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 * Copyright (c) 1999, 2016, Oracle and/or its affiliates. All rights reserved.
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
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 * This code is free software; you can redistribute it and/or modify it
 * under the terms of the GNU General Public License version 2 only, as
 * published by the Free Software Foundation.  Oracle designates this
 * particular file as subject to the "Classpath" exception as provided
 * by Oracle in the LICENSE file that accompanied this code.
 *
 * This code is distributed in the hope that it will be useful, but WITHOUT
 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
 * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
 * version 2 for more details (a copy is included in the LICENSE file that
 * accompanied this code).
 *
 * You should have received a copy of the GNU General Public License version
 * 2 along with this work; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
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package org.openjdk.tools.javac.code;

import org.openjdk.tools.javac.code.Kinds.Kind;
import java.lang.ref.WeakReference;
import java.util.*;
import java.util.function.BiConsumer;
import java.util.stream.Stream;
import java.util.stream.StreamSupport;

import org.openjdk.tools.javac.code.Symbol.CompletionFailure;
import org.openjdk.tools.javac.code.Symbol.TypeSymbol;
import org.openjdk.tools.javac.tree.JCTree.JCImport;
import org.openjdk.tools.javac.util.*;
import org.openjdk.tools.javac.util.List;

import static org.openjdk.tools.javac.code.Scope.LookupKind.NON_RECURSIVE;
import static org.openjdk.tools.javac.code.Scope.LookupKind.RECURSIVE;

/** A scope represents an area of visibility in a Java program. The
 *  Scope class is a container for symbols which provides
 *  efficient access to symbols given their names. Scopes are implemented
 *  as hash tables with "open addressing" and "double hashing".
 *  Scopes can be nested. Nested scopes can share their hash tables.
 *
 *  

This is NOT part of any supported API. * If you write code that depends on this, you do so at your own risk. * This code and its internal interfaces are subject to change or * deletion without notice. */ public abstract class Scope { /** The scope's owner. */ public final Symbol owner; protected Scope(Symbol owner) { this.owner = owner; } /**Returns all Symbols in this Scope. Symbols from outward Scopes are included. */ public final Iterable getSymbols() { return getSymbols(noFilter); } /**Returns Symbols that match the given filter. Symbols from outward Scopes are included. */ public final Iterable getSymbols(Filter sf) { return getSymbols(sf, RECURSIVE); } /**Returns all Symbols in this Scope. Symbols from outward Scopes are included * iff lookupKind == RECURSIVE. */ public final Iterable getSymbols(LookupKind lookupKind) { return getSymbols(noFilter, lookupKind); } /**Returns Symbols that match the given filter. Symbols from outward Scopes are included * iff lookupKind == RECURSIVE. */ public abstract Iterable getSymbols(Filter sf, LookupKind lookupKind); /**Returns Symbols with the given name. Symbols from outward Scopes are included. */ public final Iterable getSymbolsByName(Name name) { return getSymbolsByName(name, RECURSIVE); } /**Returns Symbols with the given name that match the given filter. * Symbols from outward Scopes are included. */ public final Iterable getSymbolsByName(final Name name, final Filter sf) { return getSymbolsByName(name, sf, RECURSIVE); } /**Returns Symbols with the given name. Symbols from outward Scopes are included * iff lookupKind == RECURSIVE. */ public final Iterable getSymbolsByName(Name name, LookupKind lookupKind) { return getSymbolsByName(name, noFilter, lookupKind); } /**Returns Symbols with the given name that match the given filter. * Symbols from outward Scopes are included iff lookupKind == RECURSIVE. */ public abstract Iterable getSymbolsByName(final Name name, final Filter sf, final LookupKind lookupKind); /** Return the first Symbol from this or outward scopes with the given name. * Returns null if none. */ public final Symbol findFirst(Name name) { return findFirst(name, noFilter); } /** Return the first Symbol from this or outward scopes with the given name that matches the * given filter. Returns null if none. */ public Symbol findFirst(Name name, Filter sf) { Iterator it = getSymbolsByName(name, sf).iterator(); return it.hasNext() ? it.next() : null; } /** Returns true iff there are is at least one Symbol in this scope matching the given filter. * Does not inspect outward scopes. */ public boolean anyMatch(Filter filter) { return getSymbols(filter, NON_RECURSIVE).iterator().hasNext(); } /** Returns true iff the given Symbol is in this scope or any outward scope. */ public boolean includes(final Symbol sym) { return includes(sym, RECURSIVE); } /** Returns true iff the given Symbol is in this scope, optionally checking outward scopes. */ public boolean includes(final Symbol sym, LookupKind lookupKind) { return getSymbolsByName(sym.name, t -> t == sym, lookupKind).iterator().hasNext(); } /** Returns true iff this scope does not contain any Symbol. Does not inspect outward scopes. */ public boolean isEmpty() { return !getSymbols(NON_RECURSIVE).iterator().hasNext(); } /** Returns the Scope from which the givins Symbol originates in this scope. */ public abstract Scope getOrigin(Symbol byName); /** Returns true iff the given Symbol is part of this scope due to a static import. */ public abstract boolean isStaticallyImported(Symbol byName); private static final Filter noFilter = null; /** A list of scopes to be notified if items are to be removed from this scope. */ ScopeListenerList listeners = new ScopeListenerList(); public interface ScopeListener { void symbolAdded(Symbol sym, Scope s); void symbolRemoved(Symbol sym, Scope s); } /** * A list of scope listeners; listeners are stored in weak references, to avoid memory leaks. * When the listener list is scanned (upon notification), elements corresponding to GC-ed * listeners are removed so that the listener list size is kept in check. */ public static class ScopeListenerList { List> listeners = List.nil(); void add(ScopeListener sl) { listeners = listeners.prepend(new WeakReference<>(sl)); } void symbolAdded(Symbol sym, Scope scope) { walkReferences(sym, scope, false); } void symbolRemoved(Symbol sym, Scope scope) { walkReferences(sym, scope, true); } private void walkReferences(Symbol sym, Scope scope, boolean isRemove) { ListBuffer> newListeners = new ListBuffer<>(); for (WeakReference wsl : listeners) { ScopeListener sl = wsl.get(); if (sl != null) { if (isRemove) { sl.symbolRemoved(sym, scope); } else { sl.symbolAdded(sym, scope); } newListeners.add(wsl); } } listeners = newListeners.toList(); } } public enum LookupKind { RECURSIVE, NON_RECURSIVE; } /**A scope into which Symbols can be added.*/ public abstract static class WriteableScope extends Scope { public WriteableScope(Symbol owner) { super(owner); } /** Enter the given Symbol into this scope. */ public abstract void enter(Symbol c); /** Enter symbol sym in this scope if not already there. */ public abstract void enterIfAbsent(Symbol c); public abstract void remove(Symbol c); /** Construct a fresh scope within this scope, with same owner. The new scope may * shares internal structures with the this scope. Used in connection with * method leave if scope access is stack-like in order to avoid allocation * of fresh tables. */ public final WriteableScope dup() { return dup(this.owner); } /** Construct a fresh scope within this scope, with new owner. The new scope may * shares internal structures with the this scope. Used in connection with * method leave if scope access is stack-like in order to avoid allocation * of fresh tables. */ public abstract WriteableScope dup(Symbol newOwner); /** Must be called on dup-ed scopes to be able to work with the outward scope again. */ public abstract WriteableScope leave(); /** Construct a fresh scope within this scope, with same owner. The new scope * will not share internal structures with this scope. */ public final WriteableScope dupUnshared() { return dupUnshared(owner); } /** Construct a fresh scope within this scope, with new owner. The new scope * will not share internal structures with this scope. */ public abstract WriteableScope dupUnshared(Symbol newOwner); /** Create a new WriteableScope. */ public static WriteableScope create(Symbol owner) { return new ScopeImpl(owner); } } private static class ScopeImpl extends WriteableScope { /** The number of scopes that share this scope's hash table. */ private int shared; /** Next enclosing scope (with whom this scope may share a hashtable) */ public ScopeImpl next; /** A hash table for the scope's entries. */ Entry[] table; /** Mask for hash codes, always equal to (table.length - 1). */ int hashMask; /** A linear list that also contains all entries in * reverse order of appearance (i.e later entries are pushed on top). */ public Entry elems; /** The number of elements in this scope. * This includes deleted elements, whose value is the sentinel. */ int nelems = 0; int removeCount = 0; /** Use as a "not-found" result for lookup. * Also used to mark deleted entries in the table. */ private static final Entry sentinel = new Entry(null, null, null, null); /** The hash table's initial size. */ private static final int INITIAL_SIZE = 0x10; /** Construct a new scope, within scope next, with given owner, using * given table. The table's length must be an exponent of 2. */ private ScopeImpl(ScopeImpl next, Symbol owner, Entry[] table) { super(owner); this.next = next; Assert.check(owner != null); this.table = table; this.hashMask = table.length - 1; } /** Convenience constructor used for dup and dupUnshared. */ private ScopeImpl(ScopeImpl next, Symbol owner, Entry[] table, int nelems) { this(next, owner, table); this.nelems = nelems; } /** Construct a new scope, within scope next, with given owner, * using a fresh table of length INITIAL_SIZE. */ public ScopeImpl(Symbol owner) { this(null, owner, new Entry[INITIAL_SIZE]); } /** Construct a fresh scope within this scope, with new owner, * which shares its table with the outer scope. Used in connection with * method leave if scope access is stack-like in order to avoid allocation * of fresh tables. */ public WriteableScope dup(Symbol newOwner) { ScopeImpl result = new ScopeImpl(this, newOwner, this.table, this.nelems); shared++; // System.out.println("====> duping scope " + this.hashCode() + " owned by " + newOwner + " to " + result.hashCode()); // new Error().printStackTrace(System.out); return result; } /** Construct a fresh scope within this scope, with new owner, * with a new hash table, whose contents initially are those of * the table of its outer scope. */ public WriteableScope dupUnshared(Symbol newOwner) { if (shared > 0) { //The nested Scopes might have already added something to the table, so all items //that don't originate in this Scope or any of its outer Scopes need to be cleared: Set acceptScopes = Collections.newSetFromMap(new IdentityHashMap<>()); ScopeImpl c = this; while (c != null) { acceptScopes.add(c); c = c.next; } int n = 0; Entry[] oldTable = this.table; Entry[] newTable = new Entry[this.table.length]; for (int i = 0; i < oldTable.length; i++) { Entry e = oldTable[i]; while (e != null && e != sentinel && !acceptScopes.contains(e.scope)) { e = e.shadowed; } if (e != null) { n++; newTable[i] = e; } } return new ScopeImpl(this, newOwner, newTable, n); } else { return new ScopeImpl(this, newOwner, this.table.clone(), this.nelems); } } /** Remove all entries of this scope from its table, if shared * with next. */ public WriteableScope leave() { Assert.check(shared == 0); if (table != next.table) return next; while (elems != null) { int hash = getIndex(elems.sym.name); Entry e = table[hash]; Assert.check(e == elems, elems.sym); table[hash] = elems.shadowed; elems = elems.sibling; } Assert.check(next.shared > 0); next.shared--; next.nelems = nelems; // System.out.println("====> leaving scope " + this.hashCode() + " owned by " + this.owner + " to " + next.hashCode()); // new Error().printStackTrace(System.out); return next; } /** Double size of hash table. */ private void dble() { Assert.check(shared == 0); Entry[] oldtable = table; Entry[] newtable = new Entry[oldtable.length * 2]; for (ScopeImpl s = this; s != null; s = s.next) { if (s.table == oldtable) { Assert.check(s == this || s.shared != 0); s.table = newtable; s.hashMask = newtable.length - 1; } } int n = 0; for (int i = oldtable.length; --i >= 0; ) { Entry e = oldtable[i]; if (e != null && e != sentinel) { table[getIndex(e.sym.name)] = e; n++; } } // We don't need to update nelems for shared inherited scopes, // since that gets handled by leave(). nelems = n; } /** Enter symbol sym in this scope. */ public void enter(Symbol sym) { Assert.check(shared == 0); if (nelems * 3 >= hashMask * 2) dble(); int hash = getIndex(sym.name); Entry old = table[hash]; if (old == null) { old = sentinel; nelems++; } Entry e = new Entry(sym, old, elems, this); table[hash] = e; elems = e; //notify listeners listeners.symbolAdded(sym, this); } /** Remove symbol from this scope. */ public void remove(Symbol sym) { Assert.check(shared == 0); Entry e = lookup(sym.name, candidate -> candidate == sym); if (e.scope == null) return; // remove e from table and shadowed list; int i = getIndex(sym.name); Entry te = table[i]; if (te == e) table[i] = e.shadowed; else while (true) { if (te.shadowed == e) { te.shadowed = e.shadowed; break; } te = te.shadowed; } // remove e from elems and sibling list te = elems; if (te == e) elems = e.sibling; else while (true) { if (te.sibling == e) { te.sibling = e.sibling; break; } te = te.sibling; } removeCount++; //notify listeners listeners.symbolRemoved(sym, this); } /** Enter symbol sym in this scope if not already there. */ public void enterIfAbsent(Symbol sym) { Assert.check(shared == 0); Entry e = lookup(sym.name); while (e.scope == this && e.sym.kind != sym.kind) e = e.next(); if (e.scope != this) enter(sym); } /** Given a class, is there already a class with same fully * qualified name in this (import) scope? */ public boolean includes(Symbol c) { for (Scope.Entry e = lookup(c.name); e.scope == this; e = e.next()) { if (e.sym == c) return true; } return false; } /** Return the entry associated with given name, starting in * this scope and proceeding outwards. If no entry was found, * return the sentinel, which is characterized by having a null in * both its scope and sym fields, whereas both fields are non-null * for regular entries. */ protected Entry lookup(Name name) { return lookup(name, noFilter); } protected Entry lookup(Name name, Filter sf) { Entry e = table[getIndex(name)]; if (e == null || e == sentinel) return sentinel; while (e.scope != null && (e.sym.name != name || (sf != null && !sf.accepts(e.sym)))) e = e.shadowed; return e; } public Symbol findFirst(Name name, Filter sf) { return lookup(name, sf).sym; } /*void dump (java.io.PrintStream out) { out.println(this); for (int l=0; l < table.length; l++) { Entry le = table[l]; out.print("#"+l+": "); if (le==sentinel) out.println("sentinel"); else if(le == null) out.println("null"); else out.println(""+le+" s:"+le.sym); } }*/ /** Look for slot in the table. * We use open addressing with double hashing. */ int getIndex (Name name) { int h = name.hashCode(); int i = h & hashMask; // The expression below is always odd, so it is guaranteed // to be mutually prime with table.length, a power of 2. int x = hashMask - ((h + (h >> 16)) << 1); int d = -1; // Index of a deleted item. for (;;) { Entry e = table[i]; if (e == null) return d >= 0 ? d : i; if (e == sentinel) { // We have to keep searching even if we see a deleted item. // However, remember the index in case we fail to find the name. if (d < 0) d = i; } else if (e.sym.name == name) return i; i = (i + x) & hashMask; } } public boolean anyMatch(Filter sf) { return getSymbols(sf, NON_RECURSIVE).iterator().hasNext(); } public Iterable getSymbols(final Filter sf, final LookupKind lookupKind) { return () -> new Iterator() { private ScopeImpl currScope = ScopeImpl.this; private Entry currEntry = elems; private int seenRemoveCount = currScope.removeCount; { update(); } public boolean hasNext() { if (seenRemoveCount != currScope.removeCount && currEntry != null && !currEntry.scope.includes(currEntry.sym)) { doNext(); //skip entry that is no longer in the Scope seenRemoveCount = currScope.removeCount; } return currEntry != null; } public Symbol next() { if (!hasNext()) { throw new NoSuchElementException(); } return doNext(); } private Symbol doNext() { Symbol sym = (currEntry == null ? null : currEntry.sym); if (currEntry != null) { currEntry = currEntry.sibling; } update(); return sym; } private void update() { skipToNextMatchingEntry(); if (lookupKind == RECURSIVE) { while (currEntry == null && currScope.next != null) { currScope = currScope.next; currEntry = currScope.elems; seenRemoveCount = currScope.removeCount; skipToNextMatchingEntry(); } } } void skipToNextMatchingEntry() { while (currEntry != null && sf != null && !sf.accepts(currEntry.sym)) { currEntry = currEntry.sibling; } } }; } public Iterable getSymbolsByName(final Name name, final Filter sf, final LookupKind lookupKind) { return () -> new Iterator() { Entry currentEntry = lookup(name, sf); int seenRemoveCount = currentEntry.scope != null ? currentEntry.scope.removeCount : -1; public boolean hasNext() { if (currentEntry.scope != null && seenRemoveCount != currentEntry.scope.removeCount && !currentEntry.scope.includes(currentEntry.sym)) { doNext(); //skip entry that is no longer in the Scope } return currentEntry.scope != null && (lookupKind == RECURSIVE || currentEntry.scope == ScopeImpl.this); } public Symbol next() { if (!hasNext()) { throw new NoSuchElementException(); } return doNext(); } private Symbol doNext() { Entry prevEntry = currentEntry; currentEntry = currentEntry.next(sf); return prevEntry.sym; } public void remove() { throw new UnsupportedOperationException(); } }; } public Scope getOrigin(Symbol s) { for (Scope.Entry e = lookup(s.name); e.scope != null ; e = e.next()) { if (e.sym == s) { return this; } } return null; } @Override public boolean isStaticallyImported(Symbol s) { return false; } public String toString() { StringBuilder result = new StringBuilder(); result.append("Scope["); for (ScopeImpl s = this; s != null ; s = s.next) { if (s != this) result.append(" | "); for (Entry e = s.elems; e != null; e = e.sibling) { if (e != s.elems) result.append(", "); result.append(e.sym); } } result.append("]"); return result.toString(); } } /** A class for scope entries. */ private static class Entry { /** The referenced symbol. * sym == null iff this == sentinel */ public Symbol sym; /** An entry with the same hash code, or sentinel. */ private Entry shadowed; /** Next entry in same scope. */ public Entry sibling; /** The entry's scope. * scope == null iff this == sentinel */ public ScopeImpl scope; public Entry(Symbol sym, Entry shadowed, Entry sibling, ScopeImpl scope) { this.sym = sym; this.shadowed = shadowed; this.sibling = sibling; this.scope = scope; } /** Return next entry with the same name as this entry, proceeding * outwards if not found in this scope. */ public Entry next() { return shadowed; } public Entry next(Filter sf) { if (shadowed.sym == null || sf == null || sf.accepts(shadowed.sym)) return shadowed; else return shadowed.next(sf); } } public static class ImportScope extends CompoundScope { public ImportScope(Symbol owner) { super(owner); } /**Finalize the content of the ImportScope to speed-up future lookups. * No further changes to class hierarchy or class content will be reflected. */ public void finalizeScope() { for (List scopes = this.subScopes; scopes.nonEmpty(); scopes = scopes.tail) { Scope impScope = scopes.head; if (impScope instanceof FilterImportScope && impScope.owner.kind == Kind.TYP) { WriteableScope finalized = WriteableScope.create(impScope.owner); for (Symbol sym : impScope.getSymbols()) { finalized.enter(sym); } finalized.listeners.add(new ScopeListener() { @Override public void symbolAdded(Symbol sym, Scope s) { Assert.error("The scope is sealed."); } @Override public void symbolRemoved(Symbol sym, Scope s) { Assert.error("The scope is sealed."); } }); scopes.head = finalized; } } } } public static class NamedImportScope extends ImportScope { public NamedImportScope(Symbol owner, Scope currentFileScope) { super(owner); prependSubScope(currentFileScope); } public Scope importByName(Types types, Scope origin, Name name, ImportFilter filter, JCImport imp, BiConsumer cfHandler) { return appendScope(new FilterImportScope(types, origin, name, filter, imp, cfHandler)); } public Scope importType(Scope delegate, Scope origin, Symbol sym) { return appendScope(new SingleEntryScope(delegate.owner, sym, origin)); } private Scope appendScope(Scope newScope) { List existingScopes = this.subScopes.reverse(); subScopes = List.of(existingScopes.head); subScopes = subScopes.prepend(newScope); for (Scope s : existingScopes.tail) { subScopes = subScopes.prepend(s); } return newScope; } private static class SingleEntryScope extends Scope { private final Symbol sym; private final List content; private final Scope origin; public SingleEntryScope(Symbol owner, Symbol sym, Scope origin) { super(owner); this.sym = sym; this.content = List.of(sym); this.origin = origin; } @Override public Iterable getSymbols(Filter sf, LookupKind lookupKind) { return sf == null || sf.accepts(sym) ? content : Collections.emptyList(); } @Override public Iterable getSymbolsByName(Name name, Filter sf, LookupKind lookupKind) { return sym.name == name && (sf == null || sf.accepts(sym)) ? content : Collections.emptyList(); } @Override public Scope getOrigin(Symbol byName) { return sym == byName ? origin : null; } @Override public boolean isStaticallyImported(Symbol byName) { return false; } } } public static class StarImportScope extends ImportScope { public StarImportScope(Symbol owner) { super(owner); } public void importAll(Types types, Scope origin, ImportFilter filter, JCImport imp, BiConsumer cfHandler) { for (Scope existing : subScopes) { Assert.check(existing instanceof FilterImportScope); FilterImportScope fis = (FilterImportScope) existing; if (fis.origin == origin && fis.filter == filter && fis.imp.staticImport == imp.staticImport) return ; //avoid entering the same scope twice } prependSubScope(new FilterImportScope(types, origin, null, filter, imp, cfHandler)); } public boolean isFilled() { return subScopes.nonEmpty(); } } public interface ImportFilter { public boolean accepts(Scope origin, Symbol sym); } private static class FilterImportScope extends Scope { private final Types types; private final Scope origin; private final Name filterName; private final ImportFilter filter; private final JCImport imp; private final BiConsumer cfHandler; public FilterImportScope(Types types, Scope origin, Name filterName, ImportFilter filter, JCImport imp, BiConsumer cfHandler) { super(origin.owner); this.types = types; this.origin = origin; this.filterName = filterName; this.filter = filter; this.imp = imp; this.cfHandler = cfHandler; } @Override public Iterable getSymbols(final Filter sf, final LookupKind lookupKind) { if (filterName != null) return getSymbolsByName(filterName, sf, lookupKind); try { SymbolImporter si = new SymbolImporter(imp.staticImport) { @Override Iterable doLookup(TypeSymbol tsym) { return tsym.members().getSymbols(sf, lookupKind); } }; return si.importFrom((TypeSymbol) origin.owner) :: iterator; } catch (CompletionFailure cf) { cfHandler.accept(imp, cf); return Collections.emptyList(); } } @Override public Iterable getSymbolsByName(final Name name, final Filter sf, final LookupKind lookupKind) { if (filterName != null && filterName != name) return Collections.emptyList(); try { SymbolImporter si = new SymbolImporter(imp.staticImport) { @Override Iterable doLookup(TypeSymbol tsym) { return tsym.members().getSymbolsByName(name, sf, lookupKind); } }; return si.importFrom((TypeSymbol) origin.owner) :: iterator; } catch (CompletionFailure cf) { cfHandler.accept(imp, cf); return Collections.emptyList(); } } @Override public Scope getOrigin(Symbol byName) { return origin; } @Override public boolean isStaticallyImported(Symbol byName) { return imp.staticImport; } abstract class SymbolImporter { Set processed = new HashSet<>(); List> delegates = List.nil(); final boolean inspectSuperTypes; public SymbolImporter(boolean inspectSuperTypes) { this.inspectSuperTypes = inspectSuperTypes; } Stream importFrom(TypeSymbol tsym) { if (tsym == null || !processed.add(tsym)) return Stream.empty(); Stream result = Stream.empty(); if (inspectSuperTypes) { // also import inherited names result = importFrom(types.supertype(tsym.type).tsym); for (Type t : types.interfaces(tsym.type)) result = Stream.concat(importFrom(t.tsym), result); } return Stream.concat(StreamSupport.stream(doLookup(tsym).spliterator(), false) .filter(s -> filter.accepts(origin, s)), result); } abstract Iterable doLookup(TypeSymbol tsym); } } /** A class scope adds capabilities to keep track of changes in related * class scopes - this allows client to realize whether a class scope * has changed, either directly (because a new member has been added/removed * to this scope) or indirectly (i.e. because a new member has been * added/removed into a supertype scope) */ public static class CompoundScope extends Scope implements ScopeListener { List subScopes = List.nil(); private int mark = 0; public CompoundScope(Symbol owner) { super(owner); } public void prependSubScope(Scope that) { if (that != null) { subScopes = subScopes.prepend(that); that.listeners.add(this); mark++; listeners.symbolAdded(null, this); } } public void symbolAdded(Symbol sym, Scope s) { mark++; listeners.symbolAdded(sym, s); } public void symbolRemoved(Symbol sym, Scope s) { mark++; listeners.symbolRemoved(sym, s); } public int getMark() { return mark; } @Override public String toString() { StringBuilder buf = new StringBuilder(); buf.append("CompoundScope{"); String sep = ""; for (Scope s : subScopes) { buf.append(sep); buf.append(s); sep = ","; } buf.append("}"); return buf.toString(); } @Override public Iterable getSymbols(final Filter sf, final LookupKind lookupKind) { return () -> Iterators.createCompoundIterator(subScopes, scope -> scope.getSymbols(sf, lookupKind) .iterator()); } @Override public Iterable getSymbolsByName(final Name name, final Filter sf, final LookupKind lookupKind) { return () -> Iterators.createCompoundIterator(subScopes, scope -> scope.getSymbolsByName(name, sf, lookupKind) .iterator()); } @Override public Scope getOrigin(Symbol sym) { for (Scope delegate : subScopes) { if (delegate.includes(sym)) return delegate.getOrigin(sym); } return null; } @Override public boolean isStaticallyImported(Symbol sym) { for (Scope delegate : subScopes) { if (delegate.includes(sym)) return delegate.isStaticallyImported(sym); } return false; } } /** An error scope, for which the owner should be an error symbol. */ public static class ErrorScope extends ScopeImpl { ErrorScope(ScopeImpl next, Symbol errSymbol, Entry[] table) { super(next, /*owner=*/errSymbol, table); } public ErrorScope(Symbol errSymbol) { super(errSymbol); } public WriteableScope dup(Symbol newOwner) { return new ErrorScope(this, newOwner, table); } public WriteableScope dupUnshared(Symbol newOwner) { return new ErrorScope(this, newOwner, table.clone()); } public Entry lookup(Name name) { Entry e = super.lookup(name); if (e.scope == null) return new Entry(owner, null, null, null); else return e; } } }





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