/* NSC -- new Scala compiler
* Copyright 2005-2012 LAMP/EPFL
* @author Martin Odersky
*/
package dotty.tools.dotc
package core
import Symbols._
import Types.{TermRef, NoPrefix}
import Flags.Implicit
import Names._
import Periods._
import Decorators._
import Contexts._
import Denotations._
import SymDenotations._
import printing.Texts._
import printing.Printer
import util.common._
import SymDenotations.NoDenotation
import collection.mutable.ListBuffer
object Scopes {
/** Maximal fill factor of hash table */
private final val FillFactor = 2.0/3.0
/** A hashtable is created once current size exceeds MinHash * FillFactor
* The initial hash table has twice that size (i.e 24).
*/
private final val MinHash = 12
/** The maximal permissible number of recursions when creating
* a hashtable
*/
private final val MaxRecursions = 1000
class ScopeEntry private[Scopes] (val name: Name, val sym: Symbol, val owner: Scope) {
/** the next entry in the hash bucket
*/
var tail: ScopeEntry = null
/** the preceding entry in this scope
*/
var prev: ScopeEntry = null
override def toString: String = sym.toString
}
/** A scope contains a set of symbols. It can be an extension
* of some outer scope, from which it inherits all symbols.
* This class does not have any methods to add symbols to a scope
* or to delete them. These methods are provided by subclass
* MutableScope.
*/
abstract class Scope extends printing.Showable with Iterable[Symbol] {
/** The last scope-entry from which all others are reachable via `prev` */
private[dotc] def lastEntry: ScopeEntry
/** The number of symbols in this scope (including inherited ones
* from outer scopes).
*/
def size: Int
/** The number of outer scopes from which symbols are inherited */
def nestingLevel: Int
/** The symbols in this scope in the order they were entered;
* inherited from outer ones first.
*/
def toList: List[Symbol]
/** Return all symbols as an iterator in the order they were entered in this scope.
*/
def iterator: Iterator[Symbol] = toList.iterator
/** Returns a new scope with the same content as this one. */
def cloneScope(implicit ctx: Context): Scope
/** Is the scope empty? */
override def isEmpty: Boolean = lastEntry eq null
/** Lookup a symbol entry matching given name. */
def lookupEntry(name: Name)(implicit ctx: Context): ScopeEntry
/** Lookup next entry with same name as this one */
def lookupNextEntry(entry: ScopeEntry)(implicit ctx: Context): ScopeEntry
/** Lookup a symbol */
final def lookup(name: Name)(implicit ctx: Context): Symbol = {
val e = lookupEntry(name)
if (e eq null) NoSymbol else e.sym
}
/** Returns an iterator yielding every symbol with given name in this scope.
*/
final def lookupAll(name: Name)(implicit ctx: Context): Iterator[Symbol] = new Iterator[Symbol] {
var e = lookupEntry(name)
def hasNext: Boolean = e ne null
def next(): Symbol = { val r = e.sym; e = lookupNextEntry(e); r }
}
/** The denotation set of all the symbols with given name in this scope */
final def denotsNamed(name: Name, select: SymDenotation => Boolean = selectAll)(implicit ctx: Context): PreDenotation = {
var syms: PreDenotation = NoDenotation
var e = lookupEntry(name)
while (e != null) {
val d = e.sym.denot
if (select(d)) syms = syms union d
e = lookupNextEntry(e)
}
syms
}
def implicitDecls(implicit ctx: Context): List[TermRef] = Nil
final def toText(printer: Printer): Text = printer.toText(this)
}
/** A subclass of Scope that defines methods for entering and
* unlinking entries.
* 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 MutableScope protected[Scopes](initElems: ScopeEntry, initSize: Int, val nestingLevel: Int = 0)
extends Scope {
protected[Scopes] def this(base: Scope)(implicit ctx: Context) = {
this(base.lastEntry, base.size, base.nestingLevel + 1)
ensureCapacity(MinHash)(ctx) // WTH? it seems the implicit is not in scope for a secondary constructor call.
}
def this() = this(null, 0, 0)
private[dotc] var lastEntry: ScopeEntry = initElems
/** The size of the scope */
private[this] var _size = initSize
override final def size = _size
private def size_= (x: Int) = _size = x
/** the hash table
*/
private var hashTable: Array[ScopeEntry] = null
/** a cache for all elements, to be used by symbol iterator.
*/
private var elemsCache: List[Symbol] = null
def cloneScope(implicit ctx: Context): MutableScope = newScopeWith(this.toList: _*)
/** create and enter a scope entry */
protected def newScopeEntry(sym: Symbol)(implicit ctx: Context): ScopeEntry = {
ensureCapacity(if (hashTable ne null) hashTable.length else MinHash)
val e = new ScopeEntry(sym.name, sym, this)
e.prev = lastEntry
lastEntry = e
if (hashTable ne null) enterInHash(e)
size += 1
elemsCache = null
e
}
private def enterInHash(e: ScopeEntry)(implicit ctx: Context): Unit = {
val idx = e.name.hashCode & (hashTable.length - 1)
e.tail = hashTable(idx)
assert(e.tail != e)
hashTable(idx) = e
}
/** enter a symbol in this scope. */
final def enter[T <: Symbol](sym: T)(implicit ctx: Context): T = {
if (sym.isType) {
assert(lookup(sym.name) == NoSymbol,
s"duplicate type ${sym.debugString}; previous was ${lookup(sym.name).debugString}") // !!! DEBUG
}
newScopeEntry(sym)
sym
}
/** enter a symbol, asserting that no symbol with same name exists in scope */
final def enterUnique(sym: Symbol)(implicit ctx: Context): Unit = {
assert(lookup(sym.name) == NoSymbol, (sym.showLocated, lookup(sym.name).showLocated))
enter(sym)
}
private def ensureCapacity(tableSize: Int)(implicit ctx: Context): Unit =
if (size >= tableSize * FillFactor) createHash(tableSize * 2)
private def createHash(tableSize: Int)(implicit ctx: Context): Unit =
if (size > tableSize * FillFactor) createHash(tableSize * 2)
else {
hashTable = new Array[ScopeEntry](tableSize)
enterAllInHash(lastEntry)
}
private def enterAllInHash(e: ScopeEntry, n: Int = 0)(implicit ctx: Context): Unit = {
if (e ne null) {
if (n < MaxRecursions) {
enterAllInHash(e.prev, n + 1)
enterInHash(e)
} else {
var entries: List[ScopeEntry] = List()
var ee = e
while (ee ne null) {
entries = ee :: entries
ee = ee.prev
}
entries foreach enterInHash
}
}
}
/** Remove entry from this scope (which is required to be present) */
final def unlink(e: ScopeEntry)(implicit ctx: Context): Unit = {
if (lastEntry == e) {
lastEntry = e.prev
} else {
var e1 = lastEntry
while (e1.prev != e) e1 = e1.prev
e1.prev = e.prev
}
if (hashTable ne null) {
val index = e.name.hashCode & (hashTable.length - 1)
var e1 = hashTable(index)
if (e1 == e)
hashTable(index) = e.tail
else {
while (e1.tail != e) e1 = e1.tail;
e1.tail = e.tail
}
}
elemsCache = null
size -= 1
}
/** remove symbol from this scope if it is present */
final def unlink(sym: Symbol)(implicit ctx: Context): Unit = {
var e = lookupEntry(sym.name)
while (e ne null) {
if (e.sym == sym) unlink(e);
e = lookupNextEntry(e)
}
}
/** Lookup a symbol entry matching given name.
*/
override final def lookupEntry(name: Name)(implicit ctx: Context): ScopeEntry = {
var e: ScopeEntry = null
if (hashTable ne null) {
e = hashTable(name.hashCode & (hashTable.length - 1))
while ((e ne null) && e.name != name) {
e = e.tail
}
} else {
e = lastEntry
while ((e ne null) && e.name != name) {
e = e.prev
}
}
e
}
/** lookup next entry with same name as this one */
override final def lookupNextEntry(entry: ScopeEntry)(implicit ctx: Context): ScopeEntry = {
var e = entry
if (hashTable ne null)
do { e = e.tail } while ((e ne null) && e.name != entry.name)
else
do { e = e.prev } while ((e ne null) && e.name != entry.name)
e
}
/** Returns all symbols as a list in the order they were entered in this scope.
* Does _not_ include the elements of inherited scopes.
*/
override final def toList: List[Symbol] = {
if (elemsCache eq null) {
elemsCache = Nil
var e = lastEntry
while ((e ne null) && e.owner == this) {
elemsCache = e.sym :: elemsCache
e = e.prev
}
}
elemsCache
}
override def implicitDecls(implicit ctx: Context): List[TermRef] = {
var irefs = new ListBuffer[TermRef]
var e = lastEntry
while (e ne null) {
if (e.sym is Implicit) {
val d = e.sym.denot
irefs += TermRef.withSig(NoPrefix, e.sym.asTerm.name, d.signature, e.sym.denot)
}
e = e.prev
}
irefs.toList
}
/** Vanilla scope - symbols are stored in declaration order.
*/
final def sorted: List[Symbol] = toList
override def foreach[U](p: Symbol => U): Unit = toList foreach p
override def filter(p: Symbol => Boolean): List[Symbol] = {
var syms: List[Symbol] = Nil
var e = lastEntry
while ((e ne null) && e.owner == this) {
val sym = e.sym
if (p(sym)) syms = sym :: syms
e = e.prev
}
syms
}
}
/** Create a new scope */
def newScope: MutableScope = new MutableScope()
/** Create a new scope nested in another one with which it shares its elements */
def newNestedScope(outer: Scope)(implicit ctx: Context): MutableScope = new MutableScope(outer)
/** Create a new scope with given initial elements */
def newScopeWith(elems: Symbol*)(implicit ctx: Context): MutableScope = {
val scope = newScope
elems foreach scope.enter
scope
}
/** Create new scope for the members of package `pkg` */
def newPackageScope(pkgClass: Symbol): MutableScope = 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: => MutableScope): MutableScope = op
val selectAll: SymDenotation => Boolean = alwaysTrue
val selectPrivate: SymDenotation => Boolean = d => (d.flagsUNSAFE is Flags.Private)
val selectNonPrivate: SymDenotation => Boolean = d => !(d.flagsUNSAFE is Flags.Private)
/** The empty scope (immutable).
*/
object EmptyScope extends Scope {
override def lastEntry = null
override def size = 0
override def nestingLevel = 0
override def toList = Nil
override def cloneScope(implicit ctx: Context): Scope = this
override def lookupEntry(name: Name)(implicit ctx: Context): ScopeEntry = null
override def lookupNextEntry(entry: ScopeEntry)(implicit ctx: Context): ScopeEntry = null
}
/** A class for error scopes (mutable)
*/
class ErrorScope(owner: Symbol) extends MutableScope
}