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src/share/classes/com/sun/tools/javac/comp/LambdaToMethod.java@25aaff78d754 (annotated)

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

Thu, 22 Aug 2013 13:12:43 +0100

author
vromero
date
Thu, 22 Aug 2013 13:12:43 +0100
changeset 1974
25aaff78d754
parent 1969
7de231613e4a
child 2027
4932bb04c4b8
permissions
-rw-r--r--

8023112: javac should not use lazy constant evaluation approach for method references
Reviewed-by: jjg, mcimadamore

rfield@1380 1 /*
mcimadamore@1595 2 * Copyright (c) 2010, 2013, 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@1380 39 import com.sun.tools.javac.code.Symbol.VarSymbol;
rfield@1380 40 import com.sun.tools.javac.code.Symtab;
rfield@1380 41 import com.sun.tools.javac.code.Type;
rfield@1380 42 import com.sun.tools.javac.code.Type.MethodType;
rfield@1380 43 import com.sun.tools.javac.code.Types;
rfield@1717 44 import com.sun.tools.javac.comp.LambdaToMethod.LambdaAnalyzerPreprocessor.*;
mcimadamore@1612 45 import com.sun.tools.javac.comp.Lower.BasicFreeVarCollector;
rfield@1380 46 import com.sun.tools.javac.jvm.*;
rfield@1380 47 import com.sun.tools.javac.util.*;
rfield@1380 48 import com.sun.tools.javac.util.JCDiagnostic.DiagnosticPosition;
rfield@1380 49 import com.sun.source.tree.MemberReferenceTree.ReferenceMode;
rfield@1380 50
rfield@1380 51 import java.util.HashMap;
rfield@1380 52 import java.util.LinkedHashMap;
rfield@1380 53 import java.util.Map;
rfield@1380 54
rfield@1380 55 import static com.sun.tools.javac.comp.LambdaToMethod.LambdaSymbolKind.*;
rfield@1380 56 import static com.sun.tools.javac.code.Flags.*;
rfield@1380 57 import static com.sun.tools.javac.code.Kinds.*;
rfield@1587 58 import static com.sun.tools.javac.code.TypeTag.*;
rfield@1380 59 import static com.sun.tools.javac.tree.JCTree.Tag.*;
rfield@1380 60
rfield@1380 61 /**
rfield@1380 62 * This pass desugars lambda expressions into static methods
rfield@1380 63 *
rfield@1380 64 * <p><b>This is NOT part of any supported API.
rfield@1380 65 * If you write code that depends on this, you do so at your own risk.
rfield@1380 66 * This code and its internal interfaces are subject to change or
rfield@1380 67 * deletion without notice.</b>
rfield@1380 68 */
rfield@1380 69 public class LambdaToMethod extends TreeTranslator {
rfield@1380 70
mcimadamore@1817 71 private JCDiagnostic.Factory diags;
mcimadamore@1817 72 private Log log;
mcimadamore@1612 73 private Lower lower;
rfield@1380 74 private Names names;
rfield@1380 75 private Symtab syms;
rfield@1380 76 private Resolve rs;
rfield@1380 77 private TreeMaker make;
rfield@1380 78 private Types types;
rfield@1380 79 private TransTypes transTypes;
rfield@1380 80 private Env<AttrContext> attrEnv;
rfield@1380 81
rfield@1380 82 /** the analyzer scanner */
rfield@1717 83 private LambdaAnalyzerPreprocessor analyzer;
rfield@1380 84
rfield@1380 85 /** map from lambda trees to translation contexts */
rfield@1380 86 private Map<JCTree, TranslationContext<?>> contextMap;
rfield@1380 87
rfield@1380 88 /** current translation context (visitor argument) */
rfield@1380 89 private TranslationContext<?> context;
rfield@1380 90
rfield@1587 91 /** info about the current class being processed */
rfield@1587 92 private KlassInfo kInfo;
rfield@1587 93
mcimadamore@1817 94 /** dump statistics about lambda code generation */
mcimadamore@1817 95 private boolean dumpLambdaToMethodStats;
mcimadamore@1817 96
rfield@1587 97 /** Flag for alternate metafactories indicating the lambda object is intended to be serializable */
rfield@1587 98 public static final int FLAG_SERIALIZABLE = 1 << 0;
rfield@1587 99
rfield@1587 100 /** Flag for alternate metafactories indicating the lambda object has multiple targets */
rfield@1587 101 public static final int FLAG_MARKERS = 1 << 1;
rfield@1587 102
mcimadamore@1882 103 /** Flag for alternate metafactories indicating the lambda object requires multiple bridges */
mcimadamore@1882 104 public static final int FLAG_BRIDGES = 1 << 2;
mcimadamore@1882 105
rfield@1587 106 private class KlassInfo {
rfield@1587 107
rfield@1587 108 /**
rfield@1587 109 * list of methods to append
rfield@1587 110 */
rfield@1587 111 private ListBuffer<JCTree> appendedMethodList;
rfield@1587 112
rfield@1587 113 /**
rfield@1587 114 * list of deserialization cases
rfield@1587 115 */
rfield@1587 116 private final Map<String, ListBuffer<JCStatement>> deserializeCases;
rfield@1587 117
rfield@1587 118 /**
rfield@1587 119 * deserialize method symbol
rfield@1587 120 */
rfield@1587 121 private final MethodSymbol deserMethodSym;
rfield@1587 122
rfield@1587 123 /**
rfield@1587 124 * deserialize method parameter symbol
rfield@1587 125 */
rfield@1587 126 private final VarSymbol deserParamSym;
rfield@1587 127
rfield@1587 128 private KlassInfo(Symbol kSym) {
rfield@1587 129 appendedMethodList = ListBuffer.lb();
rfield@1587 130 deserializeCases = new HashMap<String, ListBuffer<JCStatement>>();
rfield@1587 131 long flags = PRIVATE | STATIC | SYNTHETIC;
rfield@1587 132 MethodType type = new MethodType(List.of(syms.serializedLambdaType), syms.objectType,
rfield@1587 133 List.<Type>nil(), syms.methodClass);
rfield@1587 134 deserMethodSym = makeSyntheticMethod(flags, names.deserializeLambda, type, kSym);
mcimadamore@1595 135 deserParamSym = new VarSymbol(FINAL, names.fromString("lambda"),
mcimadamore@1595 136 syms.serializedLambdaType, deserMethodSym);
rfield@1587 137 }
rfield@1587 138
rfield@1587 139 private void addMethod(JCTree decl) {
rfield@1587 140 appendedMethodList = appendedMethodList.prepend(decl);
rfield@1587 141 }
rfield@1587 142 }
rfield@1380 143
rfield@1380 144 // <editor-fold defaultstate="collapsed" desc="Instantiating">
rfield@1380 145 private static final Context.Key<LambdaToMethod> unlambdaKey =
rfield@1380 146 new Context.Key<LambdaToMethod>();
rfield@1380 147
rfield@1380 148 public static LambdaToMethod instance(Context context) {
rfield@1380 149 LambdaToMethod instance = context.get(unlambdaKey);
rfield@1380 150 if (instance == null) {
rfield@1380 151 instance = new LambdaToMethod(context);
rfield@1380 152 }
rfield@1380 153 return instance;
rfield@1380 154 }
rfield@1380 155
rfield@1380 156 private LambdaToMethod(Context context) {
mcimadamore@1817 157 diags = JCDiagnostic.Factory.instance(context);
mcimadamore@1817 158 log = Log.instance(context);
mcimadamore@1612 159 lower = Lower.instance(context);
rfield@1380 160 names = Names.instance(context);
rfield@1380 161 syms = Symtab.instance(context);
rfield@1380 162 rs = Resolve.instance(context);
rfield@1380 163 make = TreeMaker.instance(context);
rfield@1380 164 types = Types.instance(context);
rfield@1380 165 transTypes = TransTypes.instance(context);
rfield@1717 166 analyzer = new LambdaAnalyzerPreprocessor();
mcimadamore@1817 167 Options options = Options.instance(context);
mcimadamore@1817 168 dumpLambdaToMethodStats = options.isSet("dumpLambdaToMethodStats");
rfield@1380 169 }
rfield@1380 170 // </editor-fold>
rfield@1380 171
rfield@1380 172 // <editor-fold defaultstate="collapsed" desc="translate methods">
rfield@1380 173 @Override
rfield@1380 174 public <T extends JCTree> T translate(T tree) {
rfield@1380 175 TranslationContext<?> newContext = contextMap.get(tree);
rfield@1380 176 return translate(tree, newContext != null ? newContext : context);
rfield@1380 177 }
rfield@1380 178
rfield@1762 179 <T extends JCTree> T translate(T tree, TranslationContext<?> newContext) {
rfield@1380 180 TranslationContext<?> prevContext = context;
rfield@1380 181 try {
rfield@1380 182 context = newContext;
rfield@1380 183 return super.translate(tree);
rfield@1380 184 }
rfield@1380 185 finally {
rfield@1380 186 context = prevContext;
rfield@1380 187 }
rfield@1380 188 }
rfield@1380 189
rfield@1762 190 <T extends JCTree> List<T> translate(List<T> trees, TranslationContext<?> newContext) {
rfield@1380 191 ListBuffer<T> buf = ListBuffer.lb();
rfield@1380 192 for (T tree : trees) {
rfield@1380 193 buf.append(translate(tree, newContext));
rfield@1380 194 }
rfield@1380 195 return buf.toList();
rfield@1380 196 }
rfield@1380 197
rfield@1380 198 public JCTree translateTopLevelClass(Env<AttrContext> env, JCTree cdef, TreeMaker make) {
rfield@1380 199 this.make = make;
rfield@1380 200 this.attrEnv = env;
rfield@1380 201 this.context = null;
rfield@1380 202 this.contextMap = new HashMap<JCTree, TranslationContext<?>>();
rfield@1380 203 return translate(cdef);
rfield@1380 204 }
rfield@1380 205 // </editor-fold>
rfield@1380 206
rfield@1380 207 // <editor-fold defaultstate="collapsed" desc="visitor methods">
rfield@1380 208 /**
rfield@1380 209 * Visit a class.
rfield@1380 210 * Maintain the translatedMethodList across nested classes.
rfield@1380 211 * Append the translatedMethodList to the class after it is translated.
rfield@1380 212 * @param tree
rfield@1380 213 */
rfield@1380 214 @Override
rfield@1380 215 public void visitClassDef(JCClassDecl tree) {
rfield@1380 216 if (tree.sym.owner.kind == PCK) {
rfield@1380 217 //analyze class
rfield@1717 218 tree = analyzer.analyzeAndPreprocessClass(tree);
rfield@1380 219 }
rfield@1587 220 KlassInfo prevKlassInfo = kInfo;
rfield@1380 221 try {
rfield@1587 222 kInfo = new KlassInfo(tree.sym);
rfield@1380 223 super.visitClassDef(tree);
rfield@1587 224 if (!kInfo.deserializeCases.isEmpty()) {
rfield@1587 225 kInfo.addMethod(makeDeserializeMethod(tree.sym));
rfield@1587 226 }
rfield@1380 227 //add all translated instance methods here
rfield@1587 228 List<JCTree> newMethods = kInfo.appendedMethodList.toList();
rfield@1587 229 tree.defs = tree.defs.appendList(newMethods);
rfield@1587 230 for (JCTree lambda : newMethods) {
rfield@1380 231 tree.sym.members().enter(((JCMethodDecl)lambda).sym);
rfield@1380 232 }
rfield@1380 233 result = tree;
rfield@1380 234 } finally {
rfield@1587 235 kInfo = prevKlassInfo;
rfield@1380 236 }
rfield@1380 237 }
rfield@1380 238
rfield@1380 239 /**
rfield@1380 240 * Translate a lambda into a method to be inserted into the class.
rfield@1380 241 * Then replace the lambda site with an invokedynamic call of to lambda
rfield@1380 242 * meta-factory, which will use the lambda method.
rfield@1380 243 * @param tree
rfield@1380 244 */
rfield@1380 245 @Override
rfield@1380 246 public void visitLambda(JCLambda tree) {
rfield@1380 247 LambdaTranslationContext localContext = (LambdaTranslationContext)context;
rfield@1380 248 MethodSymbol sym = (MethodSymbol)localContext.translatedSym;
rfield@1380 249 MethodType lambdaType = (MethodType) sym.type;
rfield@1380 250
jjg@1755 251 {
jjg@1969 252 Symbol owner = localContext.owner;
jjg@1755 253 ListBuffer<Attribute.TypeCompound> ownerTypeAnnos = new ListBuffer<Attribute.TypeCompound>();
jjg@1755 254 ListBuffer<Attribute.TypeCompound> lambdaTypeAnnos = new ListBuffer<Attribute.TypeCompound>();
jjg@1755 255
jjg@1755 256 for (Attribute.TypeCompound tc : owner.getRawTypeAttributes()) {
jjg@1755 257 if (tc.position.onLambda == tree) {
jjg@1755 258 lambdaTypeAnnos.append(tc);
jjg@1755 259 } else {
jjg@1755 260 ownerTypeAnnos.append(tc);
jjg@1755 261 }
jjg@1755 262 }
jjg@1755 263 if (lambdaTypeAnnos.nonEmpty()) {
jjg@1802 264 owner.setTypeAttributes(ownerTypeAnnos.toList());
jjg@1802 265 sym.setTypeAttributes(lambdaTypeAnnos.toList());
jjg@1755 266 }
jjg@1755 267 }
jjg@1755 268
rfield@1380 269 //create the method declaration hoisting the lambda body
rfield@1380 270 JCMethodDecl lambdaDecl = make.MethodDef(make.Modifiers(sym.flags_field),
rfield@1380 271 sym.name,
rfield@1380 272 make.QualIdent(lambdaType.getReturnType().tsym),
rfield@1380 273 List.<JCTypeParameter>nil(),
rfield@1380 274 localContext.syntheticParams,
rfield@1380 275 lambdaType.getThrownTypes() == null ?
rfield@1380 276 List.<JCExpression>nil() :
rfield@1380 277 make.Types(lambdaType.getThrownTypes()),
rfield@1380 278 null,
rfield@1380 279 null);
rfield@1380 280 lambdaDecl.sym = sym;
rfield@1380 281 lambdaDecl.type = lambdaType;
rfield@1380 282
rfield@1380 283 //translate lambda body
rfield@1380 284 //As the lambda body is translated, all references to lambda locals,
rfield@1380 285 //captured variables, enclosing members are adjusted accordingly
rfield@1380 286 //to refer to the static method parameters (rather than i.e. acessing to
rfield@1380 287 //captured members directly).
rfield@1380 288 lambdaDecl.body = translate(makeLambdaBody(tree, lambdaDecl));
rfield@1380 289
rfield@1380 290 //Add the method to the list of methods to be added to this class.
rfield@1587 291 kInfo.addMethod(lambdaDecl);
rfield@1380 292
rfield@1380 293 //now that we have generated a method for the lambda expression,
rfield@1380 294 //we can translate the lambda into a method reference pointing to the newly
rfield@1380 295 //created method.
rfield@1380 296 //
rfield@1380 297 //Note that we need to adjust the method handle so that it will match the
rfield@1380 298 //signature of the SAM descriptor - this means that the method reference
rfield@1380 299 //should be added the following synthetic arguments:
rfield@1380 300 //
rfield@1380 301 // * the "this" argument if it is an instance method
rfield@1380 302 // * enclosing locals captured by the lambda expression
rfield@1380 303
rfield@1380 304 ListBuffer<JCExpression> syntheticInits = ListBuffer.lb();
rfield@1380 305
rfield@1380 306 if (!sym.isStatic()) {
rfield@1380 307 syntheticInits.append(makeThis(
rfield@1587 308 sym.owner.enclClass().asType(),
rfield@1380 309 localContext.owner.enclClass()));
rfield@1380 310 }
rfield@1380 311
rfield@1380 312 //add captured locals
rfield@1380 313 for (Symbol fv : localContext.getSymbolMap(CAPTURED_VAR).keySet()) {
rfield@1380 314 if (fv != localContext.self) {
rfield@1380 315 JCTree captured_local = make.Ident(fv).setType(fv.type);
rfield@1380 316 syntheticInits.append((JCExpression) captured_local);
rfield@1380 317 }
rfield@1380 318 }
rfield@1380 319
rfield@1380 320 //then, determine the arguments to the indy call
rfield@1380 321 List<JCExpression> indy_args = translate(syntheticInits.toList(), localContext.prev);
rfield@1380 322
rfield@1380 323 //build a sam instance using an indy call to the meta-factory
rfield@1380 324 int refKind = referenceKind(sym);
rfield@1380 325
rfield@1380 326 //convert to an invokedynamic call
mcimadamore@1882 327 result = makeMetafactoryIndyCall(context, refKind, sym, indy_args);
rfield@1380 328 }
rfield@1380 329
rfield@1380 330 private JCIdent makeThis(Type type, Symbol owner) {
rfield@1380 331 VarSymbol _this = new VarSymbol(PARAMETER | FINAL | SYNTHETIC,
rfield@1380 332 names._this,
rfield@1380 333 type,
rfield@1380 334 owner);
rfield@1380 335 return make.Ident(_this);
rfield@1380 336 }
rfield@1380 337
rfield@1380 338 /**
rfield@1380 339 * Translate a method reference into an invokedynamic call to the
rfield@1380 340 * meta-factory.
rfield@1380 341 * @param tree
rfield@1380 342 */
rfield@1380 343 @Override
rfield@1380 344 public void visitReference(JCMemberReference tree) {
rfield@1380 345 ReferenceTranslationContext localContext = (ReferenceTranslationContext)context;
rfield@1380 346
rfield@1380 347 //first determine the method symbol to be used to generate the sam instance
rfield@1380 348 //this is either the method reference symbol, or the bridged reference symbol
rfield@1380 349 Symbol refSym = localContext.needsBridge() ?
rfield@1380 350 localContext.bridgeSym :
rfield@1380 351 tree.sym;
rfield@1380 352
rfield@1380 353 //build the bridge method, if needed
rfield@1380 354 if (localContext.needsBridge()) {
rfield@1380 355 bridgeMemberReference(tree, localContext);
rfield@1380 356 }
rfield@1380 357
rfield@1380 358 //the qualifying expression is treated as a special captured arg
rfield@1380 359 JCExpression init;
rfield@1380 360 switch(tree.kind) {
rfield@1380 361
mcimadamore@1435 362 case IMPLICIT_INNER: /** Inner :: new */
mcimadamore@1435 363 case SUPER: /** super :: instMethod */
rfield@1380 364 init = makeThis(
rfield@1587 365 localContext.owner.enclClass().asType(),
rfield@1587 366 localContext.owner.enclClass());
rfield@1380 367 break;
rfield@1380 368
mcimadamore@1435 369 case BOUND: /** Expr :: instMethod */
rfield@1380 370 init = tree.getQualifierExpression();
rfield@1380 371 break;
rfield@1380 372
mcimadamore@1435 373 case UNBOUND: /** Type :: instMethod */
mcimadamore@1435 374 case STATIC: /** Type :: staticMethod */
mcimadamore@1435 375 case TOPLEVEL: /** Top level :: new */
mcimadamore@1496 376 case ARRAY_CTOR: /** ArrayType :: new */
rfield@1380 377 init = null;
rfield@1380 378 break;
rfield@1380 379
rfield@1380 380 default:
rfield@1380 381 throw new InternalError("Should not have an invalid kind");
rfield@1380 382 }
rfield@1380 383
rfield@1380 384 List<JCExpression> indy_args = init==null? List.<JCExpression>nil() : translate(List.of(init), localContext.prev);
rfield@1380 385
rfield@1380 386
rfield@1380 387 //build a sam instance using an indy call to the meta-factory
mcimadamore@1882 388 result = makeMetafactoryIndyCall(localContext, localContext.referenceKind(), refSym, indy_args);
rfield@1380 389 }
rfield@1380 390
rfield@1380 391 /**
rfield@1380 392 * Translate identifiers within a lambda to the mapped identifier
rfield@1380 393 * @param tree
rfield@1380 394 */
rfield@1380 395 @Override
rfield@1380 396 public void visitIdent(JCIdent tree) {
rfield@1380 397 if (context == null || !analyzer.lambdaIdentSymbolFilter(tree.sym)) {
rfield@1380 398 super.visitIdent(tree);
rfield@1380 399 } else {
rfield@1380 400 LambdaTranslationContext lambdaContext = (LambdaTranslationContext) context;
rfield@1380 401 if (lambdaContext.getSymbolMap(PARAM).containsKey(tree.sym)) {
rfield@1380 402 Symbol translatedSym = lambdaContext.getSymbolMap(PARAM).get(tree.sym);
rfield@1380 403 result = make.Ident(translatedSym).setType(tree.type);
jjg@1802 404 translatedSym.setTypeAttributes(tree.sym.getRawTypeAttributes());
rfield@1380 405 } else if (lambdaContext.getSymbolMap(LOCAL_VAR).containsKey(tree.sym)) {
rfield@1380 406 Symbol translatedSym = lambdaContext.getSymbolMap(LOCAL_VAR).get(tree.sym);
rfield@1380 407 result = make.Ident(translatedSym).setType(tree.type);
jjg@1802 408 translatedSym.setTypeAttributes(tree.sym.getRawTypeAttributes());
rfield@1587 409 } else if (lambdaContext.getSymbolMap(TYPE_VAR).containsKey(tree.sym)) {
rfield@1587 410 Symbol translatedSym = lambdaContext.getSymbolMap(TYPE_VAR).get(tree.sym);
rfield@1587 411 result = make.Ident(translatedSym).setType(translatedSym.type);
jjg@1802 412 translatedSym.setTypeAttributes(tree.sym.getRawTypeAttributes());
rfield@1380 413 } else if (lambdaContext.getSymbolMap(CAPTURED_VAR).containsKey(tree.sym)) {
rfield@1380 414 Symbol translatedSym = lambdaContext.getSymbolMap(CAPTURED_VAR).get(tree.sym);
rfield@1380 415 result = make.Ident(translatedSym).setType(tree.type);
rfield@1380 416 } else {
rfield@1380 417 //access to untranslated symbols (i.e. compile-time constants,
rfield@1380 418 //members defined inside the lambda body, etc.) )
rfield@1380 419 super.visitIdent(tree);
rfield@1380 420 }
rfield@1380 421 }
rfield@1380 422 }
rfield@1380 423
rfield@1380 424 @Override
rfield@1380 425 public void visitVarDef(JCVariableDecl tree) {
rfield@1380 426 LambdaTranslationContext lambdaContext = (LambdaTranslationContext)context;
rfield@1380 427 if (context != null && lambdaContext.getSymbolMap(LOCAL_VAR).containsKey(tree.sym)) {
rfield@1380 428 JCExpression init = translate(tree.init);
rfield@1380 429 result = make.VarDef((VarSymbol)lambdaContext.getSymbolMap(LOCAL_VAR).get(tree.sym), init);
rfield@1587 430 } else if (context != null && lambdaContext.getSymbolMap(TYPE_VAR).containsKey(tree.sym)) {
rfield@1587 431 JCExpression init = translate(tree.init);
rfield@1587 432 VarSymbol xsym = (VarSymbol)lambdaContext.getSymbolMap(TYPE_VAR).get(tree.sym);
rfield@1587 433 result = make.VarDef(xsym, init);
rfield@1587 434 // Replace the entered symbol for this variable
rfield@1587 435 Scope sc = tree.sym.owner.members();
rfield@1587 436 if (sc != null) {
rfield@1587 437 sc.remove(tree.sym);
rfield@1587 438 sc.enter(xsym);
rfield@1587 439 }
rfield@1380 440 } else {
rfield@1380 441 super.visitVarDef(tree);
rfield@1380 442 }
rfield@1380 443 }
rfield@1380 444
rfield@1380 445 // </editor-fold>
rfield@1380 446
rfield@1380 447 // <editor-fold defaultstate="collapsed" desc="Translation helper methods">
rfield@1380 448
rfield@1380 449 private JCBlock makeLambdaBody(JCLambda tree, JCMethodDecl lambdaMethodDecl) {
rfield@1380 450 return tree.getBodyKind() == JCLambda.BodyKind.EXPRESSION ?
rfield@1380 451 makeLambdaExpressionBody((JCExpression)tree.body, lambdaMethodDecl) :
rfield@1380 452 makeLambdaStatementBody((JCBlock)tree.body, lambdaMethodDecl, tree.canCompleteNormally);
rfield@1380 453 }
rfield@1380 454
rfield@1380 455 private JCBlock makeLambdaExpressionBody(JCExpression expr, JCMethodDecl lambdaMethodDecl) {
rfield@1380 456 Type restype = lambdaMethodDecl.type.getReturnType();
rfield@1380 457 boolean isLambda_void = expr.type.hasTag(VOID);
rfield@1380 458 boolean isTarget_void = restype.hasTag(VOID);
rfield@1380 459 boolean isTarget_Void = types.isSameType(restype, types.boxedClass(syms.voidType).type);
rfield@1380 460 if (isTarget_void) {
rfield@1380 461 //target is void:
rfield@1380 462 // BODY;
rfield@1380 463 JCStatement stat = make.Exec(expr);
rfield@1380 464 return make.Block(0, List.<JCStatement>of(stat));
rfield@1380 465 } else if (isLambda_void && isTarget_Void) {
rfield@1380 466 //void to Void conversion:
rfield@1380 467 // BODY; return null;
rfield@1380 468 ListBuffer<JCStatement> stats = ListBuffer.lb();
rfield@1380 469 stats.append(make.Exec(expr));
rfield@1380 470 stats.append(make.Return(make.Literal(BOT, null).setType(syms.botType)));
rfield@1380 471 return make.Block(0, stats.toList());
rfield@1380 472 } else {
rfield@1380 473 //non-void to non-void conversion:
rfield@1380 474 // return (TYPE)BODY;
rfield@1380 475 JCExpression retExpr = transTypes.coerce(attrEnv, expr, restype);
vromero@1940 476 return make.at(retExpr).Block(0, List.<JCStatement>of(make.Return(retExpr)));
rfield@1380 477 }
rfield@1380 478 }
rfield@1380 479
rfield@1380 480 private JCBlock makeLambdaStatementBody(JCBlock block, final JCMethodDecl lambdaMethodDecl, boolean completeNormally) {
rfield@1380 481 final Type restype = lambdaMethodDecl.type.getReturnType();
rfield@1380 482 final boolean isTarget_void = restype.hasTag(VOID);
rfield@1380 483 boolean isTarget_Void = types.isSameType(restype, types.boxedClass(syms.voidType).type);
rfield@1380 484
rfield@1380 485 class LambdaBodyTranslator extends TreeTranslator {
rfield@1380 486
rfield@1380 487 @Override
rfield@1380 488 public void visitClassDef(JCClassDecl tree) {
rfield@1380 489 //do NOT recurse on any inner classes
rfield@1380 490 result = tree;
rfield@1380 491 }
rfield@1380 492
rfield@1380 493 @Override
rfield@1380 494 public void visitLambda(JCLambda tree) {
rfield@1380 495 //do NOT recurse on any nested lambdas
rfield@1380 496 result = tree;
rfield@1380 497 }
rfield@1380 498
rfield@1380 499 @Override
rfield@1380 500 public void visitReturn(JCReturn tree) {
rfield@1380 501 boolean isLambda_void = tree.expr == null;
rfield@1380 502 if (isTarget_void && !isLambda_void) {
rfield@1380 503 //Void to void conversion:
rfield@1380 504 // { TYPE $loc = RET-EXPR; return; }
rfield@1380 505 VarSymbol loc = makeSyntheticVar(0, names.fromString("$loc"), tree.expr.type, lambdaMethodDecl.sym);
rfield@1380 506 JCVariableDecl varDef = make.VarDef(loc, tree.expr);
rfield@1380 507 result = make.Block(0, List.<JCStatement>of(varDef, make.Return(null)));
rfield@1380 508 } else if (!isTarget_void || !isLambda_void) {
rfield@1380 509 //non-void to non-void conversion:
rfield@1380 510 // return (TYPE)RET-EXPR;
rfield@1380 511 tree.expr = transTypes.coerce(attrEnv, tree.expr, restype);
rfield@1380 512 result = tree;
rfield@1380 513 } else {
rfield@1380 514 result = tree;
rfield@1380 515 }
rfield@1380 516
rfield@1380 517 }
rfield@1380 518 }
rfield@1380 519
rfield@1380 520 JCBlock trans_block = new LambdaBodyTranslator().translate(block);
rfield@1380 521 if (completeNormally && isTarget_Void) {
rfield@1380 522 //there's no return statement and the lambda (possibly inferred)
rfield@1380 523 //return type is java.lang.Void; emit a synthetic return statement
rfield@1380 524 trans_block.stats = trans_block.stats.append(make.Return(make.Literal(BOT, null).setType(syms.botType)));
rfield@1380 525 }
rfield@1380 526 return trans_block;
rfield@1380 527 }
rfield@1380 528
rfield@1587 529 private JCMethodDecl makeDeserializeMethod(Symbol kSym) {
rfield@1587 530 ListBuffer<JCCase> cases = ListBuffer.lb();
rfield@1587 531 ListBuffer<JCBreak> breaks = ListBuffer.lb();
rfield@1587 532 for (Map.Entry<String, ListBuffer<JCStatement>> entry : kInfo.deserializeCases.entrySet()) {
rfield@1587 533 JCBreak br = make.Break(null);
rfield@1587 534 breaks.add(br);
rfield@1587 535 List<JCStatement> stmts = entry.getValue().append(br).toList();
rfield@1587 536 cases.add(make.Case(make.Literal(entry.getKey()), stmts));
rfield@1587 537 }
rfield@1587 538 JCSwitch sw = make.Switch(deserGetter("getImplMethodName", syms.stringType), cases.toList());
rfield@1587 539 for (JCBreak br : breaks) {
rfield@1587 540 br.target = sw;
rfield@1587 541 }
rfield@1587 542 JCBlock body = make.Block(0L, List.<JCStatement>of(
rfield@1587 543 sw,
rfield@1587 544 make.Throw(makeNewClass(
rfield@1587 545 syms.illegalArgumentExceptionType,
rfield@1587 546 List.<JCExpression>of(make.Literal("Invalid lambda deserialization"))))));
rfield@1587 547 JCMethodDecl deser = make.MethodDef(make.Modifiers(kInfo.deserMethodSym.flags()),
rfield@1587 548 names.deserializeLambda,
rfield@1587 549 make.QualIdent(kInfo.deserMethodSym.getReturnType().tsym),
rfield@1587 550 List.<JCTypeParameter>nil(),
rfield@1587 551 List.of(make.VarDef(kInfo.deserParamSym, null)),
rfield@1587 552 List.<JCExpression>nil(),
rfield@1587 553 body,
rfield@1587 554 null);
rfield@1587 555 deser.sym = kInfo.deserMethodSym;
rfield@1587 556 deser.type = kInfo.deserMethodSym.type;
rfield@1587 557 //System.err.printf("DESER: '%s'\n", deser);
rfield@1587 558 return deser;
rfield@1587 559 }
rfield@1587 560
rfield@1587 561 /** Make an attributed class instance creation expression.
rfield@1587 562 * @param ctype The class type.
rfield@1587 563 * @param args The constructor arguments.
rfield@1717 564 * @param cons The constructor symbol
rfield@1587 565 */
rfield@1717 566 JCNewClass makeNewClass(Type ctype, List<JCExpression> args, Symbol cons) {
rfield@1587 567 JCNewClass tree = make.NewClass(null,
rfield@1587 568 null, make.QualIdent(ctype.tsym), args, null);
rfield@1717 569 tree.constructor = cons;
rfield@1587 570 tree.type = ctype;
rfield@1587 571 return tree;
rfield@1587 572 }
rfield@1587 573
rfield@1717 574 /** Make an attributed class instance creation expression.
rfield@1717 575 * @param ctype The class type.
rfield@1717 576 * @param args The constructor arguments.
rfield@1717 577 */
rfield@1717 578 JCNewClass makeNewClass(Type ctype, List<JCExpression> args) {
rfield@1717 579 return makeNewClass(ctype, args,
rfield@1717 580 rs.resolveConstructor(null, attrEnv, ctype, TreeInfo.types(args), List.<Type>nil()));
rfield@1717 581 }
rfield@1717 582
rfield@1587 583 private void addDeserializationCase(int implMethodKind, Symbol refSym, Type targetType, MethodSymbol samSym,
rfield@1587 584 DiagnosticPosition pos, List<Object> staticArgs, MethodType indyType) {
rfield@1587 585 String functionalInterfaceClass = classSig(targetType);
rfield@1587 586 String functionalInterfaceMethodName = samSym.getSimpleName().toString();
rfield@1587 587 String functionalInterfaceMethodSignature = methodSig(types.erasure(samSym.type));
rfield@1622 588 String implClass = classSig(types.erasure(refSym.owner.type));
rfield@1587 589 String implMethodName = refSym.getQualifiedName().toString();
rfield@1587 590 String implMethodSignature = methodSig(types.erasure(refSym.type));
rfield@1587 591
rfield@1587 592 JCExpression kindTest = eqTest(syms.intType, deserGetter("getImplMethodKind", syms.intType), make.Literal(implMethodKind));
rfield@1587 593 ListBuffer<JCExpression> serArgs = ListBuffer.lb();
rfield@1587 594 int i = 0;
rfield@1587 595 for (Type t : indyType.getParameterTypes()) {
rfield@1587 596 List<JCExpression> indexAsArg = ListBuffer.<JCExpression>lb().append(make.Literal(i)).toList();
rfield@1587 597 List<Type> argTypes = ListBuffer.<Type>lb().append(syms.intType).toList();
rfield@1587 598 serArgs.add(make.TypeCast(types.erasure(t), deserGetter("getCapturedArg", syms.objectType, argTypes, indexAsArg)));
rfield@1587 599 ++i;
rfield@1587 600 }
rfield@1587 601 JCStatement stmt = make.If(
rfield@1587 602 deserTest(deserTest(deserTest(deserTest(deserTest(
rfield@1587 603 kindTest,
rfield@1587 604 "getFunctionalInterfaceClass", functionalInterfaceClass),
rfield@1587 605 "getFunctionalInterfaceMethodName", functionalInterfaceMethodName),
rfield@1587 606 "getFunctionalInterfaceMethodSignature", functionalInterfaceMethodSignature),
rfield@1587 607 "getImplClass", implClass),
rfield@1587 608 "getImplMethodSignature", implMethodSignature),
rfield@1587 609 make.Return(makeIndyCall(
rfield@1587 610 pos,
rfield@1587 611 syms.lambdaMetafactory,
mcimadamore@1882 612 names.altMetafactory,
mcimadamore@1882 613 staticArgs, indyType, serArgs.toList(), samSym.name)),
rfield@1587 614 null);
rfield@1587 615 ListBuffer<JCStatement> stmts = kInfo.deserializeCases.get(implMethodName);
rfield@1587 616 if (stmts == null) {
rfield@1587 617 stmts = ListBuffer.lb();
rfield@1587 618 kInfo.deserializeCases.put(implMethodName, stmts);
rfield@1587 619 }
rfield@1587 620 /****
rfield@1587 621 System.err.printf("+++++++++++++++++\n");
rfield@1587 622 System.err.printf("*functionalInterfaceClass: '%s'\n", functionalInterfaceClass);
rfield@1587 623 System.err.printf("*functionalInterfaceMethodName: '%s'\n", functionalInterfaceMethodName);
rfield@1587 624 System.err.printf("*functionalInterfaceMethodSignature: '%s'\n", functionalInterfaceMethodSignature);
rfield@1587 625 System.err.printf("*implMethodKind: %d\n", implMethodKind);
rfield@1587 626 System.err.printf("*implClass: '%s'\n", implClass);
rfield@1587 627 System.err.printf("*implMethodName: '%s'\n", implMethodName);
rfield@1587 628 System.err.printf("*implMethodSignature: '%s'\n", implMethodSignature);
rfield@1587 629 ****/
rfield@1587 630 stmts.append(stmt);
rfield@1587 631 }
rfield@1587 632
rfield@1587 633 private JCExpression eqTest(Type argType, JCExpression arg1, JCExpression arg2) {
rfield@1587 634 JCBinary testExpr = make.Binary(JCTree.Tag.EQ, arg1, arg2);
rfield@1587 635 testExpr.operator = rs.resolveBinaryOperator(null, JCTree.Tag.EQ, attrEnv, argType, argType);
rfield@1587 636 testExpr.setType(syms.booleanType);
rfield@1587 637 return testExpr;
rfield@1587 638 }
rfield@1587 639
rfield@1587 640 private JCExpression deserTest(JCExpression prev, String func, String lit) {
rfield@1587 641 MethodType eqmt = new MethodType(List.of(syms.objectType), syms.booleanType, List.<Type>nil(), syms.methodClass);
rfield@1587 642 Symbol eqsym = rs.resolveQualifiedMethod(null, attrEnv, syms.objectType, names.equals, List.of(syms.objectType), List.<Type>nil());
rfield@1587 643 JCMethodInvocation eqtest = make.Apply(
rfield@1587 644 List.<JCExpression>nil(),
rfield@1587 645 make.Select(deserGetter(func, syms.stringType), eqsym).setType(eqmt),
rfield@1587 646 List.<JCExpression>of(make.Literal(lit)));
rfield@1587 647 eqtest.setType(syms.booleanType);
rfield@1587 648 JCBinary compound = make.Binary(JCTree.Tag.AND, prev, eqtest);
rfield@1587 649 compound.operator = rs.resolveBinaryOperator(null, JCTree.Tag.AND, attrEnv, syms.booleanType, syms.booleanType);
rfield@1587 650 compound.setType(syms.booleanType);
rfield@1587 651 return compound;
rfield@1587 652 }
rfield@1587 653
rfield@1587 654 private JCExpression deserGetter(String func, Type type) {
rfield@1587 655 return deserGetter(func, type, List.<Type>nil(), List.<JCExpression>nil());
rfield@1587 656 }
rfield@1587 657
rfield@1587 658 private JCExpression deserGetter(String func, Type type, List<Type> argTypes, List<JCExpression> args) {
rfield@1587 659 MethodType getmt = new MethodType(argTypes, type, List.<Type>nil(), syms.methodClass);
rfield@1587 660 Symbol getsym = rs.resolveQualifiedMethod(null, attrEnv, syms.serializedLambdaType, names.fromString(func), argTypes, List.<Type>nil());
rfield@1587 661 return make.Apply(
rfield@1587 662 List.<JCExpression>nil(),
rfield@1587 663 make.Select(make.Ident(kInfo.deserParamSym).setType(syms.serializedLambdaType), getsym).setType(getmt),
rfield@1587 664 args).setType(type);
rfield@1587 665 }
rfield@1587 666
rfield@1380 667 /**
rfield@1380 668 * Create new synthetic method with given flags, name, type, owner
rfield@1380 669 */
rfield@1380 670 private MethodSymbol makeSyntheticMethod(long flags, Name name, Type type, Symbol owner) {
rfield@1380 671 return new MethodSymbol(flags | SYNTHETIC, name, type, owner);
rfield@1380 672 }
rfield@1380 673
rfield@1380 674 /**
rfield@1380 675 * Create new synthetic variable with given flags, name, type, owner
rfield@1380 676 */
rfield@1380 677 private VarSymbol makeSyntheticVar(long flags, String name, Type type, Symbol owner) {
rfield@1380 678 return makeSyntheticVar(flags, names.fromString(name), type, owner);
rfield@1380 679 }
rfield@1380 680
rfield@1380 681 /**
rfield@1380 682 * Create new synthetic variable with given flags, name, type, owner
rfield@1380 683 */
rfield@1380 684 private VarSymbol makeSyntheticVar(long flags, Name name, Type type, Symbol owner) {
rfield@1380 685 return new VarSymbol(flags | SYNTHETIC, name, type, owner);
rfield@1380 686 }
rfield@1380 687
rfield@1380 688 /**
rfield@1380 689 * Set varargsElement field on a given tree (must be either a new class tree
rfield@1380 690 * or a method call tree)
rfield@1380 691 */
rfield@1380 692 private void setVarargsIfNeeded(JCTree tree, Type varargsElement) {
rfield@1380 693 if (varargsElement != null) {
rfield@1380 694 switch (tree.getTag()) {
rfield@1380 695 case APPLY: ((JCMethodInvocation)tree).varargsElement = varargsElement; break;
rfield@1380 696 case NEWCLASS: ((JCNewClass)tree).varargsElement = varargsElement; break;
rfield@1380 697 default: throw new AssertionError();
rfield@1380 698 }
rfield@1380 699 }
rfield@1380 700 }
rfield@1380 701
rfield@1380 702 /**
rfield@1380 703 * Convert method/constructor arguments by inserting appropriate cast
rfield@1380 704 * as required by type-erasure - this is needed when bridging a lambda/method
rfield@1380 705 * reference, as the bridged signature might require downcast to be compatible
rfield@1380 706 * with the generated signature.
rfield@1380 707 */
rfield@1380 708 private List<JCExpression> convertArgs(Symbol meth, List<JCExpression> args, Type varargsElement) {
rfield@1380 709 Assert.check(meth.kind == Kinds.MTH);
rfield@1380 710 List<Type> formals = types.erasure(meth.type).getParameterTypes();
rfield@1380 711 if (varargsElement != null) {
rfield@1380 712 Assert.check((meth.flags() & VARARGS) != 0);
rfield@1380 713 }
rfield@1380 714 return transTypes.translateArgs(args, formals, varargsElement, attrEnv);
rfield@1380 715 }
rfield@1380 716
rfield@1380 717 // </editor-fold>
rfield@1380 718
rfield@1380 719 /**
rfield@1380 720 * Generate an adapter method "bridge" for a method reference which cannot
rfield@1380 721 * be used directly.
rfield@1380 722 */
rfield@1380 723 private class MemberReferenceBridger {
rfield@1380 724
rfield@1380 725 private final JCMemberReference tree;
rfield@1380 726 private final ReferenceTranslationContext localContext;
rfield@1380 727 private final ListBuffer<JCExpression> args = ListBuffer.lb();
rfield@1380 728 private final ListBuffer<JCVariableDecl> params = ListBuffer.lb();
rfield@1380 729
rfield@1380 730 MemberReferenceBridger(JCMemberReference tree, ReferenceTranslationContext localContext) {
rfield@1380 731 this.tree = tree;
rfield@1380 732 this.localContext = localContext;
rfield@1380 733 }
rfield@1380 734
rfield@1380 735 /**
rfield@1380 736 * Generate the bridge
rfield@1380 737 */
rfield@1380 738 JCMethodDecl bridge() {
rfield@1380 739 int prevPos = make.pos;
rfield@1380 740 try {
rfield@1380 741 make.at(tree);
rfield@1380 742 Type samDesc = localContext.bridgedRefSig();
rfield@1380 743 List<Type> samPTypes = samDesc.getParameterTypes();
rfield@1380 744
rfield@1380 745 //an extra argument is prepended to the signature of the bridge in case
rfield@1380 746 //the member reference is an instance method reference (in which case
rfield@1380 747 //the receiver expression is passed to the bridge itself).
rfield@1380 748 Type recType = null;
rfield@1380 749 switch (tree.kind) {
rfield@1380 750 case IMPLICIT_INNER:
rfield@1380 751 recType = tree.sym.owner.type.getEnclosingType();
rfield@1380 752 break;
rfield@1380 753 case BOUND:
rfield@1380 754 recType = tree.getQualifierExpression().type;
rfield@1380 755 break;
rfield@1380 756 case UNBOUND:
rfield@1380 757 recType = samPTypes.head;
rfield@1380 758 samPTypes = samPTypes.tail;
rfield@1380 759 break;
rfield@1380 760 }
rfield@1380 761
rfield@1380 762 //generate the parameter list for the bridged member reference - the
rfield@1380 763 //bridge signature will match the signature of the target sam descriptor
rfield@1380 764
rfield@1380 765 VarSymbol rcvr = (recType == null)
rfield@1380 766 ? null
rfield@1380 767 : addParameter("rec$", recType, false);
rfield@1380 768
rfield@1380 769 List<Type> refPTypes = tree.sym.type.getParameterTypes();
rfield@1380 770 int refSize = refPTypes.size();
rfield@1380 771 int samSize = samPTypes.size();
mcimadamore@1595 772 // Last parameter to copy from referenced method
mcimadamore@1595 773 int last = localContext.needsVarArgsConversion() ? refSize - 1 : refSize;
rfield@1380 774
rfield@1380 775 List<Type> l = refPTypes;
rfield@1380 776 // Use parameter types of the referenced method, excluding final var args
rfield@1380 777 for (int i = 0; l.nonEmpty() && i < last; ++i) {
rfield@1380 778 addParameter("x$" + i, l.head, true);
rfield@1380 779 l = l.tail;
rfield@1380 780 }
rfield@1380 781 // Flatten out the var args
rfield@1380 782 for (int i = last; i < samSize; ++i) {
rfield@1380 783 addParameter("xva$" + i, tree.varargsElement, true);
rfield@1380 784 }
rfield@1380 785
rfield@1380 786 //generate the bridge method declaration
rfield@1380 787 JCMethodDecl bridgeDecl = make.MethodDef(make.Modifiers(localContext.bridgeSym.flags()),
rfield@1380 788 localContext.bridgeSym.name,
rfield@1380 789 make.QualIdent(samDesc.getReturnType().tsym),
rfield@1380 790 List.<JCTypeParameter>nil(),
rfield@1380 791 params.toList(),
rfield@1380 792 tree.sym.type.getThrownTypes() == null
rfield@1380 793 ? List.<JCExpression>nil()
rfield@1380 794 : make.Types(tree.sym.type.getThrownTypes()),
rfield@1380 795 null,
rfield@1380 796 null);
rfield@1380 797 bridgeDecl.sym = (MethodSymbol) localContext.bridgeSym;
mcimadamore@1595 798 bridgeDecl.type = localContext.bridgeSym.type =
mcimadamore@1595 799 types.createMethodTypeWithParameters(samDesc, TreeInfo.types(params.toList()));
rfield@1380 800
rfield@1380 801 //bridge method body generation - this can be either a method call or a
rfield@1380 802 //new instance creation expression, depending on the member reference kind
rfield@1380 803 JCExpression bridgeExpr = (tree.getMode() == ReferenceMode.INVOKE)
mcimadamore@1614 804 ? bridgeExpressionInvoke(makeReceiver(rcvr))
rfield@1380 805 : bridgeExpressionNew();
rfield@1380 806
rfield@1380 807 //the body is either a return expression containing a method call,
rfield@1380 808 //or the method call itself, depending on whether the return type of
rfield@1380 809 //the bridge is non-void/void.
rfield@1380 810 bridgeDecl.body = makeLambdaExpressionBody(bridgeExpr, bridgeDecl);
rfield@1380 811
rfield@1380 812 return bridgeDecl;
rfield@1380 813 } finally {
rfield@1380 814 make.at(prevPos);
rfield@1380 815 }
rfield@1380 816 }
mcimadamore@1614 817 //where
mcimadamore@1614 818 private JCExpression makeReceiver(VarSymbol rcvr) {
mcimadamore@1614 819 if (rcvr == null) return null;
mcimadamore@1614 820 JCExpression rcvrExpr = make.Ident(rcvr);
mcimadamore@1614 821 Type rcvrType = tree.sym.enclClass().type;
mcimadamore@1614 822 if (!rcvr.type.tsym.isSubClass(rcvrType.tsym, types)) {
mcimadamore@1614 823 rcvrExpr = make.TypeCast(make.Type(rcvrType), rcvrExpr).setType(rcvrType);
mcimadamore@1614 824 }
mcimadamore@1614 825 return rcvrExpr;
mcimadamore@1614 826 }
rfield@1380 827
rfield@1380 828 /**
rfield@1380 829 * determine the receiver of the bridged method call - the receiver can
rfield@1380 830 * be either the synthetic receiver parameter or a type qualifier; the
rfield@1380 831 * original qualifier expression is never used here, as it might refer
rfield@1380 832 * to symbols not available in the static context of the bridge
rfield@1380 833 */
mcimadamore@1614 834 private JCExpression bridgeExpressionInvoke(JCExpression rcvr) {
rfield@1380 835 JCExpression qualifier =
rfield@1380 836 tree.sym.isStatic() ?
rfield@1380 837 make.Type(tree.sym.owner.type) :
rfield@1380 838 (rcvr != null) ?
mcimadamore@1614 839 rcvr :
rfield@1380 840 tree.getQualifierExpression();
rfield@1380 841
rfield@1380 842 //create the qualifier expression
rfield@1380 843 JCFieldAccess select = make.Select(qualifier, tree.sym.name);
rfield@1380 844 select.sym = tree.sym;
rfield@1380 845 select.type = tree.sym.erasure(types);
rfield@1380 846
rfield@1380 847 //create the method call expression
rfield@1380 848 JCExpression apply = make.Apply(List.<JCExpression>nil(), select,
mcimadamore@1595 849 convertArgs(tree.sym, args.toList(), tree.varargsElement)).
mcimadamore@1595 850 setType(tree.sym.erasure(types).getReturnType());
rfield@1380 851
rfield@1380 852 apply = transTypes.coerce(apply, localContext.generatedRefSig().getReturnType());
rfield@1380 853 setVarargsIfNeeded(apply, tree.varargsElement);
rfield@1380 854 return apply;
rfield@1380 855 }
rfield@1380 856
rfield@1380 857 /**
rfield@1380 858 * the enclosing expression is either 'null' (no enclosing type) or set
rfield@1380 859 * to the first bridge synthetic parameter
rfield@1380 860 */
rfield@1380 861 private JCExpression bridgeExpressionNew() {
mcimadamore@1496 862 if (tree.kind == ReferenceKind.ARRAY_CTOR) {
mcimadamore@1496 863 //create the array creation expression
mcimadamore@1595 864 JCNewArray newArr = make.NewArray(
mcimadamore@1595 865 make.Type(types.elemtype(tree.getQualifierExpression().type)),
mcimadamore@1496 866 List.of(make.Ident(params.first())),
mcimadamore@1496 867 null);
mcimadamore@1496 868 newArr.type = tree.getQualifierExpression().type;
mcimadamore@1496 869 return newArr;
mcimadamore@1496 870 } else {
mcimadamore@1496 871 JCExpression encl = null;
mcimadamore@1496 872 switch (tree.kind) {
mcimadamore@1496 873 case UNBOUND:
mcimadamore@1496 874 case IMPLICIT_INNER:
mcimadamore@1496 875 encl = make.Ident(params.first());
mcimadamore@1496 876 }
mcimadamore@1496 877
mcimadamore@1496 878 //create the instance creation expression
mcimadamore@1496 879 JCNewClass newClass = make.NewClass(encl,
mcimadamore@1496 880 List.<JCExpression>nil(),
mcimadamore@1496 881 make.Type(tree.getQualifierExpression().type),
mcimadamore@1496 882 convertArgs(tree.sym, args.toList(), tree.varargsElement),
mcimadamore@1496 883 null);
mcimadamore@1496 884 newClass.constructor = tree.sym;
mcimadamore@1496 885 newClass.constructorType = tree.sym.erasure(types);
mcimadamore@1496 886 newClass.type = tree.getQualifierExpression().type;
mcimadamore@1496 887 setVarargsIfNeeded(newClass, tree.varargsElement);
mcimadamore@1496 888 return newClass;
rfield@1380 889 }
rfield@1380 890 }
rfield@1380 891
rfield@1380 892 private VarSymbol addParameter(String name, Type p, boolean genArg) {
rfield@1380 893 VarSymbol vsym = new VarSymbol(0, names.fromString(name), p, localContext.bridgeSym);
rfield@1380 894 params.append(make.VarDef(vsym, null));
rfield@1380 895 if (genArg) {
rfield@1380 896 args.append(make.Ident(vsym));
rfield@1380 897 }
rfield@1380 898 return vsym;
rfield@1380 899 }
rfield@1380 900 }
rfield@1380 901
rfield@1380 902 /**
rfield@1380 903 * Bridges a member reference - this is needed when:
rfield@1380 904 * * Var args in the referenced method need to be flattened away
rfield@1380 905 * * super is used
rfield@1380 906 */
rfield@1380 907 private void bridgeMemberReference(JCMemberReference tree, ReferenceTranslationContext localContext) {
rfield@1587 908 kInfo.addMethod(new MemberReferenceBridger(tree, localContext).bridge());
rfield@1380 909 }
rfield@1380 910
mcimadamore@1882 911 private MethodType typeToMethodType(Type mt) {
mcimadamore@1882 912 Type type = types.erasure(mt);
mcimadamore@1882 913 return new MethodType(type.getParameterTypes(),
mcimadamore@1882 914 type.getReturnType(),
mcimadamore@1882 915 type.getThrownTypes(),
mcimadamore@1882 916 syms.methodClass);
mcimadamore@1882 917 }
mcimadamore@1882 918
rfield@1380 919 /**
rfield@1380 920 * Generate an indy method call to the meta factory
rfield@1380 921 */
mcimadamore@1882 922 private JCExpression makeMetafactoryIndyCall(TranslationContext<?> context,
mcimadamore@1882 923 int refKind, Symbol refSym, List<JCExpression> indy_args) {
mcimadamore@1882 924 JCFunctionalExpression tree = context.tree;
rfield@1380 925 //determine the static bsm args
mcimadamore@1510 926 MethodSymbol samSym = (MethodSymbol) types.findDescriptorSymbol(tree.type.tsym);
rfield@1380 927 List<Object> staticArgs = List.<Object>of(
mcimadamore@1882 928 typeToMethodType(samSym.type),
vromero@1452 929 new Pool.MethodHandle(refKind, refSym, types),
mcimadamore@1882 930 typeToMethodType(tree.getDescriptorType(types)));
rfield@1380 931
rfield@1380 932 //computed indy arg types
rfield@1380 933 ListBuffer<Type> indy_args_types = ListBuffer.lb();
rfield@1380 934 for (JCExpression arg : indy_args) {
rfield@1380 935 indy_args_types.append(arg.type);
rfield@1380 936 }
rfield@1380 937
rfield@1380 938 //finally, compute the type of the indy call
rfield@1380 939 MethodType indyType = new MethodType(indy_args_types.toList(),
rfield@1380 940 tree.type,
rfield@1380 941 List.<Type>nil(),
rfield@1380 942 syms.methodClass);
rfield@1380 943
mcimadamore@1882 944 Name metafactoryName = context.needsAltMetafactory() ?
mcimadamore@1882 945 names.altMetafactory : names.metafactory;
rfield@1587 946
mcimadamore@1882 947 if (context.needsAltMetafactory()) {
rfield@1587 948 ListBuffer<Object> markers = ListBuffer.lb();
mcimadamore@1882 949 for (Type t : tree.targets.tail) {
mcimadamore@1882 950 if (t.tsym != syms.serializableType.tsym) {
mcimadamore@1882 951 markers.append(t.tsym);
rfield@1587 952 }
rfield@1587 953 }
mcimadamore@1882 954 int flags = context.isSerializable() ? FLAG_SERIALIZABLE : 0;
rfield@1587 955 boolean hasMarkers = markers.nonEmpty();
mcimadamore@1882 956 boolean hasBridges = context.bridges.nonEmpty();
mcimadamore@1882 957 if (hasMarkers) {
mcimadamore@1882 958 flags |= FLAG_MARKERS;
mcimadamore@1882 959 }
mcimadamore@1882 960 if (hasBridges) {
mcimadamore@1882 961 flags |= FLAG_BRIDGES;
mcimadamore@1882 962 }
rfield@1587 963 staticArgs = staticArgs.append(flags);
rfield@1587 964 if (hasMarkers) {
rfield@1587 965 staticArgs = staticArgs.append(markers.length());
rfield@1587 966 staticArgs = staticArgs.appendList(markers.toList());
rfield@1587 967 }
mcimadamore@1882 968 if (hasBridges) {
mcimadamore@1882 969 staticArgs = staticArgs.append(context.bridges.length() - 1);
mcimadamore@1882 970 for (Symbol s : context.bridges) {
mcimadamore@1882 971 Type s_erasure = s.erasure(types);
mcimadamore@1882 972 if (!types.isSameType(s_erasure, samSym.erasure(types))) {
mcimadamore@1882 973 staticArgs = staticArgs.append(s.erasure(types));
mcimadamore@1882 974 }
mcimadamore@1882 975 }
mcimadamore@1882 976 }
mcimadamore@1882 977 if (context.isSerializable()) {
rfield@1587 978 addDeserializationCase(refKind, refSym, tree.type, samSym,
rfield@1587 979 tree, staticArgs, indyType);
rfield@1587 980 }
rfield@1587 981 }
rfield@1587 982
mcimadamore@1882 983 return makeIndyCall(tree, syms.lambdaMetafactory, metafactoryName, staticArgs, indyType, indy_args, samSym.name);
rfield@1380 984 }
rfield@1380 985
rfield@1380 986 /**
rfield@1380 987 * Generate an indy method call with given name, type and static bootstrap
rfield@1380 988 * arguments types
rfield@1380 989 */
mcimadamore@1595 990 private JCExpression makeIndyCall(DiagnosticPosition pos, Type site, Name bsmName,
mcimadamore@1882 991 List<Object> staticArgs, MethodType indyType, List<JCExpression> indyArgs,
mcimadamore@1882 992 Name methName) {
rfield@1380 993 int prevPos = make.pos;
rfield@1380 994 try {
rfield@1380 995 make.at(pos);
rfield@1380 996 List<Type> bsm_staticArgs = List.of(syms.methodHandleLookupType,
rfield@1380 997 syms.stringType,
rfield@1380 998 syms.methodTypeType).appendList(bsmStaticArgToTypes(staticArgs));
rfield@1380 999
rfield@1380 1000 Symbol bsm = rs.resolveInternalMethod(pos, attrEnv, site,
rfield@1380 1001 bsmName, bsm_staticArgs, List.<Type>nil());
rfield@1380 1002
rfield@1380 1003 DynamicMethodSymbol dynSym =
mcimadamore@1882 1004 new DynamicMethodSymbol(methName,
rfield@1380 1005 syms.noSymbol,
mcimadamore@1595 1006 bsm.isStatic() ?
mcimadamore@1595 1007 ClassFile.REF_invokeStatic :
mcimadamore@1595 1008 ClassFile.REF_invokeVirtual,
rfield@1380 1009 (MethodSymbol)bsm,
rfield@1380 1010 indyType,
rfield@1380 1011 staticArgs.toArray());
rfield@1380 1012
rfield@1380 1013 JCFieldAccess qualifier = make.Select(make.QualIdent(site.tsym), bsmName);
rfield@1380 1014 qualifier.sym = dynSym;
rfield@1380 1015 qualifier.type = indyType.getReturnType();
rfield@1380 1016
rfield@1380 1017 JCMethodInvocation proxyCall = make.Apply(List.<JCExpression>nil(), qualifier, indyArgs);
rfield@1380 1018 proxyCall.type = indyType.getReturnType();
rfield@1380 1019 return proxyCall;
rfield@1380 1020 } finally {
rfield@1380 1021 make.at(prevPos);
rfield@1380 1022 }
rfield@1380 1023 }
rfield@1380 1024 //where
rfield@1380 1025 private List<Type> bsmStaticArgToTypes(List<Object> args) {
rfield@1380 1026 ListBuffer<Type> argtypes = ListBuffer.lb();
rfield@1380 1027 for (Object arg : args) {
rfield@1380 1028 argtypes.append(bsmStaticArgToType(arg));
rfield@1380 1029 }
rfield@1380 1030 return argtypes.toList();
rfield@1380 1031 }
rfield@1380 1032
rfield@1380 1033 private Type bsmStaticArgToType(Object arg) {
rfield@1380 1034 Assert.checkNonNull(arg);
rfield@1380 1035 if (arg instanceof ClassSymbol) {
rfield@1380 1036 return syms.classType;
rfield@1380 1037 } else if (arg instanceof Integer) {
rfield@1380 1038 return syms.intType;
rfield@1380 1039 } else if (arg instanceof Long) {
rfield@1380 1040 return syms.longType;
rfield@1380 1041 } else if (arg instanceof Float) {
rfield@1380 1042 return syms.floatType;
rfield@1380 1043 } else if (arg instanceof Double) {
rfield@1380 1044 return syms.doubleType;
rfield@1380 1045 } else if (arg instanceof String) {
rfield@1380 1046 return syms.stringType;
rfield@1380 1047 } else if (arg instanceof Pool.MethodHandle) {
rfield@1380 1048 return syms.methodHandleType;
rfield@1380 1049 } else if (arg instanceof MethodType) {
rfield@1380 1050 return syms.methodTypeType;
rfield@1380 1051 } else {
rfield@1380 1052 Assert.error("bad static arg " + arg.getClass());
rfield@1380 1053 return null;
rfield@1380 1054 }
rfield@1380 1055 }
rfield@1380 1056
rfield@1380 1057 /**
rfield@1380 1058 * Get the opcode associated with this method reference
rfield@1380 1059 */
rfield@1380 1060 private int referenceKind(Symbol refSym) {
rfield@1380 1061 if (refSym.isConstructor()) {
rfield@1380 1062 return ClassFile.REF_newInvokeSpecial;
rfield@1380 1063 } else {
rfield@1380 1064 if (refSym.isStatic()) {
rfield@1380 1065 return ClassFile.REF_invokeStatic;
rfield@1380 1066 } else if (refSym.enclClass().isInterface()) {
rfield@1380 1067 return ClassFile.REF_invokeInterface;
rfield@1380 1068 } else {
mcimadamore@1652 1069 return (refSym.flags() & PRIVATE) != 0 ?
mcimadamore@1652 1070 ClassFile.REF_invokeSpecial :
mcimadamore@1652 1071 ClassFile.REF_invokeVirtual;
rfield@1380 1072 }
rfield@1380 1073 }
rfield@1380 1074 }
rfield@1587 1075
mcimadamore@1652 1076 // <editor-fold defaultstate="collapsed" desc="Lambda/reference analyzer">
rfield@1380 1077 /**
rfield@1380 1078 * This visitor collects information about translation of a lambda expression.
rfield@1380 1079 * More specifically, it keeps track of the enclosing contexts and captured locals
rfield@1380 1080 * accessed by the lambda being translated (as well as other useful info).
rfield@1717 1081 * It also translates away problems for LambdaToMethod.
rfield@1380 1082 */
rfield@1717 1083 class LambdaAnalyzerPreprocessor extends TreeTranslator {
rfield@1380 1084
rfield@1380 1085 /** the frame stack - used to reconstruct translation info about enclosing scopes */
rfield@1380 1086 private List<Frame> frameStack;
rfield@1380 1087
rfield@1380 1088 /**
rfield@1380 1089 * keep the count of lambda expression (used to generate unambiguous
rfield@1380 1090 * names)
rfield@1380 1091 */
rfield@1380 1092 private int lambdaCount = 0;
rfield@1380 1093
rfield@1587 1094 /**
rfield@1587 1095 * keep the count of lambda expression defined in given context (used to
rfield@1587 1096 * generate unambiguous names for serializable lambdas)
rfield@1587 1097 */
rfield@1587 1098 private Map<String, Integer> serializableLambdaCounts =
rfield@1587 1099 new HashMap<String, Integer>();
rfield@1587 1100
mcimadamore@1612 1101 private Map<Symbol, JCClassDecl> localClassDefs;
mcimadamore@1612 1102
rfield@1587 1103 /**
rfield@1587 1104 * maps for fake clinit symbols to be used as owners of lambda occurring in
rfield@1587 1105 * a static var init context
rfield@1587 1106 */
rfield@1587 1107 private Map<ClassSymbol, Symbol> clinits =
rfield@1587 1108 new HashMap<ClassSymbol, Symbol>();
rfield@1587 1109
rfield@1717 1110 private JCClassDecl analyzeAndPreprocessClass(JCClassDecl tree) {
rfield@1380 1111 frameStack = List.nil();
mcimadamore@1612 1112 localClassDefs = new HashMap<Symbol, JCClassDecl>();
rfield@1717 1113 return translate(tree);
rfield@1380 1114 }
rfield@1380 1115
rfield@1380 1116 @Override
rfield@1380 1117 public void visitBlock(JCBlock tree) {
rfield@1380 1118 List<Frame> prevStack = frameStack;
rfield@1380 1119 try {
rfield@1380 1120 if (frameStack.nonEmpty() && frameStack.head.tree.hasTag(CLASSDEF)) {
rfield@1380 1121 frameStack = frameStack.prepend(new Frame(tree));
rfield@1380 1122 }
rfield@1380 1123 super.visitBlock(tree);
rfield@1380 1124 }
rfield@1380 1125 finally {
rfield@1380 1126 frameStack = prevStack;
rfield@1380 1127 }
rfield@1380 1128 }
rfield@1380 1129
rfield@1380 1130 @Override
rfield@1380 1131 public void visitClassDef(JCClassDecl tree) {
rfield@1380 1132 List<Frame> prevStack = frameStack;
mcimadamore@1595 1133 Map<String, Integer> prevSerializableLambdaCount =
mcimadamore@1595 1134 serializableLambdaCounts;
rfield@1587 1135 Map<ClassSymbol, Symbol> prevClinits = clinits;
mcimadamore@1817 1136 DiagnosticSource prevSource = log.currentSource();
rfield@1380 1137 try {
mcimadamore@1817 1138 log.useSource(tree.sym.sourcefile);
rfield@1587 1139 serializableLambdaCounts = new HashMap<String, Integer>();
rfield@1587 1140 prevClinits = new HashMap<ClassSymbol, Symbol>();
mcimadamore@1612 1141 if (tree.sym.owner.kind == MTH) {
mcimadamore@1612 1142 localClassDefs.put(tree.sym, tree);
mcimadamore@1612 1143 }
rfield@1587 1144 if (directlyEnclosingLambda() != null) {
rfield@1380 1145 tree.sym.owner = owner();
mcimadamore@1595 1146 if (tree.sym.hasOuterInstance()) {
mcimadamore@1595 1147 //if a class is defined within a lambda, the lambda must capture
mcimadamore@1595 1148 //its enclosing instance (if any)
mcimadamore@1612 1149 TranslationContext<?> localContext = context();
mcimadamore@1612 1150 while (localContext != null) {
mcimadamore@1612 1151 if (localContext.tree.getTag() == LAMBDA) {
mcimadamore@1612 1152 ((LambdaTranslationContext)localContext)
mcimadamore@1612 1153 .addSymbol(tree.sym.type.getEnclosingType().tsym, CAPTURED_THIS);
mcimadamore@1612 1154 }
mcimadamore@1612 1155 localContext = localContext.prev;
mcimadamore@1612 1156 }
rfield@1380 1157 }
rfield@1380 1158 }
rfield@1380 1159 frameStack = frameStack.prepend(new Frame(tree));
rfield@1380 1160 super.visitClassDef(tree);
rfield@1380 1161 }
rfield@1380 1162 finally {
mcimadamore@1817 1163 log.useSource(prevSource.getFile());
rfield@1380 1164 frameStack = prevStack;
rfield@1587 1165 serializableLambdaCounts = prevSerializableLambdaCount;
rfield@1587 1166 clinits = prevClinits;
rfield@1380 1167 }
rfield@1380 1168 }
rfield@1380 1169
rfield@1380 1170 @Override
rfield@1380 1171 public void visitIdent(JCIdent tree) {
rfield@1587 1172 if (context() != null && lambdaIdentSymbolFilter(tree.sym)) {
rfield@1380 1173 if (tree.sym.kind == VAR &&
rfield@1380 1174 tree.sym.owner.kind == MTH &&
rfield@1380 1175 tree.type.constValue() == null) {
rfield@1380 1176 TranslationContext<?> localContext = context();
rfield@1380 1177 while (localContext != null) {
rfield@1380 1178 if (localContext.tree.getTag() == LAMBDA) {
rfield@1380 1179 JCTree block = capturedDecl(localContext.depth, tree.sym);
rfield@1380 1180 if (block == null) break;
mcimadamore@1595 1181 ((LambdaTranslationContext)localContext)
mcimadamore@1595 1182 .addSymbol(tree.sym, CAPTURED_VAR);
rfield@1380 1183 }
rfield@1380 1184 localContext = localContext.prev;
rfield@1380 1185 }
rfield@1380 1186 } else if (tree.sym.owner.kind == TYP) {
rfield@1380 1187 TranslationContext<?> localContext = context();
rfield@1380 1188 while (localContext != null) {
rfield@1380 1189 if (localContext.tree.hasTag(LAMBDA)) {
rfield@1380 1190 JCTree block = capturedDecl(localContext.depth, tree.sym);
rfield@1380 1191 if (block == null) break;
rfield@1380 1192 switch (block.getTag()) {
rfield@1380 1193 case CLASSDEF:
rfield@1380 1194 JCClassDecl cdecl = (JCClassDecl)block;
mcimadamore@1595 1195 ((LambdaTranslationContext)localContext)
mcimadamore@1595 1196 .addSymbol(cdecl.sym, CAPTURED_THIS);
rfield@1380 1197 break;
rfield@1380 1198 default:
rfield@1380 1199 Assert.error("bad block kind");
rfield@1380 1200 }
rfield@1380 1201 }
rfield@1380 1202 localContext = localContext.prev;
rfield@1380 1203 }
rfield@1380 1204 }
rfield@1380 1205 }
rfield@1587 1206 super.visitIdent(tree);
rfield@1380 1207 }
rfield@1380 1208
rfield@1380 1209 @Override
rfield@1380 1210 public void visitLambda(JCLambda tree) {
rfield@1380 1211 List<Frame> prevStack = frameStack;
rfield@1380 1212 try {
rfield@1380 1213 LambdaTranslationContext context = (LambdaTranslationContext)makeLambdaContext(tree);
rfield@1380 1214 frameStack = frameStack.prepend(new Frame(tree));
rfield@1380 1215 for (JCVariableDecl param : tree.params) {
rfield@1380 1216 context.addSymbol(param.sym, PARAM);
rfield@1380 1217 frameStack.head.addLocal(param.sym);
rfield@1380 1218 }
rfield@1380 1219 contextMap.put(tree, context);
rfield@1717 1220 super.visitLambda(tree);
rfield@1380 1221 context.complete();
rfield@1380 1222 }
rfield@1380 1223 finally {
rfield@1380 1224 frameStack = prevStack;
rfield@1380 1225 }
rfield@1380 1226 }
rfield@1380 1227
rfield@1380 1228 @Override
rfield@1380 1229 public void visitMethodDef(JCMethodDecl tree) {
rfield@1380 1230 List<Frame> prevStack = frameStack;
rfield@1380 1231 try {
rfield@1380 1232 frameStack = frameStack.prepend(new Frame(tree));
rfield@1380 1233 super.visitMethodDef(tree);
rfield@1380 1234 }
rfield@1380 1235 finally {
rfield@1380 1236 frameStack = prevStack;
rfield@1380 1237 }
rfield@1380 1238 }
rfield@1380 1239
rfield@1380 1240 @Override
rfield@1380 1241 public void visitNewClass(JCNewClass tree) {
rfield@1380 1242 if (lambdaNewClassFilter(context(), tree)) {
mcimadamore@1612 1243 TranslationContext<?> localContext = context();
mcimadamore@1612 1244 while (localContext != null) {
mcimadamore@1612 1245 if (localContext.tree.getTag() == LAMBDA) {
mcimadamore@1612 1246 ((LambdaTranslationContext)localContext)
mcimadamore@1612 1247 .addSymbol(tree.type.getEnclosingType().tsym, CAPTURED_THIS);
mcimadamore@1612 1248 }
mcimadamore@1612 1249 localContext = localContext.prev;
mcimadamore@1612 1250 }
mcimadamore@1612 1251 }
mcimadamore@1612 1252 if (context() != null && tree.type.tsym.owner.kind == MTH) {
mcimadamore@1612 1253 LambdaTranslationContext lambdaContext = (LambdaTranslationContext)context();
mcimadamore@1612 1254 captureLocalClassDefs(tree.type.tsym, lambdaContext);
rfield@1380 1255 }
rfield@1380 1256 super.visitNewClass(tree);
rfield@1380 1257 }
mcimadamore@1612 1258 //where
mcimadamore@1612 1259 void captureLocalClassDefs(Symbol csym, final LambdaTranslationContext lambdaContext) {
mcimadamore@1612 1260 JCClassDecl localCDef = localClassDefs.get(csym);
mcimadamore@1612 1261 if (localCDef != null && localCDef.pos < lambdaContext.tree.pos) {
mcimadamore@1612 1262 BasicFreeVarCollector fvc = lower.new BasicFreeVarCollector() {
mcimadamore@1612 1263 @Override
mcimadamore@1612 1264 void addFreeVars(ClassSymbol c) {
mcimadamore@1612 1265 captureLocalClassDefs(c, lambdaContext);
mcimadamore@1612 1266 }
mcimadamore@1612 1267 @Override
mcimadamore@1612 1268 void visitSymbol(Symbol sym) {
mcimadamore@1612 1269 if (sym.kind == VAR &&
mcimadamore@1612 1270 sym.owner.kind == MTH &&
mcimadamore@1612 1271 ((VarSymbol)sym).getConstValue() == null) {
mcimadamore@1612 1272 TranslationContext<?> localContext = context();
mcimadamore@1612 1273 while (localContext != null) {
mcimadamore@1612 1274 if (localContext.tree.getTag() == LAMBDA) {
mcimadamore@1612 1275 JCTree block = capturedDecl(localContext.depth, sym);
mcimadamore@1612 1276 if (block == null) break;
mcimadamore@1612 1277 ((LambdaTranslationContext)localContext).addSymbol(sym, CAPTURED_VAR);
mcimadamore@1612 1278 }
mcimadamore@1612 1279 localContext = localContext.prev;
mcimadamore@1612 1280 }
mcimadamore@1612 1281 }
mcimadamore@1612 1282 }
mcimadamore@1612 1283 };
mcimadamore@1612 1284 fvc.scan(localCDef);
mcimadamore@1612 1285 }
rfield@1717 1286 }
rfield@1380 1287
rfield@1717 1288 /**
rfield@1717 1289 * Method references to local class constructors, may, if the local
rfield@1717 1290 * class references local variables, have implicit constructor
rfield@1717 1291 * parameters added in Lower; As a result, the invokedynamic bootstrap
rfield@1717 1292 * information added in the LambdaToMethod pass will have the wrong
rfield@1717 1293 * signature. Hooks between Lower and LambdaToMethod have been added to
rfield@1717 1294 * handle normal "new" in this case. This visitor converts potentially
rfield@1717 1295 * effected method references into a lambda containing a normal "new" of
rfield@1717 1296 * the class.
rfield@1717 1297 *
rfield@1717 1298 * @param tree
rfield@1717 1299 */
rfield@1380 1300 @Override
rfield@1380 1301 public void visitReference(JCMemberReference tree) {
rfield@1717 1302 if (tree.getMode() == ReferenceMode.NEW
rfield@1717 1303 && tree.kind != ReferenceKind.ARRAY_CTOR
rfield@1717 1304 && tree.sym.owner.isLocal()) {
rfield@1717 1305 MethodSymbol consSym = (MethodSymbol) tree.sym;
rfield@1717 1306 List<Type> ptypes = ((MethodType) consSym.type).getParameterTypes();
rfield@1717 1307 Type classType = consSym.owner.type;
rfield@1717 1308
rfield@1727 1309 // Build lambda parameters
rfield@1727 1310 // partially cloned from TreeMaker.Params until 8014021 is fixed
rfield@1727 1311 Symbol owner = owner();
rfield@1727 1312 ListBuffer<JCVariableDecl> paramBuff = new ListBuffer<JCVariableDecl>();
rfield@1727 1313 int i = 0;
rfield@1727 1314 for (List<Type> l = ptypes; l.nonEmpty(); l = l.tail) {
rfield@1727 1315 paramBuff.append(make.Param(make.paramName(i++), l.head, owner));
rfield@1727 1316 }
rfield@1727 1317 List<JCVariableDecl> params = paramBuff.toList();
rfield@1727 1318
rfield@1717 1319 // Make new-class call
rfield@1717 1320 JCNewClass nc = makeNewClass(classType, make.Idents(params));
rfield@1717 1321 nc.pos = tree.pos;
rfield@1717 1322
rfield@1717 1323 // Make lambda holding the new-class call
rfield@1717 1324 JCLambda slam = make.Lambda(params, nc);
rfield@1717 1325 slam.targets = tree.targets;
rfield@1717 1326 slam.type = tree.type;
rfield@1717 1327 slam.pos = tree.pos;
rfield@1717 1328
rfield@1717 1329 // Now it is a lambda, process as such
rfield@1717 1330 visitLambda(slam);
rfield@1717 1331 } else {
rfield@1717 1332 super.visitReference(tree);
rfield@1717 1333 contextMap.put(tree, makeReferenceContext(tree));
rfield@1717 1334 }
rfield@1380 1335 }
rfield@1380 1336
rfield@1380 1337 @Override
rfield@1380 1338 public void visitSelect(JCFieldAccess tree) {
rfield@1762 1339 if (context() != null && tree.sym.kind == VAR &&
rfield@1762 1340 (tree.sym.name == names._this ||
rfield@1762 1341 tree.sym.name == names._super)) {
rfield@1762 1342 // A select of this or super means, if we are in a lambda,
rfield@1762 1343 // we much have an instance context
rfield@1380 1344 TranslationContext<?> localContext = context();
rfield@1380 1345 while (localContext != null) {
rfield@1380 1346 if (localContext.tree.hasTag(LAMBDA)) {
rfield@1380 1347 JCClassDecl clazz = (JCClassDecl)capturedDecl(localContext.depth, tree.sym);
rfield@1380 1348 if (clazz == null) break;
rfield@1380 1349 ((LambdaTranslationContext)localContext).addSymbol(clazz.sym, CAPTURED_THIS);
rfield@1380 1350 }
rfield@1380 1351 localContext = localContext.prev;
rfield@1380 1352 }
rfield@1380 1353 }
rfield@1717 1354 super.visitSelect(tree);
rfield@1380 1355 }
rfield@1380 1356
rfield@1380 1357 @Override
rfield@1380 1358 public void visitVarDef(JCVariableDecl tree) {
rfield@1587 1359 TranslationContext<?> context = context();
rfield@1587 1360 LambdaTranslationContext ltc = (context != null && context instanceof LambdaTranslationContext)?
rfield@1587 1361 (LambdaTranslationContext)context :
rfield@1587 1362 null;
rfield@1587 1363 if (ltc != null) {
rfield@1587 1364 if (frameStack.head.tree.hasTag(LAMBDA)) {
rfield@1587 1365 ltc.addSymbol(tree.sym, LOCAL_VAR);
rfield@1587 1366 }
rfield@1587 1367 // Check for type variables (including as type arguments).
rfield@1587 1368 // If they occur within class nested in a lambda, mark for erasure
rfield@1587 1369 Type type = tree.sym.asType();
rfield@1587 1370 if (inClassWithinLambda() && !types.isSameType(types.erasure(type), type)) {
rfield@1587 1371 ltc.addSymbol(tree.sym, TYPE_VAR);
rfield@1587 1372 }
rfield@1380 1373 }
rfield@1587 1374
rfield@1380 1375 List<Frame> prevStack = frameStack;
rfield@1380 1376 try {
rfield@1380 1377 if (tree.sym.owner.kind == MTH) {
rfield@1380 1378 frameStack.head.addLocal(tree.sym);
rfield@1380 1379 }
rfield@1380 1380 frameStack = frameStack.prepend(new Frame(tree));
rfield@1380 1381 super.visitVarDef(tree);
rfield@1380 1382 }
rfield@1380 1383 finally {
rfield@1380 1384 frameStack = prevStack;
rfield@1380 1385 }
rfield@1380 1386 }
rfield@1380 1387
rfield@1380 1388 private Name lambdaName() {
rfield@1587 1389 return names.lambda.append(names.fromString("" + lambdaCount++));
rfield@1587 1390 }
rfield@1587 1391
rfield@1639 1392 /**
rfield@1639 1393 * For a serializable lambda, generate a name which maximizes name
rfield@1639 1394 * stability across deserialization.
rfield@1639 1395 * @param owner
rfield@1639 1396 * @return Name to use for the synthetic lambda method name
rfield@1639 1397 */
rfield@1587 1398 private Name serializedLambdaName(Symbol owner) {
rfield@1587 1399 StringBuilder buf = new StringBuilder();
rfield@1587 1400 buf.append(names.lambda);
rfield@1639 1401 // Append the name of the method enclosing the lambda.
rfield@1624 1402 String methodName = owner.name.toString();
rfield@1624 1403 if (methodName.equals("<clinit>"))
rfield@1624 1404 methodName = "static";
rfield@1624 1405 else if (methodName.equals("<init>"))
rfield@1624 1406 methodName = "new";
rfield@1624 1407 buf.append(methodName);
rfield@1587 1408 buf.append('$');
rfield@1639 1409 // Append a hash of the enclosing method signature to differentiate
rfield@1639 1410 // overloaded enclosing methods. For lambdas enclosed in lambdas,
rfield@1639 1411 // the generated lambda method will not have type yet, but the
rfield@1639 1412 // enclosing method's name will have been generated with this same
rfield@1639 1413 // method, so it will be unique and never be overloaded.
mcimadamore@1666 1414 Assert.check(owner.type != null || directlyEnclosingLambda() != null);
rfield@1639 1415 if (owner.type != null) {
rfield@1639 1416 int methTypeHash = methodSig(owner.type).hashCode();
rfield@1639 1417 buf.append(Integer.toHexString(methTypeHash));
rfield@1639 1418 }
rfield@1587 1419 buf.append('$');
rfield@1639 1420 // The above appended name components may not be unique, append a
rfield@1639 1421 // count based on the above name components.
rfield@1587 1422 String temp = buf.toString();
rfield@1587 1423 Integer count = serializableLambdaCounts.get(temp);
rfield@1587 1424 if (count == null) {
rfield@1587 1425 count = 0;
rfield@1587 1426 }
rfield@1587 1427 buf.append(count++);
rfield@1587 1428 serializableLambdaCounts.put(temp, count);
rfield@1587 1429 return names.fromString(buf.toString());
rfield@1380 1430 }
rfield@1380 1431
rfield@1380 1432 /**
rfield@1380 1433 * Return a valid owner given the current declaration stack
rfield@1380 1434 * (required to skip synthetic lambda symbols)
rfield@1380 1435 */
rfield@1380 1436 private Symbol owner() {
mcimadamore@1515 1437 return owner(false);
mcimadamore@1515 1438 }
mcimadamore@1515 1439
mcimadamore@1515 1440 @SuppressWarnings("fallthrough")
mcimadamore@1515 1441 private Symbol owner(boolean skipLambda) {
rfield@1380 1442 List<Frame> frameStack2 = frameStack;
rfield@1380 1443 while (frameStack2.nonEmpty()) {
rfield@1380 1444 switch (frameStack2.head.tree.getTag()) {
rfield@1380 1445 case VARDEF:
rfield@1380 1446 if (((JCVariableDecl)frameStack2.head.tree).sym.isLocal()) {
rfield@1380 1447 frameStack2 = frameStack2.tail;
rfield@1380 1448 break;
rfield@1380 1449 }
rfield@1380 1450 JCClassDecl cdecl = (JCClassDecl)frameStack2.tail.head.tree;
rfield@1587 1451 return initSym(cdecl.sym,
rfield@1587 1452 ((JCVariableDecl)frameStack2.head.tree).sym.flags() & STATIC);
rfield@1380 1453 case BLOCK:
rfield@1380 1454 JCClassDecl cdecl2 = (JCClassDecl)frameStack2.tail.head.tree;
rfield@1587 1455 return initSym(cdecl2.sym,
rfield@1587 1456 ((JCBlock)frameStack2.head.tree).flags & STATIC);
rfield@1380 1457 case CLASSDEF:
rfield@1380 1458 return ((JCClassDecl)frameStack2.head.tree).sym;
rfield@1380 1459 case METHODDEF:
rfield@1380 1460 return ((JCMethodDecl)frameStack2.head.tree).sym;
rfield@1380 1461 case LAMBDA:
mcimadamore@1515 1462 if (!skipLambda)
mcimadamore@1595 1463 return ((LambdaTranslationContext)contextMap
mcimadamore@1595 1464 .get(frameStack2.head.tree)).translatedSym;
rfield@1380 1465 default:
rfield@1380 1466 frameStack2 = frameStack2.tail;
rfield@1380 1467 }
rfield@1380 1468 }
rfield@1380 1469 Assert.error();
rfield@1380 1470 return null;
rfield@1380 1471 }
rfield@1380 1472
rfield@1587 1473 private Symbol initSym(ClassSymbol csym, long flags) {
rfield@1587 1474 boolean isStatic = (flags & STATIC) != 0;
rfield@1587 1475 if (isStatic) {
rfield@1587 1476 //static clinits are generated in Gen - so we need to fake them
rfield@1587 1477 Symbol clinit = clinits.get(csym);
rfield@1587 1478 if (clinit == null) {
rfield@1587 1479 clinit = makeSyntheticMethod(STATIC,
rfield@1587 1480 names.clinit,
rfield@1587 1481 new MethodType(List.<Type>nil(), syms.voidType, List.<Type>nil(), syms.methodClass),
rfield@1587 1482 csym);
rfield@1587 1483 clinits.put(csym, clinit);
rfield@1587 1484 }
rfield@1587 1485 return clinit;
rfield@1587 1486 } else {
rfield@1587 1487 //get the first constructor and treat it as the instance init sym
rfield@1587 1488 for (Symbol s : csym.members_field.getElementsByName(names.init)) {
rfield@1587 1489 return s;
rfield@1587 1490 }
rfield@1587 1491 }
rfield@1587 1492 Assert.error("init not found");
rfield@1587 1493 return null;
rfield@1587 1494 }
rfield@1587 1495
rfield@1587 1496 private JCTree directlyEnclosingLambda() {
rfield@1587 1497 if (frameStack.isEmpty()) {
rfield@1587 1498 return null;
rfield@1587 1499 }
rfield@1380 1500 List<Frame> frameStack2 = frameStack;
rfield@1380 1501 while (frameStack2.nonEmpty()) {
rfield@1380 1502 switch (frameStack2.head.tree.getTag()) {
rfield@1380 1503 case CLASSDEF:
rfield@1380 1504 case METHODDEF:
rfield@1380 1505 return null;
rfield@1380 1506 case LAMBDA:
rfield@1380 1507 return frameStack2.head.tree;
rfield@1380 1508 default:
rfield@1380 1509 frameStack2 = frameStack2.tail;
rfield@1380 1510 }
rfield@1380 1511 }
rfield@1380 1512 Assert.error();
rfield@1380 1513 return null;
rfield@1380 1514 }
rfield@1380 1515
rfield@1587 1516 private boolean inClassWithinLambda() {
rfield@1587 1517 if (frameStack.isEmpty()) {
rfield@1587 1518 return false;
rfield@1587 1519 }
rfield@1587 1520 List<Frame> frameStack2 = frameStack;
rfield@1587 1521 boolean classFound = false;
rfield@1587 1522 while (frameStack2.nonEmpty()) {
rfield@1587 1523 switch (frameStack2.head.tree.getTag()) {
rfield@1587 1524 case LAMBDA:
rfield@1587 1525 return classFound;
rfield@1587 1526 case CLASSDEF:
rfield@1587 1527 classFound = true;
rfield@1587 1528 frameStack2 = frameStack2.tail;
rfield@1587 1529 break;
rfield@1587 1530 default:
rfield@1587 1531 frameStack2 = frameStack2.tail;
rfield@1587 1532 }
rfield@1587 1533 }
rfield@1587 1534 // No lambda
rfield@1587 1535 return false;
rfield@1587 1536 }
rfield@1587 1537
rfield@1380 1538 /**
rfield@1380 1539 * Return the declaration corresponding to a symbol in the enclosing
rfield@1380 1540 * scope; the depth parameter is used to filter out symbols defined
rfield@1380 1541 * in nested scopes (which do not need to undergo capture).
rfield@1380 1542 */
rfield@1380 1543 private JCTree capturedDecl(int depth, Symbol sym) {
rfield@1380 1544 int currentDepth = frameStack.size() - 1;
rfield@1380 1545 for (Frame block : frameStack) {
rfield@1380 1546 switch (block.tree.getTag()) {
rfield@1380 1547 case CLASSDEF:
rfield@1380 1548 ClassSymbol clazz = ((JCClassDecl)block.tree).sym;
rfield@1380 1549 if (sym.isMemberOf(clazz, types)) {
rfield@1380 1550 return currentDepth > depth ? null : block.tree;
rfield@1380 1551 }
rfield@1380 1552 break;
rfield@1380 1553 case VARDEF:
rfield@1380 1554 if (((JCVariableDecl)block.tree).sym == sym &&
rfield@1380 1555 sym.owner.kind == MTH) { //only locals are captured
rfield@1380 1556 return currentDepth > depth ? null : block.tree;
rfield@1380 1557 }
rfield@1380 1558 break;
rfield@1380 1559 case BLOCK:
rfield@1380 1560 case METHODDEF:
rfield@1380 1561 case LAMBDA:
rfield@1380 1562 if (block.locals != null && block.locals.contains(sym)) {
rfield@1380 1563 return currentDepth > depth ? null : block.tree;
rfield@1380 1564 }
rfield@1380 1565 break;
rfield@1380 1566 default:
rfield@1380 1567 Assert.error("bad decl kind " + block.tree.getTag());
rfield@1380 1568 }
rfield@1380 1569 currentDepth--;
rfield@1380 1570 }
rfield@1380 1571 return null;
rfield@1380 1572 }
rfield@1380 1573
rfield@1380 1574 private TranslationContext<?> context() {
rfield@1380 1575 for (Frame frame : frameStack) {
rfield@1380 1576 TranslationContext<?> context = contextMap.get(frame.tree);
rfield@1380 1577 if (context != null) {
rfield@1380 1578 return context;
rfield@1380 1579 }
rfield@1380 1580 }
rfield@1380 1581 return null;
rfield@1380 1582 }
rfield@1380 1583
rfield@1380 1584 /**
rfield@1380 1585 * This is used to filter out those identifiers that needs to be adjusted
rfield@1380 1586 * when translating away lambda expressions
rfield@1380 1587 */
rfield@1380 1588 private boolean lambdaIdentSymbolFilter(Symbol sym) {
rfield@1380 1589 return (sym.kind == VAR || sym.kind == MTH)
rfield@1380 1590 && !sym.isStatic()
rfield@1380 1591 && sym.name != names.init;
rfield@1380 1592 }
rfield@1380 1593
rfield@1380 1594 /**
rfield@1380 1595 * This is used to filter out those new class expressions that need to
rfield@1380 1596 * be qualified with an enclosing tree
rfield@1380 1597 */
rfield@1380 1598 private boolean lambdaNewClassFilter(TranslationContext<?> context, JCNewClass tree) {
rfield@1380 1599 if (context != null
rfield@1380 1600 && tree.encl == null
rfield@1380 1601 && tree.def == null
rfield@1405 1602 && !tree.type.getEnclosingType().hasTag(NONE)) {
rfield@1380 1603 Type encl = tree.type.getEnclosingType();
rfield@1380 1604 Type current = context.owner.enclClass().type;
rfield@1405 1605 while (!current.hasTag(NONE)) {
rfield@1380 1606 if (current.tsym.isSubClass(encl.tsym, types)) {
rfield@1380 1607 return true;
rfield@1380 1608 }
rfield@1380 1609 current = current.getEnclosingType();
rfield@1380 1610 }
rfield@1380 1611 return false;
rfield@1380 1612 } else {
rfield@1380 1613 return false;
rfield@1380 1614 }
rfield@1380 1615 }
rfield@1380 1616
rfield@1380 1617 private TranslationContext<JCLambda> makeLambdaContext(JCLambda tree) {
rfield@1380 1618 return new LambdaTranslationContext(tree);
rfield@1380 1619 }
rfield@1380 1620
rfield@1380 1621 private TranslationContext<JCMemberReference> makeReferenceContext(JCMemberReference tree) {
rfield@1380 1622 return new ReferenceTranslationContext(tree);
rfield@1380 1623 }
rfield@1380 1624
rfield@1380 1625 private class Frame {
rfield@1380 1626 final JCTree tree;
rfield@1380 1627 List<Symbol> locals;
rfield@1380 1628
rfield@1380 1629 public Frame(JCTree tree) {
rfield@1380 1630 this.tree = tree;
rfield@1380 1631 }
rfield@1380 1632
rfield@1380 1633 void addLocal(Symbol sym) {
rfield@1380 1634 if (locals == null) {
rfield@1380 1635 locals = List.nil();
rfield@1380 1636 }
rfield@1380 1637 locals = locals.prepend(sym);
rfield@1380 1638 }
rfield@1380 1639 }
rfield@1380 1640
rfield@1380 1641 /**
rfield@1380 1642 * This class is used to store important information regarding translation of
rfield@1380 1643 * lambda expression/method references (see subclasses).
rfield@1380 1644 */
mcimadamore@1510 1645 private abstract class TranslationContext<T extends JCFunctionalExpression> {
rfield@1380 1646
rfield@1380 1647 /** the underlying (untranslated) tree */
rfield@1380 1648 T tree;
rfield@1380 1649
rfield@1380 1650 /** points to the adjusted enclosing scope in which this lambda/mref expression occurs */
rfield@1380 1651 Symbol owner;
rfield@1380 1652
rfield@1380 1653 /** the depth of this lambda expression in the frame stack */
rfield@1380 1654 int depth;
rfield@1380 1655
rfield@1380 1656 /** the enclosing translation context (set for nested lambdas/mref) */
rfield@1380 1657 TranslationContext<?> prev;
rfield@1380 1658
mcimadamore@1882 1659 /** list of methods to be bridged by the meta-factory */
mcimadamore@1882 1660 List<Symbol> bridges;
mcimadamore@1882 1661
rfield@1380 1662 TranslationContext(T tree) {
rfield@1380 1663 this.tree = tree;
rfield@1380 1664 this.owner = owner();
rfield@1380 1665 this.depth = frameStack.size() - 1;
rfield@1380 1666 this.prev = context();
mcimadamore@1882 1667 ClassSymbol csym =
mcimadamore@1882 1668 types.makeFunctionalInterfaceClass(attrEnv, names.empty, tree.targets, ABSTRACT | INTERFACE);
mcimadamore@1882 1669 this.bridges = types.functionalInterfaceBridges(csym);
rfield@1380 1670 }
rfield@1587 1671
rfield@1587 1672 /** does this functional expression need to be created using alternate metafactory? */
rfield@1587 1673 boolean needsAltMetafactory() {
mcimadamore@1882 1674 return tree.targets.length() > 1 ||
mcimadamore@1882 1675 isSerializable() ||
mcimadamore@1882 1676 bridges.length() > 1;
rfield@1587 1677 }
rfield@1587 1678
rfield@1587 1679 /** does this functional expression require serialization support? */
rfield@1587 1680 boolean isSerializable() {
mcimadamore@1882 1681 for (Type target : tree.targets) {
mcimadamore@1882 1682 if (types.asSuper(target, syms.serializableType.tsym) != null) {
rfield@1587 1683 return true;
rfield@1587 1684 }
rfield@1587 1685 }
rfield@1587 1686 return false;
rfield@1587 1687 }
rfield@1380 1688 }
rfield@1380 1689
rfield@1380 1690 /**
rfield@1380 1691 * This class retains all the useful information about a lambda expression;
rfield@1380 1692 * the contents of this class are filled by the LambdaAnalyzer visitor,
rfield@1380 1693 * and the used by the main translation routines in order to adjust references
rfield@1380 1694 * to captured locals/members, etc.
rfield@1380 1695 */
rfield@1380 1696 private class LambdaTranslationContext extends TranslationContext<JCLambda> {
rfield@1380 1697
rfield@1380 1698 /** variable in the enclosing context to which this lambda is assigned */
rfield@1380 1699 Symbol self;
rfield@1380 1700
rfield@1380 1701 /** map from original to translated lambda parameters */
rfield@1380 1702 Map<Symbol, Symbol> lambdaParams = new LinkedHashMap<Symbol, Symbol>();
rfield@1380 1703
rfield@1380 1704 /** map from original to translated lambda locals */
rfield@1380 1705 Map<Symbol, Symbol> lambdaLocals = new LinkedHashMap<Symbol, Symbol>();
rfield@1380 1706
rfield@1380 1707 /** map from variables in enclosing scope to translated synthetic parameters */
rfield@1380 1708 Map<Symbol, Symbol> capturedLocals = new LinkedHashMap<Symbol, Symbol>();
rfield@1380 1709
rfield@1380 1710 /** map from class symbols to translated synthetic parameters (for captured member access) */
rfield@1380 1711 Map<Symbol, Symbol> capturedThis = new LinkedHashMap<Symbol, Symbol>();
rfield@1380 1712
rfield@1587 1713 /** map from original to translated lambda locals */
rfield@1587 1714 Map<Symbol, Symbol> typeVars = new LinkedHashMap<Symbol, Symbol>();
rfield@1587 1715
rfield@1380 1716 /** the synthetic symbol for the method hoisting the translated lambda */
rfield@1380 1717 Symbol translatedSym;
rfield@1380 1718
rfield@1380 1719 List<JCVariableDecl> syntheticParams;
rfield@1380 1720
rfield@1380 1721 LambdaTranslationContext(JCLambda tree) {
rfield@1380 1722 super(tree);
rfield@1380 1723 Frame frame = frameStack.head;
rfield@1380 1724 if (frame.tree.hasTag(VARDEF)) {
rfield@1380 1725 self = ((JCVariableDecl)frame.tree).sym;
rfield@1380 1726 }
rfield@1587 1727 Name name = isSerializable() ? serializedLambdaName(owner) : lambdaName();
rfield@1587 1728 this.translatedSym = makeSyntheticMethod(0, name, null, owner.enclClass());
mcimadamore@1817 1729 if (dumpLambdaToMethodStats) {
mcimadamore@1817 1730 log.note(tree, "lambda.stat", needsAltMetafactory(), translatedSym);
mcimadamore@1817 1731 }
rfield@1380 1732 }
rfield@1380 1733
rfield@1380 1734 /**
rfield@1380 1735 * Translate a symbol of a given kind into something suitable for the
rfield@1380 1736 * synthetic lambda body
rfield@1380 1737 */
mcimadamore@1652 1738 Symbol translate(Name name, final Symbol sym, LambdaSymbolKind skind) {
jjg@1755 1739 Symbol ret;
rfield@1587 1740 switch (skind) {
rfield@1587 1741 case CAPTURED_THIS:
jjg@1755 1742 ret = sym; // self represented
jjg@1755 1743 break;
rfield@1587 1744 case TYPE_VAR:
rfield@1587 1745 // Just erase the type var
jjg@1755 1746 ret = new VarSymbol(sym.flags(), name,
mcimadamore@1595 1747 types.erasure(sym.type), sym.owner);
jjg@1755 1748 break;
mcimadamore@1612 1749 case CAPTURED_VAR:
jjg@1755 1750 ret = new VarSymbol(SYNTHETIC | FINAL, name, types.erasure(sym.type), translatedSym) {
mcimadamore@1612 1751 @Override
mcimadamore@1612 1752 public Symbol baseSymbol() {
mcimadamore@1612 1753 //keep mapping with original captured symbol
mcimadamore@1612 1754 return sym;
mcimadamore@1612 1755 }
mcimadamore@1612 1756 };
jjg@1755 1757 break;
rfield@1587 1758 default:
jjg@1755 1759 ret = makeSyntheticVar(FINAL, name, types.erasure(sym.type), translatedSym);
rfield@1380 1760 }
jjg@1755 1761 if (ret != sym) {
jjg@1802 1762 ret.setDeclarationAttributes(sym.getRawAttributes());
jjg@1802 1763 ret.setTypeAttributes(sym.getRawTypeAttributes());
jjg@1755 1764 }
jjg@1755 1765 return ret;
rfield@1380 1766 }
rfield@1380 1767
rfield@1380 1768 void addSymbol(Symbol sym, LambdaSymbolKind skind) {
rfield@1380 1769 Map<Symbol, Symbol> transMap = null;
mcimadamore@1652 1770 Name preferredName;
rfield@1380 1771 switch (skind) {
rfield@1380 1772 case CAPTURED_THIS:
rfield@1380 1773 transMap = capturedThis;
mcimadamore@1652 1774 preferredName = names.fromString("encl$" + capturedThis.size());
rfield@1380 1775 break;
rfield@1380 1776 case CAPTURED_VAR:
rfield@1380 1777 transMap = capturedLocals;
mcimadamore@1652 1778 preferredName = names.fromString("cap$" + capturedLocals.size());
rfield@1380 1779 break;
rfield@1380 1780 case LOCAL_VAR:
rfield@1380 1781 transMap = lambdaLocals;
mcimadamore@1652 1782 preferredName = sym.name;
rfield@1380 1783 break;
rfield@1380 1784 case PARAM:
rfield@1380 1785 transMap = lambdaParams;
mcimadamore@1652 1786 preferredName = sym.name;
rfield@1380 1787 break;
rfield@1587 1788 case TYPE_VAR:
rfield@1587 1789 transMap = typeVars;
mcimadamore@1652 1790 preferredName = sym.name;
rfield@1587 1791 break;
rfield@1380 1792 default: throw new AssertionError();
rfield@1380 1793 }
rfield@1380 1794 if (!transMap.containsKey(sym)) {
rfield@1380 1795 transMap.put(sym, translate(preferredName, sym, skind));
rfield@1380 1796 }
rfield@1380 1797 }
rfield@1380 1798
rfield@1380 1799 Map<Symbol, Symbol> getSymbolMap(LambdaSymbolKind... skinds) {
rfield@1380 1800 LinkedHashMap<Symbol, Symbol> translationMap = new LinkedHashMap<Symbol, Symbol>();
rfield@1380 1801 for (LambdaSymbolKind skind : skinds) {
rfield@1380 1802 switch (skind) {
rfield@1380 1803 case CAPTURED_THIS:
rfield@1380 1804 translationMap.putAll(capturedThis);
rfield@1380 1805 break;
rfield@1380 1806 case CAPTURED_VAR:
rfield@1380 1807 translationMap.putAll(capturedLocals);
rfield@1380 1808 break;
rfield@1380 1809 case LOCAL_VAR:
rfield@1380 1810 translationMap.putAll(lambdaLocals);
rfield@1380 1811 break;
rfield@1380 1812 case PARAM:
rfield@1380 1813 translationMap.putAll(lambdaParams);
rfield@1380 1814 break;
rfield@1587 1815 case TYPE_VAR:
rfield@1587 1816 translationMap.putAll(typeVars);
rfield@1587 1817 break;
rfield@1380 1818 default: throw new AssertionError();
rfield@1380 1819 }
rfield@1380 1820 }
rfield@1380 1821 return translationMap;
rfield@1380 1822 }
rfield@1380 1823
rfield@1380 1824 /**
rfield@1380 1825 * The translatedSym is not complete/accurate until the analysis is
rfield@1380 1826 * finished. Once the analysis is finished, the translatedSym is
rfield@1380 1827 * "completed" -- updated with type information, access modifiers,
rfield@1380 1828 * and full parameter list.
rfield@1380 1829 */
rfield@1380 1830 void complete() {
rfield@1380 1831 if (syntheticParams != null) {
rfield@1380 1832 return;
rfield@1380 1833 }
rfield@1380 1834 boolean inInterface = translatedSym.owner.isInterface();
rfield@1380 1835 boolean thisReferenced = !getSymbolMap(CAPTURED_THIS).isEmpty();
rfield@1380 1836
rfield@1752 1837 // If instance access isn't needed, make it static.
rfield@1752 1838 // Interface instance methods must be default methods.
rfield@1752 1839 // Awaiting VM channges, default methods are public
rfield@1752 1840 translatedSym.flags_field = SYNTHETIC |
rfield@1752 1841 ((inInterface && thisReferenced)? PUBLIC : PRIVATE) |
rfield@1752 1842 (thisReferenced? (inInterface? DEFAULT : 0) : STATIC);
rfield@1380 1843
rfield@1380 1844 //compute synthetic params
rfield@1380 1845 ListBuffer<JCVariableDecl> params = ListBuffer.lb();
rfield@1380 1846
rfield@1380 1847 // The signature of the method is augmented with the following
rfield@1380 1848 // synthetic parameters:
rfield@1380 1849 //
rfield@1380 1850 // 1) reference to enclosing contexts captured by the lambda expression
rfield@1380 1851 // 2) enclosing locals captured by the lambda expression
rfield@1380 1852 for (Symbol thisSym : getSymbolMap(CAPTURED_VAR, PARAM).values()) {
rfield@1380 1853 params.append(make.VarDef((VarSymbol) thisSym, null));
rfield@1380 1854 }
rfield@1380 1855
rfield@1380 1856 syntheticParams = params.toList();
rfield@1380 1857
rfield@1380 1858 //prepend synthetic args to translated lambda method signature
rfield@1587 1859 translatedSym.type = types.createMethodTypeWithParameters(
rfield@1587 1860 generatedLambdaSig(),
rfield@1380 1861 TreeInfo.types(syntheticParams));
rfield@1380 1862 }
rfield@1380 1863
rfield@1380 1864 Type generatedLambdaSig() {
mcimadamore@1882 1865 return types.erasure(tree.getDescriptorType(types));
rfield@1380 1866 }
rfield@1380 1867 }
rfield@1380 1868
rfield@1380 1869 /**
rfield@1380 1870 * This class retains all the useful information about a method reference;
rfield@1380 1871 * the contents of this class are filled by the LambdaAnalyzer visitor,
rfield@1380 1872 * and the used by the main translation routines in order to adjust method
rfield@1380 1873 * references (i.e. in case a bridge is needed)
rfield@1380 1874 */
rfield@1380 1875 private class ReferenceTranslationContext extends TranslationContext<JCMemberReference> {
rfield@1380 1876
rfield@1380 1877 final boolean isSuper;
rfield@1380 1878 final Symbol bridgeSym;
rfield@1380 1879
rfield@1380 1880 ReferenceTranslationContext(JCMemberReference tree) {
rfield@1380 1881 super(tree);
rfield@1380 1882 this.isSuper = tree.hasKind(ReferenceKind.SUPER);
rfield@1380 1883 this.bridgeSym = needsBridge()
rfield@1380 1884 ? makeSyntheticMethod(isSuper ? 0 : STATIC,
rfield@1380 1885 lambdaName().append(names.fromString("$bridge")), null,
rfield@1380 1886 owner.enclClass())
rfield@1380 1887 : null;
mcimadamore@1817 1888 if (dumpLambdaToMethodStats) {
mcimadamore@1817 1889 String key = bridgeSym == null ?
mcimadamore@1817 1890 "mref.stat" : "mref.stat.1";
mcimadamore@1817 1891 log.note(tree, key, needsAltMetafactory(), bridgeSym);
mcimadamore@1817 1892 }
rfield@1380 1893 }
rfield@1380 1894
rfield@1380 1895 /**
rfield@1380 1896 * Get the opcode associated with this method reference
rfield@1380 1897 */
rfield@1380 1898 int referenceKind() {
rfield@1380 1899 return LambdaToMethod.this.referenceKind(needsBridge() ? bridgeSym : tree.sym);
rfield@1380 1900 }
rfield@1380 1901
rfield@1380 1902 boolean needsVarArgsConversion() {
rfield@1380 1903 return tree.varargsElement != null;
rfield@1380 1904 }
rfield@1380 1905
rfield@1380 1906 /**
rfield@1380 1907 * @return Is this an array operation like clone()
rfield@1380 1908 */
rfield@1380 1909 boolean isArrayOp() {
rfield@1380 1910 return tree.sym.owner == syms.arrayClass;
rfield@1380 1911 }
rfield@1380 1912
mcimadamore@1597 1913 boolean isPrivateConstructor() {
mcimadamore@1615 1914 //hack needed to workaround 292 bug (8005122)
mcimadamore@1615 1915 //when 292 issue is fixed we should simply remove this
mcimadamore@1597 1916 return tree.sym.name == names.init &&
mcimadamore@1597 1917 (tree.sym.flags() & PRIVATE) != 0;
mcimadamore@1597 1918 }
mcimadamore@1597 1919
mcimadamore@1615 1920 boolean receiverAccessible() {
mcimadamore@1615 1921 //hack needed to workaround 292 bug (7087658)
mcimadamore@1615 1922 //when 292 issue is fixed we should remove this and change the backend
mcimadamore@1615 1923 //code to always generate a method handle to an accessible method
mcimadamore@1615 1924 return tree.ownerAccessible;
mcimadamore@1615 1925 }
mcimadamore@1615 1926
rfield@1380 1927 /**
rfield@1380 1928 * Does this reference needs a bridge (i.e. var args need to be
rfield@1380 1929 * expanded or "super" is used)
rfield@1380 1930 */
rfield@1380 1931 final boolean needsBridge() {
mcimadamore@1615 1932 return isSuper || needsVarArgsConversion() || isArrayOp() ||
mcimadamore@1615 1933 isPrivateConstructor() || !receiverAccessible();
rfield@1380 1934 }
rfield@1380 1935
rfield@1380 1936 Type generatedRefSig() {
rfield@1380 1937 return types.erasure(tree.sym.type);
rfield@1380 1938 }
rfield@1380 1939
rfield@1380 1940 Type bridgedRefSig() {
mcimadamore@1882 1941 return types.erasure(types.findDescriptorSymbol(tree.targets.head.tsym).type);
rfield@1380 1942 }
rfield@1380 1943 }
rfield@1380 1944 }
rfield@1380 1945 // </editor-fold>
rfield@1380 1946
rfield@1380 1947 enum LambdaSymbolKind {
rfield@1380 1948 CAPTURED_VAR,
rfield@1380 1949 CAPTURED_THIS,
rfield@1380 1950 LOCAL_VAR,
rfield@1587 1951 PARAM,
rfield@1587 1952 TYPE_VAR;
rfield@1587 1953 }
rfield@1587 1954
rfield@1587 1955 /**
rfield@1587 1956 * ****************************************************************
rfield@1587 1957 * Signature Generation
rfield@1587 1958 * ****************************************************************
rfield@1587 1959 */
rfield@1587 1960
rfield@1587 1961 private String methodSig(Type type) {
rfield@1587 1962 L2MSignatureGenerator sg = new L2MSignatureGenerator();
rfield@1587 1963 sg.assembleSig(type);
rfield@1587 1964 return sg.toString();
rfield@1587 1965 }
rfield@1587 1966
rfield@1587 1967 private String classSig(Type type) {
rfield@1587 1968 L2MSignatureGenerator sg = new L2MSignatureGenerator();
rfield@1587 1969 sg.assembleClassSig(type);
rfield@1587 1970 return sg.toString();
rfield@1587 1971 }
rfield@1587 1972
rfield@1587 1973 /**
rfield@1587 1974 * Signature Generation
rfield@1587 1975 */
rfield@1587 1976 private class L2MSignatureGenerator extends Types.SignatureGenerator {
rfield@1587 1977
rfield@1587 1978 /**
rfield@1587 1979 * An output buffer for type signatures.
rfield@1587 1980 */
rfield@1587 1981 StringBuilder sb = new StringBuilder();
rfield@1587 1982
rfield@1587 1983 L2MSignatureGenerator() {
rfield@1587 1984 super(types);
rfield@1587 1985 }
rfield@1587 1986
rfield@1587 1987 @Override
rfield@1587 1988 protected void append(char ch) {
rfield@1587 1989 sb.append(ch);
rfield@1587 1990 }
rfield@1587 1991
rfield@1587 1992 @Override
rfield@1587 1993 protected void append(byte[] ba) {
rfield@1587 1994 sb.append(new String(ba));
rfield@1587 1995 }
rfield@1587 1996
rfield@1587 1997 @Override
rfield@1587 1998 protected void append(Name name) {
rfield@1587 1999 sb.append(name.toString());
rfield@1587 2000 }
rfield@1587 2001
rfield@1587 2002 @Override
rfield@1587 2003 public String toString() {
rfield@1587 2004 return sb.toString();
rfield@1587 2005 }
rfield@1380 2006 }
rfield@1380 2007 }

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