package scala
package reflect
package internal
package tpe
import scala.collection.{ mutable, immutable }
import Flags._
import scala.annotation.tailrec
import Variance._
private[internal] trait TypeMaps {
self: SymbolTable =>
import definitions._
/** Normalize any type aliases within this type (@see Type#normalize).
* Note that this depends very much on the call to "normalize", not "dealias",
* so it is no longer carries the too-stealthy name "deAlias".
*/
object normalizeAliases extends TypeMap {
def apply(tp: Type): Type = mapOver(tp match {
case TypeRef(_, sym, _) if sym.isAliasType && tp.isHigherKinded => logResult(s"Normalized type alias function $tp")(tp.normalize)
case TypeRef(_, sym, _) if sym.isAliasType => tp.normalize
case tp => tp
})
}
/** Remove any occurrence of type <singleton> from this type and its parents */
object dropSingletonType extends TypeMap {
def apply(tp: Type): Type = {
tp match {
case TypeRef(_, SingletonClass, _) =>
AnyTpe
case tp1 @ RefinedType(parents, decls) =>
parents filter (_.typeSymbol != SingletonClass) match {
case Nil => AnyTpe
case p :: Nil if decls.isEmpty => mapOver(p)
case ps => mapOver(copyRefinedType(tp1, ps, decls))
}
case tp1 =>
mapOver(tp1)
}
}
}
/** Type with all top-level occurrences of abstract types replaced by their bounds */
object abstractTypesToBounds extends TypeMap {
def apply(tp: Type): Type = tp match {
case TypeRef(_, sym, _) if sym.isAliasType => apply(tp.dealias)
case TypeRef(_, sym, _) if sym.isAbstractType => apply(tp.bounds.hi)
case rtp @ RefinedType(parents, decls) => copyRefinedType(rtp, parents mapConserve this, decls)
case AnnotatedType(_, _) => mapOver(tp)
case _ => tp // no recursion - top level only
}
}
// Set to true for A* => Seq[A]
// (And it will only rewrite A* in method result types.)
// This is the pre-existing behavior.
// Or false for Seq[A] => Seq[A]
// (It will rewrite A* everywhere but method parameters.)
// This is the specified behavior.
protected def etaExpandKeepsStar = false
/** Turn any T* types into Seq[T] except when
* in method parameter position.
*/
object dropIllegalStarTypes extends TypeMap {
def apply(tp: Type): Type = tp match {
case MethodType(params, restpe) =>
// Not mapping over params
val restpe1 = apply(restpe)
if (restpe eq restpe1) tp
else MethodType(params, restpe1)
case TypeRef(_, RepeatedParamClass, arg :: Nil) =>
seqType(arg)
case _ =>
if (etaExpandKeepsStar) tp else mapOver(tp)
}
}
trait AnnotationFilter extends TypeMap {
def keepAnnotation(annot: AnnotationInfo): Boolean
override def mapOver(annot: AnnotationInfo) =
if (keepAnnotation(annot)) super.mapOver(annot)
else UnmappableAnnotation
}
trait KeepOnlyTypeConstraints extends AnnotationFilter {
// filter keeps only type constraint annotations
def keepAnnotation(annot: AnnotationInfo) = annot matches TypeConstraintClass
}
// todo. move these into scala.reflect.api
/** A prototype for mapping a function over all possible types
*/
abstract class TypeMap(trackVariance: Boolean) extends (Type => Type) {
def this() = this(trackVariance = false)
def apply(tp: Type): Type
private[this] var _variance: Variance = if (trackVariance) Covariant else Invariant
def variance_=(x: Variance) = { assert(trackVariance, this) ; _variance = x }
def variance = _variance
/** Map this function over given type */
def mapOver(tp: Type): Type = tp match {
case tr @ TypeRef(pre, sym, args) =>
val pre1 = this(pre)
val args1 = (
if (trackVariance && args.nonEmpty && !variance.isInvariant && sym.typeParams.nonEmpty)
mapOverArgs(args, sym.typeParams)
else
args mapConserve this
)
if ((pre1 eq pre) && (args1 eq args)) tp
else copyTypeRef(tp, pre1, tr.coevolveSym(pre1), args1)
case ThisType(_) => tp
case SingleType(pre, sym) =>
if (sym.isPackageClass) tp // short path
else {
val pre1 = this(pre)
if (pre1 eq pre) tp
else singleType(pre1, sym)
}
case MethodType(params, result) =>
val params1 = flipped(mapOver(params))
val result1 = this(result)
if ((params1 eq params) && (result1 eq result)) tp
else copyMethodType(tp, params1, result1.substSym(params, params1))
case PolyType(tparams, result) =>
val tparams1 = flipped(mapOver(tparams))
val result1 = this(result)
if ((tparams1 eq tparams) && (result1 eq result)) tp
else PolyType(tparams1, result1.substSym(tparams, tparams1))
case NullaryMethodType(result) =>
val result1 = this(result)
if (result1 eq result) tp
else NullaryMethodType(result1)
case ConstantType(_) => tp
case SuperType(thistp, supertp) =>
val thistp1 = this(thistp)
val supertp1 = this(supertp)
if ((thistp1 eq thistp) && (supertp1 eq supertp)) tp
else SuperType(thistp1, supertp1)
case TypeBounds(lo, hi) =>
val lo1 = flipped(this(lo))
val hi1 = this(hi)
if ((lo1 eq lo) && (hi1 eq hi)) tp
else TypeBounds(lo1, hi1)
case BoundedWildcardType(bounds) =>
val bounds1 = this(bounds)
if (bounds1 eq bounds) tp
else BoundedWildcardType(bounds1.asInstanceOf[TypeBounds])
case rtp @ RefinedType(parents, decls) =>
val parents1 = parents mapConserve this
val decls1 = mapOver(decls)
copyRefinedType(rtp, parents1, decls1)
case ExistentialType(tparams, result) =>
val tparams1 = mapOver(tparams)
val result1 = this(result)
if ((tparams1 eq tparams) && (result1 eq result)) tp
else newExistentialType(tparams1, result1.substSym(tparams, tparams1))
case OverloadedType(pre, alts) =>
val pre1 = if (pre.isInstanceOf[ClassInfoType]) pre else this(pre)
if (pre1 eq pre) tp
else OverloadedType(pre1, alts)
case AntiPolyType(pre, args) =>
val pre1 = this(pre)
val args1 = args mapConserve this
if ((pre1 eq pre) && (args1 eq args)) tp
else AntiPolyType(pre1, args1)
case tv@TypeVar(_, constr) =>
if (constr.instValid) this(constr.inst)
else tv.applyArgs(mapOverArgs(tv.typeArgs, tv.params)) //@M !args.isEmpty implies !typeParams.isEmpty
case AnnotatedType(annots, atp) =>
val annots1 = mapOverAnnotations(annots)
val atp1 = this(atp)
if ((annots1 eq annots) && (atp1 eq atp)) tp
else if (annots1.isEmpty) atp1
else AnnotatedType(annots1, atp1)
/*
case ErrorType => tp
case WildcardType => tp
case NoType => tp
case NoPrefix => tp
case ErasedSingleType(sym) => tp
*/
case _ =>
tp
// throw new Error("mapOver inapplicable for " + tp);
}
def withVariance[T](v: Variance)(body: => T): T = {
val saved = variance
variance = v
try body finally variance = saved
}
@inline final def flipped[T](body: => T): T = {
if (trackVariance) variance = variance.flip
try body
finally if (trackVariance) variance = variance.flip
}
protected def mapOverArgs(args: List[Type], tparams: List[Symbol]): List[Type] = (
if (trackVariance)
map2Conserve(args, tparams)((arg, tparam) => withVariance(variance * tparam.variance)(this(arg)))
else
args mapConserve this
)
/** Applies this map to the symbol's info, setting variance = Invariant
* if necessary when the symbol is an alias.
*/
private def applyToSymbolInfo(sym: Symbol): Type = {
if (trackVariance && !variance.isInvariant && sym.isAliasType)
withVariance(Invariant)(this(sym.info))
else
this(sym.info)
}
/** Called by mapOver to determine whether the original symbols can
* be returned, or whether they must be cloned.
*/
protected def noChangeToSymbols(origSyms: List[Symbol]): Boolean = {
@tailrec def loop(syms: List[Symbol]): Boolean = syms match {
case Nil => true
case x :: xs => (x.info eq applyToSymbolInfo(x)) && loop(xs)
}
loop(origSyms)
}
/** Map this function over given scope */
def mapOver(scope: Scope): Scope = {
val elems = scope.toList
val elems1 = mapOver(elems)
if (elems1 eq elems) scope
else newScopeWith(elems1: _*)
}
/** Map this function over given list of symbols */
def mapOver(origSyms: List[Symbol]): List[Symbol] = {
// fast path in case nothing changes due to map
if (noChangeToSymbols(origSyms)) origSyms
// map is not the identity --> do cloning properly
else cloneSymbolsAndModify(origSyms, TypeMap.this)
}
def mapOver(annot: AnnotationInfo): AnnotationInfo = {
val AnnotationInfo(atp, args, assocs) = annot
val atp1 = mapOver(atp)
val args1 = mapOverAnnotArgs(args)
// there is no need to rewrite assocs, as they are constants
if ((args eq args1) && (atp eq atp1)) annot
else if (args1.isEmpty && args.nonEmpty) UnmappableAnnotation // some annotation arg was unmappable
else AnnotationInfo(atp1, args1, assocs) setPos annot.pos
}
def mapOverAnnotations(annots: List[AnnotationInfo]): List[AnnotationInfo] = {
val annots1 = annots mapConserve mapOver
if (annots1 eq annots) annots
else annots1 filterNot (_ eq UnmappableAnnotation)
}
/** Map over a set of annotation arguments. If any
* of the arguments cannot be mapped, then return Nil. */
def mapOverAnnotArgs(args: List[Tree]): List[Tree] = {
val args1 = args mapConserve mapOver
if (args1 contains UnmappableTree) Nil
else args1
}
def mapOver(tree: Tree): Tree =
mapOver(tree, () => return UnmappableTree)
/** Map a tree that is part of an annotation argument.
* If the tree cannot be mapped, then invoke giveup().
* The default is to transform the tree with
* TypeMapTransformer.
*/
def mapOver(tree: Tree, giveup: ()=>Nothing): Tree =
(new TypeMapTransformer).transform(tree)
/** This transformer leaves the tree alone except to remap
* its types. */
class TypeMapTransformer extends Transformer {
override def transform(tree: Tree) = {
val tree1 = super.transform(tree)
val tpe1 = TypeMap.this(tree1.tpe)
if ((tree eq tree1) && (tree.tpe eq tpe1))
tree
else
tree1.shallowDuplicate.setType(tpe1)
}
}
}
abstract class TypeTraverser extends TypeMap {
def traverse(tp: Type): Unit
def apply(tp: Type): Type = { traverse(tp); tp }
}
abstract class TypeTraverserWithResult[T] extends TypeTraverser {
def result: T
def clear(): Unit
}
abstract class TypeCollector[T](initial: T) extends TypeTraverser {
var result: T = _
def collect(tp: Type) = {
result = initial
traverse(tp)
result
}
}
/** The raw to existential map converts a ''raw type'' to an existential type.
* It is necessary because we might have read a raw type of a
* parameterized Java class from a class file. At the time we read the type
* the corresponding class file might still not be read, so we do not
* know what the type parameters of the type are. Therefore
* the conversion of raw types to existential types might not have taken place
* in ClassFileparser.sigToType (where it is usually done).
*/
def rawToExistential = new TypeMap {
private var expanded = immutable.Set[Symbol]()
def apply(tp: Type): Type = tp match {
case TypeRef(pre, sym, List()) if isRawIfWithoutArgs(sym) =>
if (expanded contains sym) AnyRefTpe
else try {
expanded += sym
val eparams = mapOver(typeParamsToExistentials(sym))
existentialAbstraction(eparams, typeRef(apply(pre), sym, eparams map (_.tpe)))
} finally {
expanded -= sym
}
case _ =>
mapOver(tp)
}
}
/***
*@M: I think this is more desirable, but Martin prefers to leave raw-types as-is as much as possible
object rawToExistentialInJava extends TypeMap {
def apply(tp: Type): Type = tp match {
// any symbol that occurs in a java sig, not just java symbols
// see https://issues.scala-lang.org/browse/SI-2454?focusedCommentId=46618
case TypeRef(pre, sym, List()) if !sym.typeParams.isEmpty =>
val eparams = typeParamsToExistentials(sym, sym.typeParams)
existentialAbstraction(eparams, TypeRef(pre, sym, eparams map (_.tpe)))
case _ =>
mapOver(tp)
}
}
*/
/** Used by existentialAbstraction.
*/
class ExistentialExtrapolation(tparams: List[Symbol]) extends TypeMap(trackVariance = true) {
private val occurCount = mutable.HashMap[Symbol, Int]()
private def countOccs(tp: Type) = {
tp foreach {
case TypeRef(_, sym, _) =>
if (tparams contains sym)
occurCount(sym) += 1
case _ => ()
}
}
def extrapolate(tpe: Type): Type = {
tparams foreach (t => occurCount(t) = 0)
countOccs(tpe)
for (tparam <- tparams)
countOccs(tparam.info)
apply(tpe)
}
/** If these conditions all hold:
* 1) we are in covariant (or contravariant) position
* 2) this type occurs exactly once in the existential scope
* 3) the widened upper (or lower) bound of this type contains no references to tparams
* Then we replace this lone occurrence of the type with the widened upper (or lower) bound.
* All other types pass through unchanged.
*/
def apply(tp: Type): Type = {
val tp1 = mapOver(tp)
if (variance.isInvariant) tp1
else tp1 match {
case TypeRef(pre, sym, args) if tparams contains sym =>
val repl = if (variance.isPositive) dropSingletonType(tp1.bounds.hi) else tp1.bounds.lo
val count = occurCount(sym)
val containsTypeParam = tparams exists (repl contains _)
def msg = {
val word = if (variance.isPositive) "upper" else "lower"
s"Widened lone occurrence of $tp1 inside existential to $word bound"
}
if (!repl.typeSymbol.isBottomClass && count == 1 && !containsTypeParam)
debuglogResult(msg)(repl)
else
tp1
case _ =>
tp1
}
}
override def mapOver(tp: Type): Type = tp match {
case SingleType(pre, sym) =>
if (sym.isPackageClass) tp // short path
else {
val pre1 = this(pre)
if ((pre1 eq pre) || !pre1.isStable) tp
else singleType(pre1, sym)
}
case _ => super.mapOver(tp)
}
// Do not discard the types of existential ident's. The
// symbol of the Ident itself cannot be listed in the
// existential's parameters, so the resulting existential
// type would be ill-formed.
override def mapOver(tree: Tree) = tree match {
case Ident(_) if tree.tpe.isStable => tree
case _ => super.mapOver(tree)
}
}
/**
* Get rid of BoundedWildcardType where variance allows us to do so.
* Invariant: `wildcardExtrapolation(tp) =:= tp`
*
* For example, the MethodType given by `def bla(x: (_ >: String)): (_ <: Int)`
* is both a subtype and a supertype of `def bla(x: String): Int`.
*/
object wildcardExtrapolation extends TypeMap(trackVariance = true) {
def apply(tp: Type): Type =
tp match {
case BoundedWildcardType(TypeBounds(lo, AnyTpe)) if variance.isContravariant => lo
case BoundedWildcardType(TypeBounds(NothingTpe, hi)) if variance.isCovariant => hi
case tp => mapOver(tp)
}
}
/** Might the given symbol be important when calculating the prefix
* of a type? When tp.asSeenFrom(pre, clazz) is called on `tp`,
* the result will be `tp` unchanged if `pre` is trivial and `clazz`
* is a symbol such that isPossiblePrefix(clazz) == false.
*/
def isPossiblePrefix(clazz: Symbol) = clazz.isClass && !clazz.isPackageClass
protected[internal] def skipPrefixOf(pre: Type, clazz: Symbol) = (
(pre eq NoType) || (pre eq NoPrefix) || !isPossiblePrefix(clazz)
)
def newAsSeenFromMap(pre: Type, clazz: Symbol): AsSeenFromMap =
new AsSeenFromMap(pre, clazz)
/** A map to compute the asSeenFrom method.
*/
class AsSeenFromMap(seenFromPrefix: Type, seenFromClass: Symbol) extends TypeMap with KeepOnlyTypeConstraints {
// Some example source constructs relevant in asSeenFrom:
//
// object CaptureThis {
// trait X[A] { def f: this.type = this }
// class Y[A] { def f: this.type = this }
// // Created new existential to represent This(CaptureThis.X) seen from CaptureThis.X[B]: type _1.type <: CaptureThis.X[B] with Singleton
// def f1[B] = new X[B] { }
// // TODO - why is the behavior different when it's a class?
// def f2[B] = new Y[B] { }
// }
// class CaptureVal[T] {
// val f: java.util.List[_ <: T] = null
// // Captured existential skolem for type _$1 seen from CaptureVal.this.f.type: type _$1
// def g = f get 0
// }
// class ClassParam[T] {
// // AsSeenFromMap(Inner.this.type, class Inner)/classParameterAsSeen(T)#loop(ClassParam.this.type, class ClassParam)
// class Inner(lhs: T) { def f = lhs }
// }
def capturedParams: List[Symbol] = _capturedParams
def capturedSkolems: List[Symbol] = _capturedSkolems
def apply(tp: Type): Type = tp match {
case tp @ ThisType(_) => thisTypeAsSeen(tp)
case tp @ SingleType(_, sym) => if (sym.isPackageClass) tp else singleTypeAsSeen(tp)
case tp @ TypeRef(_, sym, _) if isTypeParamOfEnclosingClass(sym) => classParameterAsSeen(tp)
case _ => mapOver(tp)
}
private var _capturedSkolems: List[Symbol] = Nil
private var _capturedParams: List[Symbol] = Nil
private val isStablePrefix = seenFromPrefix.isStable
// isBaseClassOfEnclosingClassOrInfoIsNotYetComplete would be a more accurate
// but less succinct name.
private def isBaseClassOfEnclosingClass(base: Symbol) = {
def loop(encl: Symbol): Boolean = (
isPossiblePrefix(encl)
&& ((encl isSubClass base) || loop(encl.owner.enclClass))
)
// The hasCompleteInfo guard is necessary to avoid cycles during the typing
// of certain classes, notably ones defined inside package objects.
!base.hasCompleteInfo || loop(seenFromClass)
}
/** Is the symbol a class type parameter from one of the enclosing
* classes, or a base class of one of them?
*/
private def isTypeParamOfEnclosingClass(sym: Symbol): Boolean = (
sym.isTypeParameter
&& sym.owner.isClass
&& isBaseClassOfEnclosingClass(sym.owner)
)
/** Creates an existential representing a type parameter which appears
* in the prefix of a ThisType.
*/
protected def captureThis(pre: Type, clazz: Symbol): Type = {
capturedParams find (_.owner == clazz) match {
case Some(p) => p.tpe
case _ =>
val qvar = clazz freshExistential nme.SINGLETON_SUFFIX setInfo singletonBounds(pre)
_capturedParams ::= qvar
debuglog(s"Captured This(${clazz.fullNameString}) seen from $seenFromPrefix: ${qvar.defString}")
qvar.tpe
}
}
protected def captureSkolems(skolems: List[Symbol]) {
for (p <- skolems; if !(capturedSkolems contains p)) {
debuglog(s"Captured $p seen from $seenFromPrefix")
_capturedSkolems ::= p
}
}
/** Find the type argument in an applied type which corresponds to a type parameter.
* The arguments are required to be related as follows, through intermediary `clazz`.
* An exception will be thrown if this is violated.
*
* @param lhs its symbol is a type parameter of `clazz`
* @param rhs a type application constructed from `clazz`
*/
private def correspondingTypeArgument(lhs: Type, rhs: Type): Type = {
val TypeRef(_, lhsSym, lhsArgs) = lhs
val TypeRef(_, rhsSym, rhsArgs) = rhs
require(lhsSym.owner == rhsSym, s"$lhsSym is not a type parameter of $rhsSym")
// Find the type parameter position; we'll use the corresponding argument.
// Why are we checking by name rather than by equality? Because for
// reasons which aren't yet fully clear, we can arrive here holding a type
// parameter whose owner is rhsSym, and which shares the name of an actual
// type parameter of rhsSym, but which is not among the type parameters of
// rhsSym. One can see examples of it at SI-4365.
val argIndex = rhsSym.typeParams indexWhere (lhsSym.name == _.name)
// don't be too zealous with the exceptions, see #2641
if (argIndex < 0 && rhs.parents.exists(typeIsErroneous))
ErrorType
else {
// It's easy to get here when working on hardcore type machinery (not to
// mention when not doing so, see above) so let's provide a standout error.
def own_s(s: Symbol) = s.nameString + " in " + s.owner.nameString
def explain =
sm"""| sought ${own_s(lhsSym)}
| classSym ${own_s(rhsSym)}
| tparams ${rhsSym.typeParams map own_s mkString ", "}
|"""
if (!rhsArgs.isDefinedAt(argIndex))
abort(s"Something is wrong: cannot find $lhs in applied type $rhs\n" + explain)
else {
val targ = rhsArgs(argIndex)
// @M! don't just replace the whole thing, might be followed by type application
val result = appliedType(targ, lhsArgs mapConserve this)
def msg = s"Created $result, though could not find ${own_s(lhsSym)} among tparams of ${own_s(rhsSym)}"
if (!rhsSym.typeParams.contains(lhsSym))
devWarning(s"Inconsistent tparam/owner views: had to fall back on names\n$msg\n$explain")
result
}
}
}
// 0) @pre: `classParam` is a class type parameter
// 1) Walk the owner chain of `seenFromClass` until we find the class which owns `classParam`
// 2) Take the base type of the prefix at that point with respect to the owning class
// 3) Solve for the type parameters through correspondence with the type args of the base type
//
// Only class type parameters (and not skolems) are considered, because other type parameters
// are not influenced by the prefix through which they are seen. Note that type params of
// anonymous type functions, which currently can only arise from normalising type aliases, are
// owned by the type alias of which they are the eta-expansion.
private def classParameterAsSeen(classParam: Type): Type = {
val TypeRef(_, tparam, _) = classParam
def loop(pre: Type, clazz: Symbol): Type = {
// have to deconst because it may be a Class[T]
def nextBase = (pre baseType clazz).deconst
//@M! see test pos/tcpoly_return_overriding.scala why mapOver is necessary
if (skipPrefixOf(pre, clazz))
mapOver(classParam)
else if (!matchesPrefixAndClass(pre, clazz)(tparam.owner))
loop(nextBase.prefix, clazz.owner)
else nextBase match {
case NoType => loop(NoType, clazz.owner) // backstop for SI-2797, must remove `SingletonType#isHigherKinded` and run pos/t2797.scala to get here.
case applied @ TypeRef(_, _, _) => correspondingTypeArgument(classParam, applied)
case ExistentialType(eparams, qtpe) => captureSkolems(eparams) ; loop(qtpe, clazz)
case t => abort(s"$tparam in ${tparam.owner} cannot be instantiated from ${seenFromPrefix.widen}")
}
}
loop(seenFromPrefix, seenFromClass)
}
// Does the candidate symbol match the given prefix and class?
// Since pre may be something like ThisType(A) where trait A { self: B => },
// we have to test the typeSymbol of the widened type, not pre.typeSymbol, or
// B will not be considered.
private def matchesPrefixAndClass(pre: Type, clazz: Symbol)(candidate: Symbol) =
(clazz == candidate) && (pre.widen.typeSymbol isSubClass clazz)
// Whether the annotation tree currently being mapped over has had a This(_) node rewritten.
private[this] var wroteAnnotation = false
private object annotationArgRewriter extends TypeMapTransformer {
private def matchesThis(thiz: Symbol) = matchesPrefixAndClass(seenFromPrefix, seenFromClass)(thiz)
// what symbol should really be used?
private def newThis(): Tree = {
wroteAnnotation = true
val presym = seenFromPrefix.widen.typeSymbol
val thisSym = presym.owner.newValue(presym.name.toTermName, presym.pos) setInfo seenFromPrefix
gen.mkAttributedQualifier(seenFromPrefix, thisSym)
}
/** Rewrite `This` trees in annotation argument trees */
override def transform(tree: Tree): Tree = super.transform(tree) match {
case This(_) if matchesThis(tree.symbol) => newThis()
case tree => tree
}
}
// This becomes considerably cheaper if we optimize for the common cases:
// where the prefix is stable and where no This nodes are rewritten. If
// either is true, then we don't need to worry about calling giveup. So if
// the prefix is unstable, use a stack variable to indicate whether the tree
// was touched. This takes us to one allocation per AsSeenFromMap rather
// than an allocation on every call to mapOver, and no extra work when the
// tree only has its types remapped.
override def mapOver(tree: Tree, giveup: ()=>Nothing): Tree = {
if (isStablePrefix)
annotationArgRewriter transform tree
else {
val saved = wroteAnnotation
wroteAnnotation = false
try annotationArgRewriter transform tree
finally if (wroteAnnotation) giveup() else wroteAnnotation = saved
}
}
private def thisTypeAsSeen(tp: ThisType): Type = {
def loop(pre: Type, clazz: Symbol): Type = {
val pre1 = pre match {
case SuperType(thistpe, _) => thistpe
case _ => pre
}
if (skipPrefixOf(pre, clazz))
mapOver(tp) // TODO - is mapOver necessary here?
else if (!matchesPrefixAndClass(pre, clazz)(tp.sym))
loop((pre baseType clazz).prefix, clazz.owner)
else if (pre1.isStable)
pre1
else
captureThis(pre1, clazz)
}
loop(seenFromPrefix, seenFromClass)
}
private def singleTypeAsSeen(tp: SingleType): Type = {
val SingleType(pre, sym) = tp
val pre1 = this(pre)
if (pre1 eq pre) tp
else if (pre1.isStable) singleType(pre1, sym)
else pre1.memberType(sym).resultType //todo: this should be rolled into existential abstraction
}
override def toString = s"AsSeenFromMap($seenFromPrefix, $seenFromClass)"
}
/** A base class to compute all substitutions */
abstract class SubstMap[T](from: List[Symbol], to: List[T]) extends TypeMap {
// OPT this check was 2-3% of some profiles, demoted to -Xdev
if (isDeveloper) assert(sameLength(from, to), "Unsound substitution from "+ from +" to "+ to)
/** Are `sym` and `sym1` the same? Can be tuned by subclasses. */
protected def matches(sym: Symbol, sym1: Symbol): Boolean = sym eq sym1
/** Map target to type, can be tuned by subclasses */
protected def toType(fromtp: Type, tp: T): Type
protected def renameBoundSyms(tp: Type): Type = tp match {
case MethodType(ps, restp) =>
createFromClonedSymbols(ps, restp)((ps1, tp1) => copyMethodType(tp, ps1, renameBoundSyms(tp1)))
case PolyType(bs, restp) =>
createFromClonedSymbols(bs, restp)((ps1, tp1) => PolyType(ps1, renameBoundSyms(tp1)))
case ExistentialType(bs, restp) =>
createFromClonedSymbols(bs, restp)(newExistentialType)
case _ =>
tp
}
@tailrec private def subst(tp: Type, sym: Symbol, from: List[Symbol], to: List[T]): Type = (
if (from.isEmpty) tp
// else if (to.isEmpty) error("Unexpected substitution on '%s': from = %s but to == Nil".format(tp, from))
else if (matches(from.head, sym)) toType(tp, to.head)
else subst(tp, sym, from.tail, to.tail)
)
def apply(tp0: Type): Type = if (from.isEmpty) tp0 else {
val boundSyms = tp0.boundSyms
val tp1 = if (boundSyms.nonEmpty && (boundSyms exists from.contains)) renameBoundSyms(tp0) else tp0
val tp = mapOver(tp1)
def substFor(sym: Symbol) = subst(tp, sym, from, to)
tp match {
// @M
// 1) arguments must also be substituted (even when the "head" of the
// applied type has already been substituted)
// example: (subst RBound[RT] from [type RT,type RBound] to
// [type RT&,type RBound&]) = RBound&[RT&]
// 2) avoid loops (which occur because alpha-conversion is
// not performed properly imo)
// e.g. if in class Iterable[a] there is a new Iterable[(a,b)],
// we must replace the a in Iterable[a] by (a,b)
// (must not recurse --> loops)
// 3) replacing m by List in m[Int] should yield List[Int], not just List
case TypeRef(NoPrefix, sym, args) =>
val tcon = substFor(sym)
if ((tp eq tcon) || args.isEmpty) tcon
else appliedType(tcon.typeConstructor, args)
case SingleType(NoPrefix, sym) =>
substFor(sym)
case ClassInfoType(parents, decls, sym) =>
val parents1 = parents mapConserve this
// We don't touch decls here; they will be touched when an enclosing TreeSubstituter
// transforms the tree that defines them.
if (parents1 eq parents) tp
else ClassInfoType(parents1, decls, sym)
case _ =>
tp
}
}
}
/** A map to implement the `substSym` method. */
class SubstSymMap(from: List[Symbol], to: List[Symbol]) extends SubstMap(from, to) {
def this(pairs: (Symbol, Symbol)*) = this(pairs.toList.map(_._1), pairs.toList.map(_._2))
protected def toType(fromtp: Type, sym: Symbol) = fromtp match {
case TypeRef(pre, _, args) => copyTypeRef(fromtp, pre, sym, args)
case SingleType(pre, _) => singleType(pre, sym)
}
@tailrec private def subst(sym: Symbol, from: List[Symbol], to: List[Symbol]): Symbol = (
if (from.isEmpty) sym
// else if (to.isEmpty) error("Unexpected substitution on '%s': from = %s but to == Nil".format(sym, from))
else if (matches(from.head, sym)) to.head
else subst(sym, from.tail, to.tail)
)
private def substFor(sym: Symbol) = subst(sym, from, to)
override def apply(tp: Type): Type = (
if (from.isEmpty) tp
else tp match {
case TypeRef(pre, sym, args) if pre ne NoPrefix =>
val newSym = substFor(sym)
// mapOver takes care of subst'ing in args
mapOver ( if (sym eq newSym) tp else copyTypeRef(tp, pre, newSym, args) )
// assert(newSym.typeParams.length == sym.typeParams.length, "typars mismatch in SubstSymMap: "+(sym, sym.typeParams, newSym, newSym.typeParams))
case SingleType(pre, sym) if pre ne NoPrefix =>
val newSym = substFor(sym)
mapOver( if (sym eq newSym) tp else singleType(pre, newSym) )
case _ =>
super.apply(tp)
}
)
object mapTreeSymbols extends TypeMapTransformer {
val strictCopy = newStrictTreeCopier
def termMapsTo(sym: Symbol) = from indexOf sym match {
case -1 => None
case idx => Some(to(idx))
}
// if tree.symbol is mapped to another symbol, passes the new symbol into the
// constructor `trans` and sets the symbol and the type on the resulting tree.
def transformIfMapped(tree: Tree)(trans: Symbol => Tree) = termMapsTo(tree.symbol) match {
case Some(toSym) => trans(toSym) setSymbol toSym setType tree.tpe
case None => tree
}
// changes trees which refer to one of the mapped symbols. trees are copied before attributes are modified.
override def transform(tree: Tree) = {
// super.transform maps symbol references in the types of `tree`. it also copies trees where necessary.
super.transform(tree) match {
case id @ Ident(_) =>
transformIfMapped(id)(toSym =>
strictCopy.Ident(id, toSym.name))
case sel @ Select(qual, name) =>
transformIfMapped(sel)(toSym =>
strictCopy.Select(sel, qual, toSym.name))
case tree => tree
}
}
}
override def mapOver(tree: Tree, giveup: ()=>Nothing): Tree = {
mapTreeSymbols.transform(tree)
}
}
/** A map to implement the `subst` method. */
class SubstTypeMap(val from: List[Symbol], val to: List[Type]) extends SubstMap(from, to) {
protected def toType(fromtp: Type, tp: Type) = tp
override def mapOver(tree: Tree, giveup: () => Nothing): Tree = {
object trans extends TypeMapTransformer {
override def transform(tree: Tree) = tree match {
case Ident(name) =>
from indexOf tree.symbol match {
case -1 => super.transform(tree)
case idx =>
val totpe = to(idx)
if (totpe.isStable) tree.duplicate setType totpe
else giveup()
}
case _ =>
super.transform(tree)
}
}
trans.transform(tree)
}
}
/** A map to implement the `substThis` method. */
class SubstThisMap(from: Symbol, to: Type) extends TypeMap {
def apply(tp: Type): Type = tp match {
case ThisType(sym) if (sym == from) => to
case _ => mapOver(tp)
}
}
class SubstWildcardMap(from: List[Symbol]) extends TypeMap {
def apply(tp: Type): Type = try {
tp match {
case TypeRef(_, sym, _) if from contains sym =>
BoundedWildcardType(sym.info.bounds)
case _ =>
mapOver(tp)
}
} catch {
case ex: MalformedType =>
WildcardType
}
}
// dependent method types
object IsDependentCollector extends TypeCollector(false) {
def traverse(tp: Type) {
if (tp.isImmediatelyDependent) result = true
else if (!result) mapOver(tp.dealias)
}
}
object ApproximateDependentMap extends TypeMap {
def apply(tp: Type): Type =
if (tp.isImmediatelyDependent) WildcardType
else mapOver(tp)
}
/** Note: This map is needed even for non-dependent method types, despite what the name might imply.
*/
class InstantiateDependentMap(params: List[Symbol], actuals0: List[Type]) extends TypeMap with KeepOnlyTypeConstraints {
private val actuals = actuals0.toIndexedSeq
private val existentials = new Array[Symbol](actuals.size)
def existentialsNeeded: List[Symbol] = existentials.iterator.filter(_ ne null).toList
private object StableArgTp {
// type of actual arg corresponding to param -- if the type is stable
def unapply(param: Symbol): Option[Type] = (params indexOf param) match {
case -1 => None
case pid =>
val tp = actuals(pid)
if (tp.isStable && (tp.typeSymbol != NothingClass)) Some(tp)
else None
}
}
/** Return the type symbol for referencing a parameter that's instantiated to an unstable actual argument.
*
* To soundly abstract over an unstable value (x: T) while retaining the most type information,
* use `x.type forSome { type x.type <: T with Singleton}`
* `typeOf[T].narrowExistentially(symbolOf[x])`.
*
* See also: captureThis in AsSeenFromMap.
*/
private def existentialFor(pid: Int) = {
if (existentials(pid) eq null) {
val param = params(pid)
existentials(pid) = (
param.owner.newExistential(param.name.toTypeName append nme.SINGLETON_SUFFIX, param.pos, param.flags)
setInfo singletonBounds(actuals(pid))
)
}
existentials(pid)
}
private object UnstableArgTp {
// existential quantifier and type of corresponding actual arg with unstable type
def unapply(param: Symbol): Option[(Symbol, Type)] = (params indexOf param) match {
case -1 => None
case pid =>
val sym = existentialFor(pid)
Some((sym, sym.tpe_*)) // refers to an actual value, must be kind-*
}
}
private object StabilizedArgTp {
def unapply(param: Symbol): Option[Type] =
param match {
case StableArgTp(tp) => Some(tp) // (1)
case UnstableArgTp(_, tp) => Some(tp) // (2)
case _ => None
}
}
/** instantiate `param.type` to the (sound approximation of the) type `T`
* of the actual argument `arg` that was passed in for `param`
*
* (1) If `T` is stable, we can just use that.
*
* (2) SI-3873: it'd be unsound to instantiate `param.type` to an unstable `T`,
* so we approximate to `X forSome {type X <: T with Singleton}` -- we can't soundly say more.
*/
def apply(tp: Type): Type = tp match {
case SingleType(NoPrefix, StabilizedArgTp(tp)) => tp
case _ => mapOver(tp)
}
//AM propagate more info to annotations -- this seems a bit ad-hoc... (based on code by spoon)
override def mapOver(arg: Tree, giveup: ()=>Nothing): Tree = {
// TODO: this should be simplified; in the stable case, one can
// probably just use an Ident to the tree.symbol.
//
// @PP: That leads to failure here, where stuff no longer has type
// 'String @Annot("stuff")' but 'String @Annot(x)'.
//
// def m(x: String): String @Annot(x) = x
// val stuff = m("stuff")
//
// (TODO cont.) Why an existential in the non-stable case?
//
// @PP: In the following:
//
// def m = { val x = "three" ; val y: String @Annot(x) = x; y }
//
// m is typed as 'String @Annot(x) forSome { val x: String }'.
//
// Both examples are from run/constrained-types.scala.
object treeTrans extends Transformer {
override def transform(tree: Tree): Tree = tree.symbol match {
case StableArgTp(tp) => gen.mkAttributedQualifier(tp, tree.symbol)
case UnstableArgTp(quant, tp) => Ident(quant) copyAttrs tree setType tp
case _ => super.transform(tree)
}
}
treeTrans transform arg
}
}
/** A map to convert every occurrence of a wildcard type to a fresh
* type variable */
object wildcardToTypeVarMap extends TypeMap {
def apply(tp: Type): Type = tp match {
case WildcardType =>
TypeVar(tp, new TypeConstraint)
case BoundedWildcardType(bounds) =>
TypeVar(tp, new TypeConstraint(bounds))
case _ =>
mapOver(tp)
}
}
/** A map to convert each occurrence of a type variable to its origin. */
object typeVarToOriginMap extends TypeMap {
def apply(tp: Type): Type = tp match {
case TypeVar(origin, _) => origin
case _ => mapOver(tp)
}
}
/** A map to implement the `contains` method. */
class ContainsCollector(sym: Symbol) extends TypeCollector(false) {
def traverse(tp: Type) {
if (!result) {
tp match {
case _: ExistentialType =>
// ExistentialType#normalize internally calls contains, which leads to exponential performance
// for types like: `A[_ <: B[_ <: ... ]]`. Example: pos/existential-contains.scala.
//
// We can just map over the components and wait until we see the underlying type before we call
// normalize.
mapOver(tp)
case _ =>
tp.normalize match {
case TypeRef(_, sym1, _) if (sym == sym1) => result = true
case SingleType(_, sym1) if (sym == sym1) => result = true
case _ => mapOver(tp)
}
}
}
}
override def mapOver(arg: Tree) = {
for (t <- arg) {
traverse(t.tpe)
if (t.symbol == sym)
result = true
}
arg
}
}
/** A map to implement the `filter` method. */
class FilterTypeCollector(p: Type => Boolean) extends TypeCollector[List[Type]](Nil) {
override def collect(tp: Type) = super.collect(tp).reverse
def traverse(tp: Type) {
if (p(tp)) result ::= tp
mapOver(tp)
}
}
/** A map to implement the `collect` method. */
class CollectTypeCollector[T](pf: PartialFunction[Type, T]) extends TypeCollector[List[T]](Nil) {
override def collect(tp: Type) = super.collect(tp).reverse
def traverse(tp: Type) {
if (pf.isDefinedAt(tp)) result ::= pf(tp)
mapOver(tp)
}
}
class ForEachTypeTraverser(f: Type => Unit) extends TypeTraverser {
def traverse(tp: Type) {
f(tp)
mapOver(tp)
}
}
/** A map to implement the `filter` method. */
class FindTypeCollector(p: Type => Boolean) extends TypeCollector[Option[Type]](None) {
def traverse(tp: Type) {
if (result.isEmpty) {
if (p(tp)) result = Some(tp)
mapOver(tp)
}
}
}
/** A map to implement the `contains` method. */
object ErroneousCollector extends TypeCollector(false) {
def traverse(tp: Type) {
if (!result) {
result = tp.isError
mapOver(tp)
}
}
}
object adaptToNewRunMap extends TypeMap {
private def adaptToNewRun(pre: Type, sym: Symbol): Symbol = {
if (phase.flatClasses || sym.isRootSymbol || (pre eq NoPrefix) || (pre eq NoType) || sym.isPackageClass)
sym
else if (sym.isModuleClass) {
val sourceModule1 = adaptToNewRun(pre, sym.sourceModule)
sourceModule1.moduleClass orElse sourceModule1.initialize.moduleClass orElse {
val msg = "Cannot adapt module class; sym = %s, sourceModule = %s, sourceModule.moduleClass = %s => sourceModule1 = %s, sourceModule1.moduleClass = %s"
debuglog(msg.format(sym, sym.sourceModule, sym.sourceModule.moduleClass, sourceModule1, sourceModule1.moduleClass))
sym
}
}
else {
var rebind0 = pre.findMember(sym.name, BRIDGE, 0, stableOnly = true) orElse {
if (sym.isAliasType) throw missingAliasException
devWarning(s"$pre.$sym no longer exist at phase $phase")
throw new MissingTypeControl // For build manager and presentation compiler purposes
}
/* The two symbols have the same fully qualified name */
def corresponds(sym1: Symbol, sym2: Symbol): Boolean =
sym1.name == sym2.name && (sym1.isPackageClass || corresponds(sym1.owner, sym2.owner))
if (!corresponds(sym.owner, rebind0.owner)) {
debuglog("ADAPT1 pre = "+pre+", sym = "+sym.fullLocationString+", rebind = "+rebind0.fullLocationString)
val bcs = pre.baseClasses.dropWhile(bc => !corresponds(bc, sym.owner))
if (bcs.isEmpty)
assert(pre.typeSymbol.isRefinementClass, pre) // if pre is a refinementclass it might be a structural type => OK to leave it in.
else
rebind0 = pre.baseType(bcs.head).member(sym.name)
debuglog(
"ADAPT2 pre = " + pre +
", bcs.head = " + bcs.head +
", sym = " + sym.fullLocationString +
", rebind = " + rebind0.fullLocationString
)
}
rebind0.suchThat(sym => sym.isType || sym.isStable) orElse {
debuglog("" + phase + " " +phase.flatClasses+sym.owner+sym.name+" "+sym.isType)
throw new MalformedType(pre, sym.nameString)
}
}
}
def apply(tp: Type): Type = tp match {
case ThisType(sym) =>
try {
val sym1 = adaptToNewRun(sym.owner.thisType, sym)
if (sym1 == sym) tp else ThisType(sym1)
} catch {
case ex: MissingTypeControl =>
tp
}
case SingleType(pre, sym) =>
if (sym.hasPackageFlag) tp
else {
val pre1 = this(pre)
try {
val sym1 = adaptToNewRun(pre1, sym)
if ((pre1 eq pre) && (sym1 eq sym)) tp
else singleType(pre1, sym1)
} catch {
case _: MissingTypeControl =>
tp
}
}
case TypeRef(pre, sym, args) =>
if (sym.isPackageClass) tp
else {
val pre1 = this(pre)
val args1 = args mapConserve (this)
try {
val sym1 = adaptToNewRun(pre1, sym)
if ((pre1 eq pre) && (sym1 eq sym) && (args1 eq args)/* && sym.isExternal*/) {
tp
} else if (sym1 == NoSymbol) {
devWarning(s"adapt to new run failed: pre=$pre pre1=$pre1 sym=$sym")
tp
} else {
copyTypeRef(tp, pre1, sym1, args1)
}
} catch {
case ex: MissingAliasControl =>
apply(tp.dealias)
case _: MissingTypeControl =>
tp
}
}
case MethodType(params, restp) =>
val restp1 = this(restp)
if (restp1 eq restp) tp
else copyMethodType(tp, params, restp1)
case NullaryMethodType(restp) =>
val restp1 = this(restp)
if (restp1 eq restp) tp
else NullaryMethodType(restp1)
case PolyType(tparams, restp) =>
val restp1 = this(restp)
if (restp1 eq restp) tp
else PolyType(tparams, restp1)
// Lukas: we need to check (together) whether we should also include parameter types
// of PolyType and MethodType in adaptToNewRun
case ClassInfoType(parents, decls, clazz) =>
if (clazz.isPackageClass) tp
else {
val parents1 = parents mapConserve (this)
if (parents1 eq parents) tp
else ClassInfoType(parents1, decls, clazz)
}
case RefinedType(parents, decls) =>
val parents1 = parents mapConserve (this)
if (parents1 eq parents) tp
else refinedType(parents1, tp.typeSymbol.owner, decls, tp.typeSymbol.owner.pos)
case SuperType(_, _) => mapOver(tp)
case TypeBounds(_, _) => mapOver(tp)
case TypeVar(_, _) => mapOver(tp)
case AnnotatedType(_, _) => mapOver(tp)
case ExistentialType(_, _) => mapOver(tp)
case _ => tp
}
}
}
