path: root/src/reflect/scala/reflect/internal/Scopes.scala

                            
                                
/* NSC -- new Scala compiler
 * Copyright 2005-2013 LAMP/EPFL
 * @author  Martin Odersky
 */

package scala
package reflect
package internal

import scala.annotation.tailrec

trait Scopes extends api.Scopes { self: SymbolTable =>

  /** An ADT to represent the results of symbol name lookups.
   */
  sealed trait NameLookup { def symbol: Symbol ; def isSuccess = false }
  case class LookupSucceeded(qualifier: Tree, symbol: Symbol) extends NameLookup { override def isSuccess = true }
  case class LookupAmbiguous(msg: String) extends NameLookup { def symbol = NoSymbol }
  case class LookupInaccessible(symbol: Symbol, msg: String) extends NameLookup
  case object LookupNotFound extends NameLookup { def symbol = NoSymbol }

  class ScopeEntry(val sym: Symbol, val owner: Scope) {
    /** the next entry in the hash bucket
     */
    var tail: ScopeEntry = null

    /** the next entry in this scope
     */
    var next: ScopeEntry = null

    def depth = owner.nestingLevel
    override def hashCode(): Int = sym.name.start
    override def toString() = s"$sym (depth=$depth)"
  }

  private def newScopeEntry(sym: Symbol, owner: Scope): ScopeEntry = {
    val e = new ScopeEntry(sym, owner)
    e.next = owner.elems
    owner.elems = e
    e
  }

  object Scope {
    def unapplySeq(decls: Scope): Some[Seq[Symbol]] = Some(decls.toList)
  }

  /** Note: constructor is protected to force everyone to use the factory methods newScope or newNestedScope instead.
   *  This is necessary because when run from reflection every scope needs to have a
   *  SynchronizedScope as mixin.
   */
  class Scope protected[Scopes]() extends ScopeApi with MemberScopeApi {

    private[scala] var elems: ScopeEntry = _

    /** The number of times this scope is nested in another
     */
    private[Scopes] var nestinglevel = 0

    /** the hash table
     */
    private[Scopes] var hashtable: Array[ScopeEntry] = null

    /** a cache for all elements, to be used by symbol iterator.
     */
    private var elemsCache: List[Symbol] = null
    private var cachedSize = -1
    private def flushElemsCache() {
      elemsCache = null
      cachedSize = -1
    }

    /** size and mask of hash tables
     *  todo: make hashtables grow?
     */
    private val HASHSIZE = 0x80
    private val HASHMASK = 0x7f

    /** the threshold number of entries from which a hashtable is constructed.
     */
    private val MIN_HASH = 8

    /** Returns a new scope with the same content as this one. */
    def cloneScope: Scope = newScopeWith(this.toList: _*)

    /** is the scope empty? */
    override def isEmpty: Boolean = elems eq null

    /** the number of entries in this scope */
    override def size: Int = {
      if (cachedSize < 0)
        cachedSize = directSize

      cachedSize
    }
    private def directSize: Int = {
      var s = 0
      var e = elems
      while (e ne null) {
        s += 1
        e = e.next
      }
      s
    }

    /** enter a scope entry
     */
    protected def enterEntry(e: ScopeEntry) {
      flushElemsCache()
      if (hashtable ne null)
        enterInHash(e)
      else if (size >= MIN_HASH)
        createHash()
    }

    private def enterInHash(e: ScopeEntry): Unit = {
      val i = e.sym.name.start & HASHMASK
      e.tail = hashtable(i)
      hashtable(i) = e
    }

    /** enter a symbol
     */
    def enter[T <: Symbol](sym: T): T = {
      enterEntry(newScopeEntry(sym, this))
      sym
    }

    /** enter a symbol, asserting that no symbol with same name exists in scope
     */
    def enterUnique(sym: Symbol) {
      assert(lookup(sym.name) == NoSymbol, (sym.fullLocationString, lookup(sym.name).fullLocationString))
      enter(sym)
    }

    def enterIfNew[T <: Symbol](sym: T): T = {
      val existing = lookupEntry(sym.name)
      if (existing == null) enter(sym)
      else existing.sym.asInstanceOf[T]
    }

    private def createHash() {
      hashtable = new Array[ScopeEntry](HASHSIZE)
      enterAllInHash(elems)
    }

    private def enterAllInHash(e: ScopeEntry, n: Int = 0) {
      if (e ne null) {
        if (n < maxRecursions) {
          enterAllInHash(e.next, n + 1)
          enterInHash(e)
        } else {
          var entries: List[ScopeEntry] = List()
          var ee = e
          while (ee ne null) {
            entries = ee :: entries
            ee = ee.next
          }
          entries foreach enterInHash
        }
      }
    }

    def rehash(sym: Symbol, newname: Name) {
      if (hashtable ne null) {
        val index = sym.name.start & HASHMASK
        var e1 = hashtable(index)
        var e: ScopeEntry = null
        if (e1 != null) {
          if (e1.sym == sym) {
            hashtable(index) = e1.tail
            e = e1
          } else {
            while (e1.tail != null && e1.tail.sym != sym) e1 = e1.tail
            if (e1.tail != null) {
              e = e1.tail
              e1.tail = e.tail
            }
          }
        }
        if (e != null) {
          val newindex = newname.start & HASHMASK
          e.tail = hashtable(newindex)
          hashtable(newindex) = e
        }
      }
    }

    /** remove entry
     */
    def unlink(e: ScopeEntry) {
      if (elems == e) {
        elems = e.next
      } else {
        var e1 = elems
        while (e1.next != e) e1 = e1.next
        e1.next = e.next
      }
      if (hashtable ne null) {
        val index = e.sym.name.start & HASHMASK
        var e1 = hashtable(index)
        if (e1 == e) {
          hashtable(index) = e.tail
        } else {
          while (e1.tail != e) e1 = e1.tail
          e1.tail = e.tail
        }
      }
      flushElemsCache()
    }

    /** remove symbol */
    def unlink(sym: Symbol) {
      var e = lookupEntry(sym.name)
      while (e ne null) {
        if (e.sym == sym) unlink(e)
        e = lookupNextEntry(e)
      }
    }

    /** Lookup a module or a class, filtering out matching names in scope
     *  which do not match that requirement.
     */
    def lookupModule(name: Name): Symbol = findSymbol(lookupAll(name.toTermName))(_.isModule)
    def lookupClass(name: Name): Symbol  = findSymbol(lookupAll(name.toTypeName))(_.isClass)

    /** True if the name exists in this scope, false otherwise. */
    def containsName(name: Name) = lookupEntry(name) != null

    /** Lookup a symbol.
     */
    def lookup(name: Name): Symbol = {
      val e = lookupEntry(name)
      if (e eq null) NoSymbol
      else if (lookupNextEntry(e) eq null) e.sym
      else {
        // We shouldn't get here: until now this method was picking a random
        // symbol when there was more than one with the name, so this should
        // only be called knowing that there are 0-1 symbols of interest. So, we
        // can safely return an overloaded symbol rather than throwing away the
        // rest of them. Most likely we still break, but at least we will break
        // in an understandable fashion (unexpectedly overloaded symbol) rather
        // than a non-deterministic bizarre one (see any bug involving overloads
        // in package objects.)
        val alts = lookupAll(name).toList
        def alts_s = alts map (s => s.defString) mkString " <and> "
        devWarning(s"scope lookup of $name found multiple symbols: $alts_s")
        // FIXME - how is one supposed to create an overloaded symbol without
        // knowing the correct owner? Using the symbol owner is not correct;
        // say for instance this is List's scope and the symbols are its three
        // mkString members. Those symbols are owned by TraversableLike, which
        // is no more meaningful an owner than NoSymbol given that we're in
        // List. Maybe it makes no difference who owns the overloaded symbol, in
        // which case let's establish that and have a canonical creation method.
        //
        // FIXME - a similar question for prefix, although there are more
        // clues from the symbols on that one, as implemented here. In general
        // the distinct list is one type and lub becomes the identity.
        // val prefix = lub(alts map (_.info.prefix) distinct)
        // Now using NoSymbol and NoPrefix always to avoid forcing info (SI-6664)
        NoSymbol.newOverloaded(NoPrefix, alts)
      }
    }

    /** Returns an iterator yielding every symbol with given name in this scope.
     */
    def lookupAll(name: Name): Iterator[Symbol] = new Iterator[Symbol] {
      var e = lookupEntry(name)
      def hasNext: Boolean = e ne null
      def next(): Symbol = try e.sym finally e = lookupNextEntry(e)
    }

    def lookupAllEntries(name: Name): Iterator[ScopeEntry] = new Iterator[ScopeEntry] {
      var e = lookupEntry(name)
      def hasNext: Boolean = e ne null
      def next(): ScopeEntry = try e finally e = lookupNextEntry(e)
    }

    def lookupUnshadowedEntries(name: Name): Iterator[ScopeEntry] = {
      lookupEntry(name) match {
        case null => Iterator.empty
        case e    => lookupAllEntries(name) filter (e1 => (e eq e1) || (e.depth == e1.depth && e.sym != e1.sym))
      }
    }

    /** lookup a symbol entry matching given name.
     *  @note from Martin: I believe this is a hotspot or will be one
     *  in future versions of the type system. I have reverted the previous
     *  change to use iterators as too costly.
     */
    def lookupEntry(name: Name): ScopeEntry = {
      var e: ScopeEntry = null
      if (hashtable ne null) {
        e = hashtable(name.start & HASHMASK)
        while ((e ne null) && e.sym.name != name) {
          e = e.tail
        }
      } else {
        e = elems
        while ((e ne null) && e.sym.name != name) {
          e = e.next
        }
      }
      e
    }

    /** lookup next entry with same name as this one
     *  @note from Martin: I believe this is a hotspot or will be one
     *  in future versions of the type system. I have reverted the previous
     *  change to use iterators as too costly.
     */
    def lookupNextEntry(entry: ScopeEntry): ScopeEntry = {
      var e = entry
      if (hashtable ne null)
        do { e = e.tail } while ((e ne null) && e.sym.name != entry.sym.name)
      else
        do { e = e.next } while ((e ne null) && e.sym.name != entry.sym.name)
      e
    }

    /** TODO - we can test this more efficiently than checking isSubScope
     *  in both directions. However the size test might be enough to quickly
     *  rule out most failures.
     */
    def isSameScope(other: Scope) = (
         (size == other.size)     // optimization - size is cached
      && (this isSubScope other)
      && (other isSubScope this)
    )

    def isSubScope(other: Scope) = {
      def scopeContainsSym(sym: Symbol): Boolean = {
        @tailrec def entryContainsSym(e: ScopeEntry): Boolean = e match {
          case null => false
          case _    =>
            val comparableInfo = sym.info.substThis(sym.owner, e.sym.owner)
            (e.sym.info =:= comparableInfo) || entryContainsSym(lookupNextEntry(e))
        }
        entryContainsSym(this lookupEntry sym.name)
      }
      other.toList forall scopeContainsSym
    }

    /** Return all symbols as a list in the order they were entered in this scope.
     */
    override def toList: List[Symbol] = {
      if (elemsCache eq null) {
        var symbols: List[Symbol] = Nil
        var count = 0
        var e = elems
        while ((e ne null) && e.owner == this) {
          count += 1
          symbols ::= e.sym
          e = e.next
        }
        elemsCache = symbols
        cachedSize = count
      }
      elemsCache
    }

    /** Vanilla scope - symbols are stored in declaration order.
     */
    def sorted: List[Symbol] = toList

    /** Return the nesting level of this scope, i.e. the number of times this scope
     *  was nested in another */
    def nestingLevel = nestinglevel

    /** Return all symbols as an iterator in the order they were entered in this scope.
     */
    def iterator: Iterator[Symbol] = toList.iterator

    override def foreach[U](p: Symbol => U): Unit = toList foreach p

    override def filterNot(p: Symbol => Boolean): Scope = (
      if (toList exists p) newScopeWith(toList filterNot p: _*)
      else this
    )
    override def filter(p: Symbol => Boolean): Scope = (
      if (toList forall p) this
      else newScopeWith(toList filter p: _*)
    )
    @deprecated("Use `toList.reverse` instead", "2.10.0") // Used in SBT 0.12.4
    def reverse: List[Symbol] = toList.reverse

    override def mkString(start: String, sep: String, end: String) =
      toList.map(_.defString).mkString(start, sep, end)

    override def toString(): String = mkString("Scope{\n  ", ";\n  ", "\n}")
  }

  implicit val ScopeTag = ClassTag[Scope](classOf[Scope])

  type MemberScope = Scope

  implicit val MemberScopeTag = ClassTag[MemberScope](classOf[MemberScope])

  /** Create a new scope */
  def newScope: Scope = new Scope()

  /** Create a new scope to be used in `findMembers`.
   *
   *  But why do we need a special scope for `findMembers`?
   *  Let me tell you a story.
   *
   * `findMembers` creates a synthetic scope and then iterates over
   *  base classes in linearization order, and for every scrutinized class
   *  iterates over `decls`, the collection of symbols declared in that class.
   *  Declarations that fit the filter get appended to the created scope.
   *
   *  The problem is that `decls` returns a Scope, and to iterate a scope performantly
   *  one needs to go from its end to its beginning.
   *
   *  Hence the `findMembers` scope is populated in a wicked order:
   *  symbols that belong to the same declaring class come in reverse order of their declaration,
   *  however, the scope itself is ordered w.r.t the linearization of the target type.
   *
   *  Once `members` became a public API, this has been confusing countless numbers of users.
   *  Therefore we introduce a special flavor of scopes to accommodate this quirk of `findMembers`
   */
  private[scala] def newFindMemberScope: Scope = new Scope() {
    override def sorted = {
      val members = toList
      val owners = members.map(_.owner).distinct
      val grouped = members groupBy (_.owner)
      owners.flatMap(owner => grouped(owner).reverse)
    }
  }

  /** Create a new scope nested in another one with which it shares its elements */
  final def newNestedScope(outer: Scope): Scope = {
    val nested = newScope // not `new Scope`, we must allow the runtime reflection universe to mixin SynchronizedScopes!
    nested.elems = outer.elems
    nested.nestinglevel = outer.nestinglevel + 1
    if (outer.hashtable ne null)
      nested.hashtable = java.util.Arrays.copyOf(outer.hashtable, outer.hashtable.length)
    nested
  }

  /** Create a new scope with given initial elements */
  def newScopeWith(elems: Symbol*): Scope = {
    val scope = newScope
    elems foreach scope.enter
    scope
  }

  /** Create new scope for the members of package `pkg` */
  def newPackageScope(pkgClass: Symbol): Scope = newScope

  /** Transform scope of members of `owner` using operation `op`
   *  This is overridden by the reflective compiler to avoid creating new scopes for packages
   */
  def scopeTransform(owner: Symbol)(op: => Scope): Scope = op


  /** The empty scope (immutable).
   */
  object EmptyScope extends Scope {
    override def enterEntry(e: ScopeEntry) {
      abort("EmptyScope.enter")
    }
  }

  /** The error scope.
   */
  class ErrorScope(owner: Symbol) extends Scope

  private final val maxRecursions = 1000
}
/* NSC -- new Scala compiler
 * Copyright 2005-2013 LAMP/EPFL
 * @author  Martin Odersky
 */

package scala
package reflect
package internal

import scala.annotation.tailrec

trait Scopes extends api.Scopes { self: SymbolTable =>

  /** An ADT to represent the results of symbol name lookups.
   */
  sealed trait NameLookup { def symbol: Symbol ; def isSuccess = false }
  case class LookupSucceeded(qualifier: Tree, symbol: Symbol) extends NameLookup { override def isSuccess = true }
  case class LookupAmbiguous(msg: String) extends NameLookup { def symbol = NoSymbol }
  case class LookupInaccessible(symbol: Symbol, msg: String) extends NameLookup
  case object LookupNotFound extends NameLookup { def symbol = NoSymbol }

  class ScopeEntry(val sym: Symbol, val owner: Scope) {
    /** the next entry in the hash bucket
     */
    var tail: ScopeEntry = null

    /** the next entry in this scope
     */
    var next: ScopeEntry = null

    def depth = owner.nestingLevel
    override def hashCode(): Int = sym.name.start
    override def toString() = s"$sym (depth=$depth)"
  }

  private def newScopeEntry(sym: Symbol, owner: Scope): ScopeEntry = {
    val e = new ScopeEntry(sym, owner)
    e.next = owner.elems
    owner.elems = e
    e
  }

  object Scope {
    def unapplySeq(decls: Scope): Some[Seq[Symbol]] = Some(decls.toList)
  }

  /** Note: constructor is protected to force everyone to use the factory methods newScope or newNestedScope instead.
   *  This is necessary because when run from reflection every scope needs to have a
   *  SynchronizedScope as mixin.
   */
  class Scope protected[Scopes]() extends ScopeApi with MemberScopeApi {

    private[scala] var elems: ScopeEntry = _

    /** The number of times this scope is nested in another
     */
    private[Scopes] var nestinglevel = 0

    /** the hash table
     */
    private[Scopes] var hashtable: Array[ScopeEntry] = null

    /** a cache for all elements, to be used by symbol iterator.
     */
    private var elemsCache: List[Symbol] = null
    private var cachedSize = -1
    private def flushElemsCache() {
      elemsCache = null
      cachedSize = -1
    }

    /** size and mask of hash tables
     *  todo: make hashtables grow?
     */
    private val HASHSIZE = 0x80
    private val HASHMASK = 0x7f

    /** the threshold number of entries from which a hashtable is constructed.
     */
    private val MIN_HASH = 8

    /** Returns a new scope with the same content as this one. */
    def cloneScope: Scope = newScopeWith(this.toList: _*)

    /** is the scope empty? */
    override def isEmpty: Boolean = elems eq null

    /** the number of entries in this scope */
    override def size: Int = {
      if (cachedSize < 0)
        cachedSize = directSize

      cachedSize
    }
    private def directSize: Int = {
      var s = 0
      var e = elems
      while (e ne null) {
        s += 1
        e = e.next
      }
      s
    }

    /** enter a scope entry
     */
    protected def enterEntry(e: ScopeEntry) {
      flushElemsCache()
      if (hashtable ne null)
        enterInHash(e)
      else if (size >= MIN_HASH)
        createHash()
    }

    private def enterInHash(e: ScopeEntry): Unit = {
      val i = e.sym.name.start & HASHMASK
      e.tail = hashtable(i)
      hashtable(i) = e
    }

    /** enter a symbol
     */
    def enter[T <: Symbol](sym: T): T = {
      enterEntry(newScopeEntry(sym, this))
      sym
    }

    /** enter a symbol, asserting that no symbol with same name exists in scope
     */
    def enterUnique(sym: Symbol) {
      assert(lookup(sym.name) == NoSymbol, (sym.fullLocationString, lookup(sym.name).fullLocationString))
      enter(sym)
    }

    def enterIfNew[T <: Symbol](sym: T): T = {
      val existing = lookupEntry(sym.name)
      if (existing == null) enter(sym)
      else existing.sym.asInstanceOf[T]
    }

    private def createHash() {
      hashtable = new Array[ScopeEntry](HASHSIZE)
      enterAllInHash(elems)
    }

    private def enterAllInHash(e: ScopeEntry, n: Int = 0) {
      if (e ne null) {
        if (n < maxRecursions) {
          enterAllInHash(e.next, n + 1)
          enterInHash(e)
        } else {
          var entries: List[ScopeEntry] = List()
          var ee = e
          while (ee ne null) {
            entries = ee :: entries
            ee = ee.next
          }
          entries foreach enterInHash
        }
      }
    }

    def rehash(sym: Symbol, newname: Name) {
      if (hashtable ne null) {
        val index = sym.name.start & HASHMASK
        var e1 = hashtable(index)
        var e: ScopeEntry = null
        if (e1 != null) {
          if (e1.sym == sym) {
            hashtable(index) = e1.tail
            e = e1
          } else {
            while (e1.tail != null && e1.tail.sym != sym) e1 = e1.tail
            if (e1.tail != null) {
              e = e1.tail
              e1.tail = e.tail
            }
          }
        }
        if (e != null) {
          val newindex = newname.start & HASHMASK
          e.tail = hashtable(newindex)
          hashtable(newindex) = e
        }
      }
    }

    /** remove entry
     */
    def unlink(e: ScopeEntry) {
      if (elems == e) {
        elems = e.next
      } else {
        var e1 = elems
        while (e1.next != e) e1 = e1.next
        e1.next = e.next
      }
      if (hashtable ne null) {
        val index = e.sym.name.start & HASHMASK
        var e1 = hashtable(index)
        if (e1 == e) {
          hashtable(index) = e.tail
        } else {
          while (e1.tail != e) e1 = e1.tail
          e1.tail = e.tail
        }
      }
      flushElemsCache()
    }

    /** remove symbol */
    def unlink(sym: Symbol) {
      var e = lookupEntry(sym.name)
      while (e ne null) {
        if (e.sym == sym) unlink(e)
        e = lookupNextEntry(e)
      }
    }

    /** Lookup a module or a class, filtering out matching names in scope
     *  which do not match that requirement.
     */
    def lookupModule(name: Name): Symbol = findSymbol(lookupAll(name.toTermName))(_.isModule)
    def lookupClass(name: Name): Symbol  = findSymbol(lookupAll(name.toTypeName))(_.isClass)

    /** True if the name exists in this scope, false otherwise. */
    def containsName(name: Name) = lookupEntry(name) != null

    /** Lookup a symbol.
     */
    def lookup(name: Name): Symbol = {
      val e = lookupEntry(name)
      if (e eq null) NoSymbol
      else if (lookupNextEntry(e) eq null) e.sym
      else {
        // We shouldn't get here: until now this method was picking a random
        // symbol when there was more than one with the name, so this should
        // only be called knowing that there are 0-1 symbols of interest. So, we
        // can safely return an overloaded symbol rather than throwing away the
        // rest of them. Most likely we still break, but at least we will break
        // in an understandable fashion (unexpectedly overloaded symbol) rather
        // than a non-deterministic bizarre one (see any bug involving overloads
        // in package objects.)
        val alts = lookupAll(name).toList
        def alts_s = alts map (s => s.defString) mkString " <and> "
        devWarning(s"scope lookup of $name found multiple symbols: $alts_s")
        // FIXME - how is one supposed to create an overloaded symbol without
        // knowing the correct owner? Using the symbol owner is not correct;
        // say for instance this is List's scope and the symbols are its three
        // mkString members. Those symbols are owned by TraversableLike, which
        // is no more meaningful an owner than NoSymbol given that we're in
        // List. Maybe it makes no difference who owns the overloaded symbol, in
        // which case let's establish that and have a canonical creation method.
        //
        // FIXME - a similar question for prefix, although there are more
        // clues from the symbols on that one, as implemented here. In general
        // the distinct list is one type and lub becomes the identity.
        // val prefix = lub(alts map (_.info.prefix) distinct)
        // Now using NoSymbol and NoPrefix always to avoid forcing info (SI-6664)
        NoSymbol.newOverloaded(NoPrefix, alts)
      }
    }

    /** Returns an iterator yielding every symbol with given name in this scope.
     */
    def lookupAll(name: Name): Iterator[Symbol] = new Iterator[Symbol] {
      var e = lookupEntry(name)
      def hasNext: Boolean = e ne null
      def next(): Symbol = try e.sym finally e = lookupNextEntry(e)
    }

    def lookupAllEntries(name: Name): Iterator[ScopeEntry] = new Iterator[ScopeEntry] {
      var e = lookupEntry(name)
      def hasNext: Boolean = e ne null
      def next(): ScopeEntry = try e finally e = lookupNextEntry(e)
    }

    def lookupUnshadowedEntries(name: Name): Iterator[ScopeEntry] = {
      lookupEntry(name) match {
        case null => Iterator.empty
        case e    => lookupAllEntries(name) filter (e1 => (e eq e1) || (e.depth == e1.depth && e.sym != e1.sym))
      }
    }

    /** lookup a symbol entry matching given name.
     *  @note from Martin: I believe this is a hotspot or will be one
     *  in future versions of the type system. I have reverted the previous
     *  change to use iterators as too costly.
     */
    def lookupEntry(name: Name): ScopeEntry = {
      var e: ScopeEntry = null
      if (hashtable ne null) {
        e = hashtable(name.start & HASHMASK)
        while ((e ne null) && e.sym.name != name) {
          e = e.tail
        }
      } else {
        e = elems
        while ((e ne null) && e.sym.name != name) {
          e = e.next
        }
      }
      e
    }

    /** lookup next entry with same name as this one
     *  @note from Martin: I believe this is a hotspot or will be one
     *  in future versions of the type system. I have reverted the previous
     *  change to use iterators as too costly.
     */
    def lookupNextEntry(entry: ScopeEntry): ScopeEntry = {
      var e = entry
      if (hashtable ne null)
        do { e = e.tail } while ((e ne null) && e.sym.name != entry.sym.name)
      else
        do { e = e.next } while ((e ne null) && e.sym.name != entry.sym.name)
      e
    }

    /** TODO - we can test this more efficiently than checking isSubScope
     *  in both directions. However the size test might be enough to quickly
     *  rule out most failures.
     */
    def isSameScope(other: Scope) = (
         (size == other.size)     // optimization - size is cached
      && (this isSubScope other)
      && (other isSubScope this)
    )

    def isSubScope(other: Scope) = {
      def scopeContainsSym(sym: Symbol): Boolean = {
        @tailrec def entryContainsSym(e: ScopeEntry): Boolean = e match {
          case null => false
          case _    =>
            val comparableInfo = sym.info.substThis(sym.owner, e.sym.owner)
            (e.sym.info =:= comparableInfo) || entryContainsSym(lookupNextEntry(e))
        }
        entryContainsSym(this lookupEntry sym.name)
      }
      other.toList forall scopeContainsSym
    }

    /** Return all symbols as a list in the order they were entered in this scope.
     */
    override def toList: List[Symbol] = {
      if (elemsCache eq null) {
        var symbols: List[Symbol] = Nil
        var count = 0
        var e = elems
        while ((e ne null) && e.owner == this) {
          count += 1
          symbols ::= e.sym
          e = e.next
        }
        elemsCache = symbols
        cachedSize = count
      }
      elemsCache
    }

    /** Vanilla scope - symbols are stored in declaration order.
     */
    def sorted: List[Symbol] = toList

    /** Return the nesting level of this scope, i.e. the number of times this scope
     *  was nested in another */
    def nestingLevel = nestinglevel

    /** Return all symbols as an iterator in the order they were entered in this scope.
     */
    def iterator: Iterator[Symbol] = toList.iterator

    override def foreach[U](p: Symbol => U): Unit = toList foreach p

    override def filterNot(p: Symbol => Boolean): Scope = (
      if (toList exists p) newScopeWith(toList filterNot p: _*)
      else this
    )
    override def filter(p: Symbol => Boolean): Scope = (
      if (toList forall p) this
      else newScopeWith(toList filter p: _*)
    )
    @deprecated("Use `toList.reverse` instead", "2.10.0") // Used in SBT 0.12.4
    def reverse: List[Symbol] = toList.reverse

    override def mkString(start: String, sep: String, end: String) =
      toList.map(_.defString).mkString(start, sep, end)

    override def toString(): String = mkString("Scope{\n  ", ";\n  ", "\n}")
  }

  implicit val ScopeTag = ClassTag[Scope](classOf[Scope])

  type MemberScope = Scope

  implicit val MemberScopeTag = ClassTag[MemberScope](classOf[MemberScope])

  /** Create a new scope */
  def newScope: Scope = new Scope()

  /** Create a new scope to be used in `findMembers`.
   *
   *  But why do we need a special scope for `findMembers`?
   *  Let me tell you a story.
   *
   * `findMembers` creates a synthetic scope and then iterates over
   *  base classes in linearization order, and for every scrutinized class
   *  iterates over `decls`, the collection of symbols declared in that class.
   *  Declarations that fit the filter get appended to the created scope.
   *
   *  The problem is that `decls` returns a Scope, and to iterate a scope performantly
   *  one needs to go from its end to its beginning.
   *
   *  Hence the `findMembers` scope is populated in a wicked order:
   *  symbols that belong to the same declaring class come in reverse order of their declaration,
   *  however, the scope itself is ordered w.r.t the linearization of the target type.
   *
   *  Once `members` became a public API, this has been confusing countless numbers of users.
   *  Therefore we introduce a special flavor of scopes to accommodate this quirk of `findMembers`
   */
  private[scala] def newFindMemberScope: Scope = new Scope() {
    override def sorted = {
      val members = toList
      val owners = members.map(_.owner).distinct
      val grouped = members groupBy (_.owner)
      owners.flatMap(owner => grouped(owner).reverse)
    }
  }

  /** Create a new scope nested in another one with which it shares its elements */
  final def newNestedScope(outer: Scope): Scope = {
    val nested = newScope // not `new Scope`, we must allow the runtime reflection universe to mixin SynchronizedScopes!
    nested.elems = outer.elems
    nested.nestinglevel = outer.nestinglevel + 1
    if (outer.hashtable ne null)
      nested.hashtable = java.util.Arrays.copyOf(outer.hashtable, outer.hashtable.length)
    nested
  }

  /** Create a new scope with given initial elements */
  def newScopeWith(elems: Symbol*): Scope = {
    val scope = newScope
    elems foreach scope.enter
    scope
  }

  /** Create new scope for the members of package `pkg` */
  def newPackageScope(pkgClass: Symbol): Scope = newScope

  /** Transform scope of members of `owner` using operation `op`
   *  This is overridden by the reflective compiler to avoid creating new scopes for packages
   */
  def scopeTransform(owner: Symbol)(op: => Scope): Scope = op


  /** The empty scope (immutable).
   */
  object EmptyScope extends Scope {
    override def enterEntry(e: ScopeEntry) {
      abort("EmptyScope.enter")
    }
  }

  /** The error scope.
   */
  class ErrorScope(owner: Symbol) extends Scope

  private final val maxRecursions = 1000
}