feature

Visibility
  1. Public
  2. All

Type Members

  1. trait ByName[ByNameType] extends Serializable

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    A type class for convert between by-name type and normal by-value type.

    A type class for convert between by-name type and normal by-value type.

    Installation

    libraryDependencies += "com.thoughtworks.feature" %% "byname" % "latest.release"
    

    This ByName type class provide an extension method extract for ByName.=> types via implicit view, which can be import as follow:

    import com.thoughtworks.feature.ByName.ops._
    Author:

    杨博 (Yang Bo) <[email protected]>

    ByNameType

    The by-name type

    Note

    When using this ByName type class, you should make sure the type parameter ByNameType is an abstract type, in case of Scala compiler bugs. You can use a trick similar to C++'s Pimpl Idiom to create opacity abstract types

    import com.thoughtworks.feature.ByName.`=>`
    trait OpacityTypes {
      type IntByName
      implicit def typeClass: ByName.Aux[IntByName, Int]
    }
    val opacityTypes: OpacityTypes = new OpacityTypes {
      type IntByName = `=>`[Int]
      override def typeClass = ByName[IntByName]
    }
    import opacityTypes._

    Now IntByName is an abstract type with underlying => Int type.


    Given a by-name parameter of the return value of getInt(),

    val getInt = stubFunction[Int]
    val boxedByName: IntByName = typeClass.make(getInt())

    when getInt returns 42,

    getInt.when.once returns 42

    then the value of the the by-name parameter should be 42;

    boxedByName.extract should be(42)

    when getInt returns 144,

    getInt.when.once returns 144

    then the value of the the by-name parameter should be 144.

    boxedByName.extract should be(144)
  2. final class Caller[+A] extends AnyVal

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    An implicit value that points to the function caller.

    An implicit value that points to the function caller.

    Usage

    libraryDependencies += "com.thoughtworks.feature" %% "caller" % "latest.release"
    Getting the caller for logging or something
    object Foo{
      def log()(implicit caller: Caller[Any]) = {
        println(caller.value)
      }
    }
    object Bar{
      Foo.log() // Bar
    }
    Restricting who you can be called from
    class IKnowWhatImDoing
    object Foo{
      def runDangerous()(implicit caller: Caller[IKnowWhatImDoing]) = {
        println(caller.value)
      }
    }
    object Bar {
      Foo.runDangerous() // compile error
    }
    object Bar2 extends IKnowWhatImDoing{
      Foo.runDangerous() // ok, prints Bar2
    }
    Getting calling class or classloader, e.g. for loading resources, without needing to worry about properly setting up and tearing down the Context ClassLoader
    object Foo{
      def getResource(path: String)(implicit caller: Caller[_]) = {
        caller.value.getClass.getClassLoader.getResourceAsStream(path)
      }
    }
    object Bar{
      Foo.getResource("/thing/file.txt") // loads resource from `Bar`s classloader, always
    }
    Authors:

    Li Haoyi

    杨博 (Yang Bo) <[email protected]>

  3. final class Constructor[F] extends AnyVal

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    An implicit value for dynamically creating classes and traits, especially dynamic mixins.

    An implicit value for dynamically creating classes and traits, especially dynamic mixins.

    Usage

    libraryDependencies += "com.thoughtworks.feature" %% "constructor" % "latest.release"
    trait A
    trait B
    
    def makeAWithB()(implicit constructor: Constructor[() => A with B]): A with B = {
      constructor.newInstance()
    }
    
    val ab: A with B = makeAWithB()

    Motivation

    This feature is useful for library authors. A library author may ask his user to create a trait type, then dynamically mix-in it with the features provided by the library.

    Suppose you are creating a DSL that compiles to JavaScript.

    You want your DSL is extensible. For example, the DSL users should be able to create custom binary operators.

    With the help of Constructor.scala, you can put the boilerplate code into a private class BinaryOperator:

    trait Ast
    
    object Ast {
    
      class Literal(val n: Int) extends Ast {
        override final def compile(): String = n.compile()
      }
    
      private[Ast] abstract class BinaryOperator(leftHandSide: Ast, rightHandSide: Ast) extends Ast {
        protected def symbol: String
        override final def compile() = s"($leftHandSide $symbol $rightHandSide)"
      }
    
      def binaryOperator[T](leftHandSide: Ast, rightHandSide: Ast)(
        implicit constructor: Constructor[(Ast, Ast) => BinaryOperator with T]): BinaryOperator with T = {
        constructor.newInstance(leftHandSide, rightHandSide)
      }
    
    }

    The users only need a very simple implementation for their custom binary operators.

    import Ast._
    
    trait Plus {
      protected final def symbol = "+"
    }
    
    trait Minus {
      protected final def symbol = "-"
    }
    
    val myAst = binaryOperator[Plus](
      new Literal(1),
      binaryOperator[Minus](
        new Literal(3),
        new Literal(5)
      )
    )
    
    print(myAst.compile()) // Output: "(1 + (3 - 5))"

    An alternative approach

    There is another approach to integrate partial implementation from users: asking users to provide custom callback functions or type classes.

    However, the callback functions or type classes approach will create additional object instances and additional references for each instance at run-time. On the other hand, the Constructor.scala approach create classes at compile-time and no additional run-time references. As a result, at run-time, Constructor.scala approach will consume less memory, and performs less indirect access on memory.

    Author:

    杨博 (Yang Bo) <[email protected]>

  4. trait Demixin[ConjunctionType] extends AnyRef

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    A type class that converts a mix-in type to shapeless.HList.

    A type class that converts a mix-in type to shapeless.HList.

    Common imports

    You may want to use Demixin with shapeless.HList.

    import shapeless._
    Examples:
    1. The Demixin type class can be summoned from Demixin.apply method:

      class A; trait B; object C;
      val demixin = Demixin[A with B with C.type with String with Int]

      Out should be a shapeless.HList of each type components in the mix-in type ConjunctionType.

      "implicitly[demixin.Out =:= (A :: B :: C.type :: String :: Int :: HNil)]" should compile

      The elements in Out should keep the same order as type components in ConjunctionType.

      "implicitly[demixin.Out =:!= (String :: A :: B :: C.type :: Int :: HNil)]" should compile
    2. ,
    3. Out of Demixin on scala.Any should be shapeless.HNil

      val demixin = Demixin[Any]
      "implicitly[demixin.Out =:= HNil]" should compile
    4. ,
    5. Out of Demixin on non-mixed-in types other than scala.Any should be a shapeless.HList that contains only one element

      val demixin = Demixin[String]
      "implicitly[demixin.Out =:= (String :: HNil)]" should compile
  5. trait Factory[Output] extends Serializable

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    A factory to create new instances, especially dynamic mix-ins.

    A factory to create new instances, especially dynamic mix-ins.

    Author:

    杨博 (Yang Bo) <[email protected]>

    Examples:
    1. Given a trait that has abstract members.

      trait Foo {
        val myValue: String
        var myVariable: Long
        def myMethod0(): Option[Double]
        def myMethod2(p0: Int, p1: Int): Int
        def myCurriedMethod(seq: Seq[Int])(mapper: Int => String): Seq[String]
        // Methods without pararmeters is disabled for now, due to https://github.com/scala/bug/issues/10647
        // def myByNameMethod: Option[Int]
      }

      When creating a factory for the trait.

      val factory = Factory[Foo]

      Then the newInstance method of the factory should accept named arguments according to abstract members.

      val createdFromNamedArguments: Foo = factory.newInstance(
        myValue = "string value",
        myVariable = 42L,
        myMethod0 = () => Some(0.5),
        myMethod2 = _ + _,
        myCurriedMethod = seq => mapper => seq.map(mapper)
      )
      createdFromNamedArguments.myValue should be("string value")
      createdFromNamedArguments.myVariable should be(42L)
      createdFromNamedArguments.myMethod0() should be(Some(0.5))
      createdFromNamedArguments.myMethod0() shouldNot be theSameInstanceAs createdFromNamedArguments.myMethod0()
      createdFromNamedArguments.myMethod2(1000, 24) should be(1024)
      createdFromNamedArguments.myCurriedMethod(Seq(2, 3, 4))(_.toString) should be(Seq("2", "3", "4"))

      When using unnamed parameters, the parameters should be passed in alphabetical order

      val createdFromUnnamedArguments: Foo = factory.newInstance(
        seq => mapper => seq.map(mapper), // myCurriedMethod
        () => Some(0.5),                  // myMethod0
        _ + _,                            // myMethod2
        "string value",                   // myValue
        42L                               // myVariable
      )
    2. ,
    3. Given two traits that have no abstract member.

      trait Foo
      trait Bar

      When creating a factory for mix-in type of the two types.

      val factory = Factory[Foo with Bar]

      Then the newInstance method of the factory should accept no parameters.

      val fooBar: Foo with Bar = factory.newInstance()
      fooBar should be(a[Foo])
      fooBar should be(a[Bar])
    4. ,
    5. Given a trait that contains an abstract method annotated as @inject.

      import com.thoughtworks.feature.Factory.inject
      trait Foo[A] {
        @inject def orderingA: Ordering[A]
      }

      When creating a factory for the trait

      val factory = Factory[Foo[Int]]

      Then the @inject method will be replaced to an implicit value.

      val foo = factory.newInstance()
      foo.orderingA should be(implicitly[Ordering[Int]])

      It will not compile if no implicit value found. For example, Foo[Symbol] requires an implicit value of type Ordering[Symbol], which is not availble.

      "Factory[Foo[Symbol]]" shouldNot compile

      If the trait does not contain abstract methods other than @inject methods, then the factory type class is a Factory.Factory0, which can be summoned by Predef.implicitly,

      val nullaryFactory = implicitly[Factory.Factory0[Foo[Int]]]

      and newInstance method is available on the Factory.Factory0 as well.

      nullaryFactory.newInstance().orderingA should be(implicitly[Ordering[Int]])
    Note

    However, if the nested type is an alias to another type outside of the type to create, then it is allowed

    trait Outer {
      type Inner = String
      val inner: Option[Inner]
    }
    val outer: Outer = Factory[Outer].newInstance(inner = Some("my value"))
    outer.inner should be(Some("my value"))
    ,

    This Factory disallows creating types that has an abstract member whose type depends on nested types. Given an abstract val inner whose type is the Inner,

    trait Outer {
      trait Inner
      val inner: Option[Inner]
    }

    then the attempt to create factory for Outer, like Factory[Outer].newInstance(inner = None), will cause a value inner has incompatible type compile error.

    ,

    @inject works on implicit abstract methods as well.

    import com.thoughtworks.feature.Factory.inject
    trait Foo[A] {
      @inject implicit def orderingA: Ordering[A]
    }
    Factory[Foo[Int]].newInstance().orderingA should be(implicitly[Ordering[Int]])
    ,

    Factories may be nested

    import com.thoughtworks.feature.Factory.inject
    import com.thoughtworks.feature.Factory.Factory1
    import com.thoughtworks.feature.ByName.`=>`
    trait Outer {
      trait AbstractParameterApi
      type AbstractParameter <: AbstractParameterApi
      trait InnerApi {
        def foo: AbstractParameter
      }
      type Inner <: InnerApi
      @inject val innerFactory: Factory1[`=>`[AbstractParameter], Inner]
    }
    val outer = Factory[Outer].newInstance()
    outer.innerFactory.newInstance(new outer.AbstractParameterApi {}) should be(an[outer.Inner])
    ,

    Factories may create types that contains refinement types

    trait SomeBuilder {
      type A
      def makeSome(a: A) = Some(a)
    }
    val someBuilder = Factory[SomeBuilder { type A = Int }].newInstance()
    someBuilder.makeSome(42) should be(Some(42))
  6. trait Glb[Mixin] extends Serializable

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    A type class that converts a mix-in type to the greatest lower bound of the components of the mix-in.

    A type class that converts a mix-in type to the greatest lower bound of the components of the mix-in.

    This Glb type class provides an extension method glb via implicit view, which can be import as follow:

    import com.thoughtworks.feature.Glb.ops._
    Author:

    杨博 (Yang Bo) <[email protected]>

    Example:
    1. Given a mix-in of two refinement components,

      type A = Option[Any] {
        def get: Immutable
      }
      type B = Option[Any] {
        def get: Iterable[String]
      }
      val ab: A with B = Some(List("cool"))

      when convert it to its greatest lower bound,

      val glbOfAB  = toAllGlbOps(ab).glb

      Then the common method should return the greatest lower bound of each components's return type.

      val result: Immutable with Iterable[String] = glbOfAB.get
      result should be(List("cool"))
    Note

    This Glb type class is implemented via scala.reflect.api.Types.glb, which is similar to intersection operator in Dotty, except this Glb works for refinement type only.

    ,

    The implicit conversion toAllGlbOps must be explicitly invoked, as a workaround of https://github.com/scala/bug/issues/10671

  7. trait ImplicitApply[F] extends Serializable

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    A dependent type class that invokes F with implicit values as parameters.

    A dependent type class that invokes F with implicit values as parameters.

    Imports

    import com.thoughtworks.feature.ImplicitApply.ops._

    This will enable the implicitApply method for any functions

    Author:

    杨博 (Yang Bo) <[email protected]>

    F

    The function type to be implicitly invoked

    Examples:
    1. Given a function f that requires an Ordering[Int]

      val f = { x: Ordering[Int] =>
        "OK"
      }

      Then f can implicitly apply as long as its parameter is implicitly available,

      f.implicitApply should be("OK")
    2. ,
    3. Given a function f that requires an call-by-name Ordering[Int]

      def f0(x: => Ordering[Int]) = "OK"
      val f = f0 _

      Then f can implicitly apply as long as its parameter is implicitly available,

      f.implicitApply should be("OK")
    Note

    You can optionally add an implicit modifier on the function parameter.

    val f = { implicit x: Ordering[Int] =>
      "OK"
    }
    f.implicitApply should be("OK")

    It is very useful when you create a curried function.

    def g[A] = { (i: A, j: A) => implicit x: Ordering[A] =>
      import x._
      if (i > j) {
        s"$i is greater than $j"
      } else {
        s"$i is not greater than $j"
      }
    }
    g(1, 2).implicitApply should be("1 is not greater than 2")
  8. trait Mixin[L <: HList] extends AnyRef

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    A type class that converts a shapeless.HList to a mix-in type.

    A type class that converts a shapeless.HList to a mix-in type.

    Common imports

    You may want to use Mixin with shapeless.HList.

    import shapeless._
    Example:
    1. Out of Mixin is a minx-in type that consists of each types in L

      val mixin = Mixin[Int :: Nil.type :: String :: HNil]
      "implicitly[mixin.Out =:= (Int with Nil.type with String)]" should compile
  9. trait PartialApply[F, ParameterName <: String with Singleton] extends Serializable

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    A dependent type class that bind the specific parameter of ParameterName to F

    A dependent type class that bind the specific parameter of ParameterName to F

    Imports

    import com.thoughtworks.feature.PartialApply.ops._

    This will enable the partialApply method for any functions

    Author:

    杨博 (Yang Bo) <[email protected]>

    F

    The function type to be partially apply

    Examples:
    1. Given a function with three parameters.

      val f = { (v1: Int, v2: Int, v3: Int) => (v1 + v2) * v3 }

      When partially applying the second parameter.

      val partiallyApplied = f.partialApply(v2 = 2)

      And applying the rest parameters.

      val result = partiallyApplied(v3 = 3, v1 = 1)

      Then the result should be the same as applying at once.

      result should be(f(1, 2, 3))
    2. ,
    3. A function with refined parameters can partially apply.

      val f: ((Int, Double, String) => String) { def apply(i: Int, d: Double, s: String): String } = { (i, d, s) =>
        (i * d) + s
      }
      f.partialApply(s = "seconds").apply(i = 60, d = 1.125) should be(f(s = "seconds", i = 60, d = 1.125))
    4. ,
    5. Partial applying can be chained.

      val f = { (v1: Int, v2: Int, v3: Int) => (v1 + v2) * v3 }
      f.partialApply(v2 = 2).partialApply(v3 = 3).partialApply(v1 = 1).apply() should be(f(1, 2, 3))
    6. ,
    7. Function objects can partially apply.

      object f extends ((Int, Double, String) => String) {
        def apply(i: Int, d: Double, s: String): String = {
          (i * d) + s
        }
      }
      f.partialApply(s = "seconds").apply(i = 60, d = 1.125) should be(f(s = "seconds", i = 60, d = 1.125))
    8. ,
    9. Case class companion can partially apply.

      case class MyCaseClass(i: Int, d: Double, s: String)
      MyCaseClass.partialApply(s = "seconds").apply(i = 60, d = 1.125) should be(MyCaseClass(s = "seconds", i = 60, d = 1.125))
    10. ,
    11. Call-by-name functions can partially apply.

      def foo(v1: => String, v2: Int) = v1 + v2
      val callByNameFunction = foo _
      PartialApply.materialize[callByNameFunction.type, "v1"].apply(callByNameFunction, "1").apply(v2 = 2) should be(foo(v1 = "1", v2 = 2))
  10. trait SelfType[A] extends AnyRef

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    A type class that extracts the self-type of A.

    A type class that extracts the self-type of A.

    Examples:
    1. Given a compound type,

      trait MySelfType1
      trait MyTrait1 { this: MySelfType1 => }
      trait MyTrait2
      trait MySelfType3
      trait MyTrait3 { this: MySelfType3 => }
      type MyCompoundType = MyTrait1 with MyTrait2 with MyTrait3 {
        type MyRefinement = Int
      }

      then the self type should be a compound type of each mix-in part,

      val selfType = SelfType[MyCompoundType]
      "implicitly[selfType.Out =:= (MySelfType1 with MySelfType3 with MyTrait1 with MyTrait2 with MyTrait3)]" should compile

      and the self type should not contain the refinement statements

      "implicitly[selfType.Out <:< { type MyRefinement = Int }]" shouldNot typeCheck
    2. ,
    3. Given a trait with an explicit self-type declaration,

      trait MySelfType
      trait MyTrait { this: MySelfType => }

      then the self type should be itself with the type of this.

      val selfType = SelfType[MyTrait]
      "implicitly[selfType.Out =:= (MySelfType with MyTrait)]" should compile
    4. ,
    5. Given a trait without an explicit self-type declaration

      trait MyTrait

      Then the self type should be itself

      val selfType = SelfType[MyTrait]
      "implicitly[selfType.Out =:= MyTrait]" should compile
  11. trait Structural[Mixin] extends Serializable

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    A type class that converts a class type to a refinement type

    A type class that converts a class type to a refinement type

    This Structural type class provides an extension method structuralize via implicit view, which can be import as follow:

    import com.thoughtworks.feature.Structural.ops._
    Examples:
    1. Given a class that contains abstract types:

      trait Container extends Iterable[String] {
        trait InnerApi
        type Inner <: InnerApi
        def inner: Inner = ???
        type Self0 >: this.type
        def self: Self0 = this
      }
      val container: Container = new Container { def iterator = Iterator.empty }

      When converting it to a structural type

      import scala.language.higherKinds
      val myStruct = container.structuralize

      Then methods on the converted struct should be able to access via reflective call

      import scala.language.reflectiveCalls
      myStruct.self should be(myStruct)
    2. ,
    3. Given a String

      val myString: String = "foo"

      When converting it to a structural type

      val myStruct = myString.structuralize

      Then methods on the converted struct should be able to access via reflective call

      import scala.language.reflectiveCalls
      myStruct.startsWith("f") should be(true)

      However, the struct is not a String

      "myStruct: String" shouldNot typeCheck
  12. final class The[Widen, Narrow <: Widen] extends AnyVal

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    A helper that summons dependent type class Widen.

    A helper that summons dependent type class Widen.

    Note

    The can be used as an alternative to implicitly for dependent type classes.

    val narrowed: Int <:< Int = The[Int <:< Any].value
    See also

    https://github.com/milessabin/shapeless/pull/695 for discussion about the motivation of The.

  13. class Untyper[Universe <: Singleton with Universe] extends AnyRef

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    A utility to convert Type to Tree.

    A utility to convert Type to Tree.

    Author:

    杨博 (Yang Bo) <[email protected]>

    Note

    The primary intent of Untyper class is for some macro libraries in this feature.scala project, although it may be also useful for other projects.

Value Members

  1. object ByName extends Serializable

    Permalink
  2. object Caller

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  3. object Constructor

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  4. object Demixin

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  5. object Factory extends LowPriorityFactory with Serializable

    Permalink
  6. object Glb extends Serializable

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  7. object ImplicitApply extends Serializable

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  8. object Mixin extends LowPriorityMixin

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  9. object PartialApply extends Serializable

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  10. object SelfType

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  11. object Structural extends Serializable

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  12. object The

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  13. package mixins

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Ungrouped