path: root/src/compiler/scala/tools/nsc/typechecker/PatternTypers.scala



/* NSC -- new Scala compiler
 * Copyright 2005-2013 LAMP/EPFL
 * @author  Paul Phillips
 */

package scala
package tools
package nsc
package typechecker

import scala.collection.mutable
import symtab.Flags
import Mode._

 /**
 *
 *  A pattern match such as
 *
 *    x match { case Foo(a, b) => ...}
 *
 *  Might match an instance of any of the following definitions of Foo.
 *  Note the analogous treatment between case classes and unapplies.
 *
 *    case class Foo(xs: Int*)
 *    case class Foo(a: Int, xs: Int*)
 *    case class Foo(a: Int, b: Int)
 *    case class Foo(a: Int, b: Int, xs: Int*)
 *
 *    object Foo { def unapplySeq(x: Any): Option[Seq[Int]] }
 *    object Foo { def unapplySeq(x: Any): Option[(Int, Seq[Int])] }
 *    object Foo { def unapply(x: Any): Option[(Int, Int)] }
 *    object Foo { def unapplySeq(x: Any): Option[(Int, Int, Seq[Int])] }
 */

trait PatternTypers {
  self: Analyzer =>

  import global._
  import definitions._

  private object FixedAndRepeatedTypes {
    def unapply(types: List[Type]) = types match {
      case init :+ last if isRepeatedParamType(last) => Some((init, dropRepeated(last)))
      case _                                         => Some((types, NoType))
    }
  }

  trait PatternTyper {
    self: Typer =>

    import TyperErrorGen._
    import infer._

    private def unit = context.unit

    // If the tree's symbol's type does not define an extractor, maybe the tree's type does.
    // this is the case when we encounter an arbitrary tree as the target of an unapply call
    // (rather than something that looks like a constructor call.) (for now, this only happens
    // due to wrapClassTagUnapply, but when we support parameterized extractors, it will become
    // more common place)
    private def hasUnapplyMember(tpe: Type): Boolean   = reallyExists(unapplyMember(tpe))
    private def hasUnapplyMember(sym: Symbol): Boolean = hasUnapplyMember(sym.tpe_*)
    private def hasUnapplyMember(fun: Tree): Boolean   = hasUnapplyMember(fun.symbol) || hasUnapplyMember(fun.tpe)

    // ad-hoc overloading resolution to deal with unapplies and case class constructors
    // If some but not all alternatives survive filtering the tree's symbol with `p`,
    // then update the tree's symbol and type to exclude the filtered out alternatives.
    private def inPlaceAdHocOverloadingResolution(fun: Tree)(p: Symbol => Boolean): Tree = fun.symbol filter p match {
      case sym if sym.exists && (sym ne fun.symbol) => fun setSymbol sym modifyType (tp => filterOverloadedAlts(tp)(p))
      case _                                        => fun
    }
    private def filterOverloadedAlts(tpe: Type)(p: Symbol => Boolean): Type = tpe match {
      case OverloadedType(pre, alts) => overloadedType(pre, alts filter p)
      case tp                        => tp
    }

    def typedConstructorPattern(fun0: Tree, pt: Type): Tree = {
      // Do some ad-hoc overloading resolution and update the tree's symbol and type
      // do not update the symbol if the tree's symbol's type does not define an unapply member
      // (e.g. since it's some method that returns an object with an unapply member)
      val fun         = inPlaceAdHocOverloadingResolution(fun0)(hasUnapplyMember)
      val canElide    = treeInfo.isQualifierSafeToElide(fun)
      val caseClass   = companionSymbolOf(fun.tpe.typeSymbol.sourceModule, context)
      val member      = unapplyMember(fun.tpe)
      def resultType  = (fun.tpe memberType member).finalResultType
      def isEmptyType = resultOfMatchingMethod(resultType, nme.isEmpty)()
      def isOkay      = (
           resultType.isErroneous
        || (resultType <:< BooleanTpe)
        || (isEmptyType <:< BooleanTpe)
        || member.isMacro
        || member.isOverloaded // the whole overloading situation is over the rails
      )

      // Dueling test cases: pos/overloaded-unapply.scala, run/case-class-23.scala, pos/t5022.scala
      // A case class with 23+ params has no unapply method.
      // A case class constructor may be overloaded with unapply methods in the companion.
      if (canElide && caseClass.isCase && !member.isOverloaded)
        logResult(s"convertToCaseConstructor($fun, $caseClass, pt=$pt)")(convertToCaseConstructor(fun, caseClass, pt))
      else if (!reallyExists(member))
        CaseClassConstructorError(fun, s"${fun.symbol} is not a case class, nor does it have an unapply/unapplySeq member")
      else if (isOkay)
        fun
      else if (isEmptyType == NoType)
        CaseClassConstructorError(fun, s"an unapply result must have a member `def isEmpty: Boolean")
      else
        CaseClassConstructorError(fun, s"an unapply result must have a member `def isEmpty: Boolean (found: def isEmpty: $isEmptyType)")
    }

    def typedArgsForFormals(args: List[Tree], formals: List[Type], mode: Mode): List[Tree] = {
      def typedArgWithFormal(arg: Tree, pt: Type) = {
        val newMode = if (isByNameParamType(pt)) mode.onlySticky else mode.onlySticky | BYVALmode
        typedArg(arg, mode, newMode, dropByName(pt))
      }
      val FixedAndRepeatedTypes(fixed, elem) = formals
      val front = (args, fixed).zipped map typedArgWithFormal
      def rest  = context withinStarPatterns (args drop front.length map (typedArgWithFormal(_, elem)))

      elem match {
        case NoType => front
        case _      => front ::: rest
      }
    }

    private def boundedArrayType(bound: Type): Type = {
      val tparam = context.owner.freshExistential("", 0) setInfo (TypeBounds upper bound)
      newExistentialType(tparam :: Nil, arrayType(tparam.tpe_*))
    }

    protected def typedStarInPattern(tree: Tree, mode: Mode, pt: Type) = {
      val Typed(expr, tpt) = tree
      val exprTyped = typed(expr, mode)
      val baseClass = exprTyped.tpe.typeSymbol match {
        case ArrayClass => ArrayClass
        case _          => SeqClass
      }
      val starType = baseClass match {
        case ArrayClass if isPrimitiveValueType(pt) || !isFullyDefined(pt) => arrayType(pt)
        case ArrayClass                                                    => boundedArrayType(pt)
        case _                                                             => seqType(pt)
      }
      val exprAdapted = adapt(exprTyped, mode, starType)
      exprAdapted.tpe baseType baseClass match {
        case TypeRef(_, _, elemtp :: Nil) => treeCopy.Typed(tree, exprAdapted, tpt setType elemtp) setType elemtp
        case _                            => setError(tree)
      }
    }

    protected def typedInPattern(tree: Typed, mode: Mode, pt: Type) = {
      val Typed(expr, tpt) = tree
      val tptTyped  = typedType(tpt, mode)
      val tpe       = tptTyped.tpe
      val exprTyped = typed(expr, mode, tpe.deconst)
      val extractor = extractorForUncheckedType(tpt.pos, tpe)

      val canRemedy = tpe match {
        case RefinedType(_, decls) if !decls.isEmpty                 => false
        case RefinedType(parents, _) if parents exists isUncheckable => false
        case _                                                       => extractor.nonEmpty
      }

      val ownType   = inferTypedPattern(tptTyped, tpe, pt, canRemedy)
      val treeTyped = treeCopy.Typed(tree, exprTyped, tptTyped) setType ownType

      extractor match {
        case EmptyTree => treeTyped
        case _         => wrapClassTagUnapply(treeTyped, extractor, tpe)
      }
    }
    private class VariantToSkolemMap extends TypeMap(trackVariance = true) {
      private val skolemBuffer = mutable.ListBuffer[TypeSymbol]()

      // !!! FIXME - skipping this when variance.isInvariant allows unsoundness, see SI-5189
      // Test case which presently requires the exclusion is run/gadts.scala.
      def eligible(tparam: Symbol) = (
           tparam.isTypeParameterOrSkolem
        && tparam.owner.isTerm
        && (settings.strictInference || !variance.isInvariant)
      )

      def skolems = try skolemBuffer.toList finally skolemBuffer.clear()
      def apply(tp: Type): Type = mapOver(tp) match {
        case tp @ TypeRef(NoPrefix, tpSym, Nil) if eligible(tpSym) =>
          val bounds = (
            if (variance.isInvariant) tpSym.tpeHK.bounds
            else if (variance.isPositive) TypeBounds.upper(tpSym.tpeHK)
            else TypeBounds.lower(tpSym.tpeHK)
          )
          // origin must be the type param so we can deskolemize
          val skolem = context.owner.newGADTSkolem(unit.freshTypeName("?" + tpSym.name), tpSym, bounds)
          skolemBuffer += skolem
          logResult(s"Created gadt skolem $skolem: ${skolem.tpe_*} to stand in for $tpSym")(skolem.tpe_*)
        case tp1 => tp1
      }
    }

    /*
     * To deal with the type slack between actual (run-time) types and statically known types, for each abstract type T,
     * reflect its variance as a skolem that is upper-bounded by T (covariant position), or lower-bounded by T (contravariant).
     *
     * Consider the following example:
     *
     *  class AbsWrapperCov[+A]
     *  case class Wrapper[B](x: Wrapped[B]) extends AbsWrapperCov[B]
     *
     *  def unwrap[T](x: AbsWrapperCov[T]): Wrapped[T] = x match {
     *    case Wrapper(wrapped) => // Wrapper's type parameter must not be assumed to be equal to T, it's *upper-bounded* by it
     *      wrapped // : Wrapped[_ <: T]
     *  }
     *
     * this method should type check if and only if Wrapped is covariant in its type parameter
     *
     * when inferring Wrapper's type parameter B from x's type AbsWrapperCov[T],
     * we must take into account that x's actual type is AbsWrapperCov[Tactual] forSome {type Tactual <: T}
     * as AbsWrapperCov is covariant in A -- in other words, we must not assume we know T exactly, all we know is its upper bound
     *
     * since method application is the only way to generate this slack between run-time and compile-time types (TODO: right!?),
     * we can simply replace skolems that represent method type parameters as seen from the method's body
     * by other skolems that are (upper/lower)-bounded by that type-parameter skolem
     * (depending on the variance position of the skolem in the statically assumed type of the scrutinee, pt)
     *
     * see test/files/../t5189*.scala
     */
    private def convertToCaseConstructor(tree: Tree, caseClass: Symbol, ptIn: Type): Tree = {
      // TODO SI-7886 / SI-5900 This is well intentioned but doesn't quite hit the nail on the head.
      //      For now, I've put it completely behind -Xstrict-inference.
      val untrustworthyPt = settings.strictInference && (
           ptIn =:= AnyTpe
        || ptIn =:= NothingTpe
        || ptIn.typeSymbol != caseClass
      )
      val variantToSkolem     = new VariantToSkolemMap
      val caseClassType       = tree.tpe.prefix memberType caseClass
      val caseConstructorType = caseClassType memberType caseClass.primaryConstructor
      val tree1               = TypeTree(caseConstructorType) setOriginal tree
      val pt                  = if (untrustworthyPt) caseClassType else ptIn

      // have to open up the existential and put the skolems in scope
      // can't simply package up pt in an ExistentialType, because that takes us back to square one (List[_ <: T] == List[T] due to covariance)
      val ptSafe   = logResult(s"case constructor from (${tree.summaryString}, $caseClassType, $pt)")(variantToSkolem(pt))
      val freeVars = variantToSkolem.skolems

      // use "tree" for the context, not context.tree: don't make another CaseDef context,
      // as instantiateTypeVar's bounds would end up there
      val ctorContext = context.makeNewScope(tree, context.owner)
      freeVars foreach ctorContext.scope.enter
      newTyper(ctorContext).infer.inferConstructorInstance(tree1, caseClass.typeParams, ptSafe)

      // simplify types without losing safety,
      // so that we get rid of unnecessary type slack, and so that error messages don't unnecessarily refer to skolems
      val extrapolator = new ExistentialExtrapolation(freeVars)
      def extrapolate(tp: Type) = extrapolator extrapolate tp

      // once the containing CaseDef has been type checked (see typedCase),
      // tree1's remaining type-slack skolems will be deskolemized (to the method type parameter skolems)
      tree1 modifyType {
        case MethodType(ctorArgs, restpe) => // ctorArgs are actually in a covariant position, since this is the type of the subpatterns of the pattern represented by this Apply node
          copyMethodType(tree1.tpe, ctorArgs map (_ modifyInfo extrapolate), extrapolate(restpe)) // no need to clone ctorArgs, this is OUR method type
        case tp => tp
      }
    }

    def doTypedUnapply(tree: Tree, fun0: Tree, fun: Tree, args: List[Tree], mode: Mode, pt: Type): Tree = {
      def duplErrTree = setError(treeCopy.Apply(tree, fun0, args))
      def duplErrorTree(err: AbsTypeError) = { context.issue(err); duplErrTree }

      if (args.length > MaxTupleArity)
        return duplErrorTree(TooManyArgsPatternError(fun))

      def freshArgType(tp: Type): Type = tp match {
        case MethodType(param :: _, _) => param.tpe
        case PolyType(tparams, restpe) => createFromClonedSymbols(tparams, freshArgType(restpe))(genPolyType)
        case OverloadedType(_, _)      => OverloadedUnapplyError(fun) ; ErrorType
        case _                         => UnapplyWithSingleArgError(fun) ; ErrorType
      }
      val unapplyMethod    = unapplyMember(fun.tpe)
      val unapplyType      = fun.tpe memberType unapplyMethod
      val unapplyParamType = firstParamType(unapplyType)
      def isSeq            = unapplyMethod.name == nme.unapplySeq

      def extractor     = extractorForUncheckedType(fun.pos, unapplyParamType)
      def canRemedy     = unapplyParamType match {
        case RefinedType(_, decls) if !decls.isEmpty                 => false
        case RefinedType(parents, _) if parents exists isUncheckable => false
        case _                                                       => extractor.nonEmpty
      }

      def freshUnapplyArgType(): Type = {
        val GenPolyType(freeVars, unappFormal) = freshArgType(unapplyType.skolemizeExistential(context.owner, tree))
        val unapplyContext = context.makeNewScope(context.tree, context.owner)
        freeVars foreach unapplyContext.scope.enter
        val pattp = newTyper(unapplyContext).infer.inferTypedPattern(tree, unappFormal, pt, canRemedy)
        // turn any unresolved type variables in freevars into existential skolems
        val skolems = freeVars map (fv => unapplyContext.owner.newExistentialSkolem(fv, fv))
        pattp.substSym(freeVars, skolems)
      }

      val unapplyArg = (
        context.owner.newValue(nme.SELECTOR_DUMMY, fun.pos, Flags.SYNTHETIC) setInfo (
          if (isApplicableSafe(Nil, unapplyType, pt :: Nil, WildcardType)) pt
          else freshUnapplyArgType()
        )
      )
      val unapplyArgTree = Ident(unapplyArg) updateAttachment SubpatternsAttachment(args)

      // clearing the type is necessary so that ref will be stabilized; see bug 881
      val fun1 = typedPos(fun.pos)(Apply(Select(fun.clearType(), unapplyMethod), unapplyArgTree :: Nil))

      def makeTypedUnapply() = {
        // the union of the expected type and the inferred type of the argument to unapply
        val glbType        = glb(ensureFullyDefined(pt) :: unapplyArg.tpe_* :: Nil)
        val wrapInTypeTest = canRemedy && !(fun1.symbol.owner isNonBottomSubClass ClassTagClass)
        val formals        = patmat.alignPatterns(context.asInstanceOf[analyzer.Context], fun1, args).unexpandedFormals
        val args1          = typedArgsForFormals(args, formals, mode)
        val result         = UnApply(fun1, args1) setPos tree.pos setType glbType

        if (wrapInTypeTest)
          wrapClassTagUnapply(result, extractor, glbType)
        else
          result
      }

      if (fun1.tpe.isErroneous)
        duplErrTree
      else if (unapplyMethod.isMacro && !fun1.isInstanceOf[Apply]) {
        if (isBlackbox(unapplyMethod)) duplErrorTree(BlackboxExtractorExpansion(tree))
        else duplErrorTree(WrongShapeExtractorExpansion(tree))
      } else
        makeTypedUnapply()
    }

    def wrapClassTagUnapply(uncheckedPattern: Tree, classTagExtractor: Tree, pt: Type): Tree = {
      // TODO: disable when in unchecked match
      // we don't create a new Context for a Match, so find the CaseDef,
      // then go out one level and navigate back to the match that has this case
      val args = List(uncheckedPattern)
      val app  = atPos(uncheckedPattern.pos)(Apply(classTagExtractor, args))
      // must call doTypedUnapply directly, as otherwise we get undesirable rewrites
      // and re-typechecks of the target of the unapply call in PATTERNmode,
      // this breaks down when the classTagExtractor (which defines the unapply member) is not a simple reference to an object,
      // but an arbitrary tree as is the case here
      val res = doTypedUnapply(app, classTagExtractor, classTagExtractor, args, PATTERNmode, pt)

      log(sm"""
        |wrapClassTagUnapply {
        |  pattern: $uncheckedPattern
        |  extract: $classTagExtractor
        |       pt: $pt
        |      res: $res
        |}""".trim)

      res
    }

    // if there's a ClassTag that allows us to turn the unchecked type test for `pt` into a checked type test
    // return the corresponding extractor (an instance of ClassTag[`pt`])
    def extractorForUncheckedType(pos: Position, pt: Type): Tree = {
      if (isPastTyper || (pt eq NoType)) EmptyTree else {
        pt match {
          case RefinedType(parents, decls) if !decls.isEmpty || (parents exists isUncheckable) => return EmptyTree
          case _                                                                               =>
        }
        // only look at top-level type, can't (reliably) do anything about unchecked type args (in general)
        // but at least make a proper type before passing it elsewhere
        val pt1 = pt.dealiasWiden match {
          case tr @ TypeRef(pre, sym, args) if args.nonEmpty => copyTypeRef(tr, pre, sym, sym.typeParams map (_.tpeHK)) // replace actual type args with dummies
          case pt1                                           => pt1
        }
        if (isCheckable(pt1)) EmptyTree
        else resolveClassTag(pos, pt1) match {
          case tree if unapplyMember(tree.tpe).exists => tree
          case _                                      => devWarning(s"Cannot create runtime type test for $pt1") ; EmptyTree
        }
      }
    }
  }
}
/* NSC -- new Scala compiler
 * Copyright 2005-2013 LAMP/EPFL
 * @author  Paul Phillips
 */

package scala
package tools
package nsc
package typechecker

import scala.collection.mutable
import symtab.Flags
import Mode._

 /**
 *
 *  A pattern match such as
 *
 *    x match { case Foo(a, b) => ...}
 *
 *  Might match an instance of any of the following definitions of Foo.
 *  Note the analogous treatment between case classes and unapplies.
 *
 *    case class Foo(xs: Int*)
 *    case class Foo(a: Int, xs: Int*)
 *    case class Foo(a: Int, b: Int)
 *    case class Foo(a: Int, b: Int, xs: Int*)
 *
 *    object Foo { def unapplySeq(x: Any): Option[Seq[Int]] }
 *    object Foo { def unapplySeq(x: Any): Option[(Int, Seq[Int])] }
 *    object Foo { def unapply(x: Any): Option[(Int, Int)] }
 *    object Foo { def unapplySeq(x: Any): Option[(Int, Int, Seq[Int])] }
 */

trait PatternTypers {
  self: Analyzer =>

  import global._
  import definitions._

  private object FixedAndRepeatedTypes {
    def unapply(types: List[Type]) = types match {
      case init :+ last if isRepeatedParamType(last) => Some((init, dropRepeated(last)))
      case _                                         => Some((types, NoType))
    }
  }

  trait PatternTyper {
    self: Typer =>

    import TyperErrorGen._
    import infer._

    private def unit = context.unit

    // If the tree's symbol's type does not define an extractor, maybe the tree's type does.
    // this is the case when we encounter an arbitrary tree as the target of an unapply call
    // (rather than something that looks like a constructor call.) (for now, this only happens
    // due to wrapClassTagUnapply, but when we support parameterized extractors, it will become
    // more common place)
    private def hasUnapplyMember(tpe: Type): Boolean   = reallyExists(unapplyMember(tpe))
    private def hasUnapplyMember(sym: Symbol): Boolean = hasUnapplyMember(sym.tpe_*)
    private def hasUnapplyMember(fun: Tree): Boolean   = hasUnapplyMember(fun.symbol) || hasUnapplyMember(fun.tpe)

    // ad-hoc overloading resolution to deal with unapplies and case class constructors
    // If some but not all alternatives survive filtering the tree's symbol with `p`,
    // then update the tree's symbol and type to exclude the filtered out alternatives.
    private def inPlaceAdHocOverloadingResolution(fun: Tree)(p: Symbol => Boolean): Tree = fun.symbol filter p match {
      case sym if sym.exists && (sym ne fun.symbol) => fun setSymbol sym modifyType (tp => filterOverloadedAlts(tp)(p))
      case _                                        => fun
    }
    private def filterOverloadedAlts(tpe: Type)(p: Symbol => Boolean): Type = tpe match {
      case OverloadedType(pre, alts) => overloadedType(pre, alts filter p)
      case tp                        => tp
    }

    def typedConstructorPattern(fun0: Tree, pt: Type): Tree = {
      // Do some ad-hoc overloading resolution and update the tree's symbol and type
      // do not update the symbol if the tree's symbol's type does not define an unapply member
      // (e.g. since it's some method that returns an object with an unapply member)
      val fun         = inPlaceAdHocOverloadingResolution(fun0)(hasUnapplyMember)
      val canElide    = treeInfo.isQualifierSafeToElide(fun)
      val caseClass   = companionSymbolOf(fun.tpe.typeSymbol.sourceModule, context)
      val member      = unapplyMember(fun.tpe)
      def resultType  = (fun.tpe memberType member).finalResultType
      def isEmptyType = resultOfMatchingMethod(resultType, nme.isEmpty)()
      def isOkay      = (
           resultType.isErroneous
        || (resultType <:< BooleanTpe)
        || (isEmptyType <:< BooleanTpe)
        || member.isMacro
        || member.isOverloaded // the whole overloading situation is over the rails
      )

      // Dueling test cases: pos/overloaded-unapply.scala, run/case-class-23.scala, pos/t5022.scala
      // A case class with 23+ params has no unapply method.
      // A case class constructor may be overloaded with unapply methods in the companion.
      if (canElide && caseClass.isCase && !member.isOverloaded)
        logResult(s"convertToCaseConstructor($fun, $caseClass, pt=$pt)")(convertToCaseConstructor(fun, caseClass, pt))
      else if (!reallyExists(member))
        CaseClassConstructorError(fun, s"${fun.symbol} is not a case class, nor does it have an unapply/unapplySeq member")
      else if (isOkay)
        fun
      else if (isEmptyType == NoType)
        CaseClassConstructorError(fun, s"an unapply result must have a member `def isEmpty: Boolean")
      else
        CaseClassConstructorError(fun, s"an unapply result must have a member `def isEmpty: Boolean (found: def isEmpty: $isEmptyType)")
    }

    def typedArgsForFormals(args: List[Tree], formals: List[Type], mode: Mode): List[Tree] = {
      def typedArgWithFormal(arg: Tree, pt: Type) = {
        val newMode = if (isByNameParamType(pt)) mode.onlySticky else mode.onlySticky | BYVALmode
        typedArg(arg, mode, newMode, dropByName(pt))
      }
      val FixedAndRepeatedTypes(fixed, elem) = formals
      val front = (args, fixed).zipped map typedArgWithFormal
      def rest  = context withinStarPatterns (args drop front.length map (typedArgWithFormal(_, elem)))

      elem match {
        case NoType => front
        case _      => front ::: rest
      }
    }

    private def boundedArrayType(bound: Type): Type = {
      val tparam = context.owner.freshExistential("", 0) setInfo (TypeBounds upper bound)
      newExistentialType(tparam :: Nil, arrayType(tparam.tpe_*))
    }

    protected def typedStarInPattern(tree: Tree, mode: Mode, pt: Type) = {
      val Typed(expr, tpt) = tree
      val exprTyped = typed(expr, mode)
      val baseClass = exprTyped.tpe.typeSymbol match {
        case ArrayClass => ArrayClass
        case _          => SeqClass
      }
      val starType = baseClass match {
        case ArrayClass if isPrimitiveValueType(pt) || !isFullyDefined(pt) => arrayType(pt)
        case ArrayClass                                                    => boundedArrayType(pt)
        case _                                                             => seqType(pt)
      }
      val exprAdapted = adapt(exprTyped, mode, starType)
      exprAdapted.tpe baseType baseClass match {
        case TypeRef(_, _, elemtp :: Nil) => treeCopy.Typed(tree, exprAdapted, tpt setType elemtp) setType elemtp
        case _                            => setError(tree)
      }
    }

    protected def typedInPattern(tree: Typed, mode: Mode, pt: Type) = {
      val Typed(expr, tpt) = tree
      val tptTyped  = typedType(tpt, mode)
      val tpe       = tptTyped.tpe
      val exprTyped = typed(expr, mode, tpe.deconst)
      val extractor = extractorForUncheckedType(tpt.pos, tpe)

      val canRemedy = tpe match {
        case RefinedType(_, decls) if !decls.isEmpty                 => false
        case RefinedType(parents, _) if parents exists isUncheckable => false
        case _                                                       => extractor.nonEmpty
      }

      val ownType   = inferTypedPattern(tptTyped, tpe, pt, canRemedy)
      val treeTyped = treeCopy.Typed(tree, exprTyped, tptTyped) setType ownType

      extractor match {
        case EmptyTree => treeTyped
        case _         => wrapClassTagUnapply(treeTyped, extractor, tpe)
      }
    }
    private class VariantToSkolemMap extends TypeMap(trackVariance = true) {
      private val skolemBuffer = mutable.ListBuffer[TypeSymbol]()

      // !!! FIXME - skipping this when variance.isInvariant allows unsoundness, see SI-5189
      // Test case which presently requires the exclusion is run/gadts.scala.
      def eligible(tparam: Symbol) = (
           tparam.isTypeParameterOrSkolem
        && tparam.owner.isTerm
        && (settings.strictInference || !variance.isInvariant)
      )

      def skolems = try skolemBuffer.toList finally skolemBuffer.clear()
      def apply(tp: Type): Type = mapOver(tp) match {
        case tp @ TypeRef(NoPrefix, tpSym, Nil) if eligible(tpSym) =>
          val bounds = (
            if (variance.isInvariant) tpSym.tpeHK.bounds
            else if (variance.isPositive) TypeBounds.upper(tpSym.tpeHK)
            else TypeBounds.lower(tpSym.tpeHK)
          )
          // origin must be the type param so we can deskolemize
          val skolem = context.owner.newGADTSkolem(unit.freshTypeName("?" + tpSym.name), tpSym, bounds)
          skolemBuffer += skolem
          logResult(s"Created gadt skolem $skolem: ${skolem.tpe_*} to stand in for $tpSym")(skolem.tpe_*)
        case tp1 => tp1
      }
    }

    /*
     * To deal with the type slack between actual (run-time) types and statically known types, for each abstract type T,
     * reflect its variance as a skolem that is upper-bounded by T (covariant position), or lower-bounded by T (contravariant).
     *
     * Consider the following example:
     *
     *  class AbsWrapperCov[+A]
     *  case class Wrapper[B](x: Wrapped[B]) extends AbsWrapperCov[B]
     *
     *  def unwrap[T](x: AbsWrapperCov[T]): Wrapped[T] = x match {
     *    case Wrapper(wrapped) => // Wrapper's type parameter must not be assumed to be equal to T, it's *upper-bounded* by it
     *      wrapped // : Wrapped[_ <: T]
     *  }
     *
     * this method should type check if and only if Wrapped is covariant in its type parameter
     *
     * when inferring Wrapper's type parameter B from x's type AbsWrapperCov[T],
     * we must take into account that x's actual type is AbsWrapperCov[Tactual] forSome {type Tactual <: T}
     * as AbsWrapperCov is covariant in A -- in other words, we must not assume we know T exactly, all we know is its upper bound
     *
     * since method application is the only way to generate this slack between run-time and compile-time types (TODO: right!?),
     * we can simply replace skolems that represent method type parameters as seen from the method's body
     * by other skolems that are (upper/lower)-bounded by that type-parameter skolem
     * (depending on the variance position of the skolem in the statically assumed type of the scrutinee, pt)
     *
     * see test/files/../t5189*.scala
     */
    private def convertToCaseConstructor(tree: Tree, caseClass: Symbol, ptIn: Type): Tree = {
      // TODO SI-7886 / SI-5900 This is well intentioned but doesn't quite hit the nail on the head.
      //      For now, I've put it completely behind -Xstrict-inference.
      val untrustworthyPt = settings.strictInference && (
           ptIn =:= AnyTpe
        || ptIn =:= NothingTpe
        || ptIn.typeSymbol != caseClass
      )
      val variantToSkolem     = new VariantToSkolemMap
      val caseClassType       = tree.tpe.prefix memberType caseClass
      val caseConstructorType = caseClassType memberType caseClass.primaryConstructor
      val tree1               = TypeTree(caseConstructorType) setOriginal tree
      val pt                  = if (untrustworthyPt) caseClassType else ptIn

      // have to open up the existential and put the skolems in scope
      // can't simply package up pt in an ExistentialType, because that takes us back to square one (List[_ <: T] == List[T] due to covariance)
      val ptSafe   = logResult(s"case constructor from (${tree.summaryString}, $caseClassType, $pt)")(variantToSkolem(pt))
      val freeVars = variantToSkolem.skolems

      // use "tree" for the context, not context.tree: don't make another CaseDef context,
      // as instantiateTypeVar's bounds would end up there
      val ctorContext = context.makeNewScope(tree, context.owner)
      freeVars foreach ctorContext.scope.enter
      newTyper(ctorContext).infer.inferConstructorInstance(tree1, caseClass.typeParams, ptSafe)

      // simplify types without losing safety,
      // so that we get rid of unnecessary type slack, and so that error messages don't unnecessarily refer to skolems
      val extrapolator = new ExistentialExtrapolation(freeVars)
      def extrapolate(tp: Type) = extrapolator extrapolate tp

      // once the containing CaseDef has been type checked (see typedCase),
      // tree1's remaining type-slack skolems will be deskolemized (to the method type parameter skolems)
      tree1 modifyType {
        case MethodType(ctorArgs, restpe) => // ctorArgs are actually in a covariant position, since this is the type of the subpatterns of the pattern represented by this Apply node
          copyMethodType(tree1.tpe, ctorArgs map (_ modifyInfo extrapolate), extrapolate(restpe)) // no need to clone ctorArgs, this is OUR method type
        case tp => tp
      }
    }

    def doTypedUnapply(tree: Tree, fun0: Tree, fun: Tree, args: List[Tree], mode: Mode, pt: Type): Tree = {
      def duplErrTree = setError(treeCopy.Apply(tree, fun0, args))
      def duplErrorTree(err: AbsTypeError) = { context.issue(err); duplErrTree }

      if (args.length > MaxTupleArity)
        return duplErrorTree(TooManyArgsPatternError(fun))

      def freshArgType(tp: Type): Type = tp match {
        case MethodType(param :: _, _) => param.tpe
        case PolyType(tparams, restpe) => createFromClonedSymbols(tparams, freshArgType(restpe))(genPolyType)
        case OverloadedType(_, _)      => OverloadedUnapplyError(fun) ; ErrorType
        case _                         => UnapplyWithSingleArgError(fun) ; ErrorType
      }
      val unapplyMethod    = unapplyMember(fun.tpe)
      val unapplyType      = fun.tpe memberType unapplyMethod
      val unapplyParamType = firstParamType(unapplyType)
      def isSeq            = unapplyMethod.name == nme.unapplySeq

      def extractor     = extractorForUncheckedType(fun.pos, unapplyParamType)
      def canRemedy     = unapplyParamType match {
        case RefinedType(_, decls) if !decls.isEmpty                 => false
        case RefinedType(parents, _) if parents exists isUncheckable => false
        case _                                                       => extractor.nonEmpty
      }

      def freshUnapplyArgType(): Type = {
        val GenPolyType(freeVars, unappFormal) = freshArgType(unapplyType.skolemizeExistential(context.owner, tree))
        val unapplyContext = context.makeNewScope(context.tree, context.owner)
        freeVars foreach unapplyContext.scope.enter
        val pattp = newTyper(unapplyContext).infer.inferTypedPattern(tree, unappFormal, pt, canRemedy)
        // turn any unresolved type variables in freevars into existential skolems
        val skolems = freeVars map (fv => unapplyContext.owner.newExistentialSkolem(fv, fv))
        pattp.substSym(freeVars, skolems)
      }

      val unapplyArg = (
        context.owner.newValue(nme.SELECTOR_DUMMY, fun.pos, Flags.SYNTHETIC) setInfo (
          if (isApplicableSafe(Nil, unapplyType, pt :: Nil, WildcardType)) pt
          else freshUnapplyArgType()
        )
      )
      val unapplyArgTree = Ident(unapplyArg) updateAttachment SubpatternsAttachment(args)

      // clearing the type is necessary so that ref will be stabilized; see bug 881
      val fun1 = typedPos(fun.pos)(Apply(Select(fun.clearType(), unapplyMethod), unapplyArgTree :: Nil))

      def makeTypedUnapply() = {
        // the union of the expected type and the inferred type of the argument to unapply
        val glbType        = glb(ensureFullyDefined(pt) :: unapplyArg.tpe_* :: Nil)
        val wrapInTypeTest = canRemedy && !(fun1.symbol.owner isNonBottomSubClass ClassTagClass)
        val formals        = patmat.alignPatterns(context.asInstanceOf[analyzer.Context], fun1, args).unexpandedFormals
        val args1          = typedArgsForFormals(args, formals, mode)
        val result         = UnApply(fun1, args1) setPos tree.pos setType glbType

        if (wrapInTypeTest)
          wrapClassTagUnapply(result, extractor, glbType)
        else
          result
      }

      if (fun1.tpe.isErroneous)
        duplErrTree
      else if (unapplyMethod.isMacro && !fun1.isInstanceOf[Apply]) {
        if (isBlackbox(unapplyMethod)) duplErrorTree(BlackboxExtractorExpansion(tree))
        else duplErrorTree(WrongShapeExtractorExpansion(tree))
      } else
        makeTypedUnapply()
    }

    def wrapClassTagUnapply(uncheckedPattern: Tree, classTagExtractor: Tree, pt: Type): Tree = {
      // TODO: disable when in unchecked match
      // we don't create a new Context for a Match, so find the CaseDef,
      // then go out one level and navigate back to the match that has this case
      val args = List(uncheckedPattern)
      val app  = atPos(uncheckedPattern.pos)(Apply(classTagExtractor, args))
      // must call doTypedUnapply directly, as otherwise we get undesirable rewrites
      // and re-typechecks of the target of the unapply call in PATTERNmode,
      // this breaks down when the classTagExtractor (which defines the unapply member) is not a simple reference to an object,
      // but an arbitrary tree as is the case here
      val res = doTypedUnapply(app, classTagExtractor, classTagExtractor, args, PATTERNmode, pt)

      log(sm"""
        |wrapClassTagUnapply {
        |  pattern: $uncheckedPattern
        |  extract: $classTagExtractor
        |       pt: $pt
        |      res: $res
        |}""".trim)

      res
    }

    // if there's a ClassTag that allows us to turn the unchecked type test for `pt` into a checked type test
    // return the corresponding extractor (an instance of ClassTag[`pt`])
    def extractorForUncheckedType(pos: Position, pt: Type): Tree = {
      if (isPastTyper || (pt eq NoType)) EmptyTree else {
        pt match {
          case RefinedType(parents, decls) if !decls.isEmpty || (parents exists isUncheckable) => return EmptyTree
          case _                                                                               =>
        }
        // only look at top-level type, can't (reliably) do anything about unchecked type args (in general)
        // but at least make a proper type before passing it elsewhere
        val pt1 = pt.dealiasWiden match {
          case tr @ TypeRef(pre, sym, args) if args.nonEmpty => copyTypeRef(tr, pre, sym, sym.typeParams map (_.tpeHK)) // replace actual type args with dummies
          case pt1                                           => pt1
        }
        if (isCheckable(pt1)) EmptyTree
        else resolveClassTag(pos, pt1) match {
          case tree if unapplyMember(tree.tpe).exists => tree
          case _                                      => devWarning(s"Cannot create runtime type test for $pt1") ; EmptyTree
        }
      }
    }
  }
}