dotty.tools.dotc.transform.ElimRepeated.scala Maven / Gradle / Ivy
package dotty.tools.dotc
package transform
import core._
import Names._
import StdNames.nme
import Types._
import dotty.tools.dotc.transform.MegaPhase._
import ast.Trees._
import Flags._
import Contexts.Context
import Symbols._
import Constants._
import Decorators._
import Denotations._, SymDenotations._
import Decorators.StringInterpolators
import dotty.tools.dotc.ast.tpd
import dotty.tools.dotc.core.Annotations.ConcreteAnnotation
import scala.collection.mutable
import DenotTransformers._
import Names.Name
import NameOps._
import TypeUtils._
object ElimRepeated {
val name = "elimRepeated"
}
/** A transformer that removes repeated parameters (T*) from all types, replacing
* them with Seq types.
*/
class ElimRepeated extends MiniPhase with InfoTransformer { thisPhase =>
import ast.tpd._
override def phaseName = ElimRepeated.name
override def changesMembers = true // the phase adds vararg bridges
def transformInfo(tp: Type, sym: Symbol)(implicit ctx: Context): Type =
elimRepeated(tp)
override def transform(ref: SingleDenotation)(implicit ctx: Context): SingleDenotation =
super.transform(ref) match {
case ref1: SymDenotation if (ref1 ne ref) && overridesJava(ref1.symbol) =>
// This method won't override the corresponding Java method at the end of this phase,
// only the bridge added by `addVarArgsBridge` will.
ref1.copySymDenotation(initFlags = ref1.flags &~ Override)
case ref1 =>
ref1
}
override def mayChange(sym: Symbol)(implicit ctx: Context): Boolean = sym is Method
private def overridesJava(sym: Symbol)(implicit ctx: Context) = sym.allOverriddenSymbols.exists(_ is JavaDefined)
private def elimRepeated(tp: Type)(implicit ctx: Context): Type = tp.stripTypeVar match {
case tp @ MethodTpe(paramNames, paramTypes, resultType) =>
val resultType1 = elimRepeated(resultType)
val paramTypes1 =
if (paramTypes.nonEmpty && paramTypes.last.isRepeatedParam) {
val last = paramTypes.last.underlyingIfRepeated(tp.isJavaMethod)
paramTypes.init :+ last
} else paramTypes
tp.derivedLambdaType(paramNames, paramTypes1, resultType1)
case tp: PolyType =>
tp.derivedLambdaType(tp.paramNames, tp.paramInfos, elimRepeated(tp.resultType))
case tp =>
tp
}
def transformTypeOfTree(tree: Tree)(implicit ctx: Context): Tree =
tree.withType(elimRepeated(tree.tpe))
override def transformIdent(tree: Ident)(implicit ctx: Context): Tree =
transformTypeOfTree(tree)
override def transformSelect(tree: Select)(implicit ctx: Context): Tree =
transformTypeOfTree(tree)
override def transformApply(tree: Apply)(implicit ctx: Context): Tree = {
val formals =
ctx.atPhase(thisPhase) { implicit ctx =>
tree.fun.tpe.widen.asInstanceOf[MethodType].paramInfos
}
val args1 = tree.args.zipWithConserve(formals) { (arg, formal) =>
arg match {
case arg: Typed if isWildcardStarArg(arg) =>
if (tree.fun.symbol.is(JavaDefined) && arg.expr.tpe.derivesFrom(defn.SeqClass))
seqToArray(arg.expr, formal.underlyingIfRepeated(isJava = true))
else arg.expr
case arg => arg
}
}
transformTypeOfTree(cpy.Apply(tree)(tree.fun, args1))
}
/** Convert sequence argument to Java array of type `pt` */
private def seqToArray(tree: Tree, pt: Type)(implicit ctx: Context): Tree = tree match {
case SeqLiteral(elems, elemtpt) =>
JavaSeqLiteral(elems, elemtpt)
case app@Apply(fun, args) if defn.Predef_wrapArray().contains(fun.symbol) => // rewrite a call to `wrapXArray(arr)` to `arr`
args.head
case _ =>
val elemType = tree.tpe.elemType
var elemClass = elemType.classSymbol
if (defn.NotRuntimeClasses contains elemClass) elemClass = defn.ObjectClass
ref(defn.DottyArraysModule)
.select(nme.seqToArray)
.appliedToType(elemType)
.appliedTo(tree, Literal(Constant(elemClass.typeRef)))
.ensureConforms(pt)
// Because of phantomclasses, the Java array's type might not conform to the return type
}
override def transformTypeApply(tree: TypeApply)(implicit ctx: Context): Tree =
transformTypeOfTree(tree)
/** If method overrides a Java varargs method, add a varargs bridge.
* Also transform trees inside method annotation
*/
override def transformDefDef(tree: DefDef)(implicit ctx: Context): Tree =
ctx.atPhase(thisPhase) { implicit ctx =>
if (tree.symbol.info.isVarArgsMethod && overridesJava(tree.symbol))
addVarArgsBridge(tree)
else
tree
}
/** Add a Java varargs bridge
* @param ddef the original method definition which is assumed to override
* a Java varargs method JM up to this phase.
* @return a thicket consisting of `ddef` and a varargs bridge method
* which overrides the Java varargs method JM from this phase on
* and forwards to `ddef`.
*/
private def addVarArgsBridge(ddef: DefDef)(implicit ctx: Context): Tree = {
val original = ddef.symbol.asTerm
val bridge = original.copy(
flags = ddef.symbol.flags &~ Private | Artifact,
info = toJavaVarArgs(ddef.symbol.info)).enteredAfter(thisPhase).asTerm
val bridgeDef = polyDefDef(bridge, trefs => vrefss => {
val (vrefs :+ varArgRef) :: vrefss1 = vrefss
val elemtp = varArgRef.tpe.widen.argTypes.head
ref(original.termRef)
.appliedToTypes(trefs)
.appliedToArgs(vrefs :+ TreeGen.wrapArray(varArgRef, elemtp))
.appliedToArgss(vrefss1)
})
Thicket(ddef, bridgeDef)
}
/** Convert type from Scala to Java varargs method */
private def toJavaVarArgs(tp: Type)(implicit ctx: Context): Type = tp match {
case tp: PolyType =>
tp.derivedLambdaType(tp.paramNames, tp.paramInfos, toJavaVarArgs(tp.resultType))
case tp: MethodType =>
val inits :+ last = tp.paramInfos
val last1 = last.underlyingIfRepeated(isJava = true)
tp.derivedLambdaType(tp.paramNames, inits :+ last1, tp.resultType)
}
}
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