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src/share/classes/com/sun/tools/javac/comp/LambdaToMethod.java@ba758e1ffa69 (annotated)

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

Thu, 26 Mar 2015 11:34:50 +0100

author

jlahoda

date

Thu, 26 Mar 2015 11:34:50 +0100

changeset 2734

ba758e1ffa69

parent 2733

7974f6da2d76

child 2893

ca5783d9a597

child 2905

f166261986cc

child 3113

0d7fcabf56ed

permissions

-rw-r--r--

8054220: Debugger doesn't show variables *outside* lambda
8058227: Debugger has no access to outer variables inside Lambda
Summary: Put local variables captured by lambda into the lambda method's LocalVariableTable.
Reviewed-by: mcimadamore, rfield

rfield@1380	1	/*
ksrini@2251	2	* Copyright (c) 2010, 2014, Oracle and/or its affiliates. All rights reserved.
rfield@1380	3	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
rfield@1380	4	*
rfield@1380	5	* This code is free software; you can redistribute it and/or modify it
rfield@1380	6	* under the terms of the GNU General Public License version 2 only, as
rfield@1380	7	* published by the Free Software Foundation. Oracle designates this
rfield@1380	8	* particular file as subject to the "Classpath" exception as provided
rfield@1380	9	* by Oracle in the LICENSE file that accompanied this code.
rfield@1380	10	*
rfield@1380	11	* This code is distributed in the hope that it will be useful, but WITHOUT
rfield@1380	12	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
rfield@1380	13	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
rfield@1380	14	* version 2 for more details (a copy is included in the LICENSE file that
rfield@1380	15	* accompanied this code).
rfield@1380	16	*
rfield@1380	17	* You should have received a copy of the GNU General Public License version
rfield@1380	18	* 2 along with this work; if not, write to the Free Software Foundation,
rfield@1380	19	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
rfield@1380	20	*
rfield@1380	21	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
rfield@1380	22	* or visit www.oracle.com if you need additional information or have any
rfield@1380	23	* questions.
rfield@1380	24	*/
rfield@1380	25	package com.sun.tools.javac.comp;
rfield@1380	26
rfield@1380	27	import com.sun.tools.javac.tree.*;
rfield@1380	28	import com.sun.tools.javac.tree.JCTree.*;
rfield@1380	29	import com.sun.tools.javac.tree.JCTree.JCMemberReference.ReferenceKind;
rfield@1380	30	import com.sun.tools.javac.tree.TreeMaker;
rfield@1380	31	import com.sun.tools.javac.tree.TreeTranslator;
jjg@1755	32	import com.sun.tools.javac.code.Attribute;
rfield@1380	33	import com.sun.tools.javac.code.Kinds;
rfield@1587	34	import com.sun.tools.javac.code.Scope;
rfield@1380	35	import com.sun.tools.javac.code.Symbol;
rfield@1380	36	import com.sun.tools.javac.code.Symbol.ClassSymbol;
rfield@1380	37	import com.sun.tools.javac.code.Symbol.DynamicMethodSymbol;
rfield@1380	38	import com.sun.tools.javac.code.Symbol.MethodSymbol;
rfield@2381	39	import com.sun.tools.javac.code.Symbol.TypeSymbol;
rfield@1380	40	import com.sun.tools.javac.code.Symbol.VarSymbol;
rfield@1380	41	import com.sun.tools.javac.code.Symtab;
rfield@1380	42	import com.sun.tools.javac.code.Type;
rfield@1380	43	import com.sun.tools.javac.code.Type.MethodType;
rfield@2614	44	import com.sun.tools.javac.code.Type.TypeVar;
rfield@1380	45	import com.sun.tools.javac.code.Types;
rfield@1717	46	import com.sun.tools.javac.comp.LambdaToMethod.LambdaAnalyzerPreprocessor.*;
mcimadamore@1612	47	import com.sun.tools.javac.comp.Lower.BasicFreeVarCollector;
rfield@1380	48	import com.sun.tools.javac.jvm.*;
rfield@1380	49	import com.sun.tools.javac.util.*;
rfield@1380	50	import com.sun.tools.javac.util.JCDiagnostic.DiagnosticPosition;
rfield@1380	51	import com.sun.source.tree.MemberReferenceTree.ReferenceMode;
rfield@1380	52
ksrini@2155	53	import java.util.EnumMap;
rfield@1380	54	import java.util.HashMap;
rfield@2381	55	import java.util.HashSet;
rfield@1380	56	import java.util.LinkedHashMap;
rfield@1380	57	import java.util.Map;
rfield@2381	58	import java.util.Set;
rfield@1380	59
rfield@1380	60	import static com.sun.tools.javac.comp.LambdaToMethod.LambdaSymbolKind.*;
rfield@1380	61	import static com.sun.tools.javac.code.Flags.*;
rfield@1380	62	import static com.sun.tools.javac.code.Kinds.*;
rfield@1587	63	import static com.sun.tools.javac.code.TypeTag.*;
rfield@1380	64	import static com.sun.tools.javac.tree.JCTree.Tag.*;
rfield@2614	65	import javax.lang.model.type.TypeKind;
rfield@1380	66
rfield@1380	67	/**
rfield@1380	68	* This pass desugars lambda expressions into static methods
rfield@1380	69	*
rfield@1380	70	* <p><b>This is NOT part of any supported API.
rfield@1380	71	* If you write code that depends on this, you do so at your own risk.
rfield@1380	72	* This code and its internal interfaces are subject to change or
rfield@1380	73	* deletion without notice.</b>
rfield@1380	74	*/
rfield@1380	75	public class LambdaToMethod extends TreeTranslator {
rfield@1380	76
ksrini@2155	77	private Attr attr;
mcimadamore@1817	78	private JCDiagnostic.Factory diags;
mcimadamore@1817	79	private Log log;
mcimadamore@1612	80	private Lower lower;
rfield@1380	81	private Names names;
rfield@1380	82	private Symtab syms;
rfield@1380	83	private Resolve rs;
rfield@1380	84	private TreeMaker make;
rfield@1380	85	private Types types;
rfield@1380	86	private TransTypes transTypes;
rfield@1380	87	private Env<AttrContext> attrEnv;
rfield@1380	88
rfield@1380	89	/** the analyzer scanner */
rfield@1717	90	private LambdaAnalyzerPreprocessor analyzer;
rfield@1380	91
rfield@1380	92	/** map from lambda trees to translation contexts */
rfield@1380	93	private Map<JCTree, TranslationContext<?>> contextMap;
rfield@1380	94
rfield@1380	95	/** current translation context (visitor argument) */
rfield@1380	96	private TranslationContext<?> context;
rfield@1380	97
rfield@1587	98	/** info about the current class being processed */
rfield@1587	99	private KlassInfo kInfo;
rfield@1587	100
mcimadamore@1817	101	/** dump statistics about lambda code generation */
mcimadamore@1817	102	private boolean dumpLambdaToMethodStats;
mcimadamore@1817	103
ksrini@2251	104	/** force serializable representation, for stress testing **/
ksrini@2251	105	private final boolean forceSerializable;
ksrini@2251	106
rfield@1587	107	/** Flag for alternate metafactories indicating the lambda object is intended to be serializable */
rfield@1587	108	public static final int FLAG_SERIALIZABLE = 1 << 0;
rfield@1587	109
rfield@1587	110	/** Flag for alternate metafactories indicating the lambda object has multiple targets */
rfield@1587	111	public static final int FLAG_MARKERS = 1 << 1;
rfield@1587	112
mcimadamore@1882	113	/** Flag for alternate metafactories indicating the lambda object requires multiple bridges */
mcimadamore@1882	114	public static final int FLAG_BRIDGES = 1 << 2;
mcimadamore@1882	115
ksrini@2155	116	// <editor-fold defaultstate="collapsed" desc="Instantiating">
ksrini@2155	117	protected static final Context.Key<LambdaToMethod> unlambdaKey =
ksrini@2155	118	new Context.Key<LambdaToMethod>();
ksrini@2155	119
ksrini@2155	120	public static LambdaToMethod instance(Context context) {
ksrini@2155	121	LambdaToMethod instance = context.get(unlambdaKey);
ksrini@2155	122	if (instance == null) {
ksrini@2155	123	instance = new LambdaToMethod(context);
ksrini@2155	124	}
ksrini@2155	125	return instance;
ksrini@2155	126	}
ksrini@2155	127	private LambdaToMethod(Context context) {
ksrini@2155	128	context.put(unlambdaKey, this);
ksrini@2155	129	diags = JCDiagnostic.Factory.instance(context);
ksrini@2155	130	log = Log.instance(context);
ksrini@2155	131	lower = Lower.instance(context);
ksrini@2155	132	names = Names.instance(context);
ksrini@2155	133	syms = Symtab.instance(context);
ksrini@2155	134	rs = Resolve.instance(context);
ksrini@2155	135	make = TreeMaker.instance(context);
ksrini@2155	136	types = Types.instance(context);
ksrini@2155	137	transTypes = TransTypes.instance(context);
ksrini@2155	138	analyzer = new LambdaAnalyzerPreprocessor();
ksrini@2155	139	Options options = Options.instance(context);
ksrini@2155	140	dumpLambdaToMethodStats = options.isSet("dumpLambdaToMethodStats");
ksrini@2155	141	attr = Attr.instance(context);
ksrini@2251	142	forceSerializable = options.isSet("forceSerializable");
ksrini@2155	143	}
ksrini@2155	144	// </editor-fold>
ksrini@2155	145
rfield@1587	146	private class KlassInfo {
rfield@1587	147
rfield@1587	148	/**
rfield@1587	149	* list of methods to append
rfield@1587	150	*/
rfield@1587	151	private ListBuffer<JCTree> appendedMethodList;
rfield@1587	152
rfield@1587	153	/**
rfield@1587	154	* list of deserialization cases
rfield@1587	155	*/
rfield@1587	156	private final Map<String, ListBuffer<JCStatement>> deserializeCases;
rfield@1587	157
rfield@1587	158	/**
rfield@1587	159	* deserialize method symbol
rfield@1587	160	*/
rfield@1587	161	private final MethodSymbol deserMethodSym;
rfield@1587	162
rfield@1587	163	/**
rfield@1587	164	* deserialize method parameter symbol
rfield@1587	165	*/
rfield@1587	166	private final VarSymbol deserParamSym;
rfield@1587	167
jlahoda@2165	168	private final JCClassDecl clazz;
jlahoda@2165	169
jlahoda@2165	170	private KlassInfo(JCClassDecl clazz) {
jlahoda@2165	171	this.clazz = clazz;
alundblad@2047	172	appendedMethodList = new ListBuffer<>();
rfield@1587	173	deserializeCases = new HashMap<String, ListBuffer<JCStatement>>();
rfield@1587	174	MethodType type = new MethodType(List.of(syms.serializedLambdaType), syms.objectType,
rfield@1587	175	List.<Type>nil(), syms.methodClass);
jlahoda@2165	176	deserMethodSym = makePrivateSyntheticMethod(STATIC, names.deserializeLambda, type, clazz.sym);
mcimadamore@1595	177	deserParamSym = new VarSymbol(FINAL, names.fromString("lambda"),
mcimadamore@1595	178	syms.serializedLambdaType, deserMethodSym);
rfield@1587	179	}
rfield@1587	180
rfield@1587	181	private void addMethod(JCTree decl) {
rfield@1587	182	appendedMethodList = appendedMethodList.prepend(decl);
rfield@1587	183	}
rfield@1587	184	}
rfield@1380	185
rfield@1380	186	// <editor-fold defaultstate="collapsed" desc="translate methods">
rfield@1380	187	@Override
rfield@1380	188	public <T extends JCTree> T translate(T tree) {
rfield@1380	189	TranslationContext<?> newContext = contextMap.get(tree);
rfield@1380	190	return translate(tree, newContext != null ? newContext : context);
rfield@1380	191	}
rfield@1380	192
rfield@1762	193	<T extends JCTree> T translate(T tree, TranslationContext<?> newContext) {
rfield@1380	194	TranslationContext<?> prevContext = context;
rfield@1380	195	try {
rfield@1380	196	context = newContext;
rfield@1380	197	return super.translate(tree);
rfield@1380	198	}
rfield@1380	199	finally {
rfield@1380	200	context = prevContext;
rfield@1380	201	}
rfield@1380	202	}
rfield@1380	203
rfield@1762	204	<T extends JCTree> List<T> translate(List<T> trees, TranslationContext<?> newContext) {
alundblad@2047	205	ListBuffer<T> buf = new ListBuffer<>();
rfield@1380	206	for (T tree : trees) {
rfield@1380	207	buf.append(translate(tree, newContext));
rfield@1380	208	}
rfield@1380	209	return buf.toList();
rfield@1380	210	}
rfield@1380	211
rfield@1380	212	public JCTree translateTopLevelClass(Env<AttrContext> env, JCTree cdef, TreeMaker make) {
rfield@1380	213	this.make = make;
rfield@1380	214	this.attrEnv = env;
rfield@1380	215	this.context = null;
rfield@1380	216	this.contextMap = new HashMap<JCTree, TranslationContext<?>>();
rfield@1380	217	return translate(cdef);
rfield@1380	218	}
rfield@1380	219	// </editor-fold>
rfield@1380	220
rfield@1380	221	// <editor-fold defaultstate="collapsed" desc="visitor methods">
rfield@1380	222	/**
rfield@1380	223	* Visit a class.
rfield@1380	224	* Maintain the translatedMethodList across nested classes.
rfield@1380	225	* Append the translatedMethodList to the class after it is translated.
rfield@1380	226	* @param tree
rfield@1380	227	*/
rfield@1380	228	@Override
rfield@1380	229	public void visitClassDef(JCClassDecl tree) {
rfield@1380	230	if (tree.sym.owner.kind == PCK) {
rfield@1380	231	//analyze class
rfield@1717	232	tree = analyzer.analyzeAndPreprocessClass(tree);
rfield@1380	233	}
rfield@1587	234	KlassInfo prevKlassInfo = kInfo;
rfield@1380	235	try {
jlahoda@2165	236	kInfo = new KlassInfo(tree);
rfield@1380	237	super.visitClassDef(tree);
rfield@1587	238	if (!kInfo.deserializeCases.isEmpty()) {
jlahoda@2165	239	int prevPos = make.pos;
jlahoda@2165	240	try {
jlahoda@2165	241	make.at(tree);
jlahoda@2165	242	kInfo.addMethod(makeDeserializeMethod(tree.sym));
jlahoda@2165	243	} finally {
jlahoda@2165	244	make.at(prevPos);
jlahoda@2165	245	}
rfield@1587	246	}
rfield@1380	247	//add all translated instance methods here
rfield@1587	248	List<JCTree> newMethods = kInfo.appendedMethodList.toList();
rfield@1587	249	tree.defs = tree.defs.appendList(newMethods);
rfield@1587	250	for (JCTree lambda : newMethods) {
rfield@1380	251	tree.sym.members().enter(((JCMethodDecl)lambda).sym);
rfield@1380	252	}
rfield@1380	253	result = tree;
rfield@1380	254	} finally {
rfield@1587	255	kInfo = prevKlassInfo;
rfield@1380	256	}
rfield@1380	257	}
rfield@1380	258
rfield@1380	259	/**
rfield@1380	260	* Translate a lambda into a method to be inserted into the class.
rfield@1380	261	* Then replace the lambda site with an invokedynamic call of to lambda
rfield@1380	262	* meta-factory, which will use the lambda method.
rfield@1380	263	* @param tree
rfield@1380	264	*/
rfield@1380	265	@Override
rfield@1380	266	public void visitLambda(JCLambda tree) {
rfield@1380	267	LambdaTranslationContext localContext = (LambdaTranslationContext)context;
jlahoda@2733	268	MethodSymbol sym = localContext.translatedSym;
rfield@1380	269	MethodType lambdaType = (MethodType) sym.type;
rfield@1380	270
jjg@1755	271	{
jjg@1969	272	Symbol owner = localContext.owner;
jjg@1755	273	ListBuffer<Attribute.TypeCompound> ownerTypeAnnos = new ListBuffer<Attribute.TypeCompound>();
jjg@1755	274	ListBuffer<Attribute.TypeCompound> lambdaTypeAnnos = new ListBuffer<Attribute.TypeCompound>();
jjg@1755	275
jjg@1755	276	for (Attribute.TypeCompound tc : owner.getRawTypeAttributes()) {
jjg@1755	277	if (tc.position.onLambda == tree) {
jjg@1755	278	lambdaTypeAnnos.append(tc);
jjg@1755	279	} else {
jjg@1755	280	ownerTypeAnnos.append(tc);
jjg@1755	281	}
jjg@1755	282	}
jjg@1755	283	if (lambdaTypeAnnos.nonEmpty()) {
jjg@1802	284	owner.setTypeAttributes(ownerTypeAnnos.toList());
jjg@1802	285	sym.setTypeAttributes(lambdaTypeAnnos.toList());
jjg@1755	286	}
jjg@1755	287	}
jjg@1755	288
rfield@1380	289	//create the method declaration hoisting the lambda body
rfield@1380	290	JCMethodDecl lambdaDecl = make.MethodDef(make.Modifiers(sym.flags_field),
rfield@1380	291	sym.name,
rfield@1380	292	make.QualIdent(lambdaType.getReturnType().tsym),
rfield@1380	293	List.<JCTypeParameter>nil(),
rfield@1380	294	localContext.syntheticParams,
rfield@1380	295	lambdaType.getThrownTypes() == null ?
rfield@1380	296	List.<JCExpression>nil() :
rfield@1380	297	make.Types(lambdaType.getThrownTypes()),
rfield@1380	298	null,
rfield@1380	299	null);
rfield@1380	300	lambdaDecl.sym = sym;
rfield@1380	301	lambdaDecl.type = lambdaType;
rfield@1380	302
rfield@1380	303	//translate lambda body
rfield@1380	304	//As the lambda body is translated, all references to lambda locals,
rfield@1380	305	//captured variables, enclosing members are adjusted accordingly
rfield@1380	306	//to refer to the static method parameters (rather than i.e. acessing to
rfield@1380	307	//captured members directly).
rfield@1380	308	lambdaDecl.body = translate(makeLambdaBody(tree, lambdaDecl));
rfield@1380	309
rfield@1380	310	//Add the method to the list of methods to be added to this class.
rfield@1587	311	kInfo.addMethod(lambdaDecl);
rfield@1380	312
rfield@1380	313	//now that we have generated a method for the lambda expression,
rfield@1380	314	//we can translate the lambda into a method reference pointing to the newly
rfield@1380	315	//created method.
rfield@1380	316	//
rfield@1380	317	//Note that we need to adjust the method handle so that it will match the
rfield@1380	318	//signature of the SAM descriptor - this means that the method reference
rfield@1380	319	//should be added the following synthetic arguments:
rfield@1380	320	//
rfield@1380	321	// * the "this" argument if it is an instance method
rfield@1380	322	// * enclosing locals captured by the lambda expression
rfield@1380	323
alundblad@2047	324	ListBuffer<JCExpression> syntheticInits = new ListBuffer<>();
rfield@1380	325
rfield@2607	326	if (localContext.methodReferenceReceiver != null) {
rfield@2607	327	syntheticInits.append(localContext.methodReferenceReceiver);
rfield@2607	328	} else if (!sym.isStatic()) {
rfield@1380	329	syntheticInits.append(makeThis(
rfield@1587	330	sym.owner.enclClass().asType(),
rfield@1380	331	localContext.owner.enclClass()));
rfield@1380	332	}
rfield@1380	333
rfield@1380	334	//add captured locals
rfield@1380	335	for (Symbol fv : localContext.getSymbolMap(CAPTURED_VAR).keySet()) {
rfield@1380	336	if (fv != localContext.self) {
rfield@1380	337	JCTree captured_local = make.Ident(fv).setType(fv.type);
rfield@1380	338	syntheticInits.append((JCExpression) captured_local);
rfield@1380	339	}
rfield@1380	340	}
rfield@1380	341
rfield@1380	342	//then, determine the arguments to the indy call
rfield@1380	343	List<JCExpression> indy_args = translate(syntheticInits.toList(), localContext.prev);
rfield@1380	344
rfield@1380	345	//build a sam instance using an indy call to the meta-factory
rfield@1380	346	int refKind = referenceKind(sym);
rfield@1380	347
rfield@1380	348	//convert to an invokedynamic call
mcimadamore@1882	349	result = makeMetafactoryIndyCall(context, refKind, sym, indy_args);
rfield@1380	350	}
rfield@1380	351
rfield@1380	352	private JCIdent makeThis(Type type, Symbol owner) {
rfield@1380	353	VarSymbol _this = new VarSymbol(PARAMETER | FINAL | SYNTHETIC,
rfield@1380	354	names._this,
rfield@1380	355	type,
rfield@1380	356	owner);
rfield@1380	357	return make.Ident(_this);
rfield@1380	358	}
rfield@1380	359
rfield@1380	360	/**
rfield@1380	361	* Translate a method reference into an invokedynamic call to the
rfield@1380	362	* meta-factory.
rfield@1380	363	* @param tree
rfield@1380	364	*/
rfield@1380	365	@Override
rfield@1380	366	public void visitReference(JCMemberReference tree) {
rfield@1380	367	ReferenceTranslationContext localContext = (ReferenceTranslationContext)context;
rfield@1380	368
rfield@1380	369	//first determine the method symbol to be used to generate the sam instance
rfield@1380	370	//this is either the method reference symbol, or the bridged reference symbol
rfield@2607	371	Symbol refSym = localContext.isSignaturePolymorphic()
rfield@2202	372	? localContext.sigPolySym
rfield@2202	373	: tree.sym;
rfield@1380	374
rfield@1380	375	//the qualifying expression is treated as a special captured arg
rfield@1380	376	JCExpression init;
rfield@1380	377	switch(tree.kind) {
rfield@1380	378
mcimadamore@1435	379	case IMPLICIT_INNER: /** Inner :: new */
mcimadamore@1435	380	case SUPER: /** super :: instMethod */
rfield@1380	381	init = makeThis(
rfield@1587	382	localContext.owner.enclClass().asType(),
rfield@1587	383	localContext.owner.enclClass());
rfield@1380	384	break;
rfield@1380	385
mcimadamore@1435	386	case BOUND: /** Expr :: instMethod */
rfield@1380	387	init = tree.getQualifierExpression();
vromero@2043	388	init = attr.makeNullCheck(init);
rfield@1380	389	break;
rfield@1380	390
mcimadamore@1435	391	case UNBOUND: /** Type :: instMethod */
mcimadamore@1435	392	case STATIC: /** Type :: staticMethod */
mcimadamore@1435	393	case TOPLEVEL: /** Top level :: new */
mcimadamore@1496	394	case ARRAY_CTOR: /** ArrayType :: new */
rfield@1380	395	init = null;
rfield@1380	396	break;
rfield@1380	397
rfield@1380	398	default:
rfield@1380	399	throw new InternalError("Should not have an invalid kind");
rfield@1380	400	}
rfield@1380	401
rfield@1380	402	List<JCExpression> indy_args = init==null? List.<JCExpression>nil() : translate(List.of(init), localContext.prev);
rfield@1380	403
rfield@1380	404
rfield@1380	405	//build a sam instance using an indy call to the meta-factory
mcimadamore@1882	406	result = makeMetafactoryIndyCall(localContext, localContext.referenceKind(), refSym, indy_args);
rfield@1380	407	}
rfield@1380	408
rfield@1380	409	/**
rfield@1380	410	* Translate identifiers within a lambda to the mapped identifier
rfield@1380	411	* @param tree
rfield@1380	412	*/
rfield@1380	413	@Override
rfield@1380	414	public void visitIdent(JCIdent tree) {
rfield@1380	415	if (context == null || !analyzer.lambdaIdentSymbolFilter(tree.sym)) {
rfield@1380	416	super.visitIdent(tree);
rfield@1380	417	} else {
jlahoda@2165	418	int prevPos = make.pos;
jlahoda@2165	419	try {
jlahoda@2165	420	make.at(tree);
jlahoda@2165	421
jlahoda@2165	422	LambdaTranslationContext lambdaContext = (LambdaTranslationContext) context;
jlahoda@2165	423	JCTree ltree = lambdaContext.translate(tree);
jlahoda@2165	424	if (ltree != null) {
jlahoda@2165	425	result = ltree;
jlahoda@2165	426	} else {
jlahoda@2165	427	//access to untranslated symbols (i.e. compile-time constants,
jlahoda@2165	428	//members defined inside the lambda body, etc.) )
jlahoda@2165	429	super.visitIdent(tree);
jlahoda@2165	430	}
jlahoda@2165	431	} finally {
jlahoda@2165	432	make.at(prevPos);
rfield@1380	433	}
rfield@1380	434	}
rfield@1380	435	}
rfield@1380	436
rfield@1380	437	@Override
rfield@1380	438	public void visitVarDef(JCVariableDecl tree) {
rfield@1380	439	LambdaTranslationContext lambdaContext = (LambdaTranslationContext)context;
rfield@1380	440	if (context != null && lambdaContext.getSymbolMap(LOCAL_VAR).containsKey(tree.sym)) {
rfield@2380	441	tree.init = translate(tree.init);
rfield@2380	442	tree.sym = (VarSymbol) lambdaContext.getSymbolMap(LOCAL_VAR).get(tree.sym);
rfield@2380	443	result = tree;
rfield@1587	444	} else if (context != null && lambdaContext.getSymbolMap(TYPE_VAR).containsKey(tree.sym)) {
rfield@1587	445	JCExpression init = translate(tree.init);
rfield@1587	446	VarSymbol xsym = (VarSymbol)lambdaContext.getSymbolMap(TYPE_VAR).get(tree.sym);
jlahoda@2165	447	int prevPos = make.pos;
jlahoda@2165	448	try {
jlahoda@2165	449	result = make.at(tree).VarDef(xsym, init);
jlahoda@2165	450	} finally {
jlahoda@2165	451	make.at(prevPos);
jlahoda@2165	452	}
rfield@1587	453	// Replace the entered symbol for this variable
rfield@1587	454	Scope sc = tree.sym.owner.members();
rfield@1587	455	if (sc != null) {
rfield@1587	456	sc.remove(tree.sym);
rfield@1587	457	sc.enter(xsym);
rfield@1587	458	}
rfield@1380	459	} else {
rfield@1380	460	super.visitVarDef(tree);
rfield@1380	461	}
rfield@1380	462	}
rfield@1380	463
rfield@1380	464	// </editor-fold>
rfield@1380	465
rfield@1380	466	// <editor-fold defaultstate="collapsed" desc="Translation helper methods">
rfield@1380	467
rfield@1380	468	private JCBlock makeLambdaBody(JCLambda tree, JCMethodDecl lambdaMethodDecl) {
rfield@1380	469	return tree.getBodyKind() == JCLambda.BodyKind.EXPRESSION ?
rfield@1380	470	makeLambdaExpressionBody((JCExpression)tree.body, lambdaMethodDecl) :
rfield@1380	471	makeLambdaStatementBody((JCBlock)tree.body, lambdaMethodDecl, tree.canCompleteNormally);
rfield@1380	472	}
rfield@1380	473
rfield@1380	474	private JCBlock makeLambdaExpressionBody(JCExpression expr, JCMethodDecl lambdaMethodDecl) {
rfield@1380	475	Type restype = lambdaMethodDecl.type.getReturnType();
rfield@1380	476	boolean isLambda_void = expr.type.hasTag(VOID);
rfield@1380	477	boolean isTarget_void = restype.hasTag(VOID);
rfield@1380	478	boolean isTarget_Void = types.isSameType(restype, types.boxedClass(syms.voidType).type);
jlahoda@2165	479	int prevPos = make.pos;
jlahoda@2165	480	try {
jlahoda@2165	481	if (isTarget_void) {
jlahoda@2165	482	//target is void:
jlahoda@2165	483	// BODY;
jlahoda@2165	484	JCStatement stat = make.at(expr).Exec(expr);
jlahoda@2165	485	return make.Block(0, List.<JCStatement>of(stat));
jlahoda@2165	486	} else if (isLambda_void && isTarget_Void) {
jlahoda@2165	487	//void to Void conversion:
jlahoda@2165	488	// BODY; return null;
jlahoda@2165	489	ListBuffer<JCStatement> stats = new ListBuffer<>();
jlahoda@2165	490	stats.append(make.at(expr).Exec(expr));
jlahoda@2165	491	stats.append(make.Return(make.Literal(BOT, null).setType(syms.botType)));
jlahoda@2165	492	return make.Block(0, stats.toList());
jlahoda@2165	493	} else {
jlahoda@2165	494	//non-void to non-void conversion:
jlahoda@2165	495	// return (TYPE)BODY;
jlahoda@2165	496	JCExpression retExpr = transTypes.coerce(attrEnv, expr, restype);
jlahoda@2165	497	return make.at(retExpr).Block(0, List.<JCStatement>of(make.Return(retExpr)));
jlahoda@2165	498	}
jlahoda@2165	499	} finally {
jlahoda@2165	500	make.at(prevPos);
rfield@1380	501	}
rfield@1380	502	}
rfield@1380	503
rfield@1380	504	private JCBlock makeLambdaStatementBody(JCBlock block, final JCMethodDecl lambdaMethodDecl, boolean completeNormally) {
rfield@1380	505	final Type restype = lambdaMethodDecl.type.getReturnType();
rfield@1380	506	final boolean isTarget_void = restype.hasTag(VOID);
rfield@1380	507	boolean isTarget_Void = types.isSameType(restype, types.boxedClass(syms.voidType).type);
rfield@1380	508
rfield@1380	509	class LambdaBodyTranslator extends TreeTranslator {
rfield@1380	510
rfield@1380	511	@Override
rfield@1380	512	public void visitClassDef(JCClassDecl tree) {
rfield@1380	513	//do NOT recurse on any inner classes
rfield@1380	514	result = tree;
rfield@1380	515	}
rfield@1380	516
rfield@1380	517	@Override
rfield@1380	518	public void visitLambda(JCLambda tree) {
rfield@1380	519	//do NOT recurse on any nested lambdas
rfield@1380	520	result = tree;
rfield@1380	521	}
rfield@1380	522
rfield@1380	523	@Override
rfield@1380	524	public void visitReturn(JCReturn tree) {
rfield@1380	525	boolean isLambda_void = tree.expr == null;
rfield@1380	526	if (isTarget_void && !isLambda_void) {
rfield@1380	527	//Void to void conversion:
rfield@1380	528	// { TYPE $loc = RET-EXPR; return; }
rfield@1380	529	VarSymbol loc = makeSyntheticVar(0, names.fromString("$loc"), tree.expr.type, lambdaMethodDecl.sym);
rfield@1380	530	JCVariableDecl varDef = make.VarDef(loc, tree.expr);
rfield@1380	531	result = make.Block(0, List.<JCStatement>of(varDef, make.Return(null)));
rfield@1380	532	} else if (!isTarget_void || !isLambda_void) {
rfield@1380	533	//non-void to non-void conversion:
rfield@1380	534	// return (TYPE)RET-EXPR;
rfield@1380	535	tree.expr = transTypes.coerce(attrEnv, tree.expr, restype);
rfield@1380	536	result = tree;
rfield@1380	537	} else {
rfield@1380	538	result = tree;
rfield@1380	539	}
rfield@1380	540
rfield@1380	541	}
rfield@1380	542	}
rfield@1380	543
rfield@1380	544	JCBlock trans_block = new LambdaBodyTranslator().translate(block);
rfield@1380	545	if (completeNormally && isTarget_Void) {
rfield@1380	546	//there's no return statement and the lambda (possibly inferred)
rfield@1380	547	//return type is java.lang.Void; emit a synthetic return statement
rfield@1380	548	trans_block.stats = trans_block.stats.append(make.Return(make.Literal(BOT, null).setType(syms.botType)));
rfield@1380	549	}
rfield@1380	550	return trans_block;
rfield@1380	551	}
rfield@1380	552
rfield@1587	553	private JCMethodDecl makeDeserializeMethod(Symbol kSym) {
alundblad@2047	554	ListBuffer<JCCase> cases = new ListBuffer<>();
alundblad@2047	555	ListBuffer<JCBreak> breaks = new ListBuffer<>();
rfield@1587	556	for (Map.Entry<String, ListBuffer<JCStatement>> entry : kInfo.deserializeCases.entrySet()) {
rfield@1587	557	JCBreak br = make.Break(null);
rfield@1587	558	breaks.add(br);
rfield@1587	559	List<JCStatement> stmts = entry.getValue().append(br).toList();
rfield@1587	560	cases.add(make.Case(make.Literal(entry.getKey()), stmts));
rfield@1587	561	}
rfield@1587	562	JCSwitch sw = make.Switch(deserGetter("getImplMethodName", syms.stringType), cases.toList());
rfield@1587	563	for (JCBreak br : breaks) {
rfield@1587	564	br.target = sw;
rfield@1587	565	}
rfield@1587	566	JCBlock body = make.Block(0L, List.<JCStatement>of(
rfield@1587	567	sw,
rfield@1587	568	make.Throw(makeNewClass(
rfield@1587	569	syms.illegalArgumentExceptionType,
rfield@1587	570	List.<JCExpression>of(make.Literal("Invalid lambda deserialization"))))));
rfield@1587	571	JCMethodDecl deser = make.MethodDef(make.Modifiers(kInfo.deserMethodSym.flags()),
rfield@1587	572	names.deserializeLambda,
rfield@1587	573	make.QualIdent(kInfo.deserMethodSym.getReturnType().tsym),
rfield@1587	574	List.<JCTypeParameter>nil(),
rfield@1587	575	List.of(make.VarDef(kInfo.deserParamSym, null)),
rfield@1587	576	List.<JCExpression>nil(),
rfield@1587	577	body,
rfield@1587	578	null);
rfield@1587	579	deser.sym = kInfo.deserMethodSym;
rfield@1587	580	deser.type = kInfo.deserMethodSym.type;
rfield@1587	581	//System.err.printf("DESER: '%s'\n", deser);
rfield@1587	582	return deser;
rfield@1587	583	}
rfield@1587	584
rfield@1587	585	/** Make an attributed class instance creation expression.
rfield@1587	586	* @param ctype The class type.
rfield@1587	587	* @param args The constructor arguments.
rfield@1717	588	* @param cons The constructor symbol
rfield@1587	589	*/
rfield@1717	590	JCNewClass makeNewClass(Type ctype, List<JCExpression> args, Symbol cons) {
rfield@1587	591	JCNewClass tree = make.NewClass(null,
rfield@1587	592	null, make.QualIdent(ctype.tsym), args, null);
rfield@1717	593	tree.constructor = cons;
rfield@1587	594	tree.type = ctype;
rfield@1587	595	return tree;
rfield@1587	596	}
rfield@1587	597
rfield@1717	598	/** Make an attributed class instance creation expression.
rfield@1717	599	* @param ctype The class type.
rfield@1717	600	* @param args The constructor arguments.
rfield@1717	601	*/
rfield@1717	602	JCNewClass makeNewClass(Type ctype, List<JCExpression> args) {
rfield@1717	603	return makeNewClass(ctype, args,
rfield@1717	604	rs.resolveConstructor(null, attrEnv, ctype, TreeInfo.types(args), List.<Type>nil()));
rfield@1717	605	}
rfield@1717	606
rfield@1587	607	private void addDeserializationCase(int implMethodKind, Symbol refSym, Type targetType, MethodSymbol samSym,
rfield@1587	608	DiagnosticPosition pos, List<Object> staticArgs, MethodType indyType) {
rfield@1587	609	String functionalInterfaceClass = classSig(targetType);
rfield@1587	610	String functionalInterfaceMethodName = samSym.getSimpleName().toString();
rfield@2158	611	String functionalInterfaceMethodSignature = typeSig(types.erasure(samSym.type));
rfield@1622	612	String implClass = classSig(types.erasure(refSym.owner.type));
rfield@1587	613	String implMethodName = refSym.getQualifiedName().toString();
rfield@2158	614	String implMethodSignature = typeSig(types.erasure(refSym.type));
rfield@1587	615
rfield@1587	616	JCExpression kindTest = eqTest(syms.intType, deserGetter("getImplMethodKind", syms.intType), make.Literal(implMethodKind));
alundblad@2047	617	ListBuffer<JCExpression> serArgs = new ListBuffer<>();
rfield@1587	618	int i = 0;
rfield@1587	619	for (Type t : indyType.getParameterTypes()) {
alundblad@2047	620	List<JCExpression> indexAsArg = new ListBuffer<JCExpression>().append(make.Literal(i)).toList();
alundblad@2047	621	List<Type> argTypes = new ListBuffer<Type>().append(syms.intType).toList();
rfield@1587	622	serArgs.add(make.TypeCast(types.erasure(t), deserGetter("getCapturedArg", syms.objectType, argTypes, indexAsArg)));
rfield@1587	623	++i;
rfield@1587	624	}
rfield@1587	625	JCStatement stmt = make.If(
rfield@1587	626	deserTest(deserTest(deserTest(deserTest(deserTest(
rfield@1587	627	kindTest,
rfield@1587	628	"getFunctionalInterfaceClass", functionalInterfaceClass),
rfield@1587	629	"getFunctionalInterfaceMethodName", functionalInterfaceMethodName),
rfield@1587	630	"getFunctionalInterfaceMethodSignature", functionalInterfaceMethodSignature),
rfield@1587	631	"getImplClass", implClass),
rfield@1587	632	"getImplMethodSignature", implMethodSignature),
rfield@1587	633	make.Return(makeIndyCall(
rfield@1587	634	pos,
rfield@1587	635	syms.lambdaMetafactory,
mcimadamore@1882	636	names.altMetafactory,
mcimadamore@1882	637	staticArgs, indyType, serArgs.toList(), samSym.name)),
rfield@1587	638	null);
rfield@1587	639	ListBuffer<JCStatement> stmts = kInfo.deserializeCases.get(implMethodName);
rfield@1587	640	if (stmts == null) {
alundblad@2047	641	stmts = new ListBuffer<>();
rfield@1587	642	kInfo.deserializeCases.put(implMethodName, stmts);
rfield@1587	643	}
rfield@1587	644	/****
rfield@1587	645	System.err.printf("+++++++++++++++++\n");
rfield@1587	646	System.err.printf("*functionalInterfaceClass: '%s'\n", functionalInterfaceClass);
rfield@1587	647	System.err.printf("*functionalInterfaceMethodName: '%s'\n", functionalInterfaceMethodName);
rfield@1587	648	System.err.printf("*functionalInterfaceMethodSignature: '%s'\n", functionalInterfaceMethodSignature);
rfield@1587	649	System.err.printf("*implMethodKind: %d\n", implMethodKind);
rfield@1587	650	System.err.printf("*implClass: '%s'\n", implClass);
rfield@1587	651	System.err.printf("*implMethodName: '%s'\n", implMethodName);
rfield@1587	652	System.err.printf("*implMethodSignature: '%s'\n", implMethodSignature);
rfield@1587	653	****/
rfield@1587	654	stmts.append(stmt);
rfield@1587	655	}
rfield@1587	656
rfield@1587	657	private JCExpression eqTest(Type argType, JCExpression arg1, JCExpression arg2) {
rfield@1587	658	JCBinary testExpr = make.Binary(JCTree.Tag.EQ, arg1, arg2);
rfield@1587	659	testExpr.operator = rs.resolveBinaryOperator(null, JCTree.Tag.EQ, attrEnv, argType, argType);
rfield@1587	660	testExpr.setType(syms.booleanType);
rfield@1587	661	return testExpr;
rfield@1587	662	}
rfield@1587	663
rfield@1587	664	private JCExpression deserTest(JCExpression prev, String func, String lit) {
rfield@1587	665	MethodType eqmt = new MethodType(List.of(syms.objectType), syms.booleanType, List.<Type>nil(), syms.methodClass);
rfield@1587	666	Symbol eqsym = rs.resolveQualifiedMethod(null, attrEnv, syms.objectType, names.equals, List.of(syms.objectType), List.<Type>nil());
rfield@1587	667	JCMethodInvocation eqtest = make.Apply(
rfield@1587	668	List.<JCExpression>nil(),
rfield@1587	669	make.Select(deserGetter(func, syms.stringType), eqsym).setType(eqmt),
rfield@1587	670	List.<JCExpression>of(make.Literal(lit)));
rfield@1587	671	eqtest.setType(syms.booleanType);
rfield@1587	672	JCBinary compound = make.Binary(JCTree.Tag.AND, prev, eqtest);
rfield@1587	673	compound.operator = rs.resolveBinaryOperator(null, JCTree.Tag.AND, attrEnv, syms.booleanType, syms.booleanType);
rfield@1587	674	compound.setType(syms.booleanType);
rfield@1587	675	return compound;
rfield@1587	676	}
rfield@1587	677
rfield@1587	678	private JCExpression deserGetter(String func, Type type) {
rfield@1587	679	return deserGetter(func, type, List.<Type>nil(), List.<JCExpression>nil());
rfield@1587	680	}
rfield@1587	681
rfield@1587	682	private JCExpression deserGetter(String func, Type type, List<Type> argTypes, List<JCExpression> args) {
rfield@1587	683	MethodType getmt = new MethodType(argTypes, type, List.<Type>nil(), syms.methodClass);
rfield@1587	684	Symbol getsym = rs.resolveQualifiedMethod(null, attrEnv, syms.serializedLambdaType, names.fromString(func), argTypes, List.<Type>nil());
rfield@1587	685	return make.Apply(
rfield@1587	686	List.<JCExpression>nil(),
rfield@1587	687	make.Select(make.Ident(kInfo.deserParamSym).setType(syms.serializedLambdaType), getsym).setType(getmt),
rfield@1587	688	args).setType(type);
rfield@1587	689	}
rfield@1587	690
rfield@1380	691	/**
rfield@1380	692	* Create new synthetic method with given flags, name, type, owner
rfield@1380	693	*/
rfield@2107	694	private MethodSymbol makePrivateSyntheticMethod(long flags, Name name, Type type, Symbol owner) {
rfield@2107	695	return new MethodSymbol(flags | SYNTHETIC | PRIVATE, name, type, owner);
rfield@1380	696	}
rfield@1380	697
rfield@1380	698	/**
rfield@1380	699	* Create new synthetic variable with given flags, name, type, owner
rfield@1380	700	*/
rfield@1380	701	private VarSymbol makeSyntheticVar(long flags, String name, Type type, Symbol owner) {
rfield@1380	702	return makeSyntheticVar(flags, names.fromString(name), type, owner);
rfield@1380	703	}
rfield@1380	704
rfield@1380	705	/**
rfield@1380	706	* Create new synthetic variable with given flags, name, type, owner
rfield@1380	707	*/
rfield@1380	708	private VarSymbol makeSyntheticVar(long flags, Name name, Type type, Symbol owner) {
rfield@1380	709	return new VarSymbol(flags | SYNTHETIC, name, type, owner);
rfield@1380	710	}
rfield@1380	711
rfield@1380	712	/**
rfield@1380	713	* Set varargsElement field on a given tree (must be either a new class tree
rfield@1380	714	* or a method call tree)
rfield@1380	715	*/
rfield@1380	716	private void setVarargsIfNeeded(JCTree tree, Type varargsElement) {
rfield@1380	717	if (varargsElement != null) {
rfield@1380	718	switch (tree.getTag()) {
rfield@1380	719	case APPLY: ((JCMethodInvocation)tree).varargsElement = varargsElement; break;
rfield@1380	720	case NEWCLASS: ((JCNewClass)tree).varargsElement = varargsElement; break;
rfield@1380	721	default: throw new AssertionError();
rfield@1380	722	}
rfield@1380	723	}
rfield@1380	724	}
rfield@1380	725
rfield@1380	726	/**
rfield@1380	727	* Convert method/constructor arguments by inserting appropriate cast
rfield@1380	728	* as required by type-erasure - this is needed when bridging a lambda/method
rfield@1380	729	* reference, as the bridged signature might require downcast to be compatible
rfield@1380	730	* with the generated signature.
rfield@1380	731	*/
rfield@1380	732	private List<JCExpression> convertArgs(Symbol meth, List<JCExpression> args, Type varargsElement) {
rfield@1380	733	Assert.check(meth.kind == Kinds.MTH);
rfield@1380	734	List<Type> formals = types.erasure(meth.type).getParameterTypes();
rfield@1380	735	if (varargsElement != null) {
rfield@1380	736	Assert.check((meth.flags() & VARARGS) != 0);
rfield@1380	737	}
rfield@1380	738	return transTypes.translateArgs(args, formals, varargsElement, attrEnv);
rfield@1380	739	}
rfield@1380	740
rfield@1380	741	// </editor-fold>
rfield@1380	742
rfield@1380	743	/**
rfield@2607	744	* Converts a method reference which cannot be used directly into a lambda
rfield@1380	745	*/
rfield@2607	746	private class MemberReferenceToLambda {
rfield@1380	747
rfield@1380	748	private final JCMemberReference tree;
rfield@1380	749	private final ReferenceTranslationContext localContext;
rfield@2607	750	private final Symbol owner;
alundblad@2047	751	private final ListBuffer<JCExpression> args = new ListBuffer<>();
alundblad@2047	752	private final ListBuffer<JCVariableDecl> params = new ListBuffer<>();
rfield@1380	753
rfield@2607	754	private JCExpression receiverExpression = null;
rfield@2607	755
rfield@2607	756	MemberReferenceToLambda(JCMemberReference tree, ReferenceTranslationContext localContext, Symbol owner) {
rfield@1380	757	this.tree = tree;
rfield@1380	758	this.localContext = localContext;
rfield@2607	759	this.owner = owner;
rfield@1380	760	}
rfield@1380	761
rfield@2607	762	JCLambda lambda() {
rfield@1380	763	int prevPos = make.pos;
rfield@1380	764	try {
rfield@1380	765	make.at(tree);
rfield@1380	766
rfield@2607	767	//body generation - this can be either a method call or a
rfield@2607	768	//new instance creation expression, depending on the member reference kind
rfield@2614	769	VarSymbol rcvr = addParametersReturnReceiver();
rfield@2607	770	JCExpression expr = (tree.getMode() == ReferenceMode.INVOKE)
rfield@2607	771	? expressionInvoke(rcvr)
rfield@2607	772	: expressionNew();
rfield@1380	773
rfield@2607	774	JCLambda slam = make.Lambda(params.toList(), expr);
rfield@2607	775	slam.targets = tree.targets;
rfield@2607	776	slam.type = tree.type;
rfield@2607	777	slam.pos = tree.pos;
rfield@2607	778	return slam;
rfield@1380	779	} finally {
rfield@1380	780	make.at(prevPos);
rfield@1380	781	}
rfield@1380	782	}
rfield@2607	783
rfield@2614	784	/**
rfield@2614	785	* Generate the parameter list for the converted member reference.
rfield@2614	786	*
rfield@2614	787	* @return The receiver variable symbol, if any
rfield@2614	788	*/
rfield@2614	789	VarSymbol addParametersReturnReceiver() {
rfield@2614	790	Type samDesc = localContext.bridgedRefSig();
rfield@2614	791	List<Type> samPTypes = samDesc.getParameterTypes();
rfield@2614	792	List<Type> descPTypes = tree.getDescriptorType(types).getParameterTypes();
rfield@2614	793
rfield@2614	794	// Determine the receiver, if any
rfield@2614	795	VarSymbol rcvr;
rfield@2614	796	switch (tree.kind) {
rfield@2614	797	case BOUND:
rfield@2614	798	// The receiver is explicit in the method reference
rfield@2614	799	rcvr = addParameter("rec$", tree.getQualifierExpression().type, false);
rfield@2614	800	receiverExpression = attr.makeNullCheck(tree.getQualifierExpression());
rfield@2614	801	break;
rfield@2614	802	case UNBOUND:
rfield@2614	803	// The receiver is the first parameter, extract it and
rfield@2614	804	// adjust the SAM and unerased type lists accordingly
rfield@2614	805	rcvr = addParameter("rec$", samDesc.getParameterTypes().head, false);
rfield@2614	806	samPTypes = samPTypes.tail;
rfield@2614	807	descPTypes = descPTypes.tail;
rfield@2614	808	break;
rfield@2614	809	default:
rfield@2614	810	rcvr = null;
rfield@2614	811	break;
rfield@2614	812	}
rfield@2614	813	List<Type> implPTypes = tree.sym.type.getParameterTypes();
rfield@2614	814	int implSize = implPTypes.size();
rfield@2614	815	int samSize = samPTypes.size();
rfield@2614	816	// Last parameter to copy from referenced method, exclude final var args
rfield@2614	817	int last = localContext.needsVarArgsConversion() ? implSize - 1 : implSize;
rfield@2614	818
rfield@2614	819	// Failsafe -- assure match-up
rfield@2614	820	boolean checkForIntersection = tree.varargsElement != null || implSize == descPTypes.size();
rfield@2614	821
rfield@2614	822	// Use parameter types of the implementation method unless the unerased
rfield@2614	823	// SAM parameter type is an intersection type, in that case use the
rfield@2614	824	// erased SAM parameter type so that the supertype relationship
rfield@2614	825	// the implementation method parameters is not obscured.
rfield@2614	826	// Note: in this loop, the lists implPTypes, samPTypes, and descPTypes
rfield@2614	827	// are used as pointers to the current parameter type information
rfield@2614	828	// and are thus not usable afterwards.
rfield@2614	829	for (int i = 0; implPTypes.nonEmpty() && i < last; ++i) {
rfield@2614	830	// By default use the implementation method parmeter type
rfield@2614	831	Type parmType = implPTypes.head;
rfield@2614	832	// If the unerased parameter type is a type variable whose
rfield@2614	833	// bound is an intersection (eg. <T extends A & B>) then
rfield@2614	834	// use the SAM parameter type
rfield@2614	835	if (checkForIntersection && descPTypes.head.getKind() == TypeKind.TYPEVAR) {
rfield@2614	836	TypeVar tv = (TypeVar) descPTypes.head;
rfield@2614	837	if (tv.bound.getKind() == TypeKind.INTERSECTION) {
rfield@2614	838	parmType = samPTypes.head;
rfield@2614	839	}
rfield@2614	840	}
rfield@2614	841	addParameter("x$" + i, parmType, true);
rfield@2614	842
rfield@2614	843	// Advance to the next parameter
rfield@2614	844	implPTypes = implPTypes.tail;
rfield@2614	845	samPTypes = samPTypes.tail;
rfield@2614	846	descPTypes = descPTypes.tail;
rfield@2614	847	}
rfield@2614	848	// Flatten out the var args
rfield@2614	849	for (int i = last; i < samSize; ++i) {
rfield@2614	850	addParameter("xva$" + i, tree.varargsElement, true);
rfield@2614	851	}
rfield@2614	852
rfield@2614	853	return rcvr;
rfield@2614	854	}
rfield@2614	855
rfield@2607	856	JCExpression getReceiverExpression() {
rfield@2607	857	return receiverExpression;
rfield@2607	858	}
rfield@2607	859
rfield@2607	860	private JCExpression makeReceiver(VarSymbol rcvr) {
rfield@2607	861	if (rcvr == null) return null;
rfield@2607	862	JCExpression rcvrExpr = make.Ident(rcvr);
rfield@2607	863	Type rcvrType = tree.sym.enclClass().type;
rfield@2607	864	if (rcvrType == syms.arrayClass.type) {
rfield@2607	865	// Map the receiver type to the actually type, not just "array"
rfield@2607	866	rcvrType = tree.getQualifierExpression().type;
mcimadamore@1614	867	}
rfield@2607	868	if (!rcvr.type.tsym.isSubClass(rcvrType.tsym, types)) {
rfield@2607	869	rcvrExpr = make.TypeCast(make.Type(rcvrType), rcvrExpr).setType(rcvrType);
rfield@2607	870	}
rfield@2607	871	return rcvrExpr;
rfield@2607	872	}
rfield@1380	873
rfield@1380	874	/**
rfield@2607	875	* determine the receiver of the method call - the receiver can
rfield@2607	876	* be a type qualifier, the synthetic receiver parameter or 'super'.
rfield@1380	877	*/
rfield@2607	878	private JCExpression expressionInvoke(VarSymbol rcvr) {
rfield@1380	879	JCExpression qualifier =
rfield@1380	880	tree.sym.isStatic() ?
rfield@1380	881	make.Type(tree.sym.owner.type) :
rfield@1380	882	(rcvr != null) ?
rfield@2607	883	makeReceiver(rcvr) :
rfield@1380	884	tree.getQualifierExpression();
rfield@1380	885
rfield@1380	886	//create the qualifier expression
rfield@1380	887	JCFieldAccess select = make.Select(qualifier, tree.sym.name);
rfield@1380	888	select.sym = tree.sym;
rfield@1380	889	select.type = tree.sym.erasure(types);
rfield@1380	890
rfield@1380	891	//create the method call expression
rfield@1380	892	JCExpression apply = make.Apply(List.<JCExpression>nil(), select,
mcimadamore@1595	893	convertArgs(tree.sym, args.toList(), tree.varargsElement)).
mcimadamore@1595	894	setType(tree.sym.erasure(types).getReturnType());
rfield@1380	895
rfield@1380	896	apply = transTypes.coerce(apply, localContext.generatedRefSig().getReturnType());
rfield@1380	897	setVarargsIfNeeded(apply, tree.varargsElement);
rfield@1380	898	return apply;
rfield@1380	899	}
rfield@1380	900
rfield@1380	901	/**
rfield@2607	902	* Lambda body to use for a 'new'.
rfield@1380	903	*/
rfield@2607	904	private JCExpression expressionNew() {
mcimadamore@1496	905	if (tree.kind == ReferenceKind.ARRAY_CTOR) {
mcimadamore@1496	906	//create the array creation expression
mcimadamore@1595	907	JCNewArray newArr = make.NewArray(
mcimadamore@1595	908	make.Type(types.elemtype(tree.getQualifierExpression().type)),
mcimadamore@1496	909	List.of(make.Ident(params.first())),
mcimadamore@1496	910	null);
mcimadamore@1496	911	newArr.type = tree.getQualifierExpression().type;
mcimadamore@1496	912	return newArr;
mcimadamore@1496	913	} else {
mcimadamore@1496	914	//create the instance creation expression
rfield@2607	915	//note that method reference syntax does not allow an explicit
rfield@2607	916	//enclosing class (so the enclosing class is null)
rfield@2607	917	JCNewClass newClass = make.NewClass(null,
mcimadamore@1496	918	List.<JCExpression>nil(),
mcimadamore@1496	919	make.Type(tree.getQualifierExpression().type),
mcimadamore@1496	920	convertArgs(tree.sym, args.toList(), tree.varargsElement),
mcimadamore@1496	921	null);
mcimadamore@1496	922	newClass.constructor = tree.sym;
mcimadamore@1496	923	newClass.constructorType = tree.sym.erasure(types);
mcimadamore@1496	924	newClass.type = tree.getQualifierExpression().type;
mcimadamore@1496	925	setVarargsIfNeeded(newClass, tree.varargsElement);
mcimadamore@1496	926	return newClass;
rfield@1380	927	}
rfield@1380	928	}
rfield@1380	929
rfield@1380	930	private VarSymbol addParameter(String name, Type p, boolean genArg) {
rfield@2607	931	VarSymbol vsym = new VarSymbol(PARAMETER | SYNTHETIC, names.fromString(name), p, owner);
rfield@2607	932	vsym.pos = tree.pos;
rfield@1380	933	params.append(make.VarDef(vsym, null));
rfield@1380	934	if (genArg) {
rfield@1380	935	args.append(make.Ident(vsym));
rfield@1380	936	}
rfield@1380	937	return vsym;
rfield@1380	938	}
rfield@1380	939	}
rfield@1380	940
mcimadamore@1882	941	private MethodType typeToMethodType(Type mt) {
mcimadamore@1882	942	Type type = types.erasure(mt);
mcimadamore@1882	943	return new MethodType(type.getParameterTypes(),
mcimadamore@1882	944	type.getReturnType(),
mcimadamore@1882	945	type.getThrownTypes(),
mcimadamore@1882	946	syms.methodClass);
mcimadamore@1882	947	}
mcimadamore@1882	948
rfield@1380	949	/**
rfield@1380	950	* Generate an indy method call to the meta factory
rfield@1380	951	*/
mcimadamore@1882	952	private JCExpression makeMetafactoryIndyCall(TranslationContext<?> context,
mcimadamore@1882	953	int refKind, Symbol refSym, List<JCExpression> indy_args) {
mcimadamore@1882	954	JCFunctionalExpression tree = context.tree;
rfield@1380	955	//determine the static bsm args
mcimadamore@1510	956	MethodSymbol samSym = (MethodSymbol) types.findDescriptorSymbol(tree.type.tsym);
rfield@1380	957	List<Object> staticArgs = List.<Object>of(
mcimadamore@1882	958	typeToMethodType(samSym.type),
vromero@1452	959	new Pool.MethodHandle(refKind, refSym, types),
mcimadamore@1882	960	typeToMethodType(tree.getDescriptorType(types)));
rfield@1380	961
rfield@1380	962	//computed indy arg types
alundblad@2047	963	ListBuffer<Type> indy_args_types = new ListBuffer<>();
rfield@1380	964	for (JCExpression arg : indy_args) {
rfield@1380	965	indy_args_types.append(arg.type);
rfield@1380	966	}
rfield@1380	967
rfield@1380	968	//finally, compute the type of the indy call
rfield@1380	969	MethodType indyType = new MethodType(indy_args_types.toList(),
rfield@1380	970	tree.type,
rfield@1380	971	List.<Type>nil(),
rfield@1380	972	syms.methodClass);
rfield@1380	973
mcimadamore@1882	974	Name metafactoryName = context.needsAltMetafactory() ?
mcimadamore@1882	975	names.altMetafactory : names.metafactory;
rfield@1587	976
mcimadamore@1882	977	if (context.needsAltMetafactory()) {
alundblad@2047	978	ListBuffer<Object> markers = new ListBuffer<>();
mcimadamore@1882	979	for (Type t : tree.targets.tail) {
mcimadamore@1882	980	if (t.tsym != syms.serializableType.tsym) {
mcimadamore@1882	981	markers.append(t.tsym);
rfield@1587	982	}
rfield@1587	983	}
mcimadamore@1882	984	int flags = context.isSerializable() ? FLAG_SERIALIZABLE : 0;
rfield@1587	985	boolean hasMarkers = markers.nonEmpty();
mcimadamore@1882	986	boolean hasBridges = context.bridges.nonEmpty();
mcimadamore@1882	987	if (hasMarkers) {
mcimadamore@1882	988	flags |= FLAG_MARKERS;
mcimadamore@1882	989	}
mcimadamore@1882	990	if (hasBridges) {
mcimadamore@1882	991	flags |= FLAG_BRIDGES;
mcimadamore@1882	992	}
rfield@1587	993	staticArgs = staticArgs.append(flags);
rfield@1587	994	if (hasMarkers) {
rfield@1587	995	staticArgs = staticArgs.append(markers.length());
rfield@1587	996	staticArgs = staticArgs.appendList(markers.toList());
rfield@1587	997	}
mcimadamore@1882	998	if (hasBridges) {
mcimadamore@1882	999	staticArgs = staticArgs.append(context.bridges.length() - 1);
mcimadamore@1882	1000	for (Symbol s : context.bridges) {
mcimadamore@1882	1001	Type s_erasure = s.erasure(types);
mcimadamore@1882	1002	if (!types.isSameType(s_erasure, samSym.erasure(types))) {
mcimadamore@1882	1003	staticArgs = staticArgs.append(s.erasure(types));
mcimadamore@1882	1004	}
mcimadamore@1882	1005	}
mcimadamore@1882	1006	}
mcimadamore@1882	1007	if (context.isSerializable()) {
jlahoda@2165	1008	int prevPos = make.pos;
jlahoda@2165	1009	try {
jlahoda@2165	1010	make.at(kInfo.clazz);
jlahoda@2165	1011	addDeserializationCase(refKind, refSym, tree.type, samSym,
jlahoda@2165	1012	tree, staticArgs, indyType);
jlahoda@2165	1013	} finally {
jlahoda@2165	1014	make.at(prevPos);
jlahoda@2165	1015	}
rfield@1587	1016	}
rfield@1587	1017	}
rfield@1587	1018
mcimadamore@1882	1019	return makeIndyCall(tree, syms.lambdaMetafactory, metafactoryName, staticArgs, indyType, indy_args, samSym.name);
rfield@1380	1020	}
rfield@1380	1021
rfield@1380	1022	/**
rfield@1380	1023	* Generate an indy method call with given name, type and static bootstrap
rfield@1380	1024	* arguments types
rfield@1380	1025	*/
mcimadamore@1595	1026	private JCExpression makeIndyCall(DiagnosticPosition pos, Type site, Name bsmName,
mcimadamore@1882	1027	List<Object> staticArgs, MethodType indyType, List<JCExpression> indyArgs,
mcimadamore@1882	1028	Name methName) {
rfield@1380	1029	int prevPos = make.pos;
rfield@1380	1030	try {
rfield@1380	1031	make.at(pos);
rfield@1380	1032	List<Type> bsm_staticArgs = List.of(syms.methodHandleLookupType,
rfield@1380	1033	syms.stringType,
rfield@1380	1034	syms.methodTypeType).appendList(bsmStaticArgToTypes(staticArgs));
rfield@1380	1035
rfield@1380	1036	Symbol bsm = rs.resolveInternalMethod(pos, attrEnv, site,
rfield@1380	1037	bsmName, bsm_staticArgs, List.<Type>nil());
rfield@1380	1038
rfield@1380	1039	DynamicMethodSymbol dynSym =
mcimadamore@1882	1040	new DynamicMethodSymbol(methName,
rfield@1380	1041	syms.noSymbol,
mcimadamore@1595	1042	bsm.isStatic() ?
mcimadamore@1595	1043	ClassFile.REF_invokeStatic :
mcimadamore@1595	1044	ClassFile.REF_invokeVirtual,
rfield@1380	1045	(MethodSymbol)bsm,
rfield@1380	1046	indyType,
rfield@1380	1047	staticArgs.toArray());
rfield@1380	1048
rfield@1380	1049	JCFieldAccess qualifier = make.Select(make.QualIdent(site.tsym), bsmName);
rfield@1380	1050	qualifier.sym = dynSym;
rfield@1380	1051	qualifier.type = indyType.getReturnType();
rfield@1380	1052
rfield@1380	1053	JCMethodInvocation proxyCall = make.Apply(List.<JCExpression>nil(), qualifier, indyArgs);
rfield@1380	1054	proxyCall.type = indyType.getReturnType();
rfield@1380	1055	return proxyCall;
rfield@1380	1056	} finally {
rfield@1380	1057	make.at(prevPos);
rfield@1380	1058	}
rfield@1380	1059	}
rfield@1380	1060	//where
rfield@1380	1061	private List<Type> bsmStaticArgToTypes(List<Object> args) {
alundblad@2047	1062	ListBuffer<Type> argtypes = new ListBuffer<>();
rfield@1380	1063	for (Object arg : args) {
rfield@1380	1064	argtypes.append(bsmStaticArgToType(arg));
rfield@1380	1065	}
rfield@1380	1066	return argtypes.toList();
rfield@1380	1067	}
rfield@1380	1068
rfield@1380	1069	private Type bsmStaticArgToType(Object arg) {
rfield@1380	1070	Assert.checkNonNull(arg);
rfield@1380	1071	if (arg instanceof ClassSymbol) {
rfield@1380	1072	return syms.classType;
rfield@1380	1073	} else if (arg instanceof Integer) {
rfield@1380	1074	return syms.intType;
rfield@1380	1075	} else if (arg instanceof Long) {
rfield@1380	1076	return syms.longType;
rfield@1380	1077	} else if (arg instanceof Float) {
rfield@1380	1078	return syms.floatType;
rfield@1380	1079	} else if (arg instanceof Double) {
rfield@1380	1080	return syms.doubleType;
rfield@1380	1081	} else if (arg instanceof String) {
rfield@1380	1082	return syms.stringType;
rfield@1380	1083	} else if (arg instanceof Pool.MethodHandle) {
rfield@1380	1084	return syms.methodHandleType;
rfield@1380	1085	} else if (arg instanceof MethodType) {
rfield@1380	1086	return syms.methodTypeType;
rfield@1380	1087	} else {
rfield@1380	1088	Assert.error("bad static arg " + arg.getClass());
rfield@1380	1089	return null;
rfield@1380	1090	}
rfield@1380	1091	}
rfield@1380	1092
rfield@1380	1093	/**
rfield@1380	1094	* Get the opcode associated with this method reference
rfield@1380	1095	*/
rfield@1380	1096	private int referenceKind(Symbol refSym) {
rfield@1380	1097	if (refSym.isConstructor()) {
rfield@1380	1098	return ClassFile.REF_newInvokeSpecial;
rfield@1380	1099	} else {
rfield@1380	1100	if (refSym.isStatic()) {
rfield@1380	1101	return ClassFile.REF_invokeStatic;
rfield@2107	1102	} else if ((refSym.flags() & PRIVATE) != 0) {
rfield@2107	1103	return ClassFile.REF_invokeSpecial;
rfield@1380	1104	} else if (refSym.enclClass().isInterface()) {
rfield@1380	1105	return ClassFile.REF_invokeInterface;
rfield@1380	1106	} else {
rfield@2107	1107	return ClassFile.REF_invokeVirtual;
rfield@1380	1108	}
rfield@1380	1109	}
rfield@1380	1110	}
rfield@1587	1111
mcimadamore@1652	1112	// <editor-fold defaultstate="collapsed" desc="Lambda/reference analyzer">
rfield@1380	1113	/**
rfield@1380	1114	* This visitor collects information about translation of a lambda expression.
rfield@1380	1115	* More specifically, it keeps track of the enclosing contexts and captured locals
rfield@1380	1116	* accessed by the lambda being translated (as well as other useful info).
rfield@1717	1117	* It also translates away problems for LambdaToMethod.
rfield@1380	1118	*/
rfield@1717	1119	class LambdaAnalyzerPreprocessor extends TreeTranslator {
rfield@1380	1120
rfield@1380	1121	/** the frame stack - used to reconstruct translation info about enclosing scopes */
rfield@1380	1122	private List<Frame> frameStack;
rfield@1380	1123
rfield@1380	1124	/**
rfield@1380	1125	* keep the count of lambda expression (used to generate unambiguous
rfield@1380	1126	* names)
rfield@1380	1127	*/
rfield@1380	1128	private int lambdaCount = 0;
rfield@1380	1129
rfield@1587	1130	/**
rfield@1587	1131	* keep the count of lambda expression defined in given context (used to
rfield@1587	1132	* generate unambiguous names for serializable lambdas)
rfield@1587	1133	*/
rfield@2158	1134	private class SyntheticMethodNameCounter {
rfield@2158	1135	private Map<String, Integer> map = new HashMap<>();
rfield@2158	1136	int getIndex(StringBuilder buf) {
rfield@2158	1137	String temp = buf.toString();
rfield@2158	1138	Integer count = map.get(temp);
rfield@2158	1139	if (count == null) {
rfield@2158	1140	count = 0;
rfield@2158	1141	}
rfield@2158	1142	++count;
rfield@2158	1143	map.put(temp, count);
rfield@2158	1144	return count;
rfield@2158	1145	}
rfield@2158	1146	}
rfield@2158	1147	private SyntheticMethodNameCounter syntheticMethodNameCounts =
rfield@2158	1148	new SyntheticMethodNameCounter();
rfield@1587	1149
mcimadamore@1612	1150	private Map<Symbol, JCClassDecl> localClassDefs;
mcimadamore@1612	1151
rfield@1587	1152	/**
rfield@1587	1153	* maps for fake clinit symbols to be used as owners of lambda occurring in
rfield@1587	1154	* a static var init context
rfield@1587	1155	*/
rfield@1587	1156	private Map<ClassSymbol, Symbol> clinits =
rfield@1587	1157	new HashMap<ClassSymbol, Symbol>();
rfield@1587	1158
rfield@1717	1159	private JCClassDecl analyzeAndPreprocessClass(JCClassDecl tree) {
rfield@1380	1160	frameStack = List.nil();
mcimadamore@1612	1161	localClassDefs = new HashMap<Symbol, JCClassDecl>();
rfield@1717	1162	return translate(tree);
rfield@1380	1163	}
rfield@1380	1164
rfield@1380	1165	@Override
rfield@1380	1166	public void visitBlock(JCBlock tree) {
rfield@1380	1167	List<Frame> prevStack = frameStack;
rfield@1380	1168	try {
rfield@1380	1169	if (frameStack.nonEmpty() && frameStack.head.tree.hasTag(CLASSDEF)) {
rfield@1380	1170	frameStack = frameStack.prepend(new Frame(tree));
rfield@1380	1171	}
rfield@1380	1172	super.visitBlock(tree);
rfield@1380	1173	}
rfield@1380	1174	finally {
rfield@1380	1175	frameStack = prevStack;
rfield@1380	1176	}
rfield@1380	1177	}
rfield@1380	1178
rfield@1380	1179	@Override
rfield@1380	1180	public void visitClassDef(JCClassDecl tree) {
rfield@1380	1181	List<Frame> prevStack = frameStack;
rfield@2158	1182	SyntheticMethodNameCounter prevSyntheticMethodNameCounts =
rfield@2158	1183	syntheticMethodNameCounts;
rfield@1587	1184	Map<ClassSymbol, Symbol> prevClinits = clinits;
mcimadamore@1817	1185	DiagnosticSource prevSource = log.currentSource();
rfield@1380	1186	try {
mcimadamore@1817	1187	log.useSource(tree.sym.sourcefile);
rfield@2158	1188	syntheticMethodNameCounts = new SyntheticMethodNameCounter();
rfield@1587	1189	prevClinits = new HashMap<ClassSymbol, Symbol>();
mcimadamore@1612	1190	if (tree.sym.owner.kind == MTH) {
mcimadamore@1612	1191	localClassDefs.put(tree.sym, tree);
mcimadamore@1612	1192	}
rfield@1587	1193	if (directlyEnclosingLambda() != null) {
rfield@1380	1194	tree.sym.owner = owner();
mcimadamore@1595	1195	if (tree.sym.hasOuterInstance()) {
mcimadamore@1595	1196	//if a class is defined within a lambda, the lambda must capture
mcimadamore@1595	1197	//its enclosing instance (if any)
mcimadamore@1612	1198	TranslationContext<?> localContext = context();
mcimadamore@1612	1199	while (localContext != null) {
mcimadamore@1612	1200	if (localContext.tree.getTag() == LAMBDA) {
mcimadamore@1612	1201	((LambdaTranslationContext)localContext)
mcimadamore@1612	1202	.addSymbol(tree.sym.type.getEnclosingType().tsym, CAPTURED_THIS);
mcimadamore@1612	1203	}
mcimadamore@1612	1204	localContext = localContext.prev;
mcimadamore@1612	1205	}
rfield@1380	1206	}
rfield@1380	1207	}
rfield@1380	1208	frameStack = frameStack.prepend(new Frame(tree));
rfield@1380	1209	super.visitClassDef(tree);
rfield@1380	1210	}
rfield@1380	1211	finally {
mcimadamore@1817	1212	log.useSource(prevSource.getFile());
rfield@1380	1213	frameStack = prevStack;
rfield@2158	1214	syntheticMethodNameCounts = prevSyntheticMethodNameCounts;
rfield@1587	1215	clinits = prevClinits;
rfield@1380	1216	}
rfield@1380	1217	}
rfield@1380	1218
rfield@1380	1219	@Override
rfield@1380	1220	public void visitIdent(JCIdent tree) {
rfield@1587	1221	if (context() != null && lambdaIdentSymbolFilter(tree.sym)) {
rfield@1380	1222	if (tree.sym.kind == VAR &&
rfield@1380	1223	tree.sym.owner.kind == MTH &&
rfield@1380	1224	tree.type.constValue() == null) {
rfield@1380	1225	TranslationContext<?> localContext = context();
rfield@1380	1226	while (localContext != null) {
rfield@1380	1227	if (localContext.tree.getTag() == LAMBDA) {
rfield@1380	1228	JCTree block = capturedDecl(localContext.depth, tree.sym);
rfield@1380	1229	if (block == null) break;
mcimadamore@1595	1230	((LambdaTranslationContext)localContext)
mcimadamore@1595	1231	.addSymbol(tree.sym, CAPTURED_VAR);
rfield@1380	1232	}
rfield@1380	1233	localContext = localContext.prev;
rfield@1380	1234	}
rfield@1380	1235	} else if (tree.sym.owner.kind == TYP) {
rfield@1380	1236	TranslationContext<?> localContext = context();
rfield@1380	1237	while (localContext != null) {
rfield@1380	1238	if (localContext.tree.hasTag(LAMBDA)) {
rfield@1380	1239	JCTree block = capturedDecl(localContext.depth, tree.sym);
rfield@1380	1240	if (block == null) break;
rfield@1380	1241	switch (block.getTag()) {
rfield@1380	1242	case CLASSDEF:
rfield@1380	1243	JCClassDecl cdecl = (JCClassDecl)block;
mcimadamore@1595	1244	((LambdaTranslationContext)localContext)
mcimadamore@1595	1245	.addSymbol(cdecl.sym, CAPTURED_THIS);
rfield@1380	1246	break;
rfield@1380	1247	default:
rfield@1380	1248	Assert.error("bad block kind");
rfield@1380	1249	}
rfield@1380	1250	}
rfield@1380	1251	localContext = localContext.prev;
rfield@1380	1252	}
rfield@1380	1253	}
rfield@1380	1254	}
rfield@1587	1255	super.visitIdent(tree);
rfield@1380	1256	}
rfield@1380	1257
rfield@1380	1258	@Override
rfield@1380	1259	public void visitLambda(JCLambda tree) {
rfield@2607	1260	analyzeLambda(tree, "lambda.stat");
rfield@2607	1261	}
rfield@2607	1262
rfield@2607	1263	private void analyzeLambda(JCLambda tree, JCExpression methodReferenceReceiver) {
rfield@2607	1264	// Translation of the receiver expression must occur first
rfield@2607	1265	JCExpression rcvr = translate(methodReferenceReceiver);
rfield@2607	1266	LambdaTranslationContext context = analyzeLambda(tree, "mref.stat.1");
rfield@2607	1267	if (rcvr != null) {
rfield@2607	1268	context.methodReferenceReceiver = rcvr;
rfield@2607	1269	}
rfield@2607	1270	}
rfield@2607	1271
rfield@2607	1272	private LambdaTranslationContext analyzeLambda(JCLambda tree, String statKey) {
rfield@1380	1273	List<Frame> prevStack = frameStack;
rfield@1380	1274	try {
rfield@2607	1275	LambdaTranslationContext context = new LambdaTranslationContext(tree);
rfield@2607	1276	if (dumpLambdaToMethodStats) {
rfield@2607	1277	log.note(tree, statKey, context.needsAltMetafactory(), context.translatedSym);
rfield@2607	1278	}
rfield@1380	1279	frameStack = frameStack.prepend(new Frame(tree));
rfield@1380	1280	for (JCVariableDecl param : tree.params) {
rfield@1380	1281	context.addSymbol(param.sym, PARAM);
rfield@1380	1282	frameStack.head.addLocal(param.sym);
rfield@1380	1283	}
rfield@1380	1284	contextMap.put(tree, context);
rfield@1717	1285	super.visitLambda(tree);
rfield@1380	1286	context.complete();
rfield@2607	1287	return context;
rfield@1380	1288	}
rfield@1380	1289	finally {
rfield@1380	1290	frameStack = prevStack;
rfield@1380	1291	}
rfield@1380	1292	}
rfield@1380	1293
rfield@1380	1294	@Override
rfield@1380	1295	public void visitMethodDef(JCMethodDecl tree) {
rfield@1380	1296	List<Frame> prevStack = frameStack;
rfield@1380	1297	try {
rfield@1380	1298	frameStack = frameStack.prepend(new Frame(tree));
rfield@1380	1299	super.visitMethodDef(tree);
rfield@1380	1300	}
rfield@1380	1301	finally {
rfield@1380	1302	frameStack = prevStack;
rfield@1380	1303	}
rfield@1380	1304	}
rfield@1380	1305
rfield@1380	1306	@Override
rfield@1380	1307	public void visitNewClass(JCNewClass tree) {
rfield@2381	1308	TypeSymbol def = tree.type.tsym;
rfield@2381	1309	boolean inReferencedClass = currentlyInClass(def);
rfield@2381	1310	boolean isLocal = def.isLocal();
rfield@2381	1311	if ((inReferencedClass && isLocal || lambdaNewClassFilter(context(), tree))) {
mcimadamore@1612	1312	TranslationContext<?> localContext = context();
mcimadamore@1612	1313	while (localContext != null) {
mcimadamore@1612	1314	if (localContext.tree.getTag() == LAMBDA) {
mcimadamore@1612	1315	((LambdaTranslationContext)localContext)
mcimadamore@1612	1316	.addSymbol(tree.type.getEnclosingType().tsym, CAPTURED_THIS);
mcimadamore@1612	1317	}
mcimadamore@1612	1318	localContext = localContext.prev;
mcimadamore@1612	1319	}
mcimadamore@1612	1320	}
rfield@2381	1321	if (context() != null && !inReferencedClass && isLocal) {
mcimadamore@1612	1322	LambdaTranslationContext lambdaContext = (LambdaTranslationContext)context();
rfield@2381	1323	captureLocalClassDefs(def, lambdaContext);
rfield@1380	1324	}
rfield@1380	1325	super.visitNewClass(tree);
rfield@1380	1326	}
mcimadamore@1612	1327	//where
mcimadamore@1612	1328	void captureLocalClassDefs(Symbol csym, final LambdaTranslationContext lambdaContext) {
mcimadamore@1612	1329	JCClassDecl localCDef = localClassDefs.get(csym);
rfield@2381	1330	if (localCDef != null && lambdaContext.freeVarProcessedLocalClasses.add(csym)) {
mcimadamore@1612	1331	BasicFreeVarCollector fvc = lower.new BasicFreeVarCollector() {
mcimadamore@1612	1332	@Override
mcimadamore@1612	1333	void addFreeVars(ClassSymbol c) {
mcimadamore@1612	1334	captureLocalClassDefs(c, lambdaContext);
mcimadamore@1612	1335	}
mcimadamore@1612	1336	@Override
mcimadamore@1612	1337	void visitSymbol(Symbol sym) {
mcimadamore@1612	1338	if (sym.kind == VAR &&
mcimadamore@1612	1339	sym.owner.kind == MTH &&
mcimadamore@1612	1340	((VarSymbol)sym).getConstValue() == null) {
mcimadamore@1612	1341	TranslationContext<?> localContext = context();
mcimadamore@1612	1342	while (localContext != null) {
mcimadamore@1612	1343	if (localContext.tree.getTag() == LAMBDA) {
mcimadamore@1612	1344	JCTree block = capturedDecl(localContext.depth, sym);
mcimadamore@1612	1345	if (block == null) break;
mcimadamore@1612	1346	((LambdaTranslationContext)localContext).addSymbol(sym, CAPTURED_VAR);
mcimadamore@1612	1347	}
mcimadamore@1612	1348	localContext = localContext.prev;
mcimadamore@1612	1349	}
mcimadamore@1612	1350	}
mcimadamore@1612	1351	}
mcimadamore@1612	1352	};
mcimadamore@1612	1353	fvc.scan(localCDef);
mcimadamore@1612	1354	}
rfield@1717	1355	}
rfield@2381	1356	//where
rfield@2381	1357	boolean currentlyInClass(Symbol csym) {
rfield@2381	1358	for (Frame frame : frameStack) {
rfield@2381	1359	if (frame.tree.hasTag(JCTree.Tag.CLASSDEF)) {
rfield@2381	1360	JCClassDecl cdef = (JCClassDecl) frame.tree;
rfield@2381	1361	if (cdef.sym == csym) {
rfield@2381	1362	return true;
rfield@2381	1363	}
rfield@2381	1364	}
rfield@2381	1365	}
rfield@2381	1366	return false;
rfield@2381	1367	}
rfield@1380	1368
rfield@1717	1369	/**
rfield@1717	1370	* Method references to local class constructors, may, if the local
rfield@1717	1371	* class references local variables, have implicit constructor
rfield@1717	1372	* parameters added in Lower; As a result, the invokedynamic bootstrap
rfield@1717	1373	* information added in the LambdaToMethod pass will have the wrong
rfield@1717	1374	* signature. Hooks between Lower and LambdaToMethod have been added to
rfield@1717	1375	* handle normal "new" in this case. This visitor converts potentially
rfield@2607	1376	* affected method references into a lambda containing a normal
rfield@2607	1377	* expression.
rfield@1717	1378	*
rfield@1717	1379	* @param tree
rfield@1717	1380	*/
rfield@1380	1381	@Override
rfield@1380	1382	public void visitReference(JCMemberReference tree) {
rfield@2607	1383	ReferenceTranslationContext rcontext = new ReferenceTranslationContext(tree);
rfield@2607	1384	contextMap.put(tree, rcontext);
rfield@2607	1385	if (rcontext.needsConversionToLambda()) {
rfield@2607	1386	// Convert to a lambda, and process as such
rfield@2607	1387	MemberReferenceToLambda conv = new MemberReferenceToLambda(tree, rcontext, owner());
rfield@2607	1388	analyzeLambda(conv.lambda(), conv.getReceiverExpression());
rfield@1717	1389	} else {
rfield@1717	1390	super.visitReference(tree);
rfield@2607	1391	if (dumpLambdaToMethodStats) {
rfield@2607	1392	log.note(tree, "mref.stat", rcontext.needsAltMetafactory(), null);
rfield@2607	1393	}
rfield@1717	1394	}
rfield@1380	1395	}
rfield@1380	1396
rfield@1380	1397	@Override
rfield@1380	1398	public void visitSelect(JCFieldAccess tree) {
rfield@1762	1399	if (context() != null && tree.sym.kind == VAR &&
rfield@1762	1400	(tree.sym.name == names._this ||
rfield@1762	1401	tree.sym.name == names._super)) {
rfield@1762	1402	// A select of this or super means, if we are in a lambda,
rfield@1762	1403	// we much have an instance context
rfield@1380	1404	TranslationContext<?> localContext = context();
rfield@1380	1405	while (localContext != null) {
rfield@1380	1406	if (localContext.tree.hasTag(LAMBDA)) {
rfield@1380	1407	JCClassDecl clazz = (JCClassDecl)capturedDecl(localContext.depth, tree.sym);
rfield@1380	1408	if (clazz == null) break;
rfield@1380	1409	((LambdaTranslationContext)localContext).addSymbol(clazz.sym, CAPTURED_THIS);
rfield@1380	1410	}
rfield@1380	1411	localContext = localContext.prev;
rfield@1380	1412	}
rfield@1380	1413	}
rfield@1717	1414	super.visitSelect(tree);
rfield@1380	1415	}
rfield@1380	1416
rfield@1380	1417	@Override
rfield@1380	1418	public void visitVarDef(JCVariableDecl tree) {
rfield@1587	1419	TranslationContext<?> context = context();
rfield@1587	1420	LambdaTranslationContext ltc = (context != null && context instanceof LambdaTranslationContext)?
rfield@1587	1421	(LambdaTranslationContext)context :
rfield@1587	1422	null;
rfield@1587	1423	if (ltc != null) {
rfield@1587	1424	if (frameStack.head.tree.hasTag(LAMBDA)) {
rfield@1587	1425	ltc.addSymbol(tree.sym, LOCAL_VAR);
rfield@1587	1426	}
rfield@1587	1427	// Check for type variables (including as type arguments).
rfield@1587	1428	// If they occur within class nested in a lambda, mark for erasure
rfield@1587	1429	Type type = tree.sym.asType();
rfield@1587	1430	if (inClassWithinLambda() && !types.isSameType(types.erasure(type), type)) {
rfield@1587	1431	ltc.addSymbol(tree.sym, TYPE_VAR);
rfield@1587	1432	}
rfield@1380	1433	}
rfield@1587	1434
rfield@1380	1435	List<Frame> prevStack = frameStack;
rfield@1380	1436	try {
rfield@1380	1437	if (tree.sym.owner.kind == MTH) {
rfield@1380	1438	frameStack.head.addLocal(tree.sym);
rfield@1380	1439	}
rfield@1380	1440	frameStack = frameStack.prepend(new Frame(tree));
rfield@1380	1441	super.visitVarDef(tree);
rfield@1380	1442	}
rfield@1380	1443	finally {
rfield@1380	1444	frameStack = prevStack;
rfield@1380	1445	}
rfield@1380	1446	}
rfield@1380	1447
rfield@1380	1448	/**
rfield@1380	1449	* Return a valid owner given the current declaration stack
rfield@1380	1450	* (required to skip synthetic lambda symbols)
rfield@1380	1451	*/
rfield@1380	1452	private Symbol owner() {
mcimadamore@1515	1453	return owner(false);
mcimadamore@1515	1454	}
mcimadamore@1515	1455
mcimadamore@1515	1456	@SuppressWarnings("fallthrough")
mcimadamore@1515	1457	private Symbol owner(boolean skipLambda) {
rfield@1380	1458	List<Frame> frameStack2 = frameStack;
rfield@1380	1459	while (frameStack2.nonEmpty()) {
rfield@1380	1460	switch (frameStack2.head.tree.getTag()) {
rfield@1380	1461	case VARDEF:
rfield@1380	1462	if (((JCVariableDecl)frameStack2.head.tree).sym.isLocal()) {
rfield@1380	1463	frameStack2 = frameStack2.tail;
rfield@1380	1464	break;
rfield@1380	1465	}
rfield@1380	1466	JCClassDecl cdecl = (JCClassDecl)frameStack2.tail.head.tree;
rfield@1587	1467	return initSym(cdecl.sym,
rfield@1587	1468	((JCVariableDecl)frameStack2.head.tree).sym.flags() & STATIC);
rfield@1380	1469	case BLOCK:
rfield@1380	1470	JCClassDecl cdecl2 = (JCClassDecl)frameStack2.tail.head.tree;
rfield@1587	1471	return initSym(cdecl2.sym,
rfield@1587	1472	((JCBlock)frameStack2.head.tree).flags & STATIC);
rfield@1380	1473	case CLASSDEF:
rfield@1380	1474	return ((JCClassDecl)frameStack2.head.tree).sym;
rfield@1380	1475	case METHODDEF:
rfield@1380	1476	return ((JCMethodDecl)frameStack2.head.tree).sym;
rfield@1380	1477	case LAMBDA:
mcimadamore@1515	1478	if (!skipLambda)
mcimadamore@1595	1479	return ((LambdaTranslationContext)contextMap
mcimadamore@1595	1480	.get(frameStack2.head.tree)).translatedSym;
rfield@1380	1481	default:
rfield@1380	1482	frameStack2 = frameStack2.tail;
rfield@1380	1483	}
rfield@1380	1484	}
rfield@1380	1485	Assert.error();
rfield@1380	1486	return null;
rfield@1380	1487	}
rfield@1380	1488
rfield@1587	1489	private Symbol initSym(ClassSymbol csym, long flags) {
rfield@1587	1490	boolean isStatic = (flags & STATIC) != 0;
rfield@1587	1491	if (isStatic) {
vromero@2222	1492	/* static clinits are generated in Gen, so we need to use a fake
vromero@2222	1493	* one. Attr creates a fake clinit method while attributing
vromero@2222	1494	* lambda expressions used as initializers of static fields, so
vromero@2222	1495	* let's use that one.
vromero@2222	1496	*/
vromero@2222	1497	MethodSymbol clinit = attr.removeClinit(csym);
vromero@2222	1498	if (clinit != null) {
vromero@2222	1499	clinits.put(csym, clinit);
vromero@2222	1500	return clinit;
vromero@2222	1501	}
vromero@2222	1502
vromero@2222	1503	/* if no clinit is found at Attr, then let's try at clinits.
vromero@2222	1504	*/
vromero@2222	1505	clinit = (MethodSymbol)clinits.get(csym);
rfield@1587	1506	if (clinit == null) {
vromero@2222	1507	/* no luck, let's create a new one
vromero@2222	1508	*/
rfield@2107	1509	clinit = makePrivateSyntheticMethod(STATIC,
rfield@1587	1510	names.clinit,
vromero@2222	1511	new MethodType(List.<Type>nil(), syms.voidType,
vromero@2222	1512	List.<Type>nil(), syms.methodClass),
rfield@1587	1513	csym);
rfield@1587	1514	clinits.put(csym, clinit);
rfield@1587	1515	}
rfield@1587	1516	return clinit;
rfield@1587	1517	} else {
rfield@1587	1518	//get the first constructor and treat it as the instance init sym
rfield@1587	1519	for (Symbol s : csym.members_field.getElementsByName(names.init)) {
rfield@1587	1520	return s;
rfield@1587	1521	}
rfield@1587	1522	}
rfield@1587	1523	Assert.error("init not found");
rfield@1587	1524	return null;
rfield@1587	1525	}
rfield@1587	1526
rfield@1587	1527	private JCTree directlyEnclosingLambda() {
rfield@1587	1528	if (frameStack.isEmpty()) {
rfield@1587	1529	return null;
rfield@1587	1530	}
rfield@1380	1531	List<Frame> frameStack2 = frameStack;
rfield@1380	1532	while (frameStack2.nonEmpty()) {
rfield@1380	1533	switch (frameStack2.head.tree.getTag()) {
rfield@1380	1534	case CLASSDEF:
rfield@1380	1535	case METHODDEF:
rfield@1380	1536	return null;
rfield@1380	1537	case LAMBDA:
rfield@1380	1538	return frameStack2.head.tree;
rfield@1380	1539	default:
rfield@1380	1540	frameStack2 = frameStack2.tail;
rfield@1380	1541	}
rfield@1380	1542	}
rfield@1380	1543	Assert.error();
rfield@1380	1544	return null;
rfield@1380	1545	}
rfield@1380	1546
rfield@1587	1547	private boolean inClassWithinLambda() {
rfield@1587	1548	if (frameStack.isEmpty()) {
rfield@1587	1549	return false;
rfield@1587	1550	}
rfield@1587	1551	List<Frame> frameStack2 = frameStack;
rfield@1587	1552	boolean classFound = false;
rfield@1587	1553	while (frameStack2.nonEmpty()) {
rfield@1587	1554	switch (frameStack2.head.tree.getTag()) {
rfield@1587	1555	case LAMBDA:
rfield@1587	1556	return classFound;
rfield@1587	1557	case CLASSDEF:
rfield@1587	1558	classFound = true;
rfield@1587	1559	frameStack2 = frameStack2.tail;
rfield@1587	1560	break;
rfield@1587	1561	default:
rfield@1587	1562	frameStack2 = frameStack2.tail;
rfield@1587	1563	}
rfield@1587	1564	}
rfield@1587	1565	// No lambda
rfield@1587	1566	return false;
rfield@1587	1567	}
rfield@1587	1568
rfield@1380	1569	/**
rfield@1380	1570	* Return the declaration corresponding to a symbol in the enclosing
rfield@1380	1571	* scope; the depth parameter is used to filter out symbols defined
rfield@1380	1572	* in nested scopes (which do not need to undergo capture).
rfield@1380	1573	*/
rfield@1380	1574	private JCTree capturedDecl(int depth, Symbol sym) {
rfield@1380	1575	int currentDepth = frameStack.size() - 1;
rfield@1380	1576	for (Frame block : frameStack) {
rfield@1380	1577	switch (block.tree.getTag()) {
rfield@1380	1578	case CLASSDEF:
rfield@1380	1579	ClassSymbol clazz = ((JCClassDecl)block.tree).sym;
rfield@1380	1580	if (sym.isMemberOf(clazz, types)) {
rfield@1380	1581	return currentDepth > depth ? null : block.tree;
rfield@1380	1582	}
rfield@1380	1583	break;
rfield@1380	1584	case VARDEF:
rfield@1380	1585	if (((JCVariableDecl)block.tree).sym == sym &&
rfield@1380	1586	sym.owner.kind == MTH) { //only locals are captured
rfield@1380	1587	return currentDepth > depth ? null : block.tree;
rfield@1380	1588	}
rfield@1380	1589	break;
rfield@1380	1590	case BLOCK:
rfield@1380	1591	case METHODDEF:
rfield@1380	1592	case LAMBDA:
rfield@1380	1593	if (block.locals != null && block.locals.contains(sym)) {
rfield@1380	1594	return currentDepth > depth ? null : block.tree;
rfield@1380	1595	}
rfield@1380	1596	break;
rfield@1380	1597	default:
rfield@1380	1598	Assert.error("bad decl kind " + block.tree.getTag());
rfield@1380	1599	}
rfield@1380	1600	currentDepth--;
rfield@1380	1601	}
rfield@1380	1602	return null;
rfield@1380	1603	}
rfield@1380	1604
rfield@1380	1605	private TranslationContext<?> context() {
rfield@1380	1606	for (Frame frame : frameStack) {
rfield@1380	1607	TranslationContext<?> context = contextMap.get(frame.tree);
rfield@1380	1608	if (context != null) {
rfield@1380	1609	return context;
rfield@1380	1610	}
rfield@1380	1611	}
rfield@1380	1612	return null;
rfield@1380	1613	}
rfield@1380	1614
rfield@1380	1615	/**
rfield@1380	1616	* This is used to filter out those identifiers that needs to be adjusted
rfield@1380	1617	* when translating away lambda expressions
rfield@1380	1618	*/
rfield@1380	1619	private boolean lambdaIdentSymbolFilter(Symbol sym) {
rfield@1380	1620	return (sym.kind == VAR || sym.kind == MTH)
rfield@1380	1621	&& !sym.isStatic()
rfield@1380	1622	&& sym.name != names.init;
rfield@1380	1623	}
rfield@1380	1624
rfield@1380	1625	/**
rfield@1380	1626	* This is used to filter out those new class expressions that need to
rfield@1380	1627	* be qualified with an enclosing tree
rfield@1380	1628	*/
rfield@1380	1629	private boolean lambdaNewClassFilter(TranslationContext<?> context, JCNewClass tree) {
rfield@1380	1630	if (context != null
rfield@1380	1631	&& tree.encl == null
rfield@1380	1632	&& tree.def == null
rfield@1405	1633	&& !tree.type.getEnclosingType().hasTag(NONE)) {
rfield@1380	1634	Type encl = tree.type.getEnclosingType();
rfield@1380	1635	Type current = context.owner.enclClass().type;
rfield@1405	1636	while (!current.hasTag(NONE)) {
rfield@1380	1637	if (current.tsym.isSubClass(encl.tsym, types)) {
rfield@1380	1638	return true;
rfield@1380	1639	}
rfield@1380	1640	current = current.getEnclosingType();
rfield@1380	1641	}
rfield@1380	1642	return false;
rfield@1380	1643	} else {
rfield@1380	1644	return false;
rfield@1380	1645	}
rfield@1380	1646	}
rfield@1380	1647
rfield@1380	1648	private class Frame {
rfield@1380	1649	final JCTree tree;
rfield@1380	1650	List<Symbol> locals;
rfield@1380	1651
rfield@1380	1652	public Frame(JCTree tree) {
rfield@1380	1653	this.tree = tree;
rfield@1380	1654	}
rfield@1380	1655
rfield@1380	1656	void addLocal(Symbol sym) {
rfield@1380	1657	if (locals == null) {
rfield@1380	1658	locals = List.nil();
rfield@1380	1659	}
rfield@1380	1660	locals = locals.prepend(sym);
rfield@1380	1661	}
rfield@1380	1662	}
rfield@1380	1663
rfield@1380	1664	/**
rfield@1380	1665	* This class is used to store important information regarding translation of
rfield@1380	1666	* lambda expression/method references (see subclasses).
rfield@1380	1667	*/
mcimadamore@1510	1668	private abstract class TranslationContext<T extends JCFunctionalExpression> {
rfield@1380	1669
rfield@1380	1670	/** the underlying (untranslated) tree */
rfield@2158	1671	final T tree;
rfield@1380	1672
rfield@1380	1673	/** points to the adjusted enclosing scope in which this lambda/mref expression occurs */
rfield@2158	1674	final Symbol owner;
rfield@1380	1675
rfield@1380	1676	/** the depth of this lambda expression in the frame stack */
rfield@2158	1677	final int depth;
rfield@1380	1678
rfield@1380	1679	/** the enclosing translation context (set for nested lambdas/mref) */
rfield@2158	1680	final TranslationContext<?> prev;
rfield@1380	1681
mcimadamore@1882	1682	/** list of methods to be bridged by the meta-factory */
rfield@2158	1683	final List<Symbol> bridges;
mcimadamore@1882	1684
rfield@1380	1685	TranslationContext(T tree) {
rfield@1380	1686	this.tree = tree;
rfield@1380	1687	this.owner = owner();
rfield@1380	1688	this.depth = frameStack.size() - 1;
rfield@1380	1689	this.prev = context();
mcimadamore@1882	1690	ClassSymbol csym =
mcimadamore@1882	1691	types.makeFunctionalInterfaceClass(attrEnv, names.empty, tree.targets, ABSTRACT | INTERFACE);
mcimadamore@1882	1692	this.bridges = types.functionalInterfaceBridges(csym);
rfield@1380	1693	}
rfield@1587	1694
rfield@1587	1695	/** does this functional expression need to be created using alternate metafactory? */
rfield@1587	1696	boolean needsAltMetafactory() {
mcimadamore@1882	1697	return tree.targets.length() > 1 ||
mcimadamore@1882	1698	isSerializable() ||
mcimadamore@1882	1699	bridges.length() > 1;
rfield@1587	1700	}
rfield@1587	1701
rfield@1587	1702	/** does this functional expression require serialization support? */
rfield@1587	1703	boolean isSerializable() {
ksrini@2251	1704	if (forceSerializable) {
ksrini@2251	1705	return true;
ksrini@2251	1706	}
mcimadamore@1882	1707	for (Type target : tree.targets) {
mcimadamore@1882	1708	if (types.asSuper(target, syms.serializableType.tsym) != null) {
rfield@1587	1709	return true;
rfield@1587	1710	}
rfield@1587	1711	}
rfield@1587	1712	return false;
rfield@1587	1713	}
rfield@2158	1714
rfield@2158	1715	/**
rfield@2158	1716	* @return Name of the enclosing method to be folded into synthetic
rfield@2158	1717	* method name
rfield@2158	1718	*/
rfield@2158	1719	String enclosingMethodName() {
rfield@2158	1720	return syntheticMethodNameComponent(owner.name);
rfield@2158	1721	}
rfield@2158	1722
rfield@2158	1723	/**
rfield@2158	1724	* @return Method name in a form that can be folded into a
rfield@2158	1725	* component of a synthetic method name
rfield@2158	1726	*/
rfield@2158	1727	String syntheticMethodNameComponent(Name name) {
rfield@2158	1728	if (name == null) {
rfield@2158	1729	return "null";
rfield@2158	1730	}
rfield@2158	1731	String methodName = name.toString();
rfield@2158	1732	if (methodName.equals("<clinit>")) {
rfield@2158	1733	methodName = "static";
rfield@2158	1734	} else if (methodName.equals("<init>")) {
rfield@2158	1735	methodName = "new";
rfield@2158	1736	}
rfield@2158	1737	return methodName;
rfield@2158	1738	}
rfield@1380	1739	}
rfield@1380	1740
rfield@1380	1741	/**
rfield@1380	1742	* This class retains all the useful information about a lambda expression;
rfield@1380	1743	* the contents of this class are filled by the LambdaAnalyzer visitor,
rfield@1380	1744	* and the used by the main translation routines in order to adjust references
rfield@1380	1745	* to captured locals/members, etc.
rfield@1380	1746	*/
rfield@1380	1747	private class LambdaTranslationContext extends TranslationContext<JCLambda> {
rfield@1380	1748
rfield@1380	1749	/** variable in the enclosing context to which this lambda is assigned */
rfield@2158	1750	final Symbol self;
rfield@2158	1751
rfield@2158	1752	/** variable in the enclosing context to which this lambda is assigned */
rfield@2158	1753	final Symbol assignedTo;
rfield@1380	1754
ksrini@2155	1755	Map<LambdaSymbolKind, Map<Symbol, Symbol>> translatedSymbols;
rfield@1587	1756
rfield@1380	1757	/** the synthetic symbol for the method hoisting the translated lambda */
jlahoda@2733	1758	MethodSymbol translatedSym;
rfield@1380	1759
rfield@1380	1760	List<JCVariableDecl> syntheticParams;
rfield@1380	1761
rfield@2381	1762	/**
rfield@2381	1763	* to prevent recursion, track local classes processed
rfield@2381	1764	*/
rfield@2381	1765	final Set<Symbol> freeVarProcessedLocalClasses;
rfield@2381	1766
rfield@2607	1767	/**
rfield@2607	1768	* For method references converted to lambdas. The method
rfield@2607	1769	* reference receiver expression. Must be treated like a captured
rfield@2607	1770	* variable.
rfield@2607	1771	*/
rfield@2607	1772	JCExpression methodReferenceReceiver;
rfield@2607	1773
rfield@1380	1774	LambdaTranslationContext(JCLambda tree) {
rfield@1380	1775	super(tree);
rfield@1380	1776	Frame frame = frameStack.head;
rfield@2158	1777	switch (frame.tree.getTag()) {
rfield@2158	1778	case VARDEF:
rfield@2158	1779	assignedTo = self = ((JCVariableDecl) frame.tree).sym;
rfield@2158	1780	break;
rfield@2158	1781	case ASSIGN:
rfield@2158	1782	self = null;
rfield@2158	1783	assignedTo = TreeInfo.symbol(((JCAssign) frame.tree).getVariable());
rfield@2158	1784	break;
rfield@2158	1785	default:
rfield@2158	1786	assignedTo = self = null;
rfield@2158	1787	break;
rfield@2158	1788	}
rfield@2158	1789
rfield@2158	1790	// This symbol will be filled-in in complete
rfield@2158	1791	this.translatedSym = makePrivateSyntheticMethod(0, null, null, owner.enclClass());
rfield@2158	1792
ksrini@2155	1793	translatedSymbols = new EnumMap<>(LambdaSymbolKind.class);
ksrini@2155	1794
ksrini@2155	1795	translatedSymbols.put(PARAM, new LinkedHashMap<Symbol, Symbol>());
ksrini@2155	1796	translatedSymbols.put(LOCAL_VAR, new LinkedHashMap<Symbol, Symbol>());
ksrini@2155	1797	translatedSymbols.put(CAPTURED_VAR, new LinkedHashMap<Symbol, Symbol>());
ksrini@2155	1798	translatedSymbols.put(CAPTURED_THIS, new LinkedHashMap<Symbol, Symbol>());
ksrini@2155	1799	translatedSymbols.put(TYPE_VAR, new LinkedHashMap<Symbol, Symbol>());
rfield@2381	1800
rfield@2381	1801	freeVarProcessedLocalClasses = new HashSet<>();
rfield@1380	1802	}
rfield@1380	1803
rfield@2158	1804	/**
rfield@2158	1805	* For a serializable lambda, generate a disambiguating string
rfield@2158	1806	* which maximizes stability across deserialization.
rfield@2158	1807	*
rfield@2158	1808	* @return String to differentiate synthetic lambda method names
rfield@2158	1809	*/
rfield@2158	1810	private String serializedLambdaDisambiguation() {
rfield@2158	1811	StringBuilder buf = new StringBuilder();
rfield@2158	1812	// Append the enclosing method signature to differentiate
rfield@2158	1813	// overloaded enclosing methods. For lambdas enclosed in
rfield@2158	1814	// lambdas, the generated lambda method will not have type yet,
rfield@2158	1815	// but the enclosing method's name will have been generated
rfield@2158	1816	// with this same method, so it will be unique and never be
rfield@2158	1817	// overloaded.
rfield@2158	1818	Assert.check(
rfield@2158	1819	owner.type != null ||
rfield@2158	1820	directlyEnclosingLambda() != null);
rfield@2158	1821	if (owner.type != null) {
rfield@2158	1822	buf.append(typeSig(owner.type));
rfield@2158	1823	buf.append(":");
rfield@2158	1824	}
rfield@2158	1825
rfield@2158	1826	// Add target type info
rfield@2158	1827	buf.append(types.findDescriptorSymbol(tree.type.tsym).owner.flatName());
rfield@2158	1828	buf.append(" ");
rfield@2158	1829
rfield@2158	1830	// Add variable assigned to
rfield@2158	1831	if (assignedTo != null) {
rfield@2158	1832	buf.append(assignedTo.flatName());
rfield@2158	1833	buf.append("=");
rfield@2158	1834	}
rfield@2158	1835	//add captured locals info: type, name, order
rfield@2158	1836	for (Symbol fv : getSymbolMap(CAPTURED_VAR).keySet()) {
rfield@2158	1837	if (fv != self) {
rfield@2158	1838	buf.append(typeSig(fv.type));
rfield@2158	1839	buf.append(" ");
rfield@2158	1840	buf.append(fv.flatName());
rfield@2158	1841	buf.append(",");
rfield@2158	1842	}
rfield@2158	1843	}
rfield@2158	1844
rfield@2158	1845	return buf.toString();
rfield@2158	1846	}
rfield@2158	1847
rfield@2158	1848	/**
rfield@2158	1849	* For a non-serializable lambda, generate a simple method.
rfield@2158	1850	*
rfield@2158	1851	* @return Name to use for the synthetic lambda method name
rfield@2158	1852	*/
rfield@2158	1853	private Name lambdaName() {
rfield@2158	1854	return names.lambda.append(names.fromString(enclosingMethodName() + "$" + lambdaCount++));
rfield@2158	1855	}
rfield@2158	1856
rfield@2158	1857	/**
rfield@2158	1858	* For a serializable lambda, generate a method name which maximizes
rfield@2158	1859	* name stability across deserialization.
rfield@2158	1860	*
rfield@2158	1861	* @return Name to use for the synthetic lambda method name
rfield@2158	1862	*/
rfield@2158	1863	private Name serializedLambdaName() {
rfield@2158	1864	StringBuilder buf = new StringBuilder();
rfield@2158	1865	buf.append(names.lambda);
rfield@2158	1866	// Append the name of the method enclosing the lambda.
rfield@2158	1867	buf.append(enclosingMethodName());
rfield@2158	1868	buf.append('$');
rfield@2158	1869	// Append a hash of the disambiguating string : enclosing method
rfield@2158	1870	// signature, etc.
rfield@2158	1871	String disam = serializedLambdaDisambiguation();
rfield@2158	1872	buf.append(Integer.toHexString(disam.hashCode()));
rfield@2158	1873	buf.append('$');
rfield@2158	1874	// The above appended name components may not be unique, append
rfield@2158	1875	// a count based on the above name components.
rfield@2158	1876	buf.append(syntheticMethodNameCounts.getIndex(buf));
rfield@2158	1877	String result = buf.toString();
rfield@2158	1878	//System.err.printf("serializedLambdaName: %s -- %s\n", result, disam);
rfield@2158	1879	return names.fromString(result);
rfield@2158	1880	}
rfield@2158	1881
rfield@1380	1882	/**
rfield@1380	1883	* Translate a symbol of a given kind into something suitable for the
rfield@1380	1884	* synthetic lambda body
rfield@1380	1885	*/
jlahoda@2734	1886	Symbol translate(final Symbol sym, LambdaSymbolKind skind) {
jjg@1755	1887	Symbol ret;
rfield@1587	1888	switch (skind) {
rfield@1587	1889	case CAPTURED_THIS:
jjg@1755	1890	ret = sym; // self represented
jjg@1755	1891	break;
rfield@1587	1892	case TYPE_VAR:
rfield@1587	1893	// Just erase the type var
jlahoda@2734	1894	ret = new VarSymbol(sym.flags(), sym.name,
mcimadamore@1595	1895	types.erasure(sym.type), sym.owner);
vromero@2027	1896
vromero@2027	1897	/* this information should also be kept for LVT generation at Gen
vromero@2027	1898	* a Symbol with pos < startPos won't be tracked.
vromero@2027	1899	*/
vromero@2027	1900	((VarSymbol)ret).pos = ((VarSymbol)sym).pos;
jjg@1755	1901	break;
mcimadamore@1612	1902	case CAPTURED_VAR:
jlahoda@2734	1903	ret = new VarSymbol(SYNTHETIC | FINAL | PARAMETER, sym.name, types.erasure(sym.type), translatedSym) {
mcimadamore@1612	1904	@Override
mcimadamore@1612	1905	public Symbol baseSymbol() {
mcimadamore@1612	1906	//keep mapping with original captured symbol
mcimadamore@1612	1907	return sym;
mcimadamore@1612	1908	}
mcimadamore@1612	1909	};
jjg@1755	1910	break;
jjg@2146	1911	case LOCAL_VAR:
jlahoda@2734	1912	ret = new VarSymbol(sym.flags() & FINAL, sym.name, sym.type, translatedSym);
jjg@2146	1913	((VarSymbol) ret).pos = ((VarSymbol) sym).pos;
jjg@2146	1914	break;
jjg@2146	1915	case PARAM:
jlahoda@2734	1916	ret = new VarSymbol((sym.flags() & FINAL) | PARAMETER, sym.name, types.erasure(sym.type), translatedSym);
jjg@2146	1917	((VarSymbol) ret).pos = ((VarSymbol) sym).pos;
jjg@2146	1918	break;
rfield@1587	1919	default:
jlahoda@2734	1920	Assert.error(skind.name());
jlahoda@2734	1921	throw new AssertionError();
rfield@1380	1922	}
jjg@1755	1923	if (ret != sym) {
jjg@1802	1924	ret.setDeclarationAttributes(sym.getRawAttributes());
jjg@1802	1925	ret.setTypeAttributes(sym.getRawTypeAttributes());
jjg@1755	1926	}
jjg@1755	1927	return ret;
rfield@1380	1928	}
rfield@1380	1929
rfield@1380	1930	void addSymbol(Symbol sym, LambdaSymbolKind skind) {
ksrini@2155	1931	Map<Symbol, Symbol> transMap = getSymbolMap(skind);
rfield@1380	1932	if (!transMap.containsKey(sym)) {
jlahoda@2734	1933	transMap.put(sym, translate(sym, skind));
rfield@1380	1934	}
rfield@1380	1935	}
rfield@1380	1936
ksrini@2155	1937	Map<Symbol, Symbol> getSymbolMap(LambdaSymbolKind skind) {
ksrini@2155	1938	Map<Symbol, Symbol> m = translatedSymbols.get(skind);
ksrini@2155	1939	Assert.checkNonNull(m);
ksrini@2155	1940	return m;
ksrini@2155	1941	}
ksrini@2155	1942
ksrini@2155	1943	JCTree translate(JCIdent lambdaIdent) {
ksrini@2155	1944	for (Map<Symbol, Symbol> m : translatedSymbols.values()) {
ksrini@2155	1945	if (m.containsKey(lambdaIdent.sym)) {
ksrini@2155	1946	Symbol tSym = m.get(lambdaIdent.sym);
ksrini@2155	1947	JCTree t = make.Ident(tSym).setType(lambdaIdent.type);
ksrini@2155	1948	tSym.setTypeAttributes(lambdaIdent.sym.getRawTypeAttributes());
ksrini@2155	1949	return t;
rfield@1380	1950	}
rfield@1380	1951	}
ksrini@2155	1952	return null;
rfield@1380	1953	}
rfield@1380	1954
rfield@1380	1955	/**
rfield@1380	1956	* The translatedSym is not complete/accurate until the analysis is
rfield@1380	1957	* finished. Once the analysis is finished, the translatedSym is
rfield@1380	1958	* "completed" -- updated with type information, access modifiers,
rfield@1380	1959	* and full parameter list.
rfield@1380	1960	*/
rfield@1380	1961	void complete() {
rfield@1380	1962	if (syntheticParams != null) {
rfield@1380	1963	return;
rfield@1380	1964	}
rfield@1380	1965	boolean inInterface = translatedSym.owner.isInterface();
rfield@1380	1966	boolean thisReferenced = !getSymbolMap(CAPTURED_THIS).isEmpty();
rfield@1380	1967
rfield@1752	1968	// If instance access isn't needed, make it static.
rfield@1752	1969	// Interface instance methods must be default methods.
rfield@2107	1970	// Lambda methods are private synthetic.
rfield@2528	1971	// Inherit ACC_STRICT from the enclosing method, or, for clinit,
rfield@2528	1972	// from the class.
jjg@2146	1973	translatedSym.flags_field = SYNTHETIC | LAMBDA_METHOD |
rfield@2528	1974	owner.flags_field & STRICTFP |
rfield@2528	1975	owner.owner.flags_field & STRICTFP |
rfield@2107	1976	PRIVATE |
rfield@1752	1977	(thisReferenced? (inInterface? DEFAULT : 0) : STATIC);
rfield@1380	1978
rfield@1380	1979	//compute synthetic params
alundblad@2047	1980	ListBuffer<JCVariableDecl> params = new ListBuffer<>();
jlahoda@2733	1981	ListBuffer<VarSymbol> parameterSymbols = new ListBuffer<>();
rfield@1380	1982
rfield@1380	1983	// The signature of the method is augmented with the following
rfield@1380	1984	// synthetic parameters:
rfield@1380	1985	//
rfield@1380	1986	// 1) reference to enclosing contexts captured by the lambda expression
rfield@1380	1987	// 2) enclosing locals captured by the lambda expression
ksrini@2155	1988	for (Symbol thisSym : getSymbolMap(CAPTURED_VAR).values()) {
rfield@1380	1989	params.append(make.VarDef((VarSymbol) thisSym, null));
jlahoda@2733	1990	parameterSymbols.append((VarSymbol) thisSym);
rfield@2607	1991	}
ksrini@2155	1992	for (Symbol thisSym : getSymbolMap(PARAM).values()) {
ksrini@2155	1993	params.append(make.VarDef((VarSymbol) thisSym, null));
jlahoda@2733	1994	parameterSymbols.append((VarSymbol) thisSym);
ksrini@2155	1995	}
rfield@1380	1996	syntheticParams = params.toList();
rfield@1380	1997
jlahoda@2733	1998	translatedSym.params = parameterSymbols.toList();
jlahoda@2733	1999
rfield@2158	2000	// Compute and set the lambda name
rfield@2158	2001	translatedSym.name = isSerializable()
rfield@2158	2002	? serializedLambdaName()
rfield@2158	2003	: lambdaName();
rfield@2158	2004
rfield@1380	2005	//prepend synthetic args to translated lambda method signature
rfield@1587	2006	translatedSym.type = types.createMethodTypeWithParameters(
rfield@1587	2007	generatedLambdaSig(),
rfield@1380	2008	TreeInfo.types(syntheticParams));
rfield@1380	2009	}
rfield@1380	2010
rfield@1380	2011	Type generatedLambdaSig() {
mcimadamore@1882	2012	return types.erasure(tree.getDescriptorType(types));
rfield@1380	2013	}
rfield@1380	2014	}
rfield@1380	2015
rfield@1380	2016	/**
rfield@1380	2017	* This class retains all the useful information about a method reference;
rfield@1380	2018	* the contents of this class are filled by the LambdaAnalyzer visitor,
rfield@1380	2019	* and the used by the main translation routines in order to adjust method
rfield@1380	2020	* references (i.e. in case a bridge is needed)
rfield@1380	2021	*/
rfield@2607	2022	private final class ReferenceTranslationContext extends TranslationContext<JCMemberReference> {
rfield@1380	2023
rfield@1380	2024	final boolean isSuper;
rfield@2202	2025	final Symbol sigPolySym;
rfield@1380	2026
rfield@1380	2027	ReferenceTranslationContext(JCMemberReference tree) {
rfield@1380	2028	super(tree);
rfield@1380	2029	this.isSuper = tree.hasKind(ReferenceKind.SUPER);
rfield@2202	2030	this.sigPolySym = isSignaturePolymorphic()
rfield@2202	2031	? makePrivateSyntheticMethod(tree.sym.flags(),
rfield@2202	2032	tree.sym.name,
rfield@2202	2033	bridgedRefSig(),
rfield@2202	2034	tree.sym.enclClass())
rfield@2202	2035	: null;
rfield@1380	2036	}
rfield@1380	2037
rfield@1380	2038	/**
rfield@1380	2039	* Get the opcode associated with this method reference
rfield@1380	2040	*/
rfield@1380	2041	int referenceKind() {
rfield@2607	2042	return LambdaToMethod.this.referenceKind(tree.sym);
rfield@1380	2043	}
rfield@1380	2044
rfield@1380	2045	boolean needsVarArgsConversion() {
rfield@1380	2046	return tree.varargsElement != null;
rfield@1380	2047	}
rfield@1380	2048
rfield@1380	2049	/**
rfield@1380	2050	* @return Is this an array operation like clone()
rfield@1380	2051	*/
rfield@1380	2052	boolean isArrayOp() {
rfield@1380	2053	return tree.sym.owner == syms.arrayClass;
rfield@1380	2054	}
rfield@1380	2055
mcimadamore@1615	2056	boolean receiverAccessible() {
mcimadamore@1615	2057	//hack needed to workaround 292 bug (7087658)
mcimadamore@1615	2058	//when 292 issue is fixed we should remove this and change the backend
mcimadamore@1615	2059	//code to always generate a method handle to an accessible method
mcimadamore@1615	2060	return tree.ownerAccessible;
mcimadamore@1615	2061	}
mcimadamore@1615	2062
rfield@1380	2063	/**
rfield@2162	2064	* The VM does not support access across nested classes (8010319).
rfield@2162	2065	* Were that ever to change, this should be removed.
rfield@2162	2066	*/
rfield@2162	2067	boolean isPrivateInOtherClass() {
rfield@2162	2068	return (tree.sym.flags() & PRIVATE) != 0 &&
rfield@2162	2069	!types.isSameType(
rfield@2162	2070	types.erasure(tree.sym.enclClass().asType()),
rfield@2162	2071	types.erasure(owner.enclClass().asType()));
rfield@2162	2072	}
rfield@2162	2073
rfield@2162	2074	/**
rfield@2202	2075	* Signature polymorphic methods need special handling.
rfield@2202	2076	* e.g. MethodHandle.invoke() MethodHandle.invokeExact()
rfield@2202	2077	*/
rfield@2202	2078	final boolean isSignaturePolymorphic() {
rfield@2202	2079	return tree.sym.kind == MTH &&
rfield@2202	2080	types.isSignaturePolymorphic((MethodSymbol)tree.sym);
rfield@2202	2081	}
rfield@2202	2082
rfield@2202	2083	/**
rfield@2614	2084	* Erasure destroys the implementation parameter subtype
rfield@2614	2085	* relationship for intersection types
rfield@2614	2086	*/
rfield@2614	2087	boolean interfaceParameterIsIntersectionType() {
rfield@2614	2088	List<Type> tl = tree.getDescriptorType(types).getParameterTypes();
rfield@2614	2089	if (tree.kind == ReferenceKind.UNBOUND) {
rfield@2614	2090	tl = tl.tail;
rfield@2614	2091	}
rfield@2614	2092	for (; tl.nonEmpty(); tl = tl.tail) {
rfield@2614	2093	Type pt = tl.head;
rfield@2614	2094	if (pt.getKind() == TypeKind.TYPEVAR) {
rfield@2614	2095	TypeVar tv = (TypeVar) pt;
rfield@2614	2096	if (tv.bound.getKind() == TypeKind.INTERSECTION) {
rfield@2614	2097	return true;
rfield@2614	2098	}
rfield@2614	2099	}
rfield@2614	2100	}
rfield@2614	2101	return false;
rfield@2614	2102	}
rfield@2614	2103
rfield@2614	2104	/**
rfield@2607	2105	* Does this reference need to be converted to a lambda
rfield@2607	2106	* (i.e. var args need to be expanded or "super" is used)
rfield@1380	2107	*/
rfield@2607	2108	final boolean needsConversionToLambda() {
rfield@2614	2109	return interfaceParameterIsIntersectionType() ||
rfield@2614	2110	isSuper ||
rfield@2614	2111	needsVarArgsConversion() ||
rfield@2614	2112	isArrayOp() ||
rfield@2162	2113	isPrivateInOtherClass() ||
rfield@2607	2114	!receiverAccessible() ||
rfield@2607	2115	(tree.getMode() == ReferenceMode.NEW &&
rfield@2607	2116	tree.kind != ReferenceKind.ARRAY_CTOR &&
rfield@2607	2117	(tree.sym.owner.isLocal() || tree.sym.owner.isInner()));
rfield@1380	2118	}
rfield@1380	2119
rfield@1380	2120	Type generatedRefSig() {
rfield@1380	2121	return types.erasure(tree.sym.type);
rfield@1380	2122	}
rfield@1380	2123
rfield@1380	2124	Type bridgedRefSig() {
mcimadamore@1882	2125	return types.erasure(types.findDescriptorSymbol(tree.targets.head.tsym).type);
rfield@1380	2126	}
rfield@1380	2127	}
rfield@1380	2128	}
rfield@1380	2129	// </editor-fold>
rfield@1380	2130
ksrini@2155	2131	/*
ksrini@2155	2132	* These keys provide mappings for various translated lambda symbols
ksrini@2155	2133	* and the prevailing order must be maintained.
ksrini@2155	2134	*/
rfield@1380	2135	enum LambdaSymbolKind {
ksrini@2155	2136	PARAM, // original to translated lambda parameters
ksrini@2155	2137	LOCAL_VAR, // original to translated lambda locals
ksrini@2155	2138	CAPTURED_VAR, // variables in enclosing scope to translated synthetic parameters
ksrini@2155	2139	CAPTURED_THIS, // class symbols to translated synthetic parameters (for captured member access)
ksrini@2155	2140	TYPE_VAR; // original to translated lambda type variables
rfield@1587	2141	}
rfield@1587	2142
rfield@1587	2143	/**
rfield@1587	2144	* ****************************************************************
rfield@1587	2145	* Signature Generation
rfield@1587	2146	* ****************************************************************
rfield@1587	2147	*/
rfield@1587	2148
rfield@2158	2149	private String typeSig(Type type) {
rfield@1587	2150	L2MSignatureGenerator sg = new L2MSignatureGenerator();
rfield@1587	2151	sg.assembleSig(type);
rfield@1587	2152	return sg.toString();
rfield@1587	2153	}
rfield@1587	2154
rfield@1587	2155	private String classSig(Type type) {
rfield@1587	2156	L2MSignatureGenerator sg = new L2MSignatureGenerator();
rfield@1587	2157	sg.assembleClassSig(type);
rfield@1587	2158	return sg.toString();
rfield@1587	2159	}
rfield@1587	2160
rfield@1587	2161	/**
rfield@1587	2162	* Signature Generation
rfield@1587	2163	*/
rfield@1587	2164	private class L2MSignatureGenerator extends Types.SignatureGenerator {
rfield@1587	2165
rfield@1587	2166	/**
rfield@1587	2167	* An output buffer for type signatures.
rfield@1587	2168	*/
rfield@1587	2169	StringBuilder sb = new StringBuilder();
rfield@1587	2170
rfield@1587	2171	L2MSignatureGenerator() {
rfield@1587	2172	super(types);
rfield@1587	2173	}
rfield@1587	2174
rfield@1587	2175	@Override
rfield@1587	2176	protected void append(char ch) {
rfield@1587	2177	sb.append(ch);
rfield@1587	2178	}
rfield@1587	2179
rfield@1587	2180	@Override
rfield@1587	2181	protected void append(byte[] ba) {
rfield@1587	2182	sb.append(new String(ba));
rfield@1587	2183	}
rfield@1587	2184
rfield@1587	2185	@Override
rfield@1587	2186	protected void append(Name name) {
rfield@1587	2187	sb.append(name.toString());
rfield@1587	2188	}
rfield@1587	2189
rfield@1587	2190	@Override
rfield@1587	2191	public String toString() {
rfield@1587	2192	return sb.toString();
rfield@1587	2193	}
rfield@1380	2194	}
rfield@1380	2195	}