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src/share/classes/com/sun/tools/javac/comp/Lower.java@62f3f07002ea (annotated)

src/share/classes/com/sun/tools/javac/comp/Lower.java

Thu, 29 Jul 2010 15:57:43 +0100

author

mcimadamore

date

Thu, 29 Jul 2010 15:57:43 +0100

changeset 617

62f3f07002ea

parent 609

13354e1abba7

child 657

70ebdef189c9

permissions

-rw-r--r--

6970833: Try-with-resource implementation throws an NPE during Flow analysis
Summary: Updated logic not to rely upon Symbol.implementation (which check in superinterfaces)
Reviewed-by: jjg

duke@1	1	/*
ohair@554	2	* Copyright (c) 1999, 2009, Oracle and/or its affiliates. All rights reserved.
duke@1	3	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
duke@1	4	*
duke@1	5	* This code is free software; you can redistribute it and/or modify it
duke@1	6	* under the terms of the GNU General Public License version 2 only, as
ohair@554	7	* published by the Free Software Foundation. Oracle designates this
duke@1	8	* particular file as subject to the "Classpath" exception as provided
ohair@554	9	* by Oracle in the LICENSE file that accompanied this code.
duke@1	10	*
duke@1	11	* This code is distributed in the hope that it will be useful, but WITHOUT
duke@1	12	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
duke@1	13	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
duke@1	14	* version 2 for more details (a copy is included in the LICENSE file that
duke@1	15	* accompanied this code).
duke@1	16	*
duke@1	17	* You should have received a copy of the GNU General Public License version
duke@1	18	* 2 along with this work; if not, write to the Free Software Foundation,
duke@1	19	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
duke@1	20	*
ohair@554	21	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
ohair@554	22	* or visit www.oracle.com if you need additional information or have any
ohair@554	23	* questions.
duke@1	24	*/
duke@1	25
duke@1	26	package com.sun.tools.javac.comp;
duke@1	27
duke@1	28	import java.util.*;
duke@1	29
duke@1	30	import com.sun.tools.javac.code.*;
duke@1	31	import com.sun.tools.javac.jvm.*;
duke@1	32	import com.sun.tools.javac.tree.*;
duke@1	33	import com.sun.tools.javac.util.*;
duke@1	34	import com.sun.tools.javac.util.JCDiagnostic.DiagnosticPosition;
duke@1	35	import com.sun.tools.javac.util.List;
duke@1	36
duke@1	37	import com.sun.tools.javac.code.Symbol.*;
duke@1	38	import com.sun.tools.javac.tree.JCTree.*;
duke@1	39	import com.sun.tools.javac.code.Type.*;
duke@1	40
duke@1	41	import com.sun.tools.javac.jvm.Target;
duke@1	42
duke@1	43	import static com.sun.tools.javac.code.Flags.*;
duke@1	44	import static com.sun.tools.javac.code.Kinds.*;
duke@1	45	import static com.sun.tools.javac.code.TypeTags.*;
duke@1	46	import static com.sun.tools.javac.jvm.ByteCodes.*;
duke@1	47
duke@1	48	/** This pass translates away some syntactic sugar: inner classes,
duke@1	49	* class literals, assertions, foreach loops, etc.
duke@1	50	*
jjg@581	51	* <p><b>This is NOT part of any supported API.
jjg@581	52	* If you write code that depends on this, you do so at your own risk.
duke@1	53	* This code and its internal interfaces are subject to change or
duke@1	54	* deletion without notice.</b>
duke@1	55	*/
duke@1	56	public class Lower extends TreeTranslator {
duke@1	57	protected static final Context.Key<Lower> lowerKey =
duke@1	58	new Context.Key<Lower>();
duke@1	59
duke@1	60	public static Lower instance(Context context) {
duke@1	61	Lower instance = context.get(lowerKey);
duke@1	62	if (instance == null)
duke@1	63	instance = new Lower(context);
duke@1	64	return instance;
duke@1	65	}
duke@1	66
jjg@113	67	private Names names;
duke@1	68	private Log log;
duke@1	69	private Symtab syms;
duke@1	70	private Resolve rs;
duke@1	71	private Check chk;
duke@1	72	private Attr attr;
duke@1	73	private TreeMaker make;
duke@1	74	private DiagnosticPosition make_pos;
duke@1	75	private ClassWriter writer;
duke@1	76	private ClassReader reader;
duke@1	77	private ConstFold cfolder;
duke@1	78	private Target target;
duke@1	79	private Source source;
duke@1	80	private boolean allowEnums;
duke@1	81	private final Name dollarAssertionsDisabled;
duke@1	82	private final Name classDollar;
duke@1	83	private Types types;
duke@1	84	private boolean debugLower;
duke@1	85
duke@1	86	protected Lower(Context context) {
duke@1	87	context.put(lowerKey, this);
jjg@113	88	names = Names.instance(context);
duke@1	89	log = Log.instance(context);
duke@1	90	syms = Symtab.instance(context);
duke@1	91	rs = Resolve.instance(context);
duke@1	92	chk = Check.instance(context);
duke@1	93	attr = Attr.instance(context);
duke@1	94	make = TreeMaker.instance(context);
duke@1	95	writer = ClassWriter.instance(context);
duke@1	96	reader = ClassReader.instance(context);
duke@1	97	cfolder = ConstFold.instance(context);
duke@1	98	target = Target.instance(context);
duke@1	99	source = Source.instance(context);
duke@1	100	allowEnums = source.allowEnums();
duke@1	101	dollarAssertionsDisabled = names.
duke@1	102	fromString(target.syntheticNameChar() + "assertionsDisabled");
duke@1	103	classDollar = names.
duke@1	104	fromString("class" + target.syntheticNameChar());
duke@1	105
duke@1	106	types = Types.instance(context);
duke@1	107	Options options = Options.instance(context);
duke@1	108	debugLower = options.get("debuglower") != null;
duke@1	109	}
duke@1	110
duke@1	111	/** The currently enclosing class.
duke@1	112	*/
duke@1	113	ClassSymbol currentClass;
duke@1	114
duke@1	115	/** A queue of all translated classes.
duke@1	116	*/
duke@1	117	ListBuffer<JCTree> translated;
duke@1	118
duke@1	119	/** Environment for symbol lookup, set by translateTopLevelClass.
duke@1	120	*/
duke@1	121	Env<AttrContext> attrEnv;
duke@1	122
duke@1	123	/** A hash table mapping syntax trees to their ending source positions.
duke@1	124	*/
duke@1	125	Map<JCTree, Integer> endPositions;
duke@1	126
duke@1	127	/**************************************************************************
duke@1	128	* Global mappings
duke@1	129	*************************************************************************/
duke@1	130
duke@1	131	/** A hash table mapping local classes to their definitions.
duke@1	132	*/
duke@1	133	Map<ClassSymbol, JCClassDecl> classdefs;
duke@1	134
duke@1	135	/** A hash table mapping virtual accessed symbols in outer subclasses
duke@1	136	* to the actually referred symbol in superclasses.
duke@1	137	*/
duke@1	138	Map<Symbol,Symbol> actualSymbols;
duke@1	139
duke@1	140	/** The current method definition.
duke@1	141	*/
duke@1	142	JCMethodDecl currentMethodDef;
duke@1	143
duke@1	144	/** The current method symbol.
duke@1	145	*/
duke@1	146	MethodSymbol currentMethodSym;
duke@1	147
duke@1	148	/** The currently enclosing outermost class definition.
duke@1	149	*/
duke@1	150	JCClassDecl outermostClassDef;
duke@1	151
duke@1	152	/** The currently enclosing outermost member definition.
duke@1	153	*/
duke@1	154	JCTree outermostMemberDef;
duke@1	155
duke@1	156	/** A navigator class for assembling a mapping from local class symbols
duke@1	157	* to class definition trees.
duke@1	158	* There is only one case; all other cases simply traverse down the tree.
duke@1	159	*/
duke@1	160	class ClassMap extends TreeScanner {
duke@1	161
duke@1	162	/** All encountered class defs are entered into classdefs table.
duke@1	163	*/
duke@1	164	public void visitClassDef(JCClassDecl tree) {
duke@1	165	classdefs.put(tree.sym, tree);
duke@1	166	super.visitClassDef(tree);
duke@1	167	}
duke@1	168	}
duke@1	169	ClassMap classMap = new ClassMap();
duke@1	170
duke@1	171	/** Map a class symbol to its definition.
duke@1	172	* @param c The class symbol of which we want to determine the definition.
duke@1	173	*/
duke@1	174	JCClassDecl classDef(ClassSymbol c) {
duke@1	175	// First lookup the class in the classdefs table.
duke@1	176	JCClassDecl def = classdefs.get(c);
duke@1	177	if (def == null && outermostMemberDef != null) {
duke@1	178	// If this fails, traverse outermost member definition, entering all
duke@1	179	// local classes into classdefs, and try again.
duke@1	180	classMap.scan(outermostMemberDef);
duke@1	181	def = classdefs.get(c);
duke@1	182	}
duke@1	183	if (def == null) {
duke@1	184	// If this fails, traverse outermost class definition, entering all
duke@1	185	// local classes into classdefs, and try again.
duke@1	186	classMap.scan(outermostClassDef);
duke@1	187	def = classdefs.get(c);
duke@1	188	}
duke@1	189	return def;
duke@1	190	}
duke@1	191
duke@1	192	/** A hash table mapping class symbols to lists of free variables.
duke@1	193	* accessed by them. Only free variables of the method immediately containing
duke@1	194	* a class are associated with that class.
duke@1	195	*/
duke@1	196	Map<ClassSymbol,List<VarSymbol>> freevarCache;
duke@1	197
duke@1	198	/** A navigator class for collecting the free variables accessed
duke@1	199	* from a local class.
duke@1	200	* There is only one case; all other cases simply traverse down the tree.
duke@1	201	*/
duke@1	202	class FreeVarCollector extends TreeScanner {
duke@1	203
duke@1	204	/** The owner of the local class.
duke@1	205	*/
duke@1	206	Symbol owner;
duke@1	207
duke@1	208	/** The local class.
duke@1	209	*/
duke@1	210	ClassSymbol clazz;
duke@1	211
duke@1	212	/** The list of owner's variables accessed from within the local class,
duke@1	213	* without any duplicates.
duke@1	214	*/
duke@1	215	List<VarSymbol> fvs;
duke@1	216
duke@1	217	FreeVarCollector(ClassSymbol clazz) {
duke@1	218	this.clazz = clazz;
duke@1	219	this.owner = clazz.owner;
duke@1	220	this.fvs = List.nil();
duke@1	221	}
duke@1	222
duke@1	223	/** Add free variable to fvs list unless it is already there.
duke@1	224	*/
duke@1	225	private void addFreeVar(VarSymbol v) {
duke@1	226	for (List<VarSymbol> l = fvs; l.nonEmpty(); l = l.tail)
duke@1	227	if (l.head == v) return;
duke@1	228	fvs = fvs.prepend(v);
duke@1	229	}
duke@1	230
duke@1	231	/** Add all free variables of class c to fvs list
duke@1	232	* unless they are already there.
duke@1	233	*/
duke@1	234	private void addFreeVars(ClassSymbol c) {
duke@1	235	List<VarSymbol> fvs = freevarCache.get(c);
duke@1	236	if (fvs != null) {
duke@1	237	for (List<VarSymbol> l = fvs; l.nonEmpty(); l = l.tail) {
duke@1	238	addFreeVar(l.head);
duke@1	239	}
duke@1	240	}
duke@1	241	}
duke@1	242
duke@1	243	/** If tree refers to a variable in owner of local class, add it to
duke@1	244	* free variables list.
duke@1	245	*/
duke@1	246	public void visitIdent(JCIdent tree) {
duke@1	247	result = tree;
duke@1	248	visitSymbol(tree.sym);
duke@1	249	}
duke@1	250	// where
duke@1	251	private void visitSymbol(Symbol _sym) {
duke@1	252	Symbol sym = _sym;
duke@1	253	if (sym.kind == VAR || sym.kind == MTH) {
duke@1	254	while (sym != null && sym.owner != owner)
duke@1	255	sym = proxies.lookup(proxyName(sym.name)).sym;
duke@1	256	if (sym != null && sym.owner == owner) {
duke@1	257	VarSymbol v = (VarSymbol)sym;
duke@1	258	if (v.getConstValue() == null) {
duke@1	259	addFreeVar(v);
duke@1	260	}
duke@1	261	} else {
duke@1	262	if (outerThisStack.head != null &&
duke@1	263	outerThisStack.head != _sym)
duke@1	264	visitSymbol(outerThisStack.head);
duke@1	265	}
duke@1	266	}
duke@1	267	}
duke@1	268
duke@1	269	/** If tree refers to a class instance creation expression
duke@1	270	* add all free variables of the freshly created class.
duke@1	271	*/
duke@1	272	public void visitNewClass(JCNewClass tree) {
duke@1	273	ClassSymbol c = (ClassSymbol)tree.constructor.owner;
duke@1	274	addFreeVars(c);
duke@1	275	if (tree.encl == null &&
duke@1	276	c.hasOuterInstance() &&
duke@1	277	outerThisStack.head != null)
duke@1	278	visitSymbol(outerThisStack.head);
duke@1	279	super.visitNewClass(tree);
duke@1	280	}
duke@1	281
duke@1	282	/** If tree refers to a qualified this or super expression
duke@1	283	* for anything but the current class, add the outer this
duke@1	284	* stack as a free variable.
duke@1	285	*/
duke@1	286	public void visitSelect(JCFieldAccess tree) {
duke@1	287	if ((tree.name == names._this || tree.name == names._super) &&
duke@1	288	tree.selected.type.tsym != clazz &&
duke@1	289	outerThisStack.head != null)
duke@1	290	visitSymbol(outerThisStack.head);
duke@1	291	super.visitSelect(tree);
duke@1	292	}
duke@1	293
duke@1	294	/** If tree refers to a superclass constructor call,
duke@1	295	* add all free variables of the superclass.
duke@1	296	*/
duke@1	297	public void visitApply(JCMethodInvocation tree) {
duke@1	298	if (TreeInfo.name(tree.meth) == names._super) {
duke@1	299	addFreeVars((ClassSymbol) TreeInfo.symbol(tree.meth).owner);
duke@1	300	Symbol constructor = TreeInfo.symbol(tree.meth);
duke@1	301	ClassSymbol c = (ClassSymbol)constructor.owner;
duke@1	302	if (c.hasOuterInstance() &&
duke@1	303	tree.meth.getTag() != JCTree.SELECT &&
duke@1	304	outerThisStack.head != null)
duke@1	305	visitSymbol(outerThisStack.head);
duke@1	306	}
duke@1	307	super.visitApply(tree);
duke@1	308	}
duke@1	309	}
duke@1	310
duke@1	311	/** Return the variables accessed from within a local class, which
duke@1	312	* are declared in the local class' owner.
duke@1	313	* (in reverse order of first access).
duke@1	314	*/
duke@1	315	List<VarSymbol> freevars(ClassSymbol c) {
duke@1	316	if ((c.owner.kind & (VAR | MTH)) != 0) {
duke@1	317	List<VarSymbol> fvs = freevarCache.get(c);
duke@1	318	if (fvs == null) {
duke@1	319	FreeVarCollector collector = new FreeVarCollector(c);
duke@1	320	collector.scan(classDef(c));
duke@1	321	fvs = collector.fvs;
duke@1	322	freevarCache.put(c, fvs);
duke@1	323	}
duke@1	324	return fvs;
duke@1	325	} else {
duke@1	326	return List.nil();
duke@1	327	}
duke@1	328	}
duke@1	329
duke@1	330	Map<TypeSymbol,EnumMapping> enumSwitchMap = new LinkedHashMap<TypeSymbol,EnumMapping>();
duke@1	331
duke@1	332	EnumMapping mapForEnum(DiagnosticPosition pos, TypeSymbol enumClass) {
duke@1	333	EnumMapping map = enumSwitchMap.get(enumClass);
duke@1	334	if (map == null)
duke@1	335	enumSwitchMap.put(enumClass, map = new EnumMapping(pos, enumClass));
duke@1	336	return map;
duke@1	337	}
duke@1	338
duke@1	339	/** This map gives a translation table to be used for enum
duke@1	340	* switches.
duke@1	341	*
duke@1	342	* <p>For each enum that appears as the type of a switch
duke@1	343	* expression, we maintain an EnumMapping to assist in the
duke@1	344	* translation, as exemplified by the following example:
duke@1	345	*
duke@1	346	* <p>we translate
duke@1	347	* <pre>
duke@1	348	* switch(colorExpression) {
duke@1	349	* case red: stmt1;
duke@1	350	* case green: stmt2;
duke@1	351	* }
duke@1	352	* </pre>
duke@1	353	* into
duke@1	354	* <pre>
duke@1	355	* switch(Outer$0.$EnumMap$Color[colorExpression.ordinal()]) {
duke@1	356	* case 1: stmt1;
duke@1	357	* case 2: stmt2
duke@1	358	* }
duke@1	359	* </pre>
darcy@430	360	* with the auxiliary table initialized as follows:
duke@1	361	* <pre>
duke@1	362	* class Outer$0 {
duke@1	363	* synthetic final int[] $EnumMap$Color = new int[Color.values().length];
duke@1	364	* static {
duke@1	365	* try { $EnumMap$Color[red.ordinal()] = 1; } catch (NoSuchFieldError ex) {}
duke@1	366	* try { $EnumMap$Color[green.ordinal()] = 2; } catch (NoSuchFieldError ex) {}
duke@1	367	* }
duke@1	368	* }
duke@1	369	* </pre>
duke@1	370	* class EnumMapping provides mapping data and support methods for this translation.
duke@1	371	*/
duke@1	372	class EnumMapping {
duke@1	373	EnumMapping(DiagnosticPosition pos, TypeSymbol forEnum) {
duke@1	374	this.forEnum = forEnum;
duke@1	375	this.values = new LinkedHashMap<VarSymbol,Integer>();
duke@1	376	this.pos = pos;
duke@1	377	Name varName = names
duke@1	378	.fromString(target.syntheticNameChar() +
duke@1	379	"SwitchMap" +
duke@1	380	target.syntheticNameChar() +
duke@1	381	writer.xClassName(forEnum.type).toString()
duke@1	382	.replace('/', '.')
duke@1	383	.replace('.', target.syntheticNameChar()));
duke@1	384	ClassSymbol outerCacheClass = outerCacheClass();
duke@1	385	this.mapVar = new VarSymbol(STATIC | SYNTHETIC | FINAL,
duke@1	386	varName,
duke@1	387	new ArrayType(syms.intType, syms.arrayClass),
duke@1	388	outerCacheClass);
duke@1	389	enterSynthetic(pos, mapVar, outerCacheClass.members());
duke@1	390	}
duke@1	391
duke@1	392	DiagnosticPosition pos = null;
duke@1	393
duke@1	394	// the next value to use
duke@1	395	int next = 1; // 0 (unused map elements) go to the default label
duke@1	396
duke@1	397	// the enum for which this is a map
duke@1	398	final TypeSymbol forEnum;
duke@1	399
duke@1	400	// the field containing the map
duke@1	401	final VarSymbol mapVar;
duke@1	402
duke@1	403	// the mapped values
duke@1	404	final Map<VarSymbol,Integer> values;
duke@1	405
duke@1	406	JCLiteral forConstant(VarSymbol v) {
duke@1	407	Integer result = values.get(v);
duke@1	408	if (result == null)
duke@1	409	values.put(v, result = next++);
duke@1	410	return make.Literal(result);
duke@1	411	}
duke@1	412
duke@1	413	// generate the field initializer for the map
duke@1	414	void translate() {
duke@1	415	make.at(pos.getStartPosition());
duke@1	416	JCClassDecl owner = classDef((ClassSymbol)mapVar.owner);
duke@1	417
duke@1	418	// synthetic static final int[] $SwitchMap$Color = new int[Color.values().length];
duke@1	419	MethodSymbol valuesMethod = lookupMethod(pos,
duke@1	420	names.values,
duke@1	421	forEnum.type,
duke@1	422	List.<Type>nil());
duke@1	423	JCExpression size = make // Color.values().length
duke@1	424	.Select(make.App(make.QualIdent(valuesMethod)),
duke@1	425	syms.lengthVar);
duke@1	426	JCExpression mapVarInit = make
duke@1	427	.NewArray(make.Type(syms.intType), List.of(size), null)
duke@1	428	.setType(new ArrayType(syms.intType, syms.arrayClass));
duke@1	429
duke@1	430	// try { $SwitchMap$Color[red.ordinal()] = 1; } catch (java.lang.NoSuchFieldError ex) {}
duke@1	431	ListBuffer<JCStatement> stmts = new ListBuffer<JCStatement>();
duke@1	432	Symbol ordinalMethod = lookupMethod(pos,
duke@1	433	names.ordinal,
duke@1	434	forEnum.type,
duke@1	435	List.<Type>nil());
duke@1	436	List<JCCatch> catcher = List.<JCCatch>nil()
duke@1	437	.prepend(make.Catch(make.VarDef(new VarSymbol(PARAMETER, names.ex,
duke@1	438	syms.noSuchFieldErrorType,
duke@1	439	syms.noSymbol),
duke@1	440	null),
duke@1	441	make.Block(0, List.<JCStatement>nil())));
duke@1	442	for (Map.Entry<VarSymbol,Integer> e : values.entrySet()) {
duke@1	443	VarSymbol enumerator = e.getKey();
duke@1	444	Integer mappedValue = e.getValue();
duke@1	445	JCExpression assign = make
duke@1	446	.Assign(make.Indexed(mapVar,
duke@1	447	make.App(make.Select(make.QualIdent(enumerator),
duke@1	448	ordinalMethod))),
duke@1	449	make.Literal(mappedValue))
duke@1	450	.setType(syms.intType);
duke@1	451	JCStatement exec = make.Exec(assign);
duke@1	452	JCStatement _try = make.Try(make.Block(0, List.of(exec)), catcher, null);
duke@1	453	stmts.append(_try);
duke@1	454	}
duke@1	455
duke@1	456	owner.defs = owner.defs
duke@1	457	.prepend(make.Block(STATIC, stmts.toList()))
duke@1	458	.prepend(make.VarDef(mapVar, mapVarInit));
duke@1	459	}
duke@1	460	}
duke@1	461
duke@1	462
duke@1	463	/**************************************************************************
duke@1	464	* Tree building blocks
duke@1	465	*************************************************************************/
duke@1	466
duke@1	467	/** Equivalent to make.at(pos.getStartPosition()) with side effect of caching
duke@1	468	* pos as make_pos, for use in diagnostics.
duke@1	469	**/
duke@1	470	TreeMaker make_at(DiagnosticPosition pos) {
duke@1	471	make_pos = pos;
duke@1	472	return make.at(pos);
duke@1	473	}
duke@1	474
duke@1	475	/** Make an attributed tree representing a literal. This will be an
duke@1	476	* Ident node in the case of boolean literals, a Literal node in all
duke@1	477	* other cases.
duke@1	478	* @param type The literal's type.
duke@1	479	* @param value The literal's value.
duke@1	480	*/
duke@1	481	JCExpression makeLit(Type type, Object value) {
duke@1	482	return make.Literal(type.tag, value).setType(type.constType(value));
duke@1	483	}
duke@1	484
duke@1	485	/** Make an attributed tree representing null.
duke@1	486	*/
duke@1	487	JCExpression makeNull() {
duke@1	488	return makeLit(syms.botType, null);
duke@1	489	}
duke@1	490
duke@1	491	/** Make an attributed class instance creation expression.
duke@1	492	* @param ctype The class type.
duke@1	493	* @param args The constructor arguments.
duke@1	494	*/
duke@1	495	JCNewClass makeNewClass(Type ctype, List<JCExpression> args) {
duke@1	496	JCNewClass tree = make.NewClass(null,
duke@1	497	null, make.QualIdent(ctype.tsym), args, null);
duke@1	498	tree.constructor = rs.resolveConstructor(
duke@1	499	make_pos, attrEnv, ctype, TreeInfo.types(args), null, false, false);
duke@1	500	tree.type = ctype;
duke@1	501	return tree;
duke@1	502	}
duke@1	503
duke@1	504	/** Make an attributed unary expression.
duke@1	505	* @param optag The operators tree tag.
duke@1	506	* @param arg The operator's argument.
duke@1	507	*/
duke@1	508	JCUnary makeUnary(int optag, JCExpression arg) {
duke@1	509	JCUnary tree = make.Unary(optag, arg);
duke@1	510	tree.operator = rs.resolveUnaryOperator(
duke@1	511	make_pos, optag, attrEnv, arg.type);
duke@1	512	tree.type = tree.operator.type.getReturnType();
duke@1	513	return tree;
duke@1	514	}
duke@1	515
duke@1	516	/** Make an attributed binary expression.
duke@1	517	* @param optag The operators tree tag.
duke@1	518	* @param lhs The operator's left argument.
duke@1	519	* @param rhs The operator's right argument.
duke@1	520	*/
duke@1	521	JCBinary makeBinary(int optag, JCExpression lhs, JCExpression rhs) {
duke@1	522	JCBinary tree = make.Binary(optag, lhs, rhs);
duke@1	523	tree.operator = rs.resolveBinaryOperator(
duke@1	524	make_pos, optag, attrEnv, lhs.type, rhs.type);
duke@1	525	tree.type = tree.operator.type.getReturnType();
duke@1	526	return tree;
duke@1	527	}
duke@1	528
duke@1	529	/** Make an attributed assignop expression.
duke@1	530	* @param optag The operators tree tag.
duke@1	531	* @param lhs The operator's left argument.
duke@1	532	* @param rhs The operator's right argument.
duke@1	533	*/
duke@1	534	JCAssignOp makeAssignop(int optag, JCTree lhs, JCTree rhs) {
duke@1	535	JCAssignOp tree = make.Assignop(optag, lhs, rhs);
duke@1	536	tree.operator = rs.resolveBinaryOperator(
duke@1	537	make_pos, tree.getTag() - JCTree.ASGOffset, attrEnv, lhs.type, rhs.type);
duke@1	538	tree.type = lhs.type;
duke@1	539	return tree;
duke@1	540	}
duke@1	541
duke@1	542	/** Convert tree into string object, unless it has already a
duke@1	543	* reference type..
duke@1	544	*/
duke@1	545	JCExpression makeString(JCExpression tree) {
duke@1	546	if (tree.type.tag >= CLASS) {
duke@1	547	return tree;
duke@1	548	} else {
duke@1	549	Symbol valueOfSym = lookupMethod(tree.pos(),
duke@1	550	names.valueOf,
duke@1	551	syms.stringType,
duke@1	552	List.of(tree.type));
duke@1	553	return make.App(make.QualIdent(valueOfSym), List.of(tree));
duke@1	554	}
duke@1	555	}
duke@1	556
duke@1	557	/** Create an empty anonymous class definition and enter and complete
duke@1	558	* its symbol. Return the class definition's symbol.
duke@1	559	* and create
duke@1	560	* @param flags The class symbol's flags
duke@1	561	* @param owner The class symbol's owner
duke@1	562	*/
duke@1	563	ClassSymbol makeEmptyClass(long flags, ClassSymbol owner) {
duke@1	564	// Create class symbol.
duke@1	565	ClassSymbol c = reader.defineClass(names.empty, owner);
duke@1	566	c.flatname = chk.localClassName(c);
duke@1	567	c.sourcefile = owner.sourcefile;
duke@1	568	c.completer = null;
duke@1	569	c.members_field = new Scope(c);
duke@1	570	c.flags_field = flags;
duke@1	571	ClassType ctype = (ClassType) c.type;
duke@1	572	ctype.supertype_field = syms.objectType;
duke@1	573	ctype.interfaces_field = List.nil();
duke@1	574
duke@1	575	JCClassDecl odef = classDef(owner);
duke@1	576
duke@1	577	// Enter class symbol in owner scope and compiled table.
duke@1	578	enterSynthetic(odef.pos(), c, owner.members());
duke@1	579	chk.compiled.put(c.flatname, c);
duke@1	580
duke@1	581	// Create class definition tree.
duke@1	582	JCClassDecl cdef = make.ClassDef(
duke@1	583	make.Modifiers(flags), names.empty,
duke@1	584	List.<JCTypeParameter>nil(),
duke@1	585	null, List.<JCExpression>nil(), List.<JCTree>nil());
duke@1	586	cdef.sym = c;
duke@1	587	cdef.type = c.type;
duke@1	588
duke@1	589	// Append class definition tree to owner's definitions.
duke@1	590	odef.defs = odef.defs.prepend(cdef);
duke@1	591
duke@1	592	return c;
duke@1	593	}
duke@1	594
duke@1	595	/**************************************************************************
duke@1	596	* Symbol manipulation utilities
duke@1	597	*************************************************************************/
duke@1	598
duke@1	599	/** Enter a synthetic symbol in a given scope, but complain if there was already one there.
duke@1	600	* @param pos Position for error reporting.
duke@1	601	* @param sym The symbol.
duke@1	602	* @param s The scope.
duke@1	603	*/
duke@1	604	private void enterSynthetic(DiagnosticPosition pos, Symbol sym, Scope s) {
mcimadamore@359	605	s.enter(sym);
mcimadamore@359	606	}
mcimadamore@359	607
darcy@609	608	/** Create a fresh synthetic name within a given scope - the unique name is
darcy@609	609	* obtained by appending '$' chars at the end of the name until no match
darcy@609	610	* is found.
darcy@609	611	*
darcy@609	612	* @param name base name
darcy@609	613	* @param s scope in which the name has to be unique
darcy@609	614	* @return fresh synthetic name
darcy@609	615	*/
darcy@609	616	private Name makeSyntheticName(Name name, Scope s) {
darcy@609	617	do {
darcy@609	618	name = name.append(
darcy@609	619	target.syntheticNameChar(),
darcy@609	620	names.empty);
darcy@609	621	} while (lookupSynthetic(name, s) != null);
darcy@609	622	return name;
darcy@609	623	}
darcy@609	624
mcimadamore@359	625	/** Check whether synthetic symbols generated during lowering conflict
mcimadamore@359	626	* with user-defined symbols.
mcimadamore@359	627	*
mcimadamore@359	628	* @param translatedTrees lowered class trees
mcimadamore@359	629	*/
mcimadamore@359	630	void checkConflicts(List<JCTree> translatedTrees) {
mcimadamore@359	631	for (JCTree t : translatedTrees) {
mcimadamore@359	632	t.accept(conflictsChecker);
mcimadamore@359	633	}
mcimadamore@359	634	}
mcimadamore@359	635
mcimadamore@359	636	JCTree.Visitor conflictsChecker = new TreeScanner() {
mcimadamore@359	637
mcimadamore@359	638	TypeSymbol currentClass;
mcimadamore@359	639
mcimadamore@359	640	@Override
mcimadamore@359	641	public void visitMethodDef(JCMethodDecl that) {
mcimadamore@359	642	chk.checkConflicts(that.pos(), that.sym, currentClass);
mcimadamore@359	643	super.visitMethodDef(that);
mcimadamore@359	644	}
mcimadamore@359	645
mcimadamore@359	646	@Override
mcimadamore@359	647	public void visitVarDef(JCVariableDecl that) {
mcimadamore@359	648	if (that.sym.owner.kind == TYP) {
mcimadamore@359	649	chk.checkConflicts(that.pos(), that.sym, currentClass);
mcimadamore@359	650	}
mcimadamore@359	651	super.visitVarDef(that);
mcimadamore@359	652	}
mcimadamore@359	653
mcimadamore@359	654	@Override
mcimadamore@359	655	public void visitClassDef(JCClassDecl that) {
mcimadamore@359	656	TypeSymbol prevCurrentClass = currentClass;
mcimadamore@359	657	currentClass = that.sym;
mcimadamore@359	658	try {
mcimadamore@359	659	super.visitClassDef(that);
mcimadamore@359	660	}
mcimadamore@359	661	finally {
mcimadamore@359	662	currentClass = prevCurrentClass;
duke@1	663	}
duke@1	664	}
mcimadamore@359	665	};
duke@1	666
duke@1	667	/** Look up a synthetic name in a given scope.
duke@1	668	* @param scope The scope.
duke@1	669	* @param name The name.
duke@1	670	*/
duke@1	671	private Symbol lookupSynthetic(Name name, Scope s) {
duke@1	672	Symbol sym = s.lookup(name).sym;
duke@1	673	return (sym==null || (sym.flags()&SYNTHETIC)==0) ? null : sym;
duke@1	674	}
duke@1	675
duke@1	676	/** Look up a method in a given scope.
duke@1	677	*/
duke@1	678	private MethodSymbol lookupMethod(DiagnosticPosition pos, Name name, Type qual, List<Type> args) {
duke@1	679	return rs.resolveInternalMethod(pos, attrEnv, qual, name, args, null);
duke@1	680	}
duke@1	681
duke@1	682	/** Look up a constructor.
duke@1	683	*/
duke@1	684	private MethodSymbol lookupConstructor(DiagnosticPosition pos, Type qual, List<Type> args) {
duke@1	685	return rs.resolveInternalConstructor(pos, attrEnv, qual, args, null);
duke@1	686	}
duke@1	687
duke@1	688	/** Look up a field.
duke@1	689	*/
duke@1	690	private VarSymbol lookupField(DiagnosticPosition pos, Type qual, Name name) {
duke@1	691	return rs.resolveInternalField(pos, attrEnv, qual, name);
duke@1	692	}
duke@1	693
jjg@595	694	/** Anon inner classes are used as access constructor tags.
jjg@595	695	* accessConstructorTag will use an existing anon class if one is available,
jjg@595	696	* and synthethise a class (with makeEmptyClass) if one is not available.
jjg@595	697	* However, there is a small possibility that an existing class will not
jjg@595	698	* be generated as expected if it is inside a conditional with a constant
jjg@595	699	* expression. If that is found to be the case, create an empty class here.
jjg@595	700	*/
jjg@595	701	private void checkAccessConstructorTags() {
jjg@595	702	for (List<ClassSymbol> l = accessConstrTags; l.nonEmpty(); l = l.tail) {
jjg@595	703	ClassSymbol c = l.head;
jjg@595	704	if (isTranslatedClassAvailable(c))
jjg@595	705	continue;
jjg@595	706	// Create class definition tree.
jjg@595	707	JCClassDecl cdef = make.ClassDef(
jjg@595	708	make.Modifiers(STATIC | SYNTHETIC), names.empty,
jjg@595	709	List.<JCTypeParameter>nil(),
jjg@595	710	null, List.<JCExpression>nil(), List.<JCTree>nil());
jjg@595	711	cdef.sym = c;
jjg@595	712	cdef.type = c.type;
jjg@595	713	// add it to the list of classes to be generated
jjg@595	714	translated.append(cdef);
jjg@595	715	}
jjg@595	716	}
jjg@595	717	// where
jjg@595	718	private boolean isTranslatedClassAvailable(ClassSymbol c) {
jjg@595	719	for (JCTree tree: translated) {
jjg@595	720	if (tree.getTag() == JCTree.CLASSDEF
jjg@595	721	&& ((JCClassDecl) tree).sym == c) {
jjg@595	722	return true;
jjg@595	723	}
jjg@595	724	}
jjg@595	725	return false;
jjg@595	726	}
jjg@595	727
duke@1	728	/**************************************************************************
duke@1	729	* Access methods
duke@1	730	*************************************************************************/
duke@1	731
duke@1	732	/** Access codes for dereferencing, assignment,
duke@1	733	* and pre/post increment/decrement.
duke@1	734	* Access codes for assignment operations are determined by method accessCode
duke@1	735	* below.
duke@1	736	*
duke@1	737	* All access codes for accesses to the current class are even.
duke@1	738	* If a member of the superclass should be accessed instead (because
duke@1	739	* access was via a qualified super), add one to the corresponding code
duke@1	740	* for the current class, making the number odd.
duke@1	741	* This numbering scheme is used by the backend to decide whether
duke@1	742	* to issue an invokevirtual or invokespecial call.
duke@1	743	*
duke@1	744	* @see Gen.visitSelect(Select tree)
duke@1	745	*/
duke@1	746	private static final int
duke@1	747	DEREFcode = 0,
duke@1	748	ASSIGNcode = 2,
duke@1	749	PREINCcode = 4,
duke@1	750	PREDECcode = 6,
duke@1	751	POSTINCcode = 8,
duke@1	752	POSTDECcode = 10,
duke@1	753	FIRSTASGOPcode = 12;
duke@1	754
duke@1	755	/** Number of access codes
duke@1	756	*/
duke@1	757	private static final int NCODES = accessCode(ByteCodes.lushrl) + 2;
duke@1	758
duke@1	759	/** A mapping from symbols to their access numbers.
duke@1	760	*/
duke@1	761	private Map<Symbol,Integer> accessNums;
duke@1	762
duke@1	763	/** A mapping from symbols to an array of access symbols, indexed by
duke@1	764	* access code.
duke@1	765	*/
duke@1	766	private Map<Symbol,MethodSymbol[]> accessSyms;
duke@1	767
duke@1	768	/** A mapping from (constructor) symbols to access constructor symbols.
duke@1	769	*/
duke@1	770	private Map<Symbol,MethodSymbol> accessConstrs;
duke@1	771
jjg@595	772	/** A list of all class symbols used for access constructor tags.
jjg@595	773	*/
jjg@595	774	private List<ClassSymbol> accessConstrTags;
jjg@595	775
duke@1	776	/** A queue for all accessed symbols.
duke@1	777	*/
duke@1	778	private ListBuffer<Symbol> accessed;
duke@1	779
duke@1	780	/** Map bytecode of binary operation to access code of corresponding
duke@1	781	* assignment operation. This is always an even number.
duke@1	782	*/
duke@1	783	private static int accessCode(int bytecode) {
duke@1	784	if (ByteCodes.iadd <= bytecode && bytecode <= ByteCodes.lxor)
duke@1	785	return (bytecode - iadd) * 2 + FIRSTASGOPcode;
duke@1	786	else if (bytecode == ByteCodes.string_add)
duke@1	787	return (ByteCodes.lxor + 1 - iadd) * 2 + FIRSTASGOPcode;
duke@1	788	else if (ByteCodes.ishll <= bytecode && bytecode <= ByteCodes.lushrl)
duke@1	789	return (bytecode - ishll + ByteCodes.lxor + 2 - iadd) * 2 + FIRSTASGOPcode;
duke@1	790	else
duke@1	791	return -1;
duke@1	792	}
duke@1	793
duke@1	794	/** return access code for identifier,
duke@1	795	* @param tree The tree representing the identifier use.
duke@1	796	* @param enclOp The closest enclosing operation node of tree,
duke@1	797	* null if tree is not a subtree of an operation.
duke@1	798	*/
duke@1	799	private static int accessCode(JCTree tree, JCTree enclOp) {
duke@1	800	if (enclOp == null)
duke@1	801	return DEREFcode;
duke@1	802	else if (enclOp.getTag() == JCTree.ASSIGN &&
duke@1	803	tree == TreeInfo.skipParens(((JCAssign) enclOp).lhs))
duke@1	804	return ASSIGNcode;
duke@1	805	else if (JCTree.PREINC <= enclOp.getTag() && enclOp.getTag() <= JCTree.POSTDEC &&
duke@1	806	tree == TreeInfo.skipParens(((JCUnary) enclOp).arg))
duke@1	807	return (enclOp.getTag() - JCTree.PREINC) * 2 + PREINCcode;
duke@1	808	else if (JCTree.BITOR_ASG <= enclOp.getTag() && enclOp.getTag() <= JCTree.MOD_ASG &&
duke@1	809	tree == TreeInfo.skipParens(((JCAssignOp) enclOp).lhs))
duke@1	810	return accessCode(((OperatorSymbol) ((JCAssignOp) enclOp).operator).opcode);
duke@1	811	else
duke@1	812	return DEREFcode;
duke@1	813	}
duke@1	814
duke@1	815	/** Return binary operator that corresponds to given access code.
duke@1	816	*/
duke@1	817	private OperatorSymbol binaryAccessOperator(int acode) {
duke@1	818	for (Scope.Entry e = syms.predefClass.members().elems;
duke@1	819	e != null;
duke@1	820	e = e.sibling) {
duke@1	821	if (e.sym instanceof OperatorSymbol) {
duke@1	822	OperatorSymbol op = (OperatorSymbol)e.sym;
duke@1	823	if (accessCode(op.opcode) == acode) return op;
duke@1	824	}
duke@1	825	}
duke@1	826	return null;
duke@1	827	}
duke@1	828
duke@1	829	/** Return tree tag for assignment operation corresponding
duke@1	830	* to given binary operator.
duke@1	831	*/
duke@1	832	private static int treeTag(OperatorSymbol operator) {
duke@1	833	switch (operator.opcode) {
duke@1	834	case ByteCodes.ior: case ByteCodes.lor:
duke@1	835	return JCTree.BITOR_ASG;
duke@1	836	case ByteCodes.ixor: case ByteCodes.lxor:
duke@1	837	return JCTree.BITXOR_ASG;
duke@1	838	case ByteCodes.iand: case ByteCodes.land:
duke@1	839	return JCTree.BITAND_ASG;
duke@1	840	case ByteCodes.ishl: case ByteCodes.lshl:
duke@1	841	case ByteCodes.ishll: case ByteCodes.lshll:
duke@1	842	return JCTree.SL_ASG;
duke@1	843	case ByteCodes.ishr: case ByteCodes.lshr:
duke@1	844	case ByteCodes.ishrl: case ByteCodes.lshrl:
duke@1	845	return JCTree.SR_ASG;
duke@1	846	case ByteCodes.iushr: case ByteCodes.lushr:
duke@1	847	case ByteCodes.iushrl: case ByteCodes.lushrl:
duke@1	848	return JCTree.USR_ASG;
duke@1	849	case ByteCodes.iadd: case ByteCodes.ladd:
duke@1	850	case ByteCodes.fadd: case ByteCodes.dadd:
duke@1	851	case ByteCodes.string_add:
duke@1	852	return JCTree.PLUS_ASG;
duke@1	853	case ByteCodes.isub: case ByteCodes.lsub:
duke@1	854	case ByteCodes.fsub: case ByteCodes.dsub:
duke@1	855	return JCTree.MINUS_ASG;
duke@1	856	case ByteCodes.imul: case ByteCodes.lmul:
duke@1	857	case ByteCodes.fmul: case ByteCodes.dmul:
duke@1	858	return JCTree.MUL_ASG;
duke@1	859	case ByteCodes.idiv: case ByteCodes.ldiv:
duke@1	860	case ByteCodes.fdiv: case ByteCodes.ddiv:
duke@1	861	return JCTree.DIV_ASG;
duke@1	862	case ByteCodes.imod: case ByteCodes.lmod:
duke@1	863	case ByteCodes.fmod: case ByteCodes.dmod:
duke@1	864	return JCTree.MOD_ASG;
duke@1	865	default:
duke@1	866	throw new AssertionError();
duke@1	867	}
duke@1	868	}
duke@1	869
duke@1	870	/** The name of the access method with number `anum' and access code `acode'.
duke@1	871	*/
duke@1	872	Name accessName(int anum, int acode) {
duke@1	873	return names.fromString(
duke@1	874	"access" + target.syntheticNameChar() + anum + acode / 10 + acode % 10);
duke@1	875	}
duke@1	876
duke@1	877	/** Return access symbol for a private or protected symbol from an inner class.
duke@1	878	* @param sym The accessed private symbol.
duke@1	879	* @param tree The accessing tree.
duke@1	880	* @param enclOp The closest enclosing operation node of tree,
duke@1	881	* null if tree is not a subtree of an operation.
duke@1	882	* @param protAccess Is access to a protected symbol in another
duke@1	883	* package?
duke@1	884	* @param refSuper Is access via a (qualified) C.super?
duke@1	885	*/
duke@1	886	MethodSymbol accessSymbol(Symbol sym, JCTree tree, JCTree enclOp,
duke@1	887	boolean protAccess, boolean refSuper) {
duke@1	888	ClassSymbol accOwner = refSuper && protAccess
duke@1	889	// For access via qualified super (T.super.x), place the
duke@1	890	// access symbol on T.
duke@1	891	? (ClassSymbol)((JCFieldAccess) tree).selected.type.tsym
duke@1	892	// Otherwise pretend that the owner of an accessed
duke@1	893	// protected symbol is the enclosing class of the current
duke@1	894	// class which is a subclass of the symbol's owner.
duke@1	895	: accessClass(sym, protAccess, tree);
duke@1	896
duke@1	897	Symbol vsym = sym;
duke@1	898	if (sym.owner != accOwner) {
duke@1	899	vsym = sym.clone(accOwner);
duke@1	900	actualSymbols.put(vsym, sym);
duke@1	901	}
duke@1	902
duke@1	903	Integer anum // The access number of the access method.
duke@1	904	= accessNums.get(vsym);
duke@1	905	if (anum == null) {
duke@1	906	anum = accessed.length();
duke@1	907	accessNums.put(vsym, anum);
duke@1	908	accessSyms.put(vsym, new MethodSymbol[NCODES]);
duke@1	909	accessed.append(vsym);
duke@1	910	// System.out.println("accessing " + vsym + " in " + vsym.location());
duke@1	911	}
duke@1	912
duke@1	913	int acode; // The access code of the access method.
duke@1	914	List<Type> argtypes; // The argument types of the access method.
duke@1	915	Type restype; // The result type of the access method.
darcy@430	916	List<Type> thrown; // The thrown exceptions of the access method.
duke@1	917	switch (vsym.kind) {
duke@1	918	case VAR:
duke@1	919	acode = accessCode(tree, enclOp);
duke@1	920	if (acode >= FIRSTASGOPcode) {
duke@1	921	OperatorSymbol operator = binaryAccessOperator(acode);
duke@1	922	if (operator.opcode == string_add)
duke@1	923	argtypes = List.of(syms.objectType);
duke@1	924	else
duke@1	925	argtypes = operator.type.getParameterTypes().tail;
duke@1	926	} else if (acode == ASSIGNcode)
duke@1	927	argtypes = List.of(vsym.erasure(types));
duke@1	928	else
duke@1	929	argtypes = List.nil();
duke@1	930	restype = vsym.erasure(types);
duke@1	931	thrown = List.nil();
duke@1	932	break;
duke@1	933	case MTH:
duke@1	934	acode = DEREFcode;
duke@1	935	argtypes = vsym.erasure(types).getParameterTypes();
duke@1	936	restype = vsym.erasure(types).getReturnType();
duke@1	937	thrown = vsym.type.getThrownTypes();
duke@1	938	break;
duke@1	939	default:
duke@1	940	throw new AssertionError();
duke@1	941	}
duke@1	942
duke@1	943	// For references via qualified super, increment acode by one,
duke@1	944	// making it odd.
duke@1	945	if (protAccess && refSuper) acode++;
duke@1	946
duke@1	947	// Instance access methods get instance as first parameter.
duke@1	948	// For protected symbols this needs to be the instance as a member
duke@1	949	// of the type containing the accessed symbol, not the class
duke@1	950	// containing the access method.
duke@1	951	if ((vsym.flags() & STATIC) == 0) {
duke@1	952	argtypes = argtypes.prepend(vsym.owner.erasure(types));
duke@1	953	}
duke@1	954	MethodSymbol[] accessors = accessSyms.get(vsym);
duke@1	955	MethodSymbol accessor = accessors[acode];
duke@1	956	if (accessor == null) {
duke@1	957	accessor = new MethodSymbol(
duke@1	958	STATIC | SYNTHETIC,
duke@1	959	accessName(anum.intValue(), acode),
duke@1	960	new MethodType(argtypes, restype, thrown, syms.methodClass),
duke@1	961	accOwner);
duke@1	962	enterSynthetic(tree.pos(), accessor, accOwner.members());
duke@1	963	accessors[acode] = accessor;
duke@1	964	}
duke@1	965	return accessor;
duke@1	966	}
duke@1	967
duke@1	968	/** The qualifier to be used for accessing a symbol in an outer class.
duke@1	969	* This is either C.sym or C.this.sym, depending on whether or not
duke@1	970	* sym is static.
duke@1	971	* @param sym The accessed symbol.
duke@1	972	*/
duke@1	973	JCExpression accessBase(DiagnosticPosition pos, Symbol sym) {
duke@1	974	return (sym.flags() & STATIC) != 0
duke@1	975	? access(make.at(pos.getStartPosition()).QualIdent(sym.owner))
duke@1	976	: makeOwnerThis(pos, sym, true);
duke@1	977	}
duke@1	978
duke@1	979	/** Do we need an access method to reference private symbol?
duke@1	980	*/
duke@1	981	boolean needsPrivateAccess(Symbol sym) {
duke@1	982	if ((sym.flags() & PRIVATE) == 0 || sym.owner == currentClass) {
duke@1	983	return false;
duke@1	984	} else if (sym.name == names.init && (sym.owner.owner.kind & (VAR | MTH)) != 0) {
duke@1	985	// private constructor in local class: relax protection
duke@1	986	sym.flags_field &= ~PRIVATE;
duke@1	987	return false;
duke@1	988	} else {
duke@1	989	return true;
duke@1	990	}
duke@1	991	}
duke@1	992
duke@1	993	/** Do we need an access method to reference symbol in other package?
duke@1	994	*/
duke@1	995	boolean needsProtectedAccess(Symbol sym, JCTree tree) {
duke@1	996	if ((sym.flags() & PROTECTED) == 0 ||
duke@1	997	sym.owner.owner == currentClass.owner || // fast special case
duke@1	998	sym.packge() == currentClass.packge())
duke@1	999	return false;
duke@1	1000	if (!currentClass.isSubClass(sym.owner, types))
duke@1	1001	return true;
duke@1	1002	if ((sym.flags() & STATIC) != 0 ||
duke@1	1003	tree.getTag() != JCTree.SELECT ||
duke@1	1004	TreeInfo.name(((JCFieldAccess) tree).selected) == names._super)
duke@1	1005	return false;
duke@1	1006	return !((JCFieldAccess) tree).selected.type.tsym.isSubClass(currentClass, types);
duke@1	1007	}
duke@1	1008
duke@1	1009	/** The class in which an access method for given symbol goes.
duke@1	1010	* @param sym The access symbol
duke@1	1011	* @param protAccess Is access to a protected symbol in another
duke@1	1012	* package?
duke@1	1013	*/
duke@1	1014	ClassSymbol accessClass(Symbol sym, boolean protAccess, JCTree tree) {
duke@1	1015	if (protAccess) {
duke@1	1016	Symbol qualifier = null;
duke@1	1017	ClassSymbol c = currentClass;
duke@1	1018	if (tree.getTag() == JCTree.SELECT && (sym.flags() & STATIC) == 0) {
duke@1	1019	qualifier = ((JCFieldAccess) tree).selected.type.tsym;
duke@1	1020	while (!qualifier.isSubClass(c, types)) {
duke@1	1021	c = c.owner.enclClass();
duke@1	1022	}
duke@1	1023	return c;
duke@1	1024	} else {
duke@1	1025	while (!c.isSubClass(sym.owner, types)) {
duke@1	1026	c = c.owner.enclClass();
duke@1	1027	}
duke@1	1028	}
duke@1	1029	return c;
duke@1	1030	} else {
duke@1	1031	// the symbol is private
duke@1	1032	return sym.owner.enclClass();
duke@1	1033	}
duke@1	1034	}
duke@1	1035
duke@1	1036	/** Ensure that identifier is accessible, return tree accessing the identifier.
duke@1	1037	* @param sym The accessed symbol.
duke@1	1038	* @param tree The tree referring to the symbol.
duke@1	1039	* @param enclOp The closest enclosing operation node of tree,
duke@1	1040	* null if tree is not a subtree of an operation.
duke@1	1041	* @param refSuper Is access via a (qualified) C.super?
duke@1	1042	*/
duke@1	1043	JCExpression access(Symbol sym, JCExpression tree, JCExpression enclOp, boolean refSuper) {
duke@1	1044	// Access a free variable via its proxy, or its proxy's proxy
duke@1	1045	while (sym.kind == VAR && sym.owner.kind == MTH &&
duke@1	1046	sym.owner.enclClass() != currentClass) {
duke@1	1047	// A constant is replaced by its constant value.
duke@1	1048	Object cv = ((VarSymbol)sym).getConstValue();
duke@1	1049	if (cv != null) {
duke@1	1050	make.at(tree.pos);
duke@1	1051	return makeLit(sym.type, cv);
duke@1	1052	}
duke@1	1053	// Otherwise replace the variable by its proxy.
duke@1	1054	sym = proxies.lookup(proxyName(sym.name)).sym;
duke@1	1055	assert sym != null && (sym.flags_field & FINAL) != 0;
duke@1	1056	tree = make.at(tree.pos).Ident(sym);
duke@1	1057	}
duke@1	1058	JCExpression base = (tree.getTag() == JCTree.SELECT) ? ((JCFieldAccess) tree).selected : null;
duke@1	1059	switch (sym.kind) {
duke@1	1060	case TYP:
duke@1	1061	if (sym.owner.kind != PCK) {
duke@1	1062	// Convert type idents to
duke@1	1063	// <flat name> or <package name> . <flat name>
duke@1	1064	Name flatname = Convert.shortName(sym.flatName());
duke@1	1065	while (base != null &&
duke@1	1066	TreeInfo.symbol(base) != null &&
duke@1	1067	TreeInfo.symbol(base).kind != PCK) {
duke@1	1068	base = (base.getTag() == JCTree.SELECT)
duke@1	1069	? ((JCFieldAccess) base).selected
duke@1	1070	: null;
duke@1	1071	}
duke@1	1072	if (tree.getTag() == JCTree.IDENT) {
duke@1	1073	((JCIdent) tree).name = flatname;
duke@1	1074	} else if (base == null) {
duke@1	1075	tree = make.at(tree.pos).Ident(sym);
duke@1	1076	((JCIdent) tree).name = flatname;
duke@1	1077	} else {
duke@1	1078	((JCFieldAccess) tree).selected = base;
duke@1	1079	((JCFieldAccess) tree).name = flatname;
duke@1	1080	}
duke@1	1081	}
duke@1	1082	break;
duke@1	1083	case MTH: case VAR:
duke@1	1084	if (sym.owner.kind == TYP) {
duke@1	1085
duke@1	1086	// Access methods are required for
duke@1	1087	// - private members,
duke@1	1088	// - protected members in a superclass of an
duke@1	1089	// enclosing class contained in another package.
duke@1	1090	// - all non-private members accessed via a qualified super.
duke@1	1091	boolean protAccess = refSuper && !needsPrivateAccess(sym)
duke@1	1092	|| needsProtectedAccess(sym, tree);
duke@1	1093	boolean accReq = protAccess || needsPrivateAccess(sym);
duke@1	1094
duke@1	1095	// A base has to be supplied for
duke@1	1096	// - simple identifiers accessing variables in outer classes.
duke@1	1097	boolean baseReq =
duke@1	1098	base == null &&
duke@1	1099	sym.owner != syms.predefClass &&
duke@1	1100	!sym.isMemberOf(currentClass, types);
duke@1	1101
duke@1	1102	if (accReq || baseReq) {
duke@1	1103	make.at(tree.pos);
duke@1	1104
duke@1	1105	// Constants are replaced by their constant value.
duke@1	1106	if (sym.kind == VAR) {
duke@1	1107	Object cv = ((VarSymbol)sym).getConstValue();
duke@1	1108	if (cv != null) return makeLit(sym.type, cv);
duke@1	1109	}
duke@1	1110
duke@1	1111	// Private variables and methods are replaced by calls
duke@1	1112	// to their access methods.
duke@1	1113	if (accReq) {
duke@1	1114	List<JCExpression> args = List.nil();
duke@1	1115	if ((sym.flags() & STATIC) == 0) {
duke@1	1116	// Instance access methods get instance
duke@1	1117	// as first parameter.
duke@1	1118	if (base == null)
duke@1	1119	base = makeOwnerThis(tree.pos(), sym, true);
duke@1	1120	args = args.prepend(base);
duke@1	1121	base = null; // so we don't duplicate code
duke@1	1122	}
duke@1	1123	Symbol access = accessSymbol(sym, tree,
duke@1	1124	enclOp, protAccess,
duke@1	1125	refSuper);
duke@1	1126	JCExpression receiver = make.Select(
duke@1	1127	base != null ? base : make.QualIdent(access.owner),
duke@1	1128	access);
duke@1	1129	return make.App(receiver, args);
duke@1	1130
duke@1	1131	// Other accesses to members of outer classes get a
duke@1	1132	// qualifier.
duke@1	1133	} else if (baseReq) {
duke@1	1134	return make.at(tree.pos).Select(
duke@1	1135	accessBase(tree.pos(), sym), sym).setType(tree.type);
duke@1	1136	}
duke@1	1137	}
duke@1	1138	}
duke@1	1139	}
duke@1	1140	return tree;
duke@1	1141	}
duke@1	1142
duke@1	1143	/** Ensure that identifier is accessible, return tree accessing the identifier.
duke@1	1144	* @param tree The identifier tree.
duke@1	1145	*/
duke@1	1146	JCExpression access(JCExpression tree) {
duke@1	1147	Symbol sym = TreeInfo.symbol(tree);
duke@1	1148	return sym == null ? tree : access(sym, tree, null, false);
duke@1	1149	}
duke@1	1150
duke@1	1151	/** Return access constructor for a private constructor,
duke@1	1152	* or the constructor itself, if no access constructor is needed.
duke@1	1153	* @param pos The position to report diagnostics, if any.
duke@1	1154	* @param constr The private constructor.
duke@1	1155	*/
duke@1	1156	Symbol accessConstructor(DiagnosticPosition pos, Symbol constr) {
duke@1	1157	if (needsPrivateAccess(constr)) {
duke@1	1158	ClassSymbol accOwner = constr.owner.enclClass();
duke@1	1159	MethodSymbol aconstr = accessConstrs.get(constr);
duke@1	1160	if (aconstr == null) {
duke@1	1161	List<Type> argtypes = constr.type.getParameterTypes();
duke@1	1162	if ((accOwner.flags_field & ENUM) != 0)
duke@1	1163	argtypes = argtypes
duke@1	1164	.prepend(syms.intType)
duke@1	1165	.prepend(syms.stringType);
duke@1	1166	aconstr = new MethodSymbol(
duke@1	1167	SYNTHETIC,
duke@1	1168	names.init,
duke@1	1169	new MethodType(
duke@1	1170	argtypes.append(
duke@1	1171	accessConstructorTag().erasure(types)),
duke@1	1172	constr.type.getReturnType(),
duke@1	1173	constr.type.getThrownTypes(),
duke@1	1174	syms.methodClass),
duke@1	1175	accOwner);
duke@1	1176	enterSynthetic(pos, aconstr, accOwner.members());
duke@1	1177	accessConstrs.put(constr, aconstr);
duke@1	1178	accessed.append(constr);
duke@1	1179	}
duke@1	1180	return aconstr;
duke@1	1181	} else {
duke@1	1182	return constr;
duke@1	1183	}
duke@1	1184	}
duke@1	1185
duke@1	1186	/** Return an anonymous class nested in this toplevel class.
duke@1	1187	*/
duke@1	1188	ClassSymbol accessConstructorTag() {
duke@1	1189	ClassSymbol topClass = currentClass.outermostClass();
duke@1	1190	Name flatname = names.fromString("" + topClass.getQualifiedName() +
duke@1	1191	target.syntheticNameChar() +
duke@1	1192	"1");
duke@1	1193	ClassSymbol ctag = chk.compiled.get(flatname);
duke@1	1194	if (ctag == null)
duke@1	1195	ctag = makeEmptyClass(STATIC | SYNTHETIC, topClass);
jjg@595	1196	// keep a record of all tags, to verify that all are generated as required
jjg@595	1197	accessConstrTags = accessConstrTags.prepend(ctag);
duke@1	1198	return ctag;
duke@1	1199	}
duke@1	1200
duke@1	1201	/** Add all required access methods for a private symbol to enclosing class.
duke@1	1202	* @param sym The symbol.
duke@1	1203	*/
duke@1	1204	void makeAccessible(Symbol sym) {
duke@1	1205	JCClassDecl cdef = classDef(sym.owner.enclClass());
duke@1	1206	assert cdef != null : "class def not found: " + sym + " in " + sym.owner;
duke@1	1207	if (sym.name == names.init) {
duke@1	1208	cdef.defs = cdef.defs.prepend(
duke@1	1209	accessConstructorDef(cdef.pos, sym, accessConstrs.get(sym)));
duke@1	1210	} else {
duke@1	1211	MethodSymbol[] accessors = accessSyms.get(sym);
duke@1	1212	for (int i = 0; i < NCODES; i++) {
duke@1	1213	if (accessors[i] != null)
duke@1	1214	cdef.defs = cdef.defs.prepend(
duke@1	1215	accessDef(cdef.pos, sym, accessors[i], i));
duke@1	1216	}
duke@1	1217	}
duke@1	1218	}
duke@1	1219
duke@1	1220	/** Construct definition of an access method.
duke@1	1221	* @param pos The source code position of the definition.
duke@1	1222	* @param vsym The private or protected symbol.
duke@1	1223	* @param accessor The access method for the symbol.
duke@1	1224	* @param acode The access code.
duke@1	1225	*/
duke@1	1226	JCTree accessDef(int pos, Symbol vsym, MethodSymbol accessor, int acode) {
duke@1	1227	// System.err.println("access " + vsym + " with " + accessor);//DEBUG
duke@1	1228	currentClass = vsym.owner.enclClass();
duke@1	1229	make.at(pos);
duke@1	1230	JCMethodDecl md = make.MethodDef(accessor, null);
duke@1	1231
duke@1	1232	// Find actual symbol
duke@1	1233	Symbol sym = actualSymbols.get(vsym);
duke@1	1234	if (sym == null) sym = vsym;
duke@1	1235
duke@1	1236	JCExpression ref; // The tree referencing the private symbol.
duke@1	1237	List<JCExpression> args; // Any additional arguments to be passed along.
duke@1	1238	if ((sym.flags() & STATIC) != 0) {
duke@1	1239	ref = make.Ident(sym);
duke@1	1240	args = make.Idents(md.params);
duke@1	1241	} else {
duke@1	1242	ref = make.Select(make.Ident(md.params.head), sym);
duke@1	1243	args = make.Idents(md.params.tail);
duke@1	1244	}
duke@1	1245	JCStatement stat; // The statement accessing the private symbol.
duke@1	1246	if (sym.kind == VAR) {
duke@1	1247	// Normalize out all odd access codes by taking floor modulo 2:
duke@1	1248	int acode1 = acode - (acode & 1);
duke@1	1249
duke@1	1250	JCExpression expr; // The access method's return value.
duke@1	1251	switch (acode1) {
duke@1	1252	case DEREFcode:
duke@1	1253	expr = ref;
duke@1	1254	break;
duke@1	1255	case ASSIGNcode:
duke@1	1256	expr = make.Assign(ref, args.head);
duke@1	1257	break;
duke@1	1258	case PREINCcode: case POSTINCcode: case PREDECcode: case POSTDECcode:
duke@1	1259	expr = makeUnary(
duke@1	1260	((acode1 - PREINCcode) >> 1) + JCTree.PREINC, ref);
duke@1	1261	break;
duke@1	1262	default:
duke@1	1263	expr = make.Assignop(
duke@1	1264	treeTag(binaryAccessOperator(acode1)), ref, args.head);
duke@1	1265	((JCAssignOp) expr).operator = binaryAccessOperator(acode1);
duke@1	1266	}
duke@1	1267	stat = make.Return(expr.setType(sym.type));
duke@1	1268	} else {
duke@1	1269	stat = make.Call(make.App(ref, args));
duke@1	1270	}
duke@1	1271	md.body = make.Block(0, List.of(stat));
duke@1	1272
duke@1	1273	// Make sure all parameters, result types and thrown exceptions
duke@1	1274	// are accessible.
duke@1	1275	for (List<JCVariableDecl> l = md.params; l.nonEmpty(); l = l.tail)
duke@1	1276	l.head.vartype = access(l.head.vartype);
duke@1	1277	md.restype = access(md.restype);
duke@1	1278	for (List<JCExpression> l = md.thrown; l.nonEmpty(); l = l.tail)
duke@1	1279	l.head = access(l.head);
duke@1	1280
duke@1	1281	return md;
duke@1	1282	}
duke@1	1283
duke@1	1284	/** Construct definition of an access constructor.
duke@1	1285	* @param pos The source code position of the definition.
duke@1	1286	* @param constr The private constructor.
duke@1	1287	* @param accessor The access method for the constructor.
duke@1	1288	*/
duke@1	1289	JCTree accessConstructorDef(int pos, Symbol constr, MethodSymbol accessor) {
duke@1	1290	make.at(pos);
duke@1	1291	JCMethodDecl md = make.MethodDef(accessor,
duke@1	1292	accessor.externalType(types),
duke@1	1293	null);
duke@1	1294	JCIdent callee = make.Ident(names._this);
duke@1	1295	callee.sym = constr;
duke@1	1296	callee.type = constr.type;
duke@1	1297	md.body =
duke@1	1298	make.Block(0, List.<JCStatement>of(
duke@1	1299	make.Call(
duke@1	1300	make.App(
duke@1	1301	callee,
duke@1	1302	make.Idents(md.params.reverse().tail.reverse())))));
duke@1	1303	return md;
duke@1	1304	}
duke@1	1305
duke@1	1306	/**************************************************************************
duke@1	1307	* Free variables proxies and this$n
duke@1	1308	*************************************************************************/
duke@1	1309
duke@1	1310	/** A scope containing all free variable proxies for currently translated
duke@1	1311	* class, as well as its this$n symbol (if needed).
duke@1	1312	* Proxy scopes are nested in the same way classes are.
duke@1	1313	* Inside a constructor, proxies and any this$n symbol are duplicated
duke@1	1314	* in an additional innermost scope, where they represent the constructor
duke@1	1315	* parameters.
duke@1	1316	*/
duke@1	1317	Scope proxies;
duke@1	1318
darcy@609	1319	/** A scope containing all unnamed resource variables/saved
darcy@609	1320	* exception variables for translated TWR blocks
darcy@609	1321	*/
darcy@609	1322	Scope twrVars;
darcy@609	1323
duke@1	1324	/** A stack containing the this$n field of the currently translated
duke@1	1325	* classes (if needed) in innermost first order.
duke@1	1326	* Inside a constructor, proxies and any this$n symbol are duplicated
duke@1	1327	* in an additional innermost scope, where they represent the constructor
duke@1	1328	* parameters.
duke@1	1329	*/
duke@1	1330	List<VarSymbol> outerThisStack;
duke@1	1331
duke@1	1332	/** The name of a free variable proxy.
duke@1	1333	*/
duke@1	1334	Name proxyName(Name name) {
duke@1	1335	return names.fromString("val" + target.syntheticNameChar() + name);
duke@1	1336	}
duke@1	1337
duke@1	1338	/** Proxy definitions for all free variables in given list, in reverse order.
duke@1	1339	* @param pos The source code position of the definition.
duke@1	1340	* @param freevars The free variables.
duke@1	1341	* @param owner The class in which the definitions go.
duke@1	1342	*/
duke@1	1343	List<JCVariableDecl> freevarDefs(int pos, List<VarSymbol> freevars, Symbol owner) {
duke@1	1344	long flags = FINAL | SYNTHETIC;
duke@1	1345	if (owner.kind == TYP &&
duke@1	1346	target.usePrivateSyntheticFields())
duke@1	1347	flags |= PRIVATE;
duke@1	1348	List<JCVariableDecl> defs = List.nil();
duke@1	1349	for (List<VarSymbol> l = freevars; l.nonEmpty(); l = l.tail) {
duke@1	1350	VarSymbol v = l.head;
duke@1	1351	VarSymbol proxy = new VarSymbol(
duke@1	1352	flags, proxyName(v.name), v.erasure(types), owner);
duke@1	1353	proxies.enter(proxy);
duke@1	1354	JCVariableDecl vd = make.at(pos).VarDef(proxy, null);
duke@1	1355	vd.vartype = access(vd.vartype);
duke@1	1356	defs = defs.prepend(vd);
duke@1	1357	}
duke@1	1358	return defs;
duke@1	1359	}
duke@1	1360
duke@1	1361	/** The name of a this$n field
duke@1	1362	* @param type The class referenced by the this$n field
duke@1	1363	*/
duke@1	1364	Name outerThisName(Type type, Symbol owner) {
duke@1	1365	Type t = type.getEnclosingType();
duke@1	1366	int nestingLevel = 0;
duke@1	1367	while (t.tag == CLASS) {
duke@1	1368	t = t.getEnclosingType();
duke@1	1369	nestingLevel++;
duke@1	1370	}
duke@1	1371	Name result = names.fromString("this" + target.syntheticNameChar() + nestingLevel);
duke@1	1372	while (owner.kind == TYP && ((ClassSymbol)owner).members().lookup(result).scope != null)
duke@1	1373	result = names.fromString(result.toString() + target.syntheticNameChar());
duke@1	1374	return result;
duke@1	1375	}
duke@1	1376
duke@1	1377	/** Definition for this$n field.
duke@1	1378	* @param pos The source code position of the definition.
duke@1	1379	* @param owner The class in which the definition goes.
duke@1	1380	*/
duke@1	1381	JCVariableDecl outerThisDef(int pos, Symbol owner) {
duke@1	1382	long flags = FINAL | SYNTHETIC;
duke@1	1383	if (owner.kind == TYP &&
duke@1	1384	target.usePrivateSyntheticFields())
duke@1	1385	flags |= PRIVATE;
duke@1	1386	Type target = types.erasure(owner.enclClass().type.getEnclosingType());
duke@1	1387	VarSymbol outerThis = new VarSymbol(
duke@1	1388	flags, outerThisName(target, owner), target, owner);
duke@1	1389	outerThisStack = outerThisStack.prepend(outerThis);
duke@1	1390	JCVariableDecl vd = make.at(pos).VarDef(outerThis, null);
duke@1	1391	vd.vartype = access(vd.vartype);
duke@1	1392	return vd;
duke@1	1393	}
duke@1	1394
duke@1	1395	/** Return a list of trees that load the free variables in given list,
duke@1	1396	* in reverse order.
duke@1	1397	* @param pos The source code position to be used for the trees.
duke@1	1398	* @param freevars The list of free variables.
duke@1	1399	*/
duke@1	1400	List<JCExpression> loadFreevars(DiagnosticPosition pos, List<VarSymbol> freevars) {
duke@1	1401	List<JCExpression> args = List.nil();
duke@1	1402	for (List<VarSymbol> l = freevars; l.nonEmpty(); l = l.tail)
duke@1	1403	args = args.prepend(loadFreevar(pos, l.head));
duke@1	1404	return args;
duke@1	1405	}
duke@1	1406	//where
duke@1	1407	JCExpression loadFreevar(DiagnosticPosition pos, VarSymbol v) {
duke@1	1408	return access(v, make.at(pos).Ident(v), null, false);
duke@1	1409	}
duke@1	1410
duke@1	1411	/** Construct a tree simulating the expression <C.this>.
duke@1	1412	* @param pos The source code position to be used for the tree.
duke@1	1413	* @param c The qualifier class.
duke@1	1414	*/
duke@1	1415	JCExpression makeThis(DiagnosticPosition pos, TypeSymbol c) {
duke@1	1416	if (currentClass == c) {
duke@1	1417	// in this case, `this' works fine
duke@1	1418	return make.at(pos).This(c.erasure(types));
duke@1	1419	} else {
duke@1	1420	// need to go via this$n
duke@1	1421	return makeOuterThis(pos, c);
duke@1	1422	}
duke@1	1423	}
duke@1	1424
darcy@609	1425	/** Optionally replace a try statement with an automatic resource
darcy@609	1426	* management (ARM) block.
darcy@609	1427	* @param tree The try statement to inspect.
darcy@609	1428	* @return An ARM block, or the original try block if there are no
darcy@609	1429	* resources to manage.
darcy@609	1430	*/
darcy@609	1431	JCTree makeArmTry(JCTry tree) {
darcy@609	1432	make_at(tree.pos());
darcy@609	1433	twrVars = twrVars.dup();
darcy@609	1434	JCBlock armBlock = makeArmBlock(tree.resources, tree.body, 0);
darcy@609	1435	if (tree.catchers.isEmpty() && tree.finalizer == null)
darcy@609	1436	result = translate(armBlock);
darcy@609	1437	else
darcy@609	1438	result = translate(make.Try(armBlock, tree.catchers, tree.finalizer));
darcy@609	1439	twrVars = twrVars.leave();
darcy@609	1440	return result;
darcy@609	1441	}
darcy@609	1442
darcy@609	1443	private JCBlock makeArmBlock(List<JCTree> resources, JCBlock block, int depth) {
darcy@609	1444	if (resources.isEmpty())
darcy@609	1445	return block;
darcy@609	1446
darcy@609	1447	// Add resource declaration or expression to block statements
darcy@609	1448	ListBuffer<JCStatement> stats = new ListBuffer<JCStatement>();
darcy@609	1449	JCTree resource = resources.head;
darcy@609	1450	JCExpression expr = null;
darcy@609	1451	if (resource instanceof JCVariableDecl) {
darcy@609	1452	JCVariableDecl var = (JCVariableDecl) resource;
darcy@609	1453	expr = make.Ident(var.sym).setType(resource.type);
darcy@609	1454	stats.add(var);
darcy@609	1455	} else {
darcy@609	1456	assert resource instanceof JCExpression;
darcy@609	1457	VarSymbol syntheticTwrVar =
darcy@609	1458	new VarSymbol(SYNTHETIC | FINAL,
darcy@609	1459	makeSyntheticName(names.fromString("twrVar" +
darcy@609	1460	depth), twrVars),
darcy@609	1461	(resource.type.tag == TypeTags.BOT) ?
darcy@609	1462	syms.autoCloseableType : resource.type,
darcy@609	1463	currentMethodSym);
darcy@609	1464	twrVars.enter(syntheticTwrVar);
darcy@609	1465	JCVariableDecl syntheticTwrVarDecl =
darcy@609	1466	make.VarDef(syntheticTwrVar, (JCExpression)resource);
darcy@609	1467	expr = (JCExpression)make.Ident(syntheticTwrVar);
darcy@609	1468	stats.add(syntheticTwrVarDecl);
darcy@609	1469	}
darcy@609	1470
darcy@609	1471	// Add primaryException declaration
darcy@609	1472	VarSymbol primaryException =
darcy@609	1473	new VarSymbol(SYNTHETIC,
darcy@609	1474	makeSyntheticName(names.fromString("primaryException" +
darcy@609	1475	depth), twrVars),
darcy@609	1476	syms.throwableType,
darcy@609	1477	currentMethodSym);
darcy@609	1478	twrVars.enter(primaryException);
darcy@609	1479	JCVariableDecl primaryExceptionTreeDecl = make.VarDef(primaryException, makeNull());
darcy@609	1480	stats.add(primaryExceptionTreeDecl);
darcy@609	1481
darcy@609	1482	// Create catch clause that saves exception and then rethrows it
darcy@609	1483	VarSymbol param =
darcy@609	1484	new VarSymbol(FINAL|SYNTHETIC,
darcy@609	1485	names.fromString("t" +
darcy@609	1486	target.syntheticNameChar()),
darcy@609	1487	syms.throwableType,
darcy@609	1488	currentMethodSym);
darcy@609	1489	JCVariableDecl paramTree = make.VarDef(param, null);
darcy@609	1490	JCStatement assign = make.Assignment(primaryException, make.Ident(param));
darcy@609	1491	JCStatement rethrowStat = make.Throw(make.Ident(param));
darcy@609	1492	JCBlock catchBlock = make.Block(0L, List.<JCStatement>of(assign, rethrowStat));
darcy@609	1493	JCCatch catchClause = make.Catch(paramTree, catchBlock);
darcy@609	1494
darcy@609	1495	int oldPos = make.pos;
darcy@609	1496	make.at(TreeInfo.endPos(block));
darcy@609	1497	JCBlock finallyClause = makeArmFinallyClause(primaryException, expr);
darcy@609	1498	make.at(oldPos);
darcy@609	1499	JCTry outerTry = make.Try(makeArmBlock(resources.tail, block, depth + 1),
darcy@609	1500	List.<JCCatch>of(catchClause),
darcy@609	1501	finallyClause);
darcy@609	1502	stats.add(outerTry);
darcy@609	1503	return make.Block(0L, stats.toList());
darcy@609	1504	}
darcy@609	1505
darcy@609	1506	private JCBlock makeArmFinallyClause(Symbol primaryException, JCExpression resource) {
darcy@609	1507	// primaryException.addSuppressedException(catchException);
darcy@609	1508	VarSymbol catchException =
darcy@609	1509	new VarSymbol(0, make.paramName(2),
darcy@609	1510	syms.throwableType,
darcy@609	1511	currentMethodSym);
darcy@609	1512	JCStatement addSuppressionStatement =
darcy@609	1513	make.Exec(makeCall(make.Ident(primaryException),
darcy@609	1514	names.fromString("addSuppressedException"),
darcy@609	1515	List.<JCExpression>of(make.Ident(catchException))));
darcy@609	1516
darcy@609	1517	// try { resource.close(); } catch (e) { primaryException.addSuppressedException(e); }
darcy@609	1518	JCBlock tryBlock =
darcy@609	1519	make.Block(0L, List.<JCStatement>of(makeResourceCloseInvocation(resource)));
darcy@609	1520	JCVariableDecl catchExceptionDecl = make.VarDef(catchException, null);
darcy@609	1521	JCBlock catchBlock = make.Block(0L, List.<JCStatement>of(addSuppressionStatement));
darcy@609	1522	List<JCCatch> catchClauses = List.<JCCatch>of(make.Catch(catchExceptionDecl, catchBlock));
darcy@609	1523	JCTry tryTree = make.Try(tryBlock, catchClauses, null);
darcy@609	1524
darcy@609	1525	// if (resource != null) resourceClose;
darcy@609	1526	JCExpression nullCheck = makeBinary(JCTree.NE,
darcy@609	1527	make.Ident(primaryException),
darcy@609	1528	makeNull());
darcy@609	1529	JCIf closeIfStatement = make.If(nullCheck,
darcy@609	1530	tryTree,
darcy@609	1531	makeResourceCloseInvocation(resource));
darcy@609	1532	return make.Block(0L, List.<JCStatement>of(closeIfStatement));
darcy@609	1533	}
darcy@609	1534
darcy@609	1535	private JCStatement makeResourceCloseInvocation(JCExpression resource) {
darcy@609	1536	// create resource.close() method invocation
darcy@609	1537	JCExpression resourceClose = makeCall(resource, names.close, List.<JCExpression>nil());
darcy@609	1538	return make.Exec(resourceClose);
darcy@609	1539	}
darcy@609	1540
duke@1	1541	/** Construct a tree that represents the outer instance
duke@1	1542	* <C.this>. Never pick the current `this'.
duke@1	1543	* @param pos The source code position to be used for the tree.
duke@1	1544	* @param c The qualifier class.
duke@1	1545	*/
duke@1	1546	JCExpression makeOuterThis(DiagnosticPosition pos, TypeSymbol c) {
duke@1	1547	List<VarSymbol> ots = outerThisStack;
duke@1	1548	if (ots.isEmpty()) {
duke@1	1549	log.error(pos, "no.encl.instance.of.type.in.scope", c);
duke@1	1550	assert false;
duke@1	1551	return makeNull();
duke@1	1552	}
duke@1	1553	VarSymbol ot = ots.head;
duke@1	1554	JCExpression tree = access(make.at(pos).Ident(ot));
duke@1	1555	TypeSymbol otc = ot.type.tsym;
duke@1	1556	while (otc != c) {
duke@1	1557	do {
duke@1	1558	ots = ots.tail;
duke@1	1559	if (ots.isEmpty()) {
duke@1	1560	log.error(pos,
duke@1	1561	"no.encl.instance.of.type.in.scope",
duke@1	1562	c);
duke@1	1563	assert false; // should have been caught in Attr
duke@1	1564	return tree;
duke@1	1565	}
duke@1	1566	ot = ots.head;
duke@1	1567	} while (ot.owner != otc);
duke@1	1568	if (otc.owner.kind != PCK && !otc.hasOuterInstance()) {
duke@1	1569	chk.earlyRefError(pos, c);
duke@1	1570	assert false; // should have been caught in Attr
duke@1	1571	return makeNull();
duke@1	1572	}
duke@1	1573	tree = access(make.at(pos).Select(tree, ot));
duke@1	1574	otc = ot.type.tsym;
duke@1	1575	}
duke@1	1576	return tree;
duke@1	1577	}
duke@1	1578
duke@1	1579	/** Construct a tree that represents the closest outer instance
duke@1	1580	* <C.this> such that the given symbol is a member of C.
duke@1	1581	* @param pos The source code position to be used for the tree.
duke@1	1582	* @param sym The accessed symbol.
duke@1	1583	* @param preciseMatch should we accept a type that is a subtype of
duke@1	1584	* sym's owner, even if it doesn't contain sym
duke@1	1585	* due to hiding, overriding, or non-inheritance
duke@1	1586	* due to protection?
duke@1	1587	*/
duke@1	1588	JCExpression makeOwnerThis(DiagnosticPosition pos, Symbol sym, boolean preciseMatch) {
duke@1	1589	Symbol c = sym.owner;
duke@1	1590	if (preciseMatch ? sym.isMemberOf(currentClass, types)
duke@1	1591	: currentClass.isSubClass(sym.owner, types)) {
duke@1	1592	// in this case, `this' works fine
duke@1	1593	return make.at(pos).This(c.erasure(types));
duke@1	1594	} else {
duke@1	1595	// need to go via this$n
duke@1	1596	return makeOwnerThisN(pos, sym, preciseMatch);
duke@1	1597	}
duke@1	1598	}
duke@1	1599
duke@1	1600	/**
duke@1	1601	* Similar to makeOwnerThis but will never pick "this".
duke@1	1602	*/
duke@1	1603	JCExpression makeOwnerThisN(DiagnosticPosition pos, Symbol sym, boolean preciseMatch) {
duke@1	1604	Symbol c = sym.owner;
duke@1	1605	List<VarSymbol> ots = outerThisStack;
duke@1	1606	if (ots.isEmpty()) {
duke@1	1607	log.error(pos, "no.encl.instance.of.type.in.scope", c);
duke@1	1608	assert false;
duke@1	1609	return makeNull();
duke@1	1610	}
duke@1	1611	VarSymbol ot = ots.head;
duke@1	1612	JCExpression tree = access(make.at(pos).Ident(ot));
duke@1	1613	TypeSymbol otc = ot.type.tsym;
duke@1	1614	while (!(preciseMatch ? sym.isMemberOf(otc, types) : otc.isSubClass(sym.owner, types))) {
duke@1	1615	do {
duke@1	1616	ots = ots.tail;
duke@1	1617	if (ots.isEmpty()) {
duke@1	1618	log.error(pos,
duke@1	1619	"no.encl.instance.of.type.in.scope",
duke@1	1620	c);
duke@1	1621	assert false;
duke@1	1622	return tree;
duke@1	1623	}
duke@1	1624	ot = ots.head;
duke@1	1625	} while (ot.owner != otc);
duke@1	1626	tree = access(make.at(pos).Select(tree, ot));
duke@1	1627	otc = ot.type.tsym;
duke@1	1628	}
duke@1	1629	return tree;
duke@1	1630	}
duke@1	1631
duke@1	1632	/** Return tree simulating the assignment <this.name = name>, where
duke@1	1633	* name is the name of a free variable.
duke@1	1634	*/
duke@1	1635	JCStatement initField(int pos, Name name) {
duke@1	1636	Scope.Entry e = proxies.lookup(name);
duke@1	1637	Symbol rhs = e.sym;
duke@1	1638	assert rhs.owner.kind == MTH;
duke@1	1639	Symbol lhs = e.next().sym;
duke@1	1640	assert rhs.owner.owner == lhs.owner;
duke@1	1641	make.at(pos);
duke@1	1642	return
duke@1	1643	make.Exec(
duke@1	1644	make.Assign(
duke@1	1645	make.Select(make.This(lhs.owner.erasure(types)), lhs),
duke@1	1646	make.Ident(rhs)).setType(lhs.erasure(types)));
duke@1	1647	}
duke@1	1648
duke@1	1649	/** Return tree simulating the assignment <this.this$n = this$n>.
duke@1	1650	*/
duke@1	1651	JCStatement initOuterThis(int pos) {
duke@1	1652	VarSymbol rhs = outerThisStack.head;
duke@1	1653	assert rhs.owner.kind == MTH;
duke@1	1654	VarSymbol lhs = outerThisStack.tail.head;
duke@1	1655	assert rhs.owner.owner == lhs.owner;
duke@1	1656	make.at(pos);
duke@1	1657	return
duke@1	1658	make.Exec(
duke@1	1659	make.Assign(
duke@1	1660	make.Select(make.This(lhs.owner.erasure(types)), lhs),
duke@1	1661	make.Ident(rhs)).setType(lhs.erasure(types)));
duke@1	1662	}
duke@1	1663
duke@1	1664	/**************************************************************************
duke@1	1665	* Code for .class
duke@1	1666	*************************************************************************/
duke@1	1667
duke@1	1668	/** Return the symbol of a class to contain a cache of
duke@1	1669	* compiler-generated statics such as class$ and the
duke@1	1670	* $assertionsDisabled flag. We create an anonymous nested class
duke@1	1671	* (unless one already exists) and return its symbol. However,
duke@1	1672	* for backward compatibility in 1.4 and earlier we use the
duke@1	1673	* top-level class itself.
duke@1	1674	*/
duke@1	1675	private ClassSymbol outerCacheClass() {
duke@1	1676	ClassSymbol clazz = outermostClassDef.sym;
duke@1	1677	if ((clazz.flags() & INTERFACE) == 0 &&
duke@1	1678	!target.useInnerCacheClass()) return clazz;
duke@1	1679	Scope s = clazz.members();
duke@1	1680	for (Scope.Entry e = s.elems; e != null; e = e.sibling)
duke@1	1681	if (e.sym.kind == TYP &&
duke@1	1682	e.sym.name == names.empty &&
duke@1	1683	(e.sym.flags() & INTERFACE) == 0) return (ClassSymbol) e.sym;
duke@1	1684	return makeEmptyClass(STATIC | SYNTHETIC, clazz);
duke@1	1685	}
duke@1	1686
duke@1	1687	/** Return symbol for "class$" method. If there is no method definition
duke@1	1688	* for class$, construct one as follows:
duke@1	1689	*
duke@1	1690	* class class$(String x0) {
duke@1	1691	* try {
duke@1	1692	* return Class.forName(x0);
duke@1	1693	* } catch (ClassNotFoundException x1) {
duke@1	1694	* throw new NoClassDefFoundError(x1.getMessage());
duke@1	1695	* }
duke@1	1696	* }
duke@1	1697	*/
duke@1	1698	private MethodSymbol classDollarSym(DiagnosticPosition pos) {
duke@1	1699	ClassSymbol outerCacheClass = outerCacheClass();
duke@1	1700	MethodSymbol classDollarSym =
duke@1	1701	(MethodSymbol)lookupSynthetic(classDollar,
duke@1	1702	outerCacheClass.members());
duke@1	1703	if (classDollarSym == null) {
duke@1	1704	classDollarSym = new MethodSymbol(
duke@1	1705	STATIC | SYNTHETIC,
duke@1	1706	classDollar,
duke@1	1707	new MethodType(
duke@1	1708	List.of(syms.stringType),
duke@1	1709	types.erasure(syms.classType),
duke@1	1710	List.<Type>nil(),
duke@1	1711	syms.methodClass),
duke@1	1712	outerCacheClass);
duke@1	1713	enterSynthetic(pos, classDollarSym, outerCacheClass.members());
duke@1	1714
duke@1	1715	JCMethodDecl md = make.MethodDef(classDollarSym, null);
duke@1	1716	try {
duke@1	1717	md.body = classDollarSymBody(pos, md);
duke@1	1718	} catch (CompletionFailure ex) {
duke@1	1719	md.body = make.Block(0, List.<JCStatement>nil());
duke@1	1720	chk.completionError(pos, ex);
duke@1	1721	}
duke@1	1722	JCClassDecl outerCacheClassDef = classDef(outerCacheClass);
duke@1	1723	outerCacheClassDef.defs = outerCacheClassDef.defs.prepend(md);
duke@1	1724	}
duke@1	1725	return classDollarSym;
duke@1	1726	}
duke@1	1727
duke@1	1728	/** Generate code for class$(String name). */
duke@1	1729	JCBlock classDollarSymBody(DiagnosticPosition pos, JCMethodDecl md) {
duke@1	1730	MethodSymbol classDollarSym = md.sym;
duke@1	1731	ClassSymbol outerCacheClass = (ClassSymbol)classDollarSym.owner;
duke@1	1732
duke@1	1733	JCBlock returnResult;
duke@1	1734
duke@1	1735	// in 1.4.2 and above, we use
duke@1	1736	// Class.forName(String name, boolean init, ClassLoader loader);
duke@1	1737	// which requires we cache the current loader in cl$
duke@1	1738	if (target.classLiteralsNoInit()) {
duke@1	1739	// clsym = "private static ClassLoader cl$"
duke@1	1740	VarSymbol clsym = new VarSymbol(STATIC|SYNTHETIC,
duke@1	1741	names.fromString("cl" + target.syntheticNameChar()),
duke@1	1742	syms.classLoaderType,
duke@1	1743	outerCacheClass);
duke@1	1744	enterSynthetic(pos, clsym, outerCacheClass.members());
duke@1	1745
duke@1	1746	// emit "private static ClassLoader cl$;"
duke@1	1747	JCVariableDecl cldef = make.VarDef(clsym, null);
duke@1	1748	JCClassDecl outerCacheClassDef = classDef(outerCacheClass);
duke@1	1749	outerCacheClassDef.defs = outerCacheClassDef.defs.prepend(cldef);
duke@1	1750
duke@1	1751	// newcache := "new cache$1[0]"
duke@1	1752	JCNewArray newcache = make.
duke@1	1753	NewArray(make.Type(outerCacheClass.type),
duke@1	1754	List.<JCExpression>of(make.Literal(INT, 0).setType(syms.intType)),
duke@1	1755	null);
duke@1	1756	newcache.type = new ArrayType(types.erasure(outerCacheClass.type),
duke@1	1757	syms.arrayClass);
duke@1	1758
duke@1	1759	// forNameSym := java.lang.Class.forName(
duke@1	1760	// String s,boolean init,ClassLoader loader)
duke@1	1761	Symbol forNameSym = lookupMethod(make_pos, names.forName,
duke@1	1762	types.erasure(syms.classType),
duke@1	1763	List.of(syms.stringType,
duke@1	1764	syms.booleanType,
duke@1	1765	syms.classLoaderType));
duke@1	1766	// clvalue := "(cl$ == null) ?
duke@1	1767	// $newcache.getClass().getComponentType().getClassLoader() : cl$"
duke@1	1768	JCExpression clvalue =
duke@1	1769	make.Conditional(
duke@1	1770	makeBinary(JCTree.EQ, make.Ident(clsym), makeNull()),
duke@1	1771	make.Assign(
duke@1	1772	make.Ident(clsym),
duke@1	1773	makeCall(
duke@1	1774	makeCall(makeCall(newcache,
duke@1	1775	names.getClass,
duke@1	1776	List.<JCExpression>nil()),
duke@1	1777	names.getComponentType,
duke@1	1778	List.<JCExpression>nil()),
duke@1	1779	names.getClassLoader,
duke@1	1780	List.<JCExpression>nil())).setType(syms.classLoaderType),
duke@1	1781	make.Ident(clsym)).setType(syms.classLoaderType);
duke@1	1782
duke@1	1783	// returnResult := "{ return Class.forName(param1, false, cl$); }"
duke@1	1784	List<JCExpression> args = List.of(make.Ident(md.params.head.sym),
duke@1	1785	makeLit(syms.booleanType, 0),
duke@1	1786	clvalue);
duke@1	1787	returnResult = make.
duke@1	1788	Block(0, List.<JCStatement>of(make.
duke@1	1789	Call(make. // return
duke@1	1790	App(make.
duke@1	1791	Ident(forNameSym), args))));
duke@1	1792	} else {
duke@1	1793	// forNameSym := java.lang.Class.forName(String s)
duke@1	1794	Symbol forNameSym = lookupMethod(make_pos,
duke@1	1795	names.forName,
duke@1	1796	types.erasure(syms.classType),
duke@1	1797	List.of(syms.stringType));
duke@1	1798	// returnResult := "{ return Class.forName(param1); }"
duke@1	1799	returnResult = make.
duke@1	1800	Block(0, List.of(make.
duke@1	1801	Call(make. // return
duke@1	1802	App(make.
duke@1	1803	QualIdent(forNameSym),
duke@1	1804	List.<JCExpression>of(make.
duke@1	1805	Ident(md.params.
duke@1	1806	head.sym))))));
duke@1	1807	}
duke@1	1808
duke@1	1809	// catchParam := ClassNotFoundException e1
duke@1	1810	VarSymbol catchParam =
duke@1	1811	new VarSymbol(0, make.paramName(1),
duke@1	1812	syms.classNotFoundExceptionType,
duke@1	1813	classDollarSym);
duke@1	1814
duke@1	1815	JCStatement rethrow;
duke@1	1816	if (target.hasInitCause()) {
duke@1	1817	// rethrow = "throw new NoClassDefFoundError().initCause(e);
duke@1	1818	JCTree throwExpr =
duke@1	1819	makeCall(makeNewClass(syms.noClassDefFoundErrorType,
duke@1	1820	List.<JCExpression>nil()),
duke@1	1821	names.initCause,
duke@1	1822	List.<JCExpression>of(make.Ident(catchParam)));
duke@1	1823	rethrow = make.Throw(throwExpr);
duke@1	1824	} else {
duke@1	1825	// getMessageSym := ClassNotFoundException.getMessage()
duke@1	1826	Symbol getMessageSym = lookupMethod(make_pos,
duke@1	1827	names.getMessage,
duke@1	1828	syms.classNotFoundExceptionType,
duke@1	1829	List.<Type>nil());
duke@1	1830	// rethrow = "throw new NoClassDefFoundError(e.getMessage());"
duke@1	1831	rethrow = make.
duke@1	1832	Throw(makeNewClass(syms.noClassDefFoundErrorType,
duke@1	1833	List.<JCExpression>of(make.App(make.Select(make.Ident(catchParam),
duke@1	1834	getMessageSym),
duke@1	1835	List.<JCExpression>nil()))));
duke@1	1836	}
duke@1	1837
duke@1	1838	// rethrowStmt := "( $rethrow )"
duke@1	1839	JCBlock rethrowStmt = make.Block(0, List.of(rethrow));
duke@1	1840
duke@1	1841	// catchBlock := "catch ($catchParam) $rethrowStmt"
duke@1	1842	JCCatch catchBlock = make.Catch(make.VarDef(catchParam, null),
duke@1	1843	rethrowStmt);
duke@1	1844
duke@1	1845	// tryCatch := "try $returnResult $catchBlock"
duke@1	1846	JCStatement tryCatch = make.Try(returnResult,
duke@1	1847	List.of(catchBlock), null);
duke@1	1848
duke@1	1849	return make.Block(0, List.of(tryCatch));
duke@1	1850	}
duke@1	1851	// where
duke@1	1852	/** Create an attributed tree of the form left.name(). */
duke@1	1853	private JCMethodInvocation makeCall(JCExpression left, Name name, List<JCExpression> args) {
duke@1	1854	assert left.type != null;
duke@1	1855	Symbol funcsym = lookupMethod(make_pos, name, left.type,
duke@1	1856	TreeInfo.types(args));
duke@1	1857	return make.App(make.Select(left, funcsym), args);
duke@1	1858	}
duke@1	1859
duke@1	1860	/** The Name Of The variable to cache T.class values.
duke@1	1861	* @param sig The signature of type T.
duke@1	1862	*/
duke@1	1863	private Name cacheName(String sig) {
duke@1	1864	StringBuffer buf = new StringBuffer();
duke@1	1865	if (sig.startsWith("[")) {
duke@1	1866	buf = buf.append("array");
duke@1	1867	while (sig.startsWith("[")) {
duke@1	1868	buf = buf.append(target.syntheticNameChar());
duke@1	1869	sig = sig.substring(1);
duke@1	1870	}
duke@1	1871	if (sig.startsWith("L")) {
duke@1	1872	sig = sig.substring(0, sig.length() - 1);
duke@1	1873	}
duke@1	1874	} else {
duke@1	1875	buf = buf.append("class" + target.syntheticNameChar());
duke@1	1876	}
duke@1	1877	buf = buf.append(sig.replace('.', target.syntheticNameChar()));
duke@1	1878	return names.fromString(buf.toString());
duke@1	1879	}
duke@1	1880
duke@1	1881	/** The variable symbol that caches T.class values.
duke@1	1882	* If none exists yet, create a definition.
duke@1	1883	* @param sig The signature of type T.
duke@1	1884	* @param pos The position to report diagnostics, if any.
duke@1	1885	*/
duke@1	1886	private VarSymbol cacheSym(DiagnosticPosition pos, String sig) {
duke@1	1887	ClassSymbol outerCacheClass = outerCacheClass();
duke@1	1888	Name cname = cacheName(sig);
duke@1	1889	VarSymbol cacheSym =
duke@1	1890	(VarSymbol)lookupSynthetic(cname, outerCacheClass.members());
duke@1	1891	if (cacheSym == null) {
duke@1	1892	cacheSym = new VarSymbol(
duke@1	1893	STATIC | SYNTHETIC, cname, types.erasure(syms.classType), outerCacheClass);
duke@1	1894	enterSynthetic(pos, cacheSym, outerCacheClass.members());
duke@1	1895
duke@1	1896	JCVariableDecl cacheDef = make.VarDef(cacheSym, null);
duke@1	1897	JCClassDecl outerCacheClassDef = classDef(outerCacheClass);
duke@1	1898	outerCacheClassDef.defs = outerCacheClassDef.defs.prepend(cacheDef);
duke@1	1899	}
duke@1	1900	return cacheSym;
duke@1	1901	}
duke@1	1902
duke@1	1903	/** The tree simulating a T.class expression.
duke@1	1904	* @param clazz The tree identifying type T.
duke@1	1905	*/
duke@1	1906	private JCExpression classOf(JCTree clazz) {
duke@1	1907	return classOfType(clazz.type, clazz.pos());
duke@1	1908	}
duke@1	1909
duke@1	1910	private JCExpression classOfType(Type type, DiagnosticPosition pos) {
duke@1	1911	switch (type.tag) {
duke@1	1912	case BYTE: case SHORT: case CHAR: case INT: case LONG: case FLOAT:
duke@1	1913	case DOUBLE: case BOOLEAN: case VOID:
duke@1	1914	// replace with <BoxedClass>.TYPE
duke@1	1915	ClassSymbol c = types.boxedClass(type);
duke@1	1916	Symbol typeSym =
duke@1	1917	rs.access(
duke@1	1918	rs.findIdentInType(attrEnv, c.type, names.TYPE, VAR),
duke@1	1919	pos, c.type, names.TYPE, true);
duke@1	1920	if (typeSym.kind == VAR)
duke@1	1921	((VarSymbol)typeSym).getConstValue(); // ensure initializer is evaluated
duke@1	1922	return make.QualIdent(typeSym);
duke@1	1923	case CLASS: case ARRAY:
duke@1	1924	if (target.hasClassLiterals()) {
duke@1	1925	VarSymbol sym = new VarSymbol(
duke@1	1926	STATIC | PUBLIC | FINAL, names._class,
duke@1	1927	syms.classType, type.tsym);
duke@1	1928	return make_at(pos).Select(make.Type(type), sym);
duke@1	1929	}
duke@1	1930	// replace with <cache == null ? cache = class$(tsig) : cache>
duke@1	1931	// where
duke@1	1932	// - <tsig> is the type signature of T,
duke@1	1933	// - <cache> is the cache variable for tsig.
duke@1	1934	String sig =
duke@1	1935	writer.xClassName(type).toString().replace('/', '.');
duke@1	1936	Symbol cs = cacheSym(pos, sig);
duke@1	1937	return make_at(pos).Conditional(
duke@1	1938	makeBinary(JCTree.EQ, make.Ident(cs), makeNull()),
duke@1	1939	make.Assign(
duke@1	1940	make.Ident(cs),
duke@1	1941	make.App(
duke@1	1942	make.Ident(classDollarSym(pos)),
duke@1	1943	List.<JCExpression>of(make.Literal(CLASS, sig)
duke@1	1944	.setType(syms.stringType))))
duke@1	1945	.setType(types.erasure(syms.classType)),
duke@1	1946	make.Ident(cs)).setType(types.erasure(syms.classType));
duke@1	1947	default:
duke@1	1948	throw new AssertionError();
duke@1	1949	}
duke@1	1950	}
duke@1	1951
duke@1	1952	/**************************************************************************
duke@1	1953	* Code for enabling/disabling assertions.
duke@1	1954	*************************************************************************/
duke@1	1955
duke@1	1956	// This code is not particularly robust if the user has
duke@1	1957	// previously declared a member named '$assertionsDisabled'.
duke@1	1958	// The same faulty idiom also appears in the translation of
duke@1	1959	// class literals above. We should report an error if a
duke@1	1960	// previous declaration is not synthetic.
duke@1	1961
duke@1	1962	private JCExpression assertFlagTest(DiagnosticPosition pos) {
duke@1	1963	// Outermost class may be either true class or an interface.
duke@1	1964	ClassSymbol outermostClass = outermostClassDef.sym;
duke@1	1965
duke@1	1966	// note that this is a class, as an interface can't contain a statement.
duke@1	1967	ClassSymbol container = currentClass;
duke@1	1968
duke@1	1969	VarSymbol assertDisabledSym =
duke@1	1970	(VarSymbol)lookupSynthetic(dollarAssertionsDisabled,
duke@1	1971	container.members());
duke@1	1972	if (assertDisabledSym == null) {
duke@1	1973	assertDisabledSym =
duke@1	1974	new VarSymbol(STATIC | FINAL | SYNTHETIC,
duke@1	1975	dollarAssertionsDisabled,
duke@1	1976	syms.booleanType,
duke@1	1977	container);
duke@1	1978	enterSynthetic(pos, assertDisabledSym, container.members());
duke@1	1979	Symbol desiredAssertionStatusSym = lookupMethod(pos,
duke@1	1980	names.desiredAssertionStatus,
duke@1	1981	types.erasure(syms.classType),
duke@1	1982	List.<Type>nil());
duke@1	1983	JCClassDecl containerDef = classDef(container);
duke@1	1984	make_at(containerDef.pos());
duke@1	1985	JCExpression notStatus = makeUnary(JCTree.NOT, make.App(make.Select(
duke@1	1986	classOfType(types.erasure(outermostClass.type),
duke@1	1987	containerDef.pos()),
duke@1	1988	desiredAssertionStatusSym)));
duke@1	1989	JCVariableDecl assertDisabledDef = make.VarDef(assertDisabledSym,
duke@1	1990	notStatus);
duke@1	1991	containerDef.defs = containerDef.defs.prepend(assertDisabledDef);
duke@1	1992	}
duke@1	1993	make_at(pos);
duke@1	1994	return makeUnary(JCTree.NOT, make.Ident(assertDisabledSym));
duke@1	1995	}
duke@1	1996
duke@1	1997
duke@1	1998	/**************************************************************************
duke@1	1999	* Building blocks for let expressions
duke@1	2000	*************************************************************************/
duke@1	2001
duke@1	2002	interface TreeBuilder {
duke@1	2003	JCTree build(JCTree arg);
duke@1	2004	}
duke@1	2005
duke@1	2006	/** Construct an expression using the builder, with the given rval
duke@1	2007	* expression as an argument to the builder. However, the rval
duke@1	2008	* expression must be computed only once, even if used multiple
duke@1	2009	* times in the result of the builder. We do that by
duke@1	2010	* constructing a "let" expression that saves the rvalue into a
duke@1	2011	* temporary variable and then uses the temporary variable in
duke@1	2012	* place of the expression built by the builder. The complete
duke@1	2013	* resulting expression is of the form
duke@1	2014	* <pre>
duke@1	2015	* (let <b>TYPE</b> <b>TEMP</b> = <b>RVAL</b>;
duke@1	2016	* in (<b>BUILDER</b>(<b>TEMP</b>)))
duke@1	2017	* </pre>
duke@1	2018	* where <code><b>TEMP</b></code> is a newly declared variable
duke@1	2019	* in the let expression.
duke@1	2020	*/
duke@1	2021	JCTree abstractRval(JCTree rval, Type type, TreeBuilder builder) {
duke@1	2022	rval = TreeInfo.skipParens(rval);
duke@1	2023	switch (rval.getTag()) {
duke@1	2024	case JCTree.LITERAL:
duke@1	2025	return builder.build(rval);
duke@1	2026	case JCTree.IDENT:
duke@1	2027	JCIdent id = (JCIdent) rval;
duke@1	2028	if ((id.sym.flags() & FINAL) != 0 && id.sym.owner.kind == MTH)
duke@1	2029	return builder.build(rval);
duke@1	2030	}
duke@1	2031	VarSymbol var =
duke@1	2032	new VarSymbol(FINAL|SYNTHETIC,
jjg@113	2033	names.fromString(
duke@1	2034	target.syntheticNameChar()
duke@1	2035	+ "" + rval.hashCode()),
duke@1	2036	type,
duke@1	2037	currentMethodSym);
mcimadamore@4	2038	rval = convert(rval,type);
duke@1	2039	JCVariableDecl def = make.VarDef(var, (JCExpression)rval); // XXX cast
duke@1	2040	JCTree built = builder.build(make.Ident(var));
duke@1	2041	JCTree res = make.LetExpr(def, built);
duke@1	2042	res.type = built.type;
duke@1	2043	return res;
duke@1	2044	}
duke@1	2045
duke@1	2046	// same as above, with the type of the temporary variable computed
duke@1	2047	JCTree abstractRval(JCTree rval, TreeBuilder builder) {
duke@1	2048	return abstractRval(rval, rval.type, builder);
duke@1	2049	}
duke@1	2050
duke@1	2051	// same as above, but for an expression that may be used as either
duke@1	2052	// an rvalue or an lvalue. This requires special handling for
duke@1	2053	// Select expressions, where we place the left-hand-side of the
duke@1	2054	// select in a temporary, and for Indexed expressions, where we
duke@1	2055	// place both the indexed expression and the index value in temps.
duke@1	2056	JCTree abstractLval(JCTree lval, final TreeBuilder builder) {
duke@1	2057	lval = TreeInfo.skipParens(lval);
duke@1	2058	switch (lval.getTag()) {
duke@1	2059	case JCTree.IDENT:
duke@1	2060	return builder.build(lval);
duke@1	2061	case JCTree.SELECT: {
duke@1	2062	final JCFieldAccess s = (JCFieldAccess)lval;
duke@1	2063	JCTree selected = TreeInfo.skipParens(s.selected);
duke@1	2064	Symbol lid = TreeInfo.symbol(s.selected);
duke@1	2065	if (lid != null && lid.kind == TYP) return builder.build(lval);
duke@1	2066	return abstractRval(s.selected, new TreeBuilder() {
duke@1	2067	public JCTree build(final JCTree selected) {
duke@1	2068	return builder.build(make.Select((JCExpression)selected, s.sym));
duke@1	2069	}
duke@1	2070	});
duke@1	2071	}
duke@1	2072	case JCTree.INDEXED: {
duke@1	2073	final JCArrayAccess i = (JCArrayAccess)lval;
duke@1	2074	return abstractRval(i.indexed, new TreeBuilder() {
duke@1	2075	public JCTree build(final JCTree indexed) {
duke@1	2076	return abstractRval(i.index, syms.intType, new TreeBuilder() {
duke@1	2077	public JCTree build(final JCTree index) {
duke@1	2078	JCTree newLval = make.Indexed((JCExpression)indexed,
duke@1	2079	(JCExpression)index);
duke@1	2080	newLval.setType(i.type);
duke@1	2081	return builder.build(newLval);
duke@1	2082	}
duke@1	2083	});
duke@1	2084	}
duke@1	2085	});
duke@1	2086	}
mcimadamore@133	2087	case JCTree.TYPECAST: {
mcimadamore@133	2088	return abstractLval(((JCTypeCast)lval).expr, builder);
mcimadamore@133	2089	}
duke@1	2090	}
duke@1	2091	throw new AssertionError(lval);
duke@1	2092	}
duke@1	2093
duke@1	2094	// evaluate and discard the first expression, then evaluate the second.
duke@1	2095	JCTree makeComma(final JCTree expr1, final JCTree expr2) {
duke@1	2096	return abstractRval(expr1, new TreeBuilder() {
duke@1	2097	public JCTree build(final JCTree discarded) {
duke@1	2098	return expr2;
duke@1	2099	}
duke@1	2100	});
duke@1	2101	}
duke@1	2102
duke@1	2103	/**************************************************************************
duke@1	2104	* Translation methods
duke@1	2105	*************************************************************************/
duke@1	2106
duke@1	2107	/** Visitor argument: enclosing operator node.
duke@1	2108	*/
duke@1	2109	private JCExpression enclOp;
duke@1	2110
duke@1	2111	/** Visitor method: Translate a single node.
duke@1	2112	* Attach the source position from the old tree to its replacement tree.
duke@1	2113	*/
duke@1	2114	public <T extends JCTree> T translate(T tree) {
duke@1	2115	if (tree == null) {
duke@1	2116	return null;
duke@1	2117	} else {
duke@1	2118	make_at(tree.pos());
duke@1	2119	T result = super.translate(tree);
duke@1	2120	if (endPositions != null && result != tree) {
duke@1	2121	Integer endPos = endPositions.remove(tree);
duke@1	2122	if (endPos != null) endPositions.put(result, endPos);
duke@1	2123	}
duke@1	2124	return result;
duke@1	2125	}
duke@1	2126	}
duke@1	2127
duke@1	2128	/** Visitor method: Translate a single node, boxing or unboxing if needed.
duke@1	2129	*/
duke@1	2130	public <T extends JCTree> T translate(T tree, Type type) {
duke@1	2131	return (tree == null) ? null : boxIfNeeded(translate(tree), type);
duke@1	2132	}
duke@1	2133
duke@1	2134	/** Visitor method: Translate tree.
duke@1	2135	*/
duke@1	2136	public <T extends JCTree> T translate(T tree, JCExpression enclOp) {
duke@1	2137	JCExpression prevEnclOp = this.enclOp;
duke@1	2138	this.enclOp = enclOp;
duke@1	2139	T res = translate(tree);
duke@1	2140	this.enclOp = prevEnclOp;
duke@1	2141	return res;
duke@1	2142	}
duke@1	2143
duke@1	2144	/** Visitor method: Translate list of trees.
duke@1	2145	*/
duke@1	2146	public <T extends JCTree> List<T> translate(List<T> trees, JCExpression enclOp) {
duke@1	2147	JCExpression prevEnclOp = this.enclOp;
duke@1	2148	this.enclOp = enclOp;
duke@1	2149	List<T> res = translate(trees);
duke@1	2150	this.enclOp = prevEnclOp;
duke@1	2151	return res;
duke@1	2152	}
duke@1	2153
duke@1	2154	/** Visitor method: Translate list of trees.
duke@1	2155	*/
duke@1	2156	public <T extends JCTree> List<T> translate(List<T> trees, Type type) {
duke@1	2157	if (trees == null) return null;
duke@1	2158	for (List<T> l = trees; l.nonEmpty(); l = l.tail)
duke@1	2159	l.head = translate(l.head, type);
duke@1	2160	return trees;
duke@1	2161	}
duke@1	2162
duke@1	2163	public void visitTopLevel(JCCompilationUnit tree) {
duke@1	2164	if (tree.packageAnnotations.nonEmpty()) {
duke@1	2165	Name name = names.package_info;
duke@1	2166	long flags = Flags.ABSTRACT | Flags.INTERFACE;
duke@1	2167	if (target.isPackageInfoSynthetic())
duke@1	2168	// package-info is marked SYNTHETIC in JDK 1.6 and later releases
duke@1	2169	flags = flags | Flags.SYNTHETIC;
duke@1	2170	JCClassDecl packageAnnotationsClass
duke@1	2171	= make.ClassDef(make.Modifiers(flags,
duke@1	2172	tree.packageAnnotations),
duke@1	2173	name, List.<JCTypeParameter>nil(),
duke@1	2174	null, List.<JCExpression>nil(), List.<JCTree>nil());
jjg@483	2175	ClassSymbol c = tree.packge.package_info;
jjg@483	2176	c.flags_field |= flags;
duke@1	2177	c.attributes_field = tree.packge.attributes_field;
duke@1	2178	ClassType ctype = (ClassType) c.type;
duke@1	2179	ctype.supertype_field = syms.objectType;
duke@1	2180	ctype.interfaces_field = List.nil();
duke@1	2181	packageAnnotationsClass.sym = c;
duke@1	2182
duke@1	2183	translated.append(packageAnnotationsClass);
duke@1	2184	}
duke@1	2185	}
duke@1	2186
duke@1	2187	public void visitClassDef(JCClassDecl tree) {
duke@1	2188	ClassSymbol currentClassPrev = currentClass;
duke@1	2189	MethodSymbol currentMethodSymPrev = currentMethodSym;
duke@1	2190	currentClass = tree.sym;
duke@1	2191	currentMethodSym = null;
duke@1	2192	classdefs.put(currentClass, tree);
duke@1	2193
duke@1	2194	proxies = proxies.dup(currentClass);
duke@1	2195	List<VarSymbol> prevOuterThisStack = outerThisStack;
duke@1	2196
duke@1	2197	// If this is an enum definition
duke@1	2198	if ((tree.mods.flags & ENUM) != 0 &&
duke@1	2199	(types.supertype(currentClass.type).tsym.flags() & ENUM) == 0)
duke@1	2200	visitEnumDef(tree);
duke@1	2201
duke@1	2202	// If this is a nested class, define a this$n field for
duke@1	2203	// it and add to proxies.
duke@1	2204	JCVariableDecl otdef = null;
duke@1	2205	if (currentClass.hasOuterInstance())
duke@1	2206	otdef = outerThisDef(tree.pos, currentClass);
duke@1	2207
duke@1	2208	// If this is a local class, define proxies for all its free variables.
duke@1	2209	List<JCVariableDecl> fvdefs = freevarDefs(
duke@1	2210	tree.pos, freevars(currentClass), currentClass);
duke@1	2211
duke@1	2212	// Recursively translate superclass, interfaces.
duke@1	2213	tree.extending = translate(tree.extending);
duke@1	2214	tree.implementing = translate(tree.implementing);
duke@1	2215
duke@1	2216	// Recursively translate members, taking into account that new members
duke@1	2217	// might be created during the translation and prepended to the member
duke@1	2218	// list `tree.defs'.
duke@1	2219	List<JCTree> seen = List.nil();
duke@1	2220	while (tree.defs != seen) {
duke@1	2221	List<JCTree> unseen = tree.defs;
duke@1	2222	for (List<JCTree> l = unseen; l.nonEmpty() && l != seen; l = l.tail) {
duke@1	2223	JCTree outermostMemberDefPrev = outermostMemberDef;
duke@1	2224	if (outermostMemberDefPrev == null) outermostMemberDef = l.head;
duke@1	2225	l.head = translate(l.head);
duke@1	2226	outermostMemberDef = outermostMemberDefPrev;
duke@1	2227	}
duke@1	2228	seen = unseen;
duke@1	2229	}
duke@1	2230
duke@1	2231	// Convert a protected modifier to public, mask static modifier.
duke@1	2232	if ((tree.mods.flags & PROTECTED) != 0) tree.mods.flags |= PUBLIC;
duke@1	2233	tree.mods.flags &= ClassFlags;
duke@1	2234
duke@1	2235	// Convert name to flat representation, replacing '.' by '$'.
duke@1	2236	tree.name = Convert.shortName(currentClass.flatName());
duke@1	2237
duke@1	2238	// Add this$n and free variables proxy definitions to class.
duke@1	2239	for (List<JCVariableDecl> l = fvdefs; l.nonEmpty(); l = l.tail) {
duke@1	2240	tree.defs = tree.defs.prepend(l.head);
duke@1	2241	enterSynthetic(tree.pos(), l.head.sym, currentClass.members());
duke@1	2242	}
duke@1	2243	if (currentClass.hasOuterInstance()) {
duke@1	2244	tree.defs = tree.defs.prepend(otdef);
duke@1	2245	enterSynthetic(tree.pos(), otdef.sym, currentClass.members());
duke@1	2246	}
duke@1	2247
duke@1	2248	proxies = proxies.leave();
duke@1	2249	outerThisStack = prevOuterThisStack;
duke@1	2250
duke@1	2251	// Append translated tree to `translated' queue.
duke@1	2252	translated.append(tree);
duke@1	2253
duke@1	2254	currentClass = currentClassPrev;
duke@1	2255	currentMethodSym = currentMethodSymPrev;
duke@1	2256
duke@1	2257	// Return empty block {} as a placeholder for an inner class.
duke@1	2258	result = make_at(tree.pos()).Block(0, List.<JCStatement>nil());
duke@1	2259	}
duke@1	2260
duke@1	2261	/** Translate an enum class. */
duke@1	2262	private void visitEnumDef(JCClassDecl tree) {
duke@1	2263	make_at(tree.pos());
duke@1	2264
duke@1	2265	// add the supertype, if needed
duke@1	2266	if (tree.extending == null)
duke@1	2267	tree.extending = make.Type(types.supertype(tree.type));
duke@1	2268
duke@1	2269	// classOfType adds a cache field to tree.defs unless
duke@1	2270	// target.hasClassLiterals().
duke@1	2271	JCExpression e_class = classOfType(tree.sym.type, tree.pos()).
duke@1	2272	setType(types.erasure(syms.classType));
duke@1	2273
duke@1	2274	// process each enumeration constant, adding implicit constructor parameters
duke@1	2275	int nextOrdinal = 0;
duke@1	2276	ListBuffer<JCExpression> values = new ListBuffer<JCExpression>();
duke@1	2277	ListBuffer<JCTree> enumDefs = new ListBuffer<JCTree>();
duke@1	2278	ListBuffer<JCTree> otherDefs = new ListBuffer<JCTree>();
duke@1	2279	for (List<JCTree> defs = tree.defs;
duke@1	2280	defs.nonEmpty();
duke@1	2281	defs=defs.tail) {
duke@1	2282	if (defs.head.getTag() == JCTree.VARDEF && (((JCVariableDecl) defs.head).mods.flags & ENUM) != 0) {
duke@1	2283	JCVariableDecl var = (JCVariableDecl)defs.head;
duke@1	2284	visitEnumConstantDef(var, nextOrdinal++);
duke@1	2285	values.append(make.QualIdent(var.sym));
duke@1	2286	enumDefs.append(var);
duke@1	2287	} else {
duke@1	2288	otherDefs.append(defs.head);
duke@1	2289	}
duke@1	2290	}
duke@1	2291
duke@1	2292	// private static final T[] #VALUES = { a, b, c };
duke@1	2293	Name valuesName = names.fromString(target.syntheticNameChar() + "VALUES");
duke@1	2294	while (tree.sym.members().lookup(valuesName).scope != null) // avoid name clash
duke@1	2295	valuesName = names.fromString(valuesName + "" + target.syntheticNameChar());
duke@1	2296	Type arrayType = new ArrayType(types.erasure(tree.type), syms.arrayClass);
duke@1	2297	VarSymbol valuesVar = new VarSymbol(PRIVATE|FINAL|STATIC|SYNTHETIC,
duke@1	2298	valuesName,
duke@1	2299	arrayType,
duke@1	2300	tree.type.tsym);
duke@1	2301	JCNewArray newArray = make.NewArray(make.Type(types.erasure(tree.type)),
duke@1	2302	List.<JCExpression>nil(),
duke@1	2303	values.toList());
duke@1	2304	newArray.type = arrayType;
duke@1	2305	enumDefs.append(make.VarDef(valuesVar, newArray));
duke@1	2306	tree.sym.members().enter(valuesVar);
duke@1	2307
duke@1	2308	Symbol valuesSym = lookupMethod(tree.pos(), names.values,
duke@1	2309	tree.type, List.<Type>nil());
jjg@86	2310	List<JCStatement> valuesBody;
jjg@86	2311	if (useClone()) {
jjg@86	2312	// return (T[]) $VALUES.clone();
jjg@86	2313	JCTypeCast valuesResult =
jjg@86	2314	make.TypeCast(valuesSym.type.getReturnType(),
jjg@86	2315	make.App(make.Select(make.Ident(valuesVar),
jjg@86	2316	syms.arrayCloneMethod)));
jjg@86	2317	valuesBody = List.<JCStatement>of(make.Return(valuesResult));
jjg@86	2318	} else {
jjg@86	2319	// template: T[] $result = new T[$values.length];
jjg@86	2320	Name resultName = names.fromString(target.syntheticNameChar() + "result");
jjg@86	2321	while (tree.sym.members().lookup(resultName).scope != null) // avoid name clash
jjg@86	2322	resultName = names.fromString(resultName + "" + target.syntheticNameChar());
jjg@86	2323	VarSymbol resultVar = new VarSymbol(FINAL|SYNTHETIC,
jjg@86	2324	resultName,
jjg@86	2325	arrayType,
jjg@86	2326	valuesSym);
jjg@86	2327	JCNewArray resultArray = make.NewArray(make.Type(types.erasure(tree.type)),
jjg@86	2328	List.of(make.Select(make.Ident(valuesVar), syms.lengthVar)),
jjg@86	2329	null);
jjg@86	2330	resultArray.type = arrayType;
jjg@86	2331	JCVariableDecl decl = make.VarDef(resultVar, resultArray);
jjg@86	2332
jjg@86	2333	// template: System.arraycopy($VALUES, 0, $result, 0, $VALUES.length);
jjg@86	2334	if (systemArraycopyMethod == null) {
jjg@86	2335	systemArraycopyMethod =
jjg@86	2336	new MethodSymbol(PUBLIC | STATIC,
jjg@86	2337	names.fromString("arraycopy"),
jjg@86	2338	new MethodType(List.<Type>of(syms.objectType,
jjg@86	2339	syms.intType,
jjg@86	2340	syms.objectType,
jjg@86	2341	syms.intType,
jjg@86	2342	syms.intType),
jjg@86	2343	syms.voidType,
jjg@86	2344	List.<Type>nil(),
jjg@86	2345	syms.methodClass),
jjg@86	2346	syms.systemType.tsym);
jjg@86	2347	}
jjg@86	2348	JCStatement copy =
jjg@86	2349	make.Exec(make.App(make.Select(make.Ident(syms.systemType.tsym),
jjg@86	2350	systemArraycopyMethod),
jjg@86	2351	List.of(make.Ident(valuesVar), make.Literal(0),
jjg@86	2352	make.Ident(resultVar), make.Literal(0),
jjg@86	2353	make.Select(make.Ident(valuesVar), syms.lengthVar))));
jjg@86	2354
jjg@86	2355	// template: return $result;
jjg@86	2356	JCStatement ret = make.Return(make.Ident(resultVar));
jjg@86	2357	valuesBody = List.<JCStatement>of(decl, copy, ret);
jjg@86	2358	}
jjg@86	2359
duke@1	2360	JCMethodDecl valuesDef =
jjg@86	2361	make.MethodDef((MethodSymbol)valuesSym, make.Block(0, valuesBody));
jjg@86	2362
duke@1	2363	enumDefs.append(valuesDef);
duke@1	2364
jjg@86	2365	if (debugLower)
jjg@86	2366	System.err.println(tree.sym + ".valuesDef = " + valuesDef);
jjg@86	2367
duke@1	2368	/** The template for the following code is:
duke@1	2369	*
duke@1	2370	* public static E valueOf(String name) {
duke@1	2371	* return (E)Enum.valueOf(E.class, name);
duke@1	2372	* }
duke@1	2373	*
duke@1	2374	* where E is tree.sym
duke@1	2375	*/
duke@1	2376	MethodSymbol valueOfSym = lookupMethod(tree.pos(),
duke@1	2377	names.valueOf,
duke@1	2378	tree.sym.type,
duke@1	2379	List.of(syms.stringType));
duke@1	2380	assert (valueOfSym.flags() & STATIC) != 0;
duke@1	2381	VarSymbol nameArgSym = valueOfSym.params.head;
duke@1	2382	JCIdent nameVal = make.Ident(nameArgSym);
duke@1	2383	JCStatement enum_ValueOf =
duke@1	2384	make.Return(make.TypeCast(tree.sym.type,
duke@1	2385	makeCall(make.Ident(syms.enumSym),
duke@1	2386	names.valueOf,
duke@1	2387	List.of(e_class, nameVal))));
duke@1	2388	JCMethodDecl valueOf = make.MethodDef(valueOfSym,
duke@1	2389	make.Block(0, List.of(enum_ValueOf)));
duke@1	2390	nameVal.sym = valueOf.params.head.sym;
duke@1	2391	if (debugLower)
duke@1	2392	System.err.println(tree.sym + ".valueOf = " + valueOf);
duke@1	2393	enumDefs.append(valueOf);
duke@1	2394
duke@1	2395	enumDefs.appendList(otherDefs.toList());
duke@1	2396	tree.defs = enumDefs.toList();
duke@1	2397
duke@1	2398	// Add the necessary members for the EnumCompatibleMode
duke@1	2399	if (target.compilerBootstrap(tree.sym)) {
duke@1	2400	addEnumCompatibleMembers(tree);
duke@1	2401	}
duke@1	2402	}
jjg@86	2403	// where
jjg@86	2404	private MethodSymbol systemArraycopyMethod;
jjg@86	2405	private boolean useClone() {
jjg@86	2406	try {
jjg@86	2407	Scope.Entry e = syms.objectType.tsym.members().lookup(names.clone);
jjg@86	2408	return (e.sym != null);
jjg@86	2409	}
jjg@86	2410	catch (CompletionFailure e) {
jjg@86	2411	return false;
jjg@86	2412	}
jjg@86	2413	}
duke@1	2414
duke@1	2415	/** Translate an enumeration constant and its initializer. */
duke@1	2416	private void visitEnumConstantDef(JCVariableDecl var, int ordinal) {
duke@1	2417	JCNewClass varDef = (JCNewClass)var.init;
duke@1	2418	varDef.args = varDef.args.
duke@1	2419	prepend(makeLit(syms.intType, ordinal)).
duke@1	2420	prepend(makeLit(syms.stringType, var.name.toString()));
duke@1	2421	}
duke@1	2422
duke@1	2423	public void visitMethodDef(JCMethodDecl tree) {
duke@1	2424	if (tree.name == names.init && (currentClass.flags_field&ENUM) != 0) {
duke@1	2425	// Add "String $enum$name, int $enum$ordinal" to the beginning of the
duke@1	2426	// argument list for each constructor of an enum.
duke@1	2427	JCVariableDecl nameParam = make_at(tree.pos()).
duke@1	2428	Param(names.fromString(target.syntheticNameChar() +
duke@1	2429	"enum" + target.syntheticNameChar() + "name"),
duke@1	2430	syms.stringType, tree.sym);
duke@1	2431	nameParam.mods.flags |= SYNTHETIC; nameParam.sym.flags_field |= SYNTHETIC;
duke@1	2432
duke@1	2433	JCVariableDecl ordParam = make.
duke@1	2434	Param(names.fromString(target.syntheticNameChar() +
duke@1	2435	"enum" + target.syntheticNameChar() +
duke@1	2436	"ordinal"),
duke@1	2437	syms.intType, tree.sym);
duke@1	2438	ordParam.mods.flags |= SYNTHETIC; ordParam.sym.flags_field |= SYNTHETIC;
duke@1	2439
duke@1	2440	tree.params = tree.params.prepend(ordParam).prepend(nameParam);
duke@1	2441
duke@1	2442	MethodSymbol m = tree.sym;
duke@1	2443	Type olderasure = m.erasure(types);
duke@1	2444	m.erasure_field = new MethodType(
duke@1	2445	olderasure.getParameterTypes().prepend(syms.intType).prepend(syms.stringType),
duke@1	2446	olderasure.getReturnType(),
duke@1	2447	olderasure.getThrownTypes(),
duke@1	2448	syms.methodClass);
duke@1	2449
duke@1	2450	if (target.compilerBootstrap(m.owner)) {
duke@1	2451	// Initialize synthetic name field
duke@1	2452	Symbol nameVarSym = lookupSynthetic(names.fromString("$name"),
duke@1	2453	tree.sym.owner.members());
duke@1	2454	JCIdent nameIdent = make.Ident(nameParam.sym);
duke@1	2455	JCIdent id1 = make.Ident(nameVarSym);
duke@1	2456	JCAssign newAssign = make.Assign(id1, nameIdent);
duke@1	2457	newAssign.type = id1.type;
duke@1	2458	JCExpressionStatement nameAssign = make.Exec(newAssign);
duke@1	2459	nameAssign.type = id1.type;
duke@1	2460	tree.body.stats = tree.body.stats.prepend(nameAssign);
duke@1	2461
duke@1	2462	// Initialize synthetic ordinal field
duke@1	2463	Symbol ordinalVarSym = lookupSynthetic(names.fromString("$ordinal"),
duke@1	2464	tree.sym.owner.members());
duke@1	2465	JCIdent ordIdent = make.Ident(ordParam.sym);
duke@1	2466	id1 = make.Ident(ordinalVarSym);
duke@1	2467	newAssign = make.Assign(id1, ordIdent);
duke@1	2468	newAssign.type = id1.type;
duke@1	2469	JCExpressionStatement ordinalAssign = make.Exec(newAssign);
duke@1	2470	ordinalAssign.type = id1.type;
duke@1	2471	tree.body.stats = tree.body.stats.prepend(ordinalAssign);
duke@1	2472	}
duke@1	2473	}
duke@1	2474
duke@1	2475	JCMethodDecl prevMethodDef = currentMethodDef;
duke@1	2476	MethodSymbol prevMethodSym = currentMethodSym;
duke@1	2477	try {
duke@1	2478	currentMethodDef = tree;
duke@1	2479	currentMethodSym = tree.sym;
duke@1	2480	visitMethodDefInternal(tree);
duke@1	2481	} finally {
duke@1	2482	currentMethodDef = prevMethodDef;
duke@1	2483	currentMethodSym = prevMethodSym;
duke@1	2484	}
duke@1	2485	}
duke@1	2486	//where
duke@1	2487	private void visitMethodDefInternal(JCMethodDecl tree) {
duke@1	2488	if (tree.name == names.init &&
duke@1	2489	(currentClass.isInner() ||
duke@1	2490	(currentClass.owner.kind & (VAR | MTH)) != 0)) {
duke@1	2491	// We are seeing a constructor of an inner class.
duke@1	2492	MethodSymbol m = tree.sym;
duke@1	2493
duke@1	2494	// Push a new proxy scope for constructor parameters.
duke@1	2495	// and create definitions for any this$n and proxy parameters.
duke@1	2496	proxies = proxies.dup(m);
duke@1	2497	List<VarSymbol> prevOuterThisStack = outerThisStack;
duke@1	2498	List<VarSymbol> fvs = freevars(currentClass);
duke@1	2499	JCVariableDecl otdef = null;
duke@1	2500	if (currentClass.hasOuterInstance())
duke@1	2501	otdef = outerThisDef(tree.pos, m);
duke@1	2502	List<JCVariableDecl> fvdefs = freevarDefs(tree.pos, fvs, m);
duke@1	2503
duke@1	2504	// Recursively translate result type, parameters and thrown list.
duke@1	2505	tree.restype = translate(tree.restype);
duke@1	2506	tree.params = translateVarDefs(tree.params);
duke@1	2507	tree.thrown = translate(tree.thrown);
duke@1	2508
duke@1	2509	// when compiling stubs, don't process body
duke@1	2510	if (tree.body == null) {
duke@1	2511	result = tree;
duke@1	2512	return;
duke@1	2513	}
duke@1	2514
duke@1	2515	// Add this$n (if needed) in front of and free variables behind
duke@1	2516	// constructor parameter list.
duke@1	2517	tree.params = tree.params.appendList(fvdefs);
duke@1	2518	if (currentClass.hasOuterInstance())
duke@1	2519	tree.params = tree.params.prepend(otdef);
duke@1	2520
duke@1	2521	// If this is an initial constructor, i.e., it does not start with
duke@1	2522	// this(...), insert initializers for this$n and proxies
duke@1	2523	// before (pre-1.4, after) the call to superclass constructor.
duke@1	2524	JCStatement selfCall = translate(tree.body.stats.head);
duke@1	2525
duke@1	2526	List<JCStatement> added = List.nil();
duke@1	2527	if (fvs.nonEmpty()) {
duke@1	2528	List<Type> addedargtypes = List.nil();
duke@1	2529	for (List<VarSymbol> l = fvs; l.nonEmpty(); l = l.tail) {
duke@1	2530	if (TreeInfo.isInitialConstructor(tree))
duke@1	2531	added = added.prepend(
duke@1	2532	initField(tree.body.pos, proxyName(l.head.name)));
duke@1	2533	addedargtypes = addedargtypes.prepend(l.head.erasure(types));
duke@1	2534	}
duke@1	2535	Type olderasure = m.erasure(types);
duke@1	2536	m.erasure_field = new MethodType(
duke@1	2537	olderasure.getParameterTypes().appendList(addedargtypes),
duke@1	2538	olderasure.getReturnType(),
duke@1	2539	olderasure.getThrownTypes(),
duke@1	2540	syms.methodClass);
duke@1	2541	}
duke@1	2542	if (currentClass.hasOuterInstance() &&
duke@1	2543	TreeInfo.isInitialConstructor(tree))
duke@1	2544	{
duke@1	2545	added = added.prepend(initOuterThis(tree.body.pos));
duke@1	2546	}
duke@1	2547
duke@1	2548	// pop local variables from proxy stack
duke@1	2549	proxies = proxies.leave();
duke@1	2550
duke@1	2551	// recursively translate following local statements and
duke@1	2552	// combine with this- or super-call
duke@1	2553	List<JCStatement> stats = translate(tree.body.stats.tail);
duke@1	2554	if (target.initializeFieldsBeforeSuper())
duke@1	2555	tree.body.stats = stats.prepend(selfCall).prependList(added);
duke@1	2556	else
duke@1	2557	tree.body.stats = stats.prependList(added).prepend(selfCall);
duke@1	2558
duke@1	2559	outerThisStack = prevOuterThisStack;
duke@1	2560	} else {
duke@1	2561	super.visitMethodDef(tree);
duke@1	2562	}
duke@1	2563	result = tree;
duke@1	2564	}
duke@1	2565
jjg@308	2566	public void visitAnnotatedType(JCAnnotatedType tree) {
jjg@308	2567	tree.underlyingType = translate(tree.underlyingType);
jjg@308	2568	result = tree.underlyingType;
jjg@308	2569	}
jjg@308	2570
duke@1	2571	public void visitTypeCast(JCTypeCast tree) {
duke@1	2572	tree.clazz = translate(tree.clazz);
duke@1	2573	if (tree.type.isPrimitive() != tree.expr.type.isPrimitive())
duke@1	2574	tree.expr = translate(tree.expr, tree.type);
duke@1	2575	else
duke@1	2576	tree.expr = translate(tree.expr);
duke@1	2577	result = tree;
duke@1	2578	}
duke@1	2579
duke@1	2580	public void visitNewClass(JCNewClass tree) {
duke@1	2581	ClassSymbol c = (ClassSymbol)tree.constructor.owner;
duke@1	2582
duke@1	2583	// Box arguments, if necessary
duke@1	2584	boolean isEnum = (tree.constructor.owner.flags() & ENUM) != 0;
duke@1	2585	List<Type> argTypes = tree.constructor.type.getParameterTypes();
duke@1	2586	if (isEnum) argTypes = argTypes.prepend(syms.intType).prepend(syms.stringType);
duke@1	2587	tree.args = boxArgs(argTypes, tree.args, tree.varargsElement);
duke@1	2588	tree.varargsElement = null;
duke@1	2589
duke@1	2590	// If created class is local, add free variables after
duke@1	2591	// explicit constructor arguments.
duke@1	2592	if ((c.owner.kind & (VAR | MTH)) != 0) {
duke@1	2593	tree.args = tree.args.appendList(loadFreevars(tree.pos(), freevars(c)));
duke@1	2594	}
duke@1	2595
duke@1	2596	// If an access constructor is used, append null as a last argument.
duke@1	2597	Symbol constructor = accessConstructor(tree.pos(), tree.constructor);
duke@1	2598	if (constructor != tree.constructor) {
duke@1	2599	tree.args = tree.args.append(makeNull());
duke@1	2600	tree.constructor = constructor;
duke@1	2601	}
duke@1	2602
duke@1	2603	// If created class has an outer instance, and new is qualified, pass
duke@1	2604	// qualifier as first argument. If new is not qualified, pass the
duke@1	2605	// correct outer instance as first argument.
duke@1	2606	if (c.hasOuterInstance()) {
duke@1	2607	JCExpression thisArg;
duke@1	2608	if (tree.encl != null) {
duke@1	2609	thisArg = attr.makeNullCheck(translate(tree.encl));
duke@1	2610	thisArg.type = tree.encl.type;
duke@1	2611	} else if ((c.owner.kind & (MTH | VAR)) != 0) {
duke@1	2612	// local class
duke@1	2613	thisArg = makeThis(tree.pos(), c.type.getEnclosingType().tsym);
duke@1	2614	} else {
duke@1	2615	// nested class
duke@1	2616	thisArg = makeOwnerThis(tree.pos(), c, false);
duke@1	2617	}
duke@1	2618	tree.args = tree.args.prepend(thisArg);
duke@1	2619	}
duke@1	2620	tree.encl = null;
duke@1	2621
duke@1	2622	// If we have an anonymous class, create its flat version, rather
duke@1	2623	// than the class or interface following new.
duke@1	2624	if (tree.def != null) {
duke@1	2625	translate(tree.def);
duke@1	2626	tree.clazz = access(make_at(tree.clazz.pos()).Ident(tree.def.sym));
duke@1	2627	tree.def = null;
duke@1	2628	} else {
duke@1	2629	tree.clazz = access(c, tree.clazz, enclOp, false);
duke@1	2630	}
duke@1	2631	result = tree;
duke@1	2632	}
duke@1	2633
duke@1	2634	// Simplify conditionals with known constant controlling expressions.
duke@1	2635	// This allows us to avoid generating supporting declarations for
duke@1	2636	// the dead code, which will not be eliminated during code generation.
duke@1	2637	// Note that Flow.isFalse and Flow.isTrue only return true
duke@1	2638	// for constant expressions in the sense of JLS 15.27, which
darcy@430	2639	// are guaranteed to have no side-effects. More aggressive
duke@1	2640	// constant propagation would require that we take care to
duke@1	2641	// preserve possible side-effects in the condition expression.
duke@1	2642
duke@1	2643	/** Visitor method for conditional expressions.
duke@1	2644	*/
duke@1	2645	public void visitConditional(JCConditional tree) {
duke@1	2646	JCTree cond = tree.cond = translate(tree.cond, syms.booleanType);
duke@1	2647	if (cond.type.isTrue()) {
duke@1	2648	result = convert(translate(tree.truepart, tree.type), tree.type);
duke@1	2649	} else if (cond.type.isFalse()) {
duke@1	2650	result = convert(translate(tree.falsepart, tree.type), tree.type);
duke@1	2651	} else {
duke@1	2652	// Condition is not a compile-time constant.
duke@1	2653	tree.truepart = translate(tree.truepart, tree.type);
duke@1	2654	tree.falsepart = translate(tree.falsepart, tree.type);
duke@1	2655	result = tree;
duke@1	2656	}
duke@1	2657	}
duke@1	2658	//where
duke@1	2659	private JCTree convert(JCTree tree, Type pt) {
duke@1	2660	if (tree.type == pt) return tree;
duke@1	2661	JCTree result = make_at(tree.pos()).TypeCast(make.Type(pt), (JCExpression)tree);
duke@1	2662	result.type = (tree.type.constValue() != null) ? cfolder.coerce(tree.type, pt)
duke@1	2663	: pt;
duke@1	2664	return result;
duke@1	2665	}
duke@1	2666
duke@1	2667	/** Visitor method for if statements.
duke@1	2668	*/
duke@1	2669	public void visitIf(JCIf tree) {
duke@1	2670	JCTree cond = tree.cond = translate(tree.cond, syms.booleanType);
duke@1	2671	if (cond.type.isTrue()) {
duke@1	2672	result = translate(tree.thenpart);
duke@1	2673	} else if (cond.type.isFalse()) {
duke@1	2674	if (tree.elsepart != null) {
duke@1	2675	result = translate(tree.elsepart);
duke@1	2676	} else {
duke@1	2677	result = make.Skip();
duke@1	2678	}
duke@1	2679	} else {
duke@1	2680	// Condition is not a compile-time constant.
duke@1	2681	tree.thenpart = translate(tree.thenpart);
duke@1	2682	tree.elsepart = translate(tree.elsepart);
duke@1	2683	result = tree;
duke@1	2684	}
duke@1	2685	}
duke@1	2686
duke@1	2687	/** Visitor method for assert statements. Translate them away.
duke@1	2688	*/
duke@1	2689	public void visitAssert(JCAssert tree) {
duke@1	2690	DiagnosticPosition detailPos = (tree.detail == null) ? tree.pos() : tree.detail.pos();
duke@1	2691	tree.cond = translate(tree.cond, syms.booleanType);
duke@1	2692	if (!tree.cond.type.isTrue()) {
duke@1	2693	JCExpression cond = assertFlagTest(tree.pos());
duke@1	2694	List<JCExpression> exnArgs = (tree.detail == null) ?
duke@1	2695	List.<JCExpression>nil() : List.of(translate(tree.detail));
duke@1	2696	if (!tree.cond.type.isFalse()) {
duke@1	2697	cond = makeBinary
duke@1	2698	(JCTree.AND,
duke@1	2699	cond,
duke@1	2700	makeUnary(JCTree.NOT, tree.cond));
duke@1	2701	}
duke@1	2702	result =
duke@1	2703	make.If(cond,
duke@1	2704	make_at(detailPos).
duke@1	2705	Throw(makeNewClass(syms.assertionErrorType, exnArgs)),
duke@1	2706	null);
duke@1	2707	} else {
duke@1	2708	result = make.Skip();
duke@1	2709	}
duke@1	2710	}
duke@1	2711
duke@1	2712	public void visitApply(JCMethodInvocation tree) {
duke@1	2713	Symbol meth = TreeInfo.symbol(tree.meth);
duke@1	2714	List<Type> argtypes = meth.type.getParameterTypes();
duke@1	2715	if (allowEnums &&
duke@1	2716	meth.name==names.init &&
duke@1	2717	meth.owner == syms.enumSym)
duke@1	2718	argtypes = argtypes.tail.tail;
duke@1	2719	tree.args = boxArgs(argtypes, tree.args, tree.varargsElement);
duke@1	2720	tree.varargsElement = null;
duke@1	2721	Name methName = TreeInfo.name(tree.meth);
duke@1	2722	if (meth.name==names.init) {
duke@1	2723	// We are seeing a this(...) or super(...) constructor call.
duke@1	2724	// If an access constructor is used, append null as a last argument.
duke@1	2725	Symbol constructor = accessConstructor(tree.pos(), meth);
duke@1	2726	if (constructor != meth) {
duke@1	2727	tree.args = tree.args.append(makeNull());
duke@1	2728	TreeInfo.setSymbol(tree.meth, constructor);
duke@1	2729	}
duke@1	2730
duke@1	2731	// If we are calling a constructor of a local class, add
duke@1	2732	// free variables after explicit constructor arguments.
duke@1	2733	ClassSymbol c = (ClassSymbol)constructor.owner;
duke@1	2734	if ((c.owner.kind & (VAR | MTH)) != 0) {
duke@1	2735	tree.args = tree.args.appendList(loadFreevars(tree.pos(), freevars(c)));
duke@1	2736	}
duke@1	2737
duke@1	2738	// If we are calling a constructor of an enum class, pass
duke@1	2739	// along the name and ordinal arguments
duke@1	2740	if ((c.flags_field&ENUM) != 0 || c.getQualifiedName() == names.java_lang_Enum) {
duke@1	2741	List<JCVariableDecl> params = currentMethodDef.params;
duke@1	2742	if (currentMethodSym.owner.hasOuterInstance())
duke@1	2743	params = params.tail; // drop this$n
duke@1	2744	tree.args = tree.args
duke@1	2745	.prepend(make_at(tree.pos()).Ident(params.tail.head.sym)) // ordinal
duke@1	2746	.prepend(make.Ident(params.head.sym)); // name
duke@1	2747	}
duke@1	2748
duke@1	2749	// If we are calling a constructor of a class with an outer
duke@1	2750	// instance, and the call
duke@1	2751	// is qualified, pass qualifier as first argument in front of
duke@1	2752	// the explicit constructor arguments. If the call
duke@1	2753	// is not qualified, pass the correct outer instance as
duke@1	2754	// first argument.
duke@1	2755	if (c.hasOuterInstance()) {
duke@1	2756	JCExpression thisArg;
duke@1	2757	if (tree.meth.getTag() == JCTree.SELECT) {
duke@1	2758	thisArg = attr.
duke@1	2759	makeNullCheck(translate(((JCFieldAccess) tree.meth).selected));
duke@1	2760	tree.meth = make.Ident(constructor);
duke@1	2761	((JCIdent) tree.meth).name = methName;
duke@1	2762	} else if ((c.owner.kind & (MTH | VAR)) != 0 || methName == names._this){
duke@1	2763	// local class or this() call
duke@1	2764	thisArg = makeThis(tree.meth.pos(), c.type.getEnclosingType().tsym);
duke@1	2765	} else {
duke@1	2766	// super() call of nested class
duke@1	2767	thisArg = makeOwnerThis(tree.meth.pos(), c, false);
duke@1	2768	}
duke@1	2769	tree.args = tree.args.prepend(thisArg);
duke@1	2770	}
duke@1	2771	} else {
duke@1	2772	// We are seeing a normal method invocation; translate this as usual.
duke@1	2773	tree.meth = translate(tree.meth);
duke@1	2774
duke@1	2775	// If the translated method itself is an Apply tree, we are
duke@1	2776	// seeing an access method invocation. In this case, append
duke@1	2777	// the method arguments to the arguments of the access method.
duke@1	2778	if (tree.meth.getTag() == JCTree.APPLY) {
duke@1	2779	JCMethodInvocation app = (JCMethodInvocation)tree.meth;
duke@1	2780	app.args = tree.args.prependList(app.args);
duke@1	2781	result = app;
duke@1	2782	return;
duke@1	2783	}
duke@1	2784	}
duke@1	2785	result = tree;
duke@1	2786	}
duke@1	2787
duke@1	2788	List<JCExpression> boxArgs(List<Type> parameters, List<JCExpression> _args, Type varargsElement) {
duke@1	2789	List<JCExpression> args = _args;
duke@1	2790	if (parameters.isEmpty()) return args;
duke@1	2791	boolean anyChanges = false;
duke@1	2792	ListBuffer<JCExpression> result = new ListBuffer<JCExpression>();
duke@1	2793	while (parameters.tail.nonEmpty()) {
duke@1	2794	JCExpression arg = translate(args.head, parameters.head);
duke@1	2795	anyChanges |= (arg != args.head);
duke@1	2796	result.append(arg);
duke@1	2797	args = args.tail;
duke@1	2798	parameters = parameters.tail;
duke@1	2799	}
duke@1	2800	Type parameter = parameters.head;
duke@1	2801	if (varargsElement != null) {
duke@1	2802	anyChanges = true;
duke@1	2803	ListBuffer<JCExpression> elems = new ListBuffer<JCExpression>();
duke@1	2804	while (args.nonEmpty()) {
duke@1	2805	JCExpression arg = translate(args.head, varargsElement);
duke@1	2806	elems.append(arg);
duke@1	2807	args = args.tail;
duke@1	2808	}
duke@1	2809	JCNewArray boxedArgs = make.NewArray(make.Type(varargsElement),
duke@1	2810	List.<JCExpression>nil(),
duke@1	2811	elems.toList());
duke@1	2812	boxedArgs.type = new ArrayType(varargsElement, syms.arrayClass);
duke@1	2813	result.append(boxedArgs);
duke@1	2814	} else {
duke@1	2815	if (args.length() != 1) throw new AssertionError(args);
duke@1	2816	JCExpression arg = translate(args.head, parameter);
duke@1	2817	anyChanges |= (arg != args.head);
duke@1	2818	result.append(arg);
duke@1	2819	if (!anyChanges) return _args;
duke@1	2820	}
duke@1	2821	return result.toList();
duke@1	2822	}
duke@1	2823
duke@1	2824	/** Expand a boxing or unboxing conversion if needed. */
duke@1	2825	@SuppressWarnings("unchecked") // XXX unchecked
duke@1	2826	<T extends JCTree> T boxIfNeeded(T tree, Type type) {
duke@1	2827	boolean havePrimitive = tree.type.isPrimitive();
duke@1	2828	if (havePrimitive == type.isPrimitive())
duke@1	2829	return tree;
duke@1	2830	if (havePrimitive) {
duke@1	2831	Type unboxedTarget = types.unboxedType(type);
duke@1	2832	if (unboxedTarget.tag != NONE) {
mcimadamore@253	2833	if (!types.isSubtype(tree.type, unboxedTarget)) //e.g. Character c = 89;
mcimadamore@253	2834	tree.type = unboxedTarget.constType(tree.type.constValue());
duke@1	2835	return (T)boxPrimitive((JCExpression)tree, type);
duke@1	2836	} else {
duke@1	2837	tree = (T)boxPrimitive((JCExpression)tree);
duke@1	2838	}
duke@1	2839	} else {
duke@1	2840	tree = (T)unbox((JCExpression)tree, type);
duke@1	2841	}
duke@1	2842	return tree;
duke@1	2843	}
duke@1	2844
duke@1	2845	/** Box up a single primitive expression. */
duke@1	2846	JCExpression boxPrimitive(JCExpression tree) {
duke@1	2847	return boxPrimitive(tree, types.boxedClass(tree.type).type);
duke@1	2848	}
duke@1	2849
duke@1	2850	/** Box up a single primitive expression. */
duke@1	2851	JCExpression boxPrimitive(JCExpression tree, Type box) {
duke@1	2852	make_at(tree.pos());
duke@1	2853	if (target.boxWithConstructors()) {
duke@1	2854	Symbol ctor = lookupConstructor(tree.pos(),
duke@1	2855	box,
duke@1	2856	List.<Type>nil()
duke@1	2857	.prepend(tree.type));
duke@1	2858	return make.Create(ctor, List.of(tree));
duke@1	2859	} else {
duke@1	2860	Symbol valueOfSym = lookupMethod(tree.pos(),
duke@1	2861	names.valueOf,
duke@1	2862	box,
duke@1	2863	List.<Type>nil()
duke@1	2864	.prepend(tree.type));
duke@1	2865	return make.App(make.QualIdent(valueOfSym), List.of(tree));
duke@1	2866	}
duke@1	2867	}
duke@1	2868
duke@1	2869	/** Unbox an object to a primitive value. */
duke@1	2870	JCExpression unbox(JCExpression tree, Type primitive) {
duke@1	2871	Type unboxedType = types.unboxedType(tree.type);
duke@1	2872	// note: the "primitive" parameter is not used. There muse be
duke@1	2873	// a conversion from unboxedType to primitive.
duke@1	2874	make_at(tree.pos());
duke@1	2875	Symbol valueSym = lookupMethod(tree.pos(),
duke@1	2876	unboxedType.tsym.name.append(names.Value), // x.intValue()
duke@1	2877	tree.type,
duke@1	2878	List.<Type>nil());
duke@1	2879	return make.App(make.Select(tree, valueSym));
duke@1	2880	}
duke@1	2881
duke@1	2882	/** Visitor method for parenthesized expressions.
duke@1	2883	* If the subexpression has changed, omit the parens.
duke@1	2884	*/
duke@1	2885	public void visitParens(JCParens tree) {
duke@1	2886	JCTree expr = translate(tree.expr);
duke@1	2887	result = ((expr == tree.expr) ? tree : expr);
duke@1	2888	}
duke@1	2889
duke@1	2890	public void visitIndexed(JCArrayAccess tree) {
duke@1	2891	tree.indexed = translate(tree.indexed);
duke@1	2892	tree.index = translate(tree.index, syms.intType);
duke@1	2893	result = tree;
duke@1	2894	}
duke@1	2895
duke@1	2896	public void visitAssign(JCAssign tree) {
duke@1	2897	tree.lhs = translate(tree.lhs, tree);
duke@1	2898	tree.rhs = translate(tree.rhs, tree.lhs.type);
duke@1	2899
duke@1	2900	// If translated left hand side is an Apply, we are
duke@1	2901	// seeing an access method invocation. In this case, append
duke@1	2902	// right hand side as last argument of the access method.
duke@1	2903	if (tree.lhs.getTag() == JCTree.APPLY) {
duke@1	2904	JCMethodInvocation app = (JCMethodInvocation)tree.lhs;
duke@1	2905	app.args = List.of(tree.rhs).prependList(app.args);
duke@1	2906	result = app;
duke@1	2907	} else {
duke@1	2908	result = tree;
duke@1	2909	}
duke@1	2910	}
duke@1	2911
duke@1	2912	public void visitAssignop(final JCAssignOp tree) {
duke@1	2913	if (!tree.lhs.type.isPrimitive() &&
duke@1	2914	tree.operator.type.getReturnType().isPrimitive()) {
duke@1	2915	// boxing required; need to rewrite as x = (unbox typeof x)(x op y);
duke@1	2916	// or if x == (typeof x)z then z = (unbox typeof x)((typeof x)z op y)
duke@1	2917	// (but without recomputing x)
mcimadamore@133	2918	JCTree newTree = abstractLval(tree.lhs, new TreeBuilder() {
duke@1	2919	public JCTree build(final JCTree lhs) {
duke@1	2920	int newTag = tree.getTag() - JCTree.ASGOffset;
duke@1	2921	// Erasure (TransTypes) can change the type of
duke@1	2922	// tree.lhs. However, we can still get the
duke@1	2923	// unerased type of tree.lhs as it is stored
duke@1	2924	// in tree.type in Attr.
duke@1	2925	Symbol newOperator = rs.resolveBinaryOperator(tree.pos(),
duke@1	2926	newTag,
duke@1	2927	attrEnv,
duke@1	2928	tree.type,
duke@1	2929	tree.rhs.type);
duke@1	2930	JCExpression expr = (JCExpression)lhs;
duke@1	2931	if (expr.type != tree.type)
duke@1	2932	expr = make.TypeCast(tree.type, expr);
duke@1	2933	JCBinary opResult = make.Binary(newTag, expr, tree.rhs);
duke@1	2934	opResult.operator = newOperator;
duke@1	2935	opResult.type = newOperator.type.getReturnType();
duke@1	2936	JCTypeCast newRhs = make.TypeCast(types.unboxedType(tree.type),
duke@1	2937	opResult);
duke@1	2938	return make.Assign((JCExpression)lhs, newRhs).setType(tree.type);
duke@1	2939	}
duke@1	2940	});
duke@1	2941	result = translate(newTree);
duke@1	2942	return;
duke@1	2943	}
duke@1	2944	tree.lhs = translate(tree.lhs, tree);
duke@1	2945	tree.rhs = translate(tree.rhs, tree.operator.type.getParameterTypes().tail.head);
duke@1	2946
duke@1	2947	// If translated left hand side is an Apply, we are
duke@1	2948	// seeing an access method invocation. In this case, append
duke@1	2949	// right hand side as last argument of the access method.
duke@1	2950	if (tree.lhs.getTag() == JCTree.APPLY) {
duke@1	2951	JCMethodInvocation app = (JCMethodInvocation)tree.lhs;
duke@1	2952	// if operation is a += on strings,
duke@1	2953	// make sure to convert argument to string
duke@1	2954	JCExpression rhs = (((OperatorSymbol)tree.operator).opcode == string_add)
duke@1	2955	? makeString(tree.rhs)
duke@1	2956	: tree.rhs;
duke@1	2957	app.args = List.of(rhs).prependList(app.args);
duke@1	2958	result = app;
duke@1	2959	} else {
duke@1	2960	result = tree;
duke@1	2961	}
duke@1	2962	}
duke@1	2963
duke@1	2964	/** Lower a tree of the form e++ or e-- where e is an object type */
duke@1	2965	JCTree lowerBoxedPostop(final JCUnary tree) {
duke@1	2966	// translate to tmp1=lval(e); tmp2=tmp1; tmp1 OP 1; tmp2
duke@1	2967	// or
duke@1	2968	// translate to tmp1=lval(e); tmp2=tmp1; (typeof tree)tmp1 OP 1; tmp2
duke@1	2969	// where OP is += or -=
mcimadamore@133	2970	final boolean cast = TreeInfo.skipParens(tree.arg).getTag() == JCTree.TYPECAST;
mcimadamore@133	2971	return abstractLval(tree.arg, new TreeBuilder() {
duke@1	2972	public JCTree build(final JCTree tmp1) {
duke@1	2973	return abstractRval(tmp1, tree.arg.type, new TreeBuilder() {
duke@1	2974	public JCTree build(final JCTree tmp2) {
duke@1	2975	int opcode = (tree.getTag() == JCTree.POSTINC)
duke@1	2976	? JCTree.PLUS_ASG : JCTree.MINUS_ASG;
duke@1	2977	JCTree lhs = cast
duke@1	2978	? make.TypeCast(tree.arg.type, (JCExpression)tmp1)
duke@1	2979	: tmp1;
duke@1	2980	JCTree update = makeAssignop(opcode,
duke@1	2981	lhs,
duke@1	2982	make.Literal(1));
duke@1	2983	return makeComma(update, tmp2);
duke@1	2984	}
duke@1	2985	});
duke@1	2986	}
duke@1	2987	});
duke@1	2988	}
duke@1	2989
duke@1	2990	public void visitUnary(JCUnary tree) {
duke@1	2991	boolean isUpdateOperator =
duke@1	2992	JCTree.PREINC <= tree.getTag() && tree.getTag() <= JCTree.POSTDEC;
duke@1	2993	if (isUpdateOperator && !tree.arg.type.isPrimitive()) {
duke@1	2994	switch(tree.getTag()) {
duke@1	2995	case JCTree.PREINC: // ++ e
duke@1	2996	// translate to e += 1
duke@1	2997	case JCTree.PREDEC: // -- e
duke@1	2998	// translate to e -= 1
duke@1	2999	{
duke@1	3000	int opcode = (tree.getTag() == JCTree.PREINC)
duke@1	3001	? JCTree.PLUS_ASG : JCTree.MINUS_ASG;
duke@1	3002	JCAssignOp newTree = makeAssignop(opcode,
duke@1	3003	tree.arg,
duke@1	3004	make.Literal(1));
duke@1	3005	result = translate(newTree, tree.type);
duke@1	3006	return;
duke@1	3007	}
duke@1	3008	case JCTree.POSTINC: // e ++
duke@1	3009	case JCTree.POSTDEC: // e --
duke@1	3010	{
duke@1	3011	result = translate(lowerBoxedPostop(tree), tree.type);
duke@1	3012	return;
duke@1	3013	}
duke@1	3014	}
duke@1	3015	throw new AssertionError(tree);
duke@1	3016	}
duke@1	3017
duke@1	3018	tree.arg = boxIfNeeded(translate(tree.arg, tree), tree.type);
duke@1	3019
duke@1	3020	if (tree.getTag() == JCTree.NOT && tree.arg.type.constValue() != null) {
duke@1	3021	tree.type = cfolder.fold1(bool_not, tree.arg.type);
duke@1	3022	}
duke@1	3023
duke@1	3024	// If translated left hand side is an Apply, we are
duke@1	3025	// seeing an access method invocation. In this case, return
darcy@430	3026	// that access method invocation as result.
duke@1	3027	if (isUpdateOperator && tree.arg.getTag() == JCTree.APPLY) {
duke@1	3028	result = tree.arg;
duke@1	3029	} else {
duke@1	3030	result = tree;
duke@1	3031	}
duke@1	3032	}
duke@1	3033
duke@1	3034	public void visitBinary(JCBinary tree) {
duke@1	3035	List<Type> formals = tree.operator.type.getParameterTypes();
duke@1	3036	JCTree lhs = tree.lhs = translate(tree.lhs, formals.head);
duke@1	3037	switch (tree.getTag()) {
duke@1	3038	case JCTree.OR:
duke@1	3039	if (lhs.type.isTrue()) {
duke@1	3040	result = lhs;
duke@1	3041	return;
duke@1	3042	}
duke@1	3043	if (lhs.type.isFalse()) {
duke@1	3044	result = translate(tree.rhs, formals.tail.head);
duke@1	3045	return;
duke@1	3046	}
duke@1	3047	break;
duke@1	3048	case JCTree.AND:
duke@1	3049	if (lhs.type.isFalse()) {
duke@1	3050	result = lhs;
duke@1	3051	return;
duke@1	3052	}
duke@1	3053	if (lhs.type.isTrue()) {
duke@1	3054	result = translate(tree.rhs, formals.tail.head);
duke@1	3055	return;
duke@1	3056	}
duke@1	3057	break;
duke@1	3058	}
duke@1	3059	tree.rhs = translate(tree.rhs, formals.tail.head);
duke@1	3060	result = tree;
duke@1	3061	}
duke@1	3062
duke@1	3063	public void visitIdent(JCIdent tree) {
duke@1	3064	result = access(tree.sym, tree, enclOp, false);
duke@1	3065	}
duke@1	3066
duke@1	3067	/** Translate away the foreach loop. */
duke@1	3068	public void visitForeachLoop(JCEnhancedForLoop tree) {
duke@1	3069	if (types.elemtype(tree.expr.type) == null)
duke@1	3070	visitIterableForeachLoop(tree);
duke@1	3071	else
duke@1	3072	visitArrayForeachLoop(tree);
duke@1	3073	}
duke@1	3074	// where
duke@1	3075	/**
darcy@430	3076	* A statement of the form
duke@1	3077	*
duke@1	3078	* <pre>
duke@1	3079	* for ( T v : arrayexpr ) stmt;
duke@1	3080	* </pre>
duke@1	3081	*
duke@1	3082	* (where arrayexpr is of an array type) gets translated to
duke@1	3083	*
duke@1	3084	* <pre>
duke@1	3085	* for ( { arraytype #arr = arrayexpr;
duke@1	3086	* int #len = array.length;
duke@1	3087	* int #i = 0; };
duke@1	3088	* #i < #len; i$++ ) {
duke@1	3089	* T v = arr$[#i];
duke@1	3090	* stmt;
duke@1	3091	* }
duke@1	3092	* </pre>
duke@1	3093	*
duke@1	3094	* where #arr, #len, and #i are freshly named synthetic local variables.
duke@1	3095	*/
duke@1	3096	private void visitArrayForeachLoop(JCEnhancedForLoop tree) {
duke@1	3097	make_at(tree.expr.pos());
duke@1	3098	VarSymbol arraycache = new VarSymbol(0,
duke@1	3099	names.fromString("arr" + target.syntheticNameChar()),
duke@1	3100	tree.expr.type,
duke@1	3101	currentMethodSym);
duke@1	3102	JCStatement arraycachedef = make.VarDef(arraycache, tree.expr);
duke@1	3103	VarSymbol lencache = new VarSymbol(0,
duke@1	3104	names.fromString("len" + target.syntheticNameChar()),
duke@1	3105	syms.intType,
duke@1	3106	currentMethodSym);
duke@1	3107	JCStatement lencachedef = make.
duke@1	3108	VarDef(lencache, make.Select(make.Ident(arraycache), syms.lengthVar));
duke@1	3109	VarSymbol index = new VarSymbol(0,
duke@1	3110	names.fromString("i" + target.syntheticNameChar()),
duke@1	3111	syms.intType,
duke@1	3112	currentMethodSym);
duke@1	3113
duke@1	3114	JCVariableDecl indexdef = make.VarDef(index, make.Literal(INT, 0));
duke@1	3115	indexdef.init.type = indexdef.type = syms.intType.constType(0);
duke@1	3116
duke@1	3117	List<JCStatement> loopinit = List.of(arraycachedef, lencachedef, indexdef);
duke@1	3118	JCBinary cond = makeBinary(JCTree.LT, make.Ident(index), make.Ident(lencache));
duke@1	3119
duke@1	3120	JCExpressionStatement step = make.Exec(makeUnary(JCTree.PREINC, make.Ident(index)));
duke@1	3121
duke@1	3122	Type elemtype = types.elemtype(tree.expr.type);
mcimadamore@33	3123	JCExpression loopvarinit = make.Indexed(make.Ident(arraycache),
mcimadamore@33	3124	make.Ident(index)).setType(elemtype);
mcimadamore@33	3125	JCVariableDecl loopvardef = (JCVariableDecl)make.VarDef(tree.var.mods,
mcimadamore@33	3126	tree.var.name,
mcimadamore@33	3127	tree.var.vartype,
mcimadamore@33	3128	loopvarinit).setType(tree.var.type);
mcimadamore@33	3129	loopvardef.sym = tree.var.sym;
duke@1	3130	JCBlock body = make.
mcimadamore@33	3131	Block(0, List.of(loopvardef, tree.body));
duke@1	3132
duke@1	3133	result = translate(make.
duke@1	3134	ForLoop(loopinit,
duke@1	3135	cond,
duke@1	3136	List.of(step),
duke@1	3137	body));
duke@1	3138	patchTargets(body, tree, result);
duke@1	3139	}
duke@1	3140	/** Patch up break and continue targets. */
duke@1	3141	private void patchTargets(JCTree body, final JCTree src, final JCTree dest) {
duke@1	3142	class Patcher extends TreeScanner {
duke@1	3143	public void visitBreak(JCBreak tree) {
duke@1	3144	if (tree.target == src)
duke@1	3145	tree.target = dest;
duke@1	3146	}
duke@1	3147	public void visitContinue(JCContinue tree) {
duke@1	3148	if (tree.target == src)
duke@1	3149	tree.target = dest;
duke@1	3150	}
duke@1	3151	public void visitClassDef(JCClassDecl tree) {}
duke@1	3152	}
duke@1	3153	new Patcher().scan(body);
duke@1	3154	}
duke@1	3155	/**
duke@1	3156	* A statement of the form
duke@1	3157	*
duke@1	3158	* <pre>
duke@1	3159	* for ( T v : coll ) stmt ;
duke@1	3160	* </pre>
duke@1	3161	*
duke@1	3162	* (where coll implements Iterable<? extends T>) gets translated to
duke@1	3163	*
duke@1	3164	* <pre>
duke@1	3165	* for ( Iterator<? extends T> #i = coll.iterator(); #i.hasNext(); ) {
duke@1	3166	* T v = (T) #i.next();
duke@1	3167	* stmt;
duke@1	3168	* }
duke@1	3169	* </pre>
duke@1	3170	*
duke@1	3171	* where #i is a freshly named synthetic local variable.
duke@1	3172	*/
duke@1	3173	private void visitIterableForeachLoop(JCEnhancedForLoop tree) {
duke@1	3174	make_at(tree.expr.pos());
duke@1	3175	Type iteratorTarget = syms.objectType;
duke@1	3176	Type iterableType = types.asSuper(types.upperBound(tree.expr.type),
duke@1	3177	syms.iterableType.tsym);
duke@1	3178	if (iterableType.getTypeArguments().nonEmpty())
duke@1	3179	iteratorTarget = types.erasure(iterableType.getTypeArguments().head);
duke@1	3180	Type eType = tree.expr.type;
duke@1	3181	tree.expr.type = types.erasure(eType);
duke@1	3182	if (eType.tag == TYPEVAR && eType.getUpperBound().isCompound())
duke@1	3183	tree.expr = make.TypeCast(types.erasure(iterableType), tree.expr);
duke@1	3184	Symbol iterator = lookupMethod(tree.expr.pos(),
duke@1	3185	names.iterator,
duke@1	3186	types.erasure(syms.iterableType),
duke@1	3187	List.<Type>nil());
duke@1	3188	VarSymbol itvar = new VarSymbol(0, names.fromString("i" + target.syntheticNameChar()),
duke@1	3189	types.erasure(iterator.type.getReturnType()),
duke@1	3190	currentMethodSym);
duke@1	3191	JCStatement init = make.
duke@1	3192	VarDef(itvar,
duke@1	3193	make.App(make.Select(tree.expr, iterator)));
duke@1	3194	Symbol hasNext = lookupMethod(tree.expr.pos(),
duke@1	3195	names.hasNext,
duke@1	3196	itvar.type,
duke@1	3197	List.<Type>nil());
duke@1	3198	JCMethodInvocation cond = make.App(make.Select(make.Ident(itvar), hasNext));
duke@1	3199	Symbol next = lookupMethod(tree.expr.pos(),
duke@1	3200	names.next,
duke@1	3201	itvar.type,
duke@1	3202	List.<Type>nil());
duke@1	3203	JCExpression vardefinit = make.App(make.Select(make.Ident(itvar), next));
mcimadamore@81	3204	if (tree.var.type.isPrimitive())
mcimadamore@81	3205	vardefinit = make.TypeCast(types.upperBound(iteratorTarget), vardefinit);
mcimadamore@81	3206	else
mcimadamore@81	3207	vardefinit = make.TypeCast(tree.var.type, vardefinit);
mcimadamore@33	3208	JCVariableDecl indexDef = (JCVariableDecl)make.VarDef(tree.var.mods,
mcimadamore@33	3209	tree.var.name,
mcimadamore@33	3210	tree.var.vartype,
mcimadamore@33	3211	vardefinit).setType(tree.var.type);
mcimadamore@33	3212	indexDef.sym = tree.var.sym;
duke@1	3213	JCBlock body = make.Block(0, List.of(indexDef, tree.body));
mcimadamore@237	3214	body.endpos = TreeInfo.endPos(tree.body);
duke@1	3215	result = translate(make.
duke@1	3216	ForLoop(List.of(init),
duke@1	3217	cond,
duke@1	3218	List.<JCExpressionStatement>nil(),
duke@1	3219	body));
duke@1	3220	patchTargets(body, tree, result);
duke@1	3221	}
duke@1	3222
duke@1	3223	public void visitVarDef(JCVariableDecl tree) {
duke@1	3224	MethodSymbol oldMethodSym = currentMethodSym;
duke@1	3225	tree.mods = translate(tree.mods);
duke@1	3226	tree.vartype = translate(tree.vartype);
duke@1	3227	if (currentMethodSym == null) {
duke@1	3228	// A class or instance field initializer.
duke@1	3229	currentMethodSym =
duke@1	3230	new MethodSymbol((tree.mods.flags&STATIC) | BLOCK,
duke@1	3231	names.empty, null,
duke@1	3232	currentClass);
duke@1	3233	}
duke@1	3234	if (tree.init != null) tree.init = translate(tree.init, tree.type);
duke@1	3235	result = tree;
duke@1	3236	currentMethodSym = oldMethodSym;
duke@1	3237	}
duke@1	3238
duke@1	3239	public void visitBlock(JCBlock tree) {
duke@1	3240	MethodSymbol oldMethodSym = currentMethodSym;
duke@1	3241	if (currentMethodSym == null) {
duke@1	3242	// Block is a static or instance initializer.
duke@1	3243	currentMethodSym =
duke@1	3244	new MethodSymbol(tree.flags | BLOCK,
duke@1	3245	names.empty, null,
duke@1	3246	currentClass);
duke@1	3247	}
duke@1	3248	super.visitBlock(tree);
duke@1	3249	currentMethodSym = oldMethodSym;
duke@1	3250	}
duke@1	3251
duke@1	3252	public void visitDoLoop(JCDoWhileLoop tree) {
duke@1	3253	tree.body = translate(tree.body);
duke@1	3254	tree.cond = translate(tree.cond, syms.booleanType);
duke@1	3255	result = tree;
duke@1	3256	}
duke@1	3257
duke@1	3258	public void visitWhileLoop(JCWhileLoop tree) {
duke@1	3259	tree.cond = translate(tree.cond, syms.booleanType);
duke@1	3260	tree.body = translate(tree.body);
duke@1	3261	result = tree;
duke@1	3262	}
duke@1	3263
duke@1	3264	public void visitForLoop(JCForLoop tree) {
duke@1	3265	tree.init = translate(tree.init);
duke@1	3266	if (tree.cond != null)
duke@1	3267	tree.cond = translate(tree.cond, syms.booleanType);
duke@1	3268	tree.step = translate(tree.step);
duke@1	3269	tree.body = translate(tree.body);
duke@1	3270	result = tree;
duke@1	3271	}
duke@1	3272
duke@1	3273	public void visitReturn(JCReturn tree) {
duke@1	3274	if (tree.expr != null)
duke@1	3275	tree.expr = translate(tree.expr,
duke@1	3276	types.erasure(currentMethodDef
duke@1	3277	.restype.type));
duke@1	3278	result = tree;
duke@1	3279	}
duke@1	3280
duke@1	3281	public void visitSwitch(JCSwitch tree) {
duke@1	3282	Type selsuper = types.supertype(tree.selector.type);
duke@1	3283	boolean enumSwitch = selsuper != null &&
duke@1	3284	(tree.selector.type.tsym.flags() & ENUM) != 0;
darcy@430	3285	boolean stringSwitch = selsuper != null &&
darcy@430	3286	types.isSameType(tree.selector.type, syms.stringType);
darcy@430	3287	Type target = enumSwitch ? tree.selector.type :
darcy@430	3288	(stringSwitch? syms.stringType : syms.intType);
duke@1	3289	tree.selector = translate(tree.selector, target);
duke@1	3290	tree.cases = translateCases(tree.cases);
duke@1	3291	if (enumSwitch) {
duke@1	3292	result = visitEnumSwitch(tree);
darcy@430	3293	} else if (stringSwitch) {
darcy@430	3294	result = visitStringSwitch(tree);
duke@1	3295	} else {
duke@1	3296	result = tree;
duke@1	3297	}
duke@1	3298	}
duke@1	3299
duke@1	3300	public JCTree visitEnumSwitch(JCSwitch tree) {
duke@1	3301	TypeSymbol enumSym = tree.selector.type.tsym;
duke@1	3302	EnumMapping map = mapForEnum(tree.pos(), enumSym);
duke@1	3303	make_at(tree.pos());
duke@1	3304	Symbol ordinalMethod = lookupMethod(tree.pos(),
duke@1	3305	names.ordinal,
duke@1	3306	tree.selector.type,
duke@1	3307	List.<Type>nil());
duke@1	3308	JCArrayAccess selector = make.Indexed(map.mapVar,
duke@1	3309	make.App(make.Select(tree.selector,
duke@1	3310	ordinalMethod)));
duke@1	3311	ListBuffer<JCCase> cases = new ListBuffer<JCCase>();
duke@1	3312	for (JCCase c : tree.cases) {
duke@1	3313	if (c.pat != null) {
duke@1	3314	VarSymbol label = (VarSymbol)TreeInfo.symbol(c.pat);
duke@1	3315	JCLiteral pat = map.forConstant(label);
duke@1	3316	cases.append(make.Case(pat, c.stats));
duke@1	3317	} else {
duke@1	3318	cases.append(c);
duke@1	3319	}
duke@1	3320	}
darcy@443	3321	JCSwitch enumSwitch = make.Switch(selector, cases.toList());
darcy@443	3322	patchTargets(enumSwitch, tree, enumSwitch);
darcy@443	3323	return enumSwitch;
duke@1	3324	}
duke@1	3325
darcy@430	3326	public JCTree visitStringSwitch(JCSwitch tree) {
darcy@430	3327	List<JCCase> caseList = tree.getCases();
darcy@430	3328	int alternatives = caseList.size();
darcy@430	3329
darcy@430	3330	if (alternatives == 0) { // Strange but legal possibility
darcy@430	3331	return make.at(tree.pos()).Exec(attr.makeNullCheck(tree.getExpression()));
darcy@430	3332	} else {
darcy@430	3333	/*
darcy@430	3334	* The general approach used is to translate a single
darcy@430	3335	* string switch statement into a series of two chained
darcy@430	3336	* switch statements: the first a synthesized statement
darcy@430	3337	* switching on the argument string's hash value and
darcy@430	3338	* computing a string's position in the list of original
darcy@430	3339	* case labels, if any, followed by a second switch on the
darcy@430	3340	* computed integer value. The second switch has the same
darcy@430	3341	* code structure as the original string switch statement
darcy@430	3342	* except that the string case labels are replaced with
darcy@430	3343	* positional integer constants starting at 0.
darcy@430	3344	*
darcy@430	3345	* The first switch statement can be thought of as an
darcy@430	3346	* inlined map from strings to their position in the case
darcy@430	3347	* label list. An alternate implementation would use an
darcy@430	3348	* actual Map for this purpose, as done for enum switches.
darcy@430	3349	*
darcy@430	3350	* With some additional effort, it would be possible to
darcy@430	3351	* use a single switch statement on the hash code of the
darcy@430	3352	* argument, but care would need to be taken to preserve
darcy@430	3353	* the proper control flow in the presence of hash
darcy@430	3354	* collisions and other complications, such as
darcy@430	3355	* fallthroughs. Switch statements with one or two
darcy@430	3356	* alternatives could also be specially translated into
darcy@430	3357	* if-then statements to omit the computation of the hash
darcy@430	3358	* code.
darcy@430	3359	*
darcy@430	3360	* The generated code assumes that the hashing algorithm
darcy@430	3361	* of String is the same in the compilation environment as
darcy@430	3362	* in the environment the code will run in. The string
darcy@430	3363	* hashing algorithm in the SE JDK has been unchanged
darcy@443	3364	* since at least JDK 1.2. Since the algorithm has been
darcy@443	3365	* specified since that release as well, it is very
darcy@443	3366	* unlikely to be changed in the future.
darcy@443	3367	*
darcy@443	3368	* Different hashing algorithms, such as the length of the
darcy@443	3369	* strings or a perfect hashing algorithm over the
darcy@443	3370	* particular set of case labels, could potentially be
darcy@443	3371	* used instead of String.hashCode.
darcy@430	3372	*/
darcy@430	3373
darcy@430	3374	ListBuffer<JCStatement> stmtList = new ListBuffer<JCStatement>();
darcy@430	3375
darcy@430	3376	// Map from String case labels to their original position in
darcy@430	3377	// the list of case labels.
darcy@430	3378	Map<String, Integer> caseLabelToPosition =
darcy@430	3379	new LinkedHashMap<String, Integer>(alternatives + 1, 1.0f);
darcy@430	3380
darcy@430	3381	// Map of hash codes to the string case labels having that hashCode.
darcy@430	3382	Map<Integer, Set<String>> hashToString =
darcy@430	3383	new LinkedHashMap<Integer, Set<String>>(alternatives + 1, 1.0f);
darcy@430	3384
darcy@430	3385	int casePosition = 0;
darcy@430	3386	for(JCCase oneCase : caseList) {
darcy@430	3387	JCExpression expression = oneCase.getExpression();
darcy@430	3388
darcy@430	3389	if (expression != null) { // expression for a "default" case is null
darcy@430	3390	String labelExpr = (String) expression.type.constValue();
darcy@430	3391	Integer mapping = caseLabelToPosition.put(labelExpr, casePosition);
darcy@430	3392	assert mapping == null;
darcy@430	3393	int hashCode = labelExpr.hashCode();
darcy@430	3394
darcy@430	3395	Set<String> stringSet = hashToString.get(hashCode);
darcy@430	3396	if (stringSet == null) {
darcy@430	3397	stringSet = new LinkedHashSet<String>(1, 1.0f);
darcy@430	3398	stringSet.add(labelExpr);
darcy@430	3399	hashToString.put(hashCode, stringSet);
darcy@430	3400	} else {
darcy@430	3401	boolean added = stringSet.add(labelExpr);
darcy@430	3402	assert added;
darcy@430	3403	}
darcy@430	3404	}
darcy@430	3405	casePosition++;
darcy@430	3406	}
darcy@430	3407
darcy@430	3408	// Synthesize a switch statement that has the effect of
darcy@430	3409	// mapping from a string to the integer position of that
darcy@430	3410	// string in the list of case labels. This is done by
darcy@430	3411	// switching on the hashCode of the string followed by an
darcy@430	3412	// if-then-else chain comparing the input for equality
darcy@430	3413	// with all the case labels having that hash value.
darcy@430	3414
darcy@430	3415	/*
darcy@430	3416	* s$ = top of stack;
darcy@430	3417	* tmp$ = -1;
darcy@430	3418	* switch($s.hashCode()) {
darcy@430	3419	* case caseLabel.hashCode:
darcy@430	3420	* if (s$.equals("caseLabel_1")
darcy@430	3421	* tmp$ = caseLabelToPosition("caseLabel_1");
darcy@430	3422	* else if (s$.equals("caseLabel_2"))
darcy@430	3423	* tmp$ = caseLabelToPosition("caseLabel_2");
darcy@430	3424	* ...
darcy@430	3425	* break;
darcy@430	3426	* ...
darcy@430	3427	* }
darcy@430	3428	*/
darcy@430	3429
darcy@430	3430	VarSymbol dollar_s = new VarSymbol(FINAL|SYNTHETIC,
darcy@430	3431	names.fromString("s" + tree.pos + target.syntheticNameChar()),
darcy@430	3432	syms.stringType,
darcy@430	3433	currentMethodSym);
darcy@430	3434	stmtList.append(make.at(tree.pos()).VarDef(dollar_s, tree.getExpression()).setType(dollar_s.type));
darcy@430	3435
darcy@430	3436	VarSymbol dollar_tmp = new VarSymbol(SYNTHETIC,
darcy@430	3437	names.fromString("tmp" + tree.pos + target.syntheticNameChar()),
darcy@430	3438	syms.intType,
darcy@430	3439	currentMethodSym);
darcy@430	3440	JCVariableDecl dollar_tmp_def =
darcy@430	3441	(JCVariableDecl)make.VarDef(dollar_tmp, make.Literal(INT, -1)).setType(dollar_tmp.type);
darcy@430	3442	dollar_tmp_def.init.type = dollar_tmp.type = syms.intType;
darcy@430	3443	stmtList.append(dollar_tmp_def);
darcy@430	3444	ListBuffer<JCCase> caseBuffer = ListBuffer.lb();
darcy@430	3445	// hashCode will trigger nullcheck on original switch expression
darcy@430	3446	JCMethodInvocation hashCodeCall = makeCall(make.Ident(dollar_s),
darcy@430	3447	names.hashCode,
darcy@430	3448	List.<JCExpression>nil()).setType(syms.intType);
darcy@430	3449	JCSwitch switch1 = make.Switch(hashCodeCall,
darcy@430	3450	caseBuffer.toList());
darcy@430	3451	for(Map.Entry<Integer, Set<String>> entry : hashToString.entrySet()) {
darcy@430	3452	int hashCode = entry.getKey();
darcy@430	3453	Set<String> stringsWithHashCode = entry.getValue();
darcy@430	3454	assert stringsWithHashCode.size() >= 1;
darcy@430	3455
darcy@430	3456	JCStatement elsepart = null;
darcy@430	3457	for(String caseLabel : stringsWithHashCode ) {
darcy@430	3458	JCMethodInvocation stringEqualsCall = makeCall(make.Ident(dollar_s),
darcy@430	3459	names.equals,
darcy@430	3460	List.<JCExpression>of(make.Literal(caseLabel)));
darcy@430	3461	elsepart = make.If(stringEqualsCall,
darcy@430	3462	make.Exec(make.Assign(make.Ident(dollar_tmp),
darcy@430	3463	make.Literal(caseLabelToPosition.get(caseLabel))).
darcy@430	3464	setType(dollar_tmp.type)),
darcy@430	3465	elsepart);
darcy@430	3466	}
darcy@430	3467
darcy@430	3468	ListBuffer<JCStatement> lb = ListBuffer.lb();
darcy@430	3469	JCBreak breakStmt = make.Break(null);
darcy@430	3470	breakStmt.target = switch1;
darcy@430	3471	lb.append(elsepart).append(breakStmt);
darcy@430	3472
darcy@430	3473	caseBuffer.append(make.Case(make.Literal(hashCode), lb.toList()));
darcy@430	3474	}
darcy@430	3475
darcy@430	3476	switch1.cases = caseBuffer.toList();
darcy@430	3477	stmtList.append(switch1);
darcy@430	3478
darcy@430	3479	// Make isomorphic switch tree replacing string labels
darcy@430	3480	// with corresponding integer ones from the label to
darcy@430	3481	// position map.
darcy@430	3482
darcy@430	3483	ListBuffer<JCCase> lb = ListBuffer.lb();
darcy@430	3484	JCSwitch switch2 = make.Switch(make.Ident(dollar_tmp), lb.toList());
darcy@430	3485	for(JCCase oneCase : caseList ) {
darcy@430	3486	// Rewire up old unlabeled break statements to the
darcy@430	3487	// replacement switch being created.
darcy@430	3488	patchTargets(oneCase, tree, switch2);
darcy@430	3489
darcy@430	3490	boolean isDefault = (oneCase.getExpression() == null);
darcy@430	3491	JCExpression caseExpr;
darcy@430	3492	if (isDefault)
darcy@430	3493	caseExpr = null;
darcy@430	3494	else {
darcy@430	3495	caseExpr = make.Literal(caseLabelToPosition.get((String)oneCase.
darcy@430	3496	getExpression().
darcy@430	3497	type.constValue()));
darcy@430	3498	}
darcy@430	3499
darcy@430	3500	lb.append(make.Case(caseExpr,
darcy@430	3501	oneCase.getStatements()));
darcy@430	3502	}
darcy@430	3503
darcy@430	3504	switch2.cases = lb.toList();
darcy@430	3505	stmtList.append(switch2);
darcy@430	3506
darcy@430	3507	return make.Block(0L, stmtList.toList());
darcy@430	3508	}
darcy@430	3509	}
darcy@430	3510
duke@1	3511	public void visitNewArray(JCNewArray tree) {
duke@1	3512	tree.elemtype = translate(tree.elemtype);
duke@1	3513	for (List<JCExpression> t = tree.dims; t.tail != null; t = t.tail)
duke@1	3514	if (t.head != null) t.head = translate(t.head, syms.intType);
duke@1	3515	tree.elems = translate(tree.elems, types.elemtype(tree.type));
duke@1	3516	result = tree;
duke@1	3517	}
duke@1	3518
duke@1	3519	public void visitSelect(JCFieldAccess tree) {
duke@1	3520	// need to special case-access of the form C.super.x
duke@1	3521	// these will always need an access method.
duke@1	3522	boolean qualifiedSuperAccess =
duke@1	3523	tree.selected.getTag() == JCTree.SELECT &&
duke@1	3524	TreeInfo.name(tree.selected) == names._super;
duke@1	3525	tree.selected = translate(tree.selected);
duke@1	3526	if (tree.name == names._class)
duke@1	3527	result = classOf(tree.selected);
duke@1	3528	else if (tree.name == names._this || tree.name == names._super)
duke@1	3529	result = makeThis(tree.pos(), tree.selected.type.tsym);
duke@1	3530	else
duke@1	3531	result = access(tree.sym, tree, enclOp, qualifiedSuperAccess);
duke@1	3532	}
duke@1	3533
duke@1	3534	public void visitLetExpr(LetExpr tree) {
duke@1	3535	tree.defs = translateVarDefs(tree.defs);
duke@1	3536	tree.expr = translate(tree.expr, tree.type);
duke@1	3537	result = tree;
duke@1	3538	}
duke@1	3539
duke@1	3540	// There ought to be nothing to rewrite here;
duke@1	3541	// we don't generate code.
duke@1	3542	public void visitAnnotation(JCAnnotation tree) {
duke@1	3543	result = tree;
duke@1	3544	}
duke@1	3545
darcy@609	3546	@Override
darcy@609	3547	public void visitTry(JCTry tree) {
darcy@609	3548	if (tree.resources.isEmpty()) {
darcy@609	3549	super.visitTry(tree);
darcy@609	3550	} else {
darcy@609	3551	result = makeArmTry(tree);
darcy@609	3552	}
darcy@609	3553	}
darcy@609	3554
duke@1	3555	/**************************************************************************
duke@1	3556	* main method
duke@1	3557	*************************************************************************/
duke@1	3558
duke@1	3559	/** Translate a toplevel class and return a list consisting of
duke@1	3560	* the translated class and translated versions of all inner classes.
duke@1	3561	* @param env The attribution environment current at the class definition.
duke@1	3562	* We need this for resolving some additional symbols.
duke@1	3563	* @param cdef The tree representing the class definition.
duke@1	3564	*/
duke@1	3565	public List<JCTree> translateTopLevelClass(Env<AttrContext> env, JCTree cdef, TreeMaker make) {
duke@1	3566	ListBuffer<JCTree> translated = null;
duke@1	3567	try {
duke@1	3568	attrEnv = env;
duke@1	3569	this.make = make;
duke@1	3570	endPositions = env.toplevel.endPositions;
duke@1	3571	currentClass = null;
duke@1	3572	currentMethodDef = null;
duke@1	3573	outermostClassDef = (cdef.getTag() == JCTree.CLASSDEF) ? (JCClassDecl)cdef : null;
duke@1	3574	outermostMemberDef = null;
duke@1	3575	this.translated = new ListBuffer<JCTree>();
duke@1	3576	classdefs = new HashMap<ClassSymbol,JCClassDecl>();
duke@1	3577	actualSymbols = new HashMap<Symbol,Symbol>();
duke@1	3578	freevarCache = new HashMap<ClassSymbol,List<VarSymbol>>();
duke@1	3579	proxies = new Scope(syms.noSymbol);
darcy@609	3580	twrVars = new Scope(syms.noSymbol);
duke@1	3581	outerThisStack = List.nil();
duke@1	3582	accessNums = new HashMap<Symbol,Integer>();
duke@1	3583	accessSyms = new HashMap<Symbol,MethodSymbol[]>();
duke@1	3584	accessConstrs = new HashMap<Symbol,MethodSymbol>();
jjg@595	3585	accessConstrTags = List.nil();
duke@1	3586	accessed = new ListBuffer<Symbol>();
duke@1	3587	translate(cdef, (JCExpression)null);
duke@1	3588	for (List<Symbol> l = accessed.toList(); l.nonEmpty(); l = l.tail)
duke@1	3589	makeAccessible(l.head);
duke@1	3590	for (EnumMapping map : enumSwitchMap.values())
duke@1	3591	map.translate();
mcimadamore@359	3592	checkConflicts(this.translated.toList());
jjg@595	3593	checkAccessConstructorTags();
duke@1	3594	translated = this.translated;
duke@1	3595	} finally {
duke@1	3596	// note that recursive invocations of this method fail hard
duke@1	3597	attrEnv = null;
duke@1	3598	this.make = null;
duke@1	3599	endPositions = null;
duke@1	3600	currentClass = null;
duke@1	3601	currentMethodDef = null;
duke@1	3602	outermostClassDef = null;
duke@1	3603	outermostMemberDef = null;
duke@1	3604	this.translated = null;
duke@1	3605	classdefs = null;
duke@1	3606	actualSymbols = null;
duke@1	3607	freevarCache = null;
duke@1	3608	proxies = null;
duke@1	3609	outerThisStack = null;
duke@1	3610	accessNums = null;
duke@1	3611	accessSyms = null;
duke@1	3612	accessConstrs = null;
jjg@595	3613	accessConstrTags = null;
duke@1	3614	accessed = null;
duke@1	3615	enumSwitchMap.clear();
duke@1	3616	}
duke@1	3617	return translated.toList();
duke@1	3618	}
duke@1	3619
duke@1	3620	//////////////////////////////////////////////////////////////
duke@1	3621	// The following contributed by Borland for bootstrapping purposes
duke@1	3622	//////////////////////////////////////////////////////////////
duke@1	3623	private void addEnumCompatibleMembers(JCClassDecl cdef) {
duke@1	3624	make_at(null);
duke@1	3625
duke@1	3626	// Add the special enum fields
duke@1	3627	VarSymbol ordinalFieldSym = addEnumOrdinalField(cdef);
duke@1	3628	VarSymbol nameFieldSym = addEnumNameField(cdef);
duke@1	3629
duke@1	3630	// Add the accessor methods for name and ordinal
duke@1	3631	MethodSymbol ordinalMethodSym = addEnumFieldOrdinalMethod(cdef, ordinalFieldSym);
duke@1	3632	MethodSymbol nameMethodSym = addEnumFieldNameMethod(cdef, nameFieldSym);
duke@1	3633
duke@1	3634	// Add the toString method
duke@1	3635	addEnumToString(cdef, nameFieldSym);
duke@1	3636
duke@1	3637	// Add the compareTo method
duke@1	3638	addEnumCompareTo(cdef, ordinalFieldSym);
duke@1	3639	}
duke@1	3640
duke@1	3641	private VarSymbol addEnumOrdinalField(JCClassDecl cdef) {
duke@1	3642	VarSymbol ordinal = new VarSymbol(PRIVATE|FINAL|SYNTHETIC,
duke@1	3643	names.fromString("$ordinal"),
duke@1	3644	syms.intType,
duke@1	3645	cdef.sym);
duke@1	3646	cdef.sym.members().enter(ordinal);
duke@1	3647	cdef.defs = cdef.defs.prepend(make.VarDef(ordinal, null));
duke@1	3648	return ordinal;
duke@1	3649	}
duke@1	3650
duke@1	3651	private VarSymbol addEnumNameField(JCClassDecl cdef) {
duke@1	3652	VarSymbol name = new VarSymbol(PRIVATE|FINAL|SYNTHETIC,
duke@1	3653	names.fromString("$name"),
duke@1	3654	syms.stringType,
duke@1	3655	cdef.sym);
duke@1	3656	cdef.sym.members().enter(name);
duke@1	3657	cdef.defs = cdef.defs.prepend(make.VarDef(name, null));
duke@1	3658	return name;
duke@1	3659	}
duke@1	3660
duke@1	3661	private MethodSymbol addEnumFieldOrdinalMethod(JCClassDecl cdef, VarSymbol ordinalSymbol) {
duke@1	3662	// Add the accessor methods for ordinal
duke@1	3663	Symbol ordinalSym = lookupMethod(cdef.pos(),
duke@1	3664	names.ordinal,
duke@1	3665	cdef.type,
duke@1	3666	List.<Type>nil());
duke@1	3667
duke@1	3668	assert(ordinalSym != null);
duke@1	3669	assert(ordinalSym instanceof MethodSymbol);
duke@1	3670
duke@1	3671	JCStatement ret = make.Return(make.Ident(ordinalSymbol));
duke@1	3672	cdef.defs = cdef.defs.append(make.MethodDef((MethodSymbol)ordinalSym,
duke@1	3673	make.Block(0L, List.of(ret))));
duke@1	3674
duke@1	3675	return (MethodSymbol)ordinalSym;
duke@1	3676	}
duke@1	3677
duke@1	3678	private MethodSymbol addEnumFieldNameMethod(JCClassDecl cdef, VarSymbol nameSymbol) {
duke@1	3679	// Add the accessor methods for name
duke@1	3680	Symbol nameSym = lookupMethod(cdef.pos(),
duke@1	3681	names._name,
duke@1	3682	cdef.type,
duke@1	3683	List.<Type>nil());
duke@1	3684
duke@1	3685	assert(nameSym != null);
duke@1	3686	assert(nameSym instanceof MethodSymbol);
duke@1	3687
duke@1	3688	JCStatement ret = make.Return(make.Ident(nameSymbol));
duke@1	3689
duke@1	3690	cdef.defs = cdef.defs.append(make.MethodDef((MethodSymbol)nameSym,
duke@1	3691	make.Block(0L, List.of(ret))));
duke@1	3692
duke@1	3693	return (MethodSymbol)nameSym;
duke@1	3694	}
duke@1	3695
duke@1	3696	private MethodSymbol addEnumToString(JCClassDecl cdef,
duke@1	3697	VarSymbol nameSymbol) {
duke@1	3698	Symbol toStringSym = lookupMethod(cdef.pos(),
duke@1	3699	names.toString,
duke@1	3700	cdef.type,
duke@1	3701	List.<Type>nil());
duke@1	3702
duke@1	3703	JCTree toStringDecl = null;
duke@1	3704	if (toStringSym != null)
duke@1	3705	toStringDecl = TreeInfo.declarationFor(toStringSym, cdef);
duke@1	3706
duke@1	3707	if (toStringDecl != null)
duke@1	3708	return (MethodSymbol)toStringSym;
duke@1	3709
duke@1	3710	JCStatement ret = make.Return(make.Ident(nameSymbol));
duke@1	3711
duke@1	3712	JCTree resTypeTree = make.Type(syms.stringType);
duke@1	3713
duke@1	3714	MethodType toStringType = new MethodType(List.<Type>nil(),
duke@1	3715	syms.stringType,
duke@1	3716	List.<Type>nil(),
duke@1	3717	cdef.sym);
duke@1	3718	toStringSym = new MethodSymbol(PUBLIC,
duke@1	3719	names.toString,
duke@1	3720	toStringType,
duke@1	3721	cdef.type.tsym);
duke@1	3722	toStringDecl = make.MethodDef((MethodSymbol)toStringSym,
duke@1	3723	make.Block(0L, List.of(ret)));
duke@1	3724
duke@1	3725	cdef.defs = cdef.defs.prepend(toStringDecl);
duke@1	3726	cdef.sym.members().enter(toStringSym);
duke@1	3727
duke@1	3728	return (MethodSymbol)toStringSym;
duke@1	3729	}
duke@1	3730
duke@1	3731	private MethodSymbol addEnumCompareTo(JCClassDecl cdef, VarSymbol ordinalSymbol) {
duke@1	3732	Symbol compareToSym = lookupMethod(cdef.pos(),
duke@1	3733	names.compareTo,
duke@1	3734	cdef.type,
duke@1	3735	List.of(cdef.sym.type));
duke@1	3736
duke@1	3737	assert(compareToSym != null);
duke@1	3738	assert(compareToSym instanceof MethodSymbol);
duke@1	3739
duke@1	3740	JCMethodDecl compareToDecl = (JCMethodDecl) TreeInfo.declarationFor(compareToSym, cdef);
duke@1	3741
duke@1	3742	ListBuffer<JCStatement> blockStatements = new ListBuffer<JCStatement>();
duke@1	3743
duke@1	3744	JCModifiers mod1 = make.Modifiers(0L);
jjg@113	3745	Name oName = names.fromString("o");
duke@1	3746	JCVariableDecl par1 = make.Param(oName, cdef.type, compareToSym);
duke@1	3747
duke@1	3748	JCIdent paramId1 = make.Ident(names.java_lang_Object);
duke@1	3749	paramId1.type = cdef.type;
duke@1	3750	paramId1.sym = par1.sym;
duke@1	3751
duke@1	3752	((MethodSymbol)compareToSym).params = List.of(par1.sym);
duke@1	3753
duke@1	3754	JCIdent par1UsageId = make.Ident(par1.sym);
duke@1	3755	JCIdent castTargetIdent = make.Ident(cdef.sym);
duke@1	3756	JCTypeCast cast = make.TypeCast(castTargetIdent, par1UsageId);
duke@1	3757	cast.setType(castTargetIdent.type);
duke@1	3758
jjg@113	3759	Name otherName = names.fromString("other");
duke@1	3760
duke@1	3761	VarSymbol otherVarSym = new VarSymbol(mod1.flags,
duke@1	3762	otherName,
duke@1	3763	cdef.type,
duke@1	3764	compareToSym);
duke@1	3765	JCVariableDecl otherVar = make.VarDef(otherVarSym, cast);
duke@1	3766	blockStatements.append(otherVar);
duke@1	3767
duke@1	3768	JCIdent id1 = make.Ident(ordinalSymbol);
duke@1	3769
duke@1	3770	JCIdent fLocUsageId = make.Ident(otherVarSym);
duke@1	3771	JCExpression sel = make.Select(fLocUsageId, ordinalSymbol);
duke@1	3772	JCBinary bin = makeBinary(JCTree.MINUS, id1, sel);
duke@1	3773	JCReturn ret = make.Return(bin);
duke@1	3774	blockStatements.append(ret);
duke@1	3775	JCMethodDecl compareToMethod = make.MethodDef((MethodSymbol)compareToSym,
duke@1	3776	make.Block(0L,
duke@1	3777	blockStatements.toList()));
duke@1	3778	compareToMethod.params = List.of(par1);
duke@1	3779	cdef.defs = cdef.defs.append(compareToMethod);
duke@1	3780
duke@1	3781	return (MethodSymbol)compareToSym;
duke@1	3782	}
duke@1	3783	//////////////////////////////////////////////////////////////
duke@1	3784	// The above contributed by Borland for bootstrapping purposes
duke@1	3785	//////////////////////////////////////////////////////////////
duke@1	3786	}