Mercurial > hg > openjdk > lambda > langtools
view src/share/classes/com/sun/tools/javac/comp/LambdaToMethod.java @ 2551:d7e155f874a7
8026704: Build failure with --enable-debug
Reviewed-by: ksrini
| author | jjg |
|---|---|
| date | Wed, 16 Oct 2013 10:47:21 -0700 |
| parents | 09a414673570 |
| children | 7de97abc4a5c |
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/* * Copyright (c) 2010, 2013, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. Oracle designates this * particular file as subject to the "Classpath" exception as provided * by Oracle in the LICENSE file that accompanied this code. * * This code is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. */ package com.sun.tools.javac.comp; import com.sun.tools.javac.tree.*; import com.sun.tools.javac.tree.JCTree.*; import com.sun.tools.javac.tree.JCTree.JCMemberReference.ReferenceKind; import com.sun.tools.javac.tree.TreeMaker; import com.sun.tools.javac.tree.TreeTranslator; import com.sun.tools.javac.code.Attribute; import com.sun.tools.javac.code.Kinds; import com.sun.tools.javac.code.Scope; import com.sun.tools.javac.code.Symbol; import com.sun.tools.javac.code.Symbol.ClassSymbol; import com.sun.tools.javac.code.Symbol.DynamicMethodSymbol; import com.sun.tools.javac.code.Symbol.MethodSymbol; import com.sun.tools.javac.code.Symbol.VarSymbol; import com.sun.tools.javac.code.Symtab; import com.sun.tools.javac.code.Type; import com.sun.tools.javac.code.Type.MethodType; import com.sun.tools.javac.code.Types; import com.sun.tools.javac.comp.LambdaToMethod.LambdaAnalyzerPreprocessor.*; import com.sun.tools.javac.comp.Lower.BasicFreeVarCollector; import com.sun.tools.javac.jvm.*; import com.sun.tools.javac.util.*; import com.sun.tools.javac.util.JCDiagnostic.DiagnosticPosition; import com.sun.source.tree.MemberReferenceTree.ReferenceMode; import java.util.HashMap; import java.util.LinkedHashMap; import java.util.Map; import static com.sun.tools.javac.comp.LambdaToMethod.LambdaSymbolKind.*; import static com.sun.tools.javac.code.Flags.*; import static com.sun.tools.javac.code.Kinds.*; import static com.sun.tools.javac.code.TypeTag.*; import static com.sun.tools.javac.tree.JCTree.Tag.*; /** * This pass desugars lambda expressions into static methods * * <p><b>This is NOT part of any supported API. * If you write code that depends on this, you do so at your own risk. * This code and its internal interfaces are subject to change or * deletion without notice.</b> */ public class LambdaToMethod extends TreeTranslator { private JCDiagnostic.Factory diags; private Log log; private Lower lower; private Names names; private Symtab syms; private Resolve rs; private TreeMaker make; private Types types; private TransTypes transTypes; private Env<AttrContext> attrEnv; /** the analyzer scanner */ private LambdaAnalyzerPreprocessor analyzer; /** map from lambda trees to translation contexts */ private Map<JCTree, TranslationContext<?>> contextMap; /** current translation context (visitor argument) */ private TranslationContext<?> context; /** info about the current class being processed */ private KlassInfo kInfo; /** dump statistics about lambda code generation */ private boolean dumpLambdaToMethodStats; /** Flag for alternate metafactories indicating the lambda object is intended to be serializable */ public static final int FLAG_SERIALIZABLE = 1 << 0; /** Flag for alternate metafactories indicating the lambda object has multiple targets */ public static final int FLAG_MARKERS = 1 << 1; /** Flag for alternate metafactories indicating the lambda object requires multiple bridges */ public static final int FLAG_BRIDGES = 1 << 2; private class KlassInfo { /** * list of methods to append */ private ListBuffer<JCTree> appendedMethodList; /** * list of deserialization cases */ private final Map<String, ListBuffer<JCStatement>> deserializeCases; /** * deserialize method symbol */ private final MethodSymbol deserMethodSym; /** * deserialize method parameter symbol */ private final VarSymbol deserParamSym; private KlassInfo(Symbol kSym) { appendedMethodList = new ListBuffer<>(); deserializeCases = new HashMap<String, ListBuffer<JCStatement>>(); MethodType type = new MethodType(List.of(syms.serializedLambdaType), syms.objectType, List.<Type>nil(), syms.methodClass); deserMethodSym = makePrivateSyntheticMethod(STATIC, names.deserializeLambda, type, kSym); deserParamSym = new VarSymbol(FINAL, names.fromString("lambda"), syms.serializedLambdaType, deserMethodSym); } private void addMethod(JCTree decl) { appendedMethodList = appendedMethodList.prepend(decl); } } // <editor-fold defaultstate="collapsed" desc="Instantiating"> private static final Context.Key<LambdaToMethod> unlambdaKey = new Context.Key<LambdaToMethod>(); public static LambdaToMethod instance(Context context) { LambdaToMethod instance = context.get(unlambdaKey); if (instance == null) { instance = new LambdaToMethod(context); } return instance; } private Attr attr; private LambdaToMethod(Context context) { diags = JCDiagnostic.Factory.instance(context); log = Log.instance(context); lower = Lower.instance(context); names = Names.instance(context); syms = Symtab.instance(context); rs = Resolve.instance(context); make = TreeMaker.instance(context); types = Types.instance(context); transTypes = TransTypes.instance(context); analyzer = new LambdaAnalyzerPreprocessor(); Options options = Options.instance(context); dumpLambdaToMethodStats = options.isSet("dumpLambdaToMethodStats"); attr = Attr.instance(context); } // </editor-fold> // <editor-fold defaultstate="collapsed" desc="translate methods"> @Override public <T extends JCTree> T translate(T tree) { TranslationContext<?> newContext = contextMap.get(tree); return translate(tree, newContext != null ? newContext : context); } <T extends JCTree> T translate(T tree, TranslationContext<?> newContext) { TranslationContext<?> prevContext = context; try { context = newContext; return super.translate(tree); } finally { context = prevContext; } } <T extends JCTree> List<T> translate(List<T> trees, TranslationContext<?> newContext) { ListBuffer<T> buf = new ListBuffer<>(); for (T tree : trees) { buf.append(translate(tree, newContext)); } return buf.toList(); } public JCTree translateTopLevelClass(Env<AttrContext> env, JCTree cdef, TreeMaker make) { this.make = make; this.attrEnv = env; this.context = null; this.contextMap = new HashMap<JCTree, TranslationContext<?>>(); return translate(cdef); } // </editor-fold> // <editor-fold defaultstate="collapsed" desc="visitor methods"> /** * Visit a class. * Maintain the translatedMethodList across nested classes. * Append the translatedMethodList to the class after it is translated. * @param tree */ @Override public void visitClassDef(JCClassDecl tree) { if (tree.sym.owner.kind == PCK) { //analyze class tree = analyzer.analyzeAndPreprocessClass(tree); } KlassInfo prevKlassInfo = kInfo; try { kInfo = new KlassInfo(tree.sym); super.visitClassDef(tree); if (!kInfo.deserializeCases.isEmpty()) { kInfo.addMethod(makeDeserializeMethod(tree.sym)); } //add all translated instance methods here List<JCTree> newMethods = kInfo.appendedMethodList.toList(); tree.defs = tree.defs.appendList(newMethods); for (JCTree lambda : newMethods) { tree.sym.members().enter(((JCMethodDecl)lambda).sym); } result = tree; } finally { kInfo = prevKlassInfo; } } /** * Translate a lambda into a method to be inserted into the class. * Then replace the lambda site with an invokedynamic call of to lambda * meta-factory, which will use the lambda method. * @param tree */ @Override public void visitLambda(JCLambda tree) { LambdaTranslationContext localContext = (LambdaTranslationContext)context; MethodSymbol sym = (MethodSymbol)localContext.translatedSym; MethodType lambdaType = (MethodType) sym.type; { Symbol owner = localContext.owner; ListBuffer<Attribute.TypeCompound> ownerTypeAnnos = new ListBuffer<Attribute.TypeCompound>(); ListBuffer<Attribute.TypeCompound> lambdaTypeAnnos = new ListBuffer<Attribute.TypeCompound>(); for (Attribute.TypeCompound tc : owner.getRawTypeAttributes()) { if (tc.position.onLambda == tree) { lambdaTypeAnnos.append(tc); } else { ownerTypeAnnos.append(tc); } } if (lambdaTypeAnnos.nonEmpty()) { owner.setTypeAttributes(ownerTypeAnnos.toList()); sym.setTypeAttributes(lambdaTypeAnnos.toList()); } } //create the method declaration hoisting the lambda body JCMethodDecl lambdaDecl = make.MethodDef(make.Modifiers(sym.flags_field), sym.name, make.QualIdent(lambdaType.getReturnType().tsym), List.<JCTypeParameter>nil(), localContext.syntheticParams, lambdaType.getThrownTypes() == null ? List.<JCExpression>nil() : make.Types(lambdaType.getThrownTypes()), null, null); lambdaDecl.sym = sym; lambdaDecl.type = lambdaType; //translate lambda body //As the lambda body is translated, all references to lambda locals, //captured variables, enclosing members are adjusted accordingly //to refer to the static method parameters (rather than i.e. acessing to //captured members directly). lambdaDecl.body = translate(makeLambdaBody(tree, lambdaDecl)); //Add the method to the list of methods to be added to this class. kInfo.addMethod(lambdaDecl); //now that we have generated a method for the lambda expression, //we can translate the lambda into a method reference pointing to the newly //created method. // //Note that we need to adjust the method handle so that it will match the //signature of the SAM descriptor - this means that the method reference //should be added the following synthetic arguments: // // * the "this" argument if it is an instance method // * enclosing locals captured by the lambda expression ListBuffer<JCExpression> syntheticInits = new ListBuffer<>(); if (!sym.isStatic()) { syntheticInits.append(makeThis( sym.owner.enclClass().asType(), localContext.owner.enclClass())); } //add captured locals for (Symbol fv : localContext.getSymbolMap(CAPTURED_VAR).keySet()) { if (fv != localContext.self) { JCTree captured_local = make.Ident(fv).setType(fv.type); syntheticInits.append((JCExpression) captured_local); } } //then, determine the arguments to the indy call List<JCExpression> indy_args = translate(syntheticInits.toList(), localContext.prev); //build a sam instance using an indy call to the meta-factory int refKind = referenceKind(sym); //convert to an invokedynamic call result = makeMetafactoryIndyCall(context, refKind, sym, indy_args); } private JCIdent makeThis(Type type, Symbol owner) { VarSymbol _this = new VarSymbol(PARAMETER | FINAL | SYNTHETIC, names._this, type, owner); return make.Ident(_this); } /** * Translate a method reference into an invokedynamic call to the * meta-factory. * @param tree */ @Override public void visitReference(JCMemberReference tree) { ReferenceTranslationContext localContext = (ReferenceTranslationContext)context; //first determine the method symbol to be used to generate the sam instance //this is either the method reference symbol, or the bridged reference symbol Symbol refSym = localContext.needsBridge() ? localContext.bridgeSym : tree.sym; //build the bridge method, if needed if (localContext.needsBridge()) { bridgeMemberReference(tree, localContext); } //the qualifying expression is treated as a special captured arg JCExpression init; switch(tree.kind) { case IMPLICIT_INNER: /** Inner :: new */ case SUPER: /** super :: instMethod */ init = makeThis( localContext.owner.enclClass().asType(), localContext.owner.enclClass()); break; case BOUND: /** Expr :: instMethod */ init = tree.getQualifierExpression(); init = attr.makeNullCheck(init); break; case UNBOUND: /** Type :: instMethod */ case STATIC: /** Type :: staticMethod */ case TOPLEVEL: /** Top level :: new */ case ARRAY_CTOR: /** ArrayType :: new */ init = null; break; default: throw new InternalError("Should not have an invalid kind"); } List<JCExpression> indy_args = init==null? List.<JCExpression>nil() : translate(List.of(init), localContext.prev); //build a sam instance using an indy call to the meta-factory result = makeMetafactoryIndyCall(localContext, localContext.referenceKind(), refSym, indy_args); } /** * Translate identifiers within a lambda to the mapped identifier * @param tree */ @Override public void visitIdent(JCIdent tree) { if (context == null || !analyzer.lambdaIdentSymbolFilter(tree.sym)) { super.visitIdent(tree); } else { LambdaTranslationContext lambdaContext = (LambdaTranslationContext) context; if (lambdaContext.getSymbolMap(PARAM).containsKey(tree.sym)) { Symbol translatedSym = lambdaContext.getSymbolMap(PARAM).get(tree.sym); result = make.Ident(translatedSym).setType(tree.type); translatedSym.setTypeAttributes(tree.sym.getRawTypeAttributes()); } else if (lambdaContext.getSymbolMap(LOCAL_VAR).containsKey(tree.sym)) { Symbol translatedSym = lambdaContext.getSymbolMap(LOCAL_VAR).get(tree.sym); result = make.Ident(translatedSym).setType(tree.type); translatedSym.setTypeAttributes(tree.sym.getRawTypeAttributes()); } else if (lambdaContext.getSymbolMap(TYPE_VAR).containsKey(tree.sym)) { Symbol translatedSym = lambdaContext.getSymbolMap(TYPE_VAR).get(tree.sym); result = make.Ident(translatedSym).setType(translatedSym.type); translatedSym.setTypeAttributes(tree.sym.getRawTypeAttributes()); } else if (lambdaContext.getSymbolMap(CAPTURED_VAR).containsKey(tree.sym)) { Symbol translatedSym = lambdaContext.getSymbolMap(CAPTURED_VAR).get(tree.sym); result = make.Ident(translatedSym).setType(tree.type); } else { //access to untranslated symbols (i.e. compile-time constants, //members defined inside the lambda body, etc.) ) super.visitIdent(tree); } } } @Override public void visitVarDef(JCVariableDecl tree) { LambdaTranslationContext lambdaContext = (LambdaTranslationContext)context; if (context != null && lambdaContext.getSymbolMap(LOCAL_VAR).containsKey(tree.sym)) { JCExpression init = translate(tree.init); result = make.VarDef((VarSymbol)lambdaContext.getSymbolMap(LOCAL_VAR).get(tree.sym), init); } else if (context != null && lambdaContext.getSymbolMap(TYPE_VAR).containsKey(tree.sym)) { JCExpression init = translate(tree.init); VarSymbol xsym = (VarSymbol)lambdaContext.getSymbolMap(TYPE_VAR).get(tree.sym); result = make.VarDef(xsym, init); // Replace the entered symbol for this variable Scope sc = tree.sym.owner.members(); if (sc != null) { sc.remove(tree.sym); sc.enter(xsym); } } else { super.visitVarDef(tree); } } // </editor-fold> // <editor-fold defaultstate="collapsed" desc="Translation helper methods"> private JCBlock makeLambdaBody(JCLambda tree, JCMethodDecl lambdaMethodDecl) { return tree.getBodyKind() == JCLambda.BodyKind.EXPRESSION ? makeLambdaExpressionBody((JCExpression)tree.body, lambdaMethodDecl) : makeLambdaStatementBody((JCBlock)tree.body, lambdaMethodDecl, tree.canCompleteNormally); } private JCBlock makeLambdaExpressionBody(JCExpression expr, JCMethodDecl lambdaMethodDecl) { Type restype = lambdaMethodDecl.type.getReturnType(); boolean isLambda_void = expr.type.hasTag(VOID); boolean isTarget_void = restype.hasTag(VOID); boolean isTarget_Void = types.isSameType(restype, types.boxedClass(syms.voidType).type); if (isTarget_void) { //target is void: // BODY; JCStatement stat = make.Exec(expr); return make.Block(0, List.<JCStatement>of(stat)); } else if (isLambda_void && isTarget_Void) { //void to Void conversion: // BODY; return null; ListBuffer<JCStatement> stats = new ListBuffer<>(); stats.append(make.Exec(expr)); stats.append(make.Return(make.Literal(BOT, null).setType(syms.botType))); return make.Block(0, stats.toList()); } else { //non-void to non-void conversion: // return (TYPE)BODY; JCExpression retExpr = transTypes.coerce(attrEnv, expr, restype); return make.at(retExpr).Block(0, List.<JCStatement>of(make.Return(retExpr))); } } private JCBlock makeLambdaStatementBody(JCBlock block, final JCMethodDecl lambdaMethodDecl, boolean completeNormally) { final Type restype = lambdaMethodDecl.type.getReturnType(); final boolean isTarget_void = restype.hasTag(VOID); boolean isTarget_Void = types.isSameType(restype, types.boxedClass(syms.voidType).type); class LambdaBodyTranslator extends TreeTranslator { @Override public void visitClassDef(JCClassDecl tree) { //do NOT recurse on any inner classes result = tree; } @Override public void visitLambda(JCLambda tree) { //do NOT recurse on any nested lambdas result = tree; } @Override public void visitReturn(JCReturn tree) { boolean isLambda_void = tree.expr == null; if (isTarget_void && !isLambda_void) { //Void to void conversion: // { TYPE $loc = RET-EXPR; return; } VarSymbol loc = makeSyntheticVar(0, names.fromString("$loc"), tree.expr.type, lambdaMethodDecl.sym); JCVariableDecl varDef = make.VarDef(loc, tree.expr); result = make.Block(0, List.<JCStatement>of(varDef, make.Return(null))); } else if (!isTarget_void || !isLambda_void) { //non-void to non-void conversion: // return (TYPE)RET-EXPR; tree.expr = transTypes.coerce(attrEnv, tree.expr, restype); result = tree; } else { result = tree; } } } JCBlock trans_block = new LambdaBodyTranslator().translate(block); if (completeNormally && isTarget_Void) { //there's no return statement and the lambda (possibly inferred) //return type is java.lang.Void; emit a synthetic return statement trans_block.stats = trans_block.stats.append(make.Return(make.Literal(BOT, null).setType(syms.botType))); } return trans_block; } private JCMethodDecl makeDeserializeMethod(Symbol kSym) { ListBuffer<JCCase> cases = new ListBuffer<>(); ListBuffer<JCBreak> breaks = new ListBuffer<>(); for (Map.Entry<String, ListBuffer<JCStatement>> entry : kInfo.deserializeCases.entrySet()) { JCBreak br = make.Break(null); breaks.add(br); List<JCStatement> stmts = entry.getValue().append(br).toList(); cases.add(make.Case(make.Literal(entry.getKey()), stmts)); } JCSwitch sw = make.Switch(deserGetter("getImplMethodName", syms.stringType), cases.toList()); for (JCBreak br : breaks) { br.target = sw; } JCBlock body = make.Block(0L, List.<JCStatement>of( sw, make.Throw(makeNewClass( syms.illegalArgumentExceptionType, List.<JCExpression>of(make.Literal("Invalid lambda deserialization")))))); JCMethodDecl deser = make.MethodDef(make.Modifiers(kInfo.deserMethodSym.flags()), names.deserializeLambda, make.QualIdent(kInfo.deserMethodSym.getReturnType().tsym), List.<JCTypeParameter>nil(), List.of(make.VarDef(kInfo.deserParamSym, null)), List.<JCExpression>nil(), body, null); deser.sym = kInfo.deserMethodSym; deser.type = kInfo.deserMethodSym.type; //System.err.printf("DESER: '%s'\n", deser); return deser; } /** Make an attributed class instance creation expression. * @param ctype The class type. * @param args The constructor arguments. * @param cons The constructor symbol */ JCNewClass makeNewClass(Type ctype, List<JCExpression> args, Symbol cons) { JCNewClass tree = make.NewClass(null, null, make.QualIdent(ctype.tsym), args, null); tree.constructor = cons; tree.type = ctype; return tree; } /** Make an attributed class instance creation expression. * @param ctype The class type. * @param args The constructor arguments. */ JCNewClass makeNewClass(Type ctype, List<JCExpression> args) { return makeNewClass(ctype, args, rs.resolveConstructor(null, attrEnv, ctype, TreeInfo.types(args), List.<Type>nil())); } private void addDeserializationCase(int implMethodKind, Symbol refSym, Type targetType, MethodSymbol samSym, DiagnosticPosition pos, List<Object> staticArgs, MethodType indyType) { String functionalInterfaceClass = classSig(targetType); String functionalInterfaceMethodName = samSym.getSimpleName().toString(); String functionalInterfaceMethodSignature = methodSig(types.erasure(samSym.type)); String implClass = classSig(types.erasure(refSym.owner.type)); String implMethodName = refSym.getQualifiedName().toString(); String implMethodSignature = methodSig(types.erasure(refSym.type)); JCExpression kindTest = eqTest(syms.intType, deserGetter("getImplMethodKind", syms.intType), make.Literal(implMethodKind)); ListBuffer<JCExpression> serArgs = new ListBuffer<>(); int i = 0; for (Type t : indyType.getParameterTypes()) { List<JCExpression> indexAsArg = new ListBuffer<JCExpression>().append(make.Literal(i)).toList(); List<Type> argTypes = new ListBuffer<Type>().append(syms.intType).toList(); serArgs.add(make.TypeCast(types.erasure(t), deserGetter("getCapturedArg", syms.objectType, argTypes, indexAsArg))); ++i; } JCStatement stmt = make.If( deserTest(deserTest(deserTest(deserTest(deserTest( kindTest, "getFunctionalInterfaceClass", functionalInterfaceClass), "getFunctionalInterfaceMethodName", functionalInterfaceMethodName), "getFunctionalInterfaceMethodSignature", functionalInterfaceMethodSignature), "getImplClass", implClass), "getImplMethodSignature", implMethodSignature), make.Return(makeIndyCall( pos, syms.lambdaMetafactory, names.altMetafactory, staticArgs, indyType, serArgs.toList(), samSym.name)), null); ListBuffer<JCStatement> stmts = kInfo.deserializeCases.get(implMethodName); if (stmts == null) { stmts = new ListBuffer<>(); kInfo.deserializeCases.put(implMethodName, stmts); } /**** System.err.printf("+++++++++++++++++\n"); System.err.printf("*functionalInterfaceClass: '%s'\n", functionalInterfaceClass); System.err.printf("*functionalInterfaceMethodName: '%s'\n", functionalInterfaceMethodName); System.err.printf("*functionalInterfaceMethodSignature: '%s'\n", functionalInterfaceMethodSignature); System.err.printf("*implMethodKind: %d\n", implMethodKind); System.err.printf("*implClass: '%s'\n", implClass); System.err.printf("*implMethodName: '%s'\n", implMethodName); System.err.printf("*implMethodSignature: '%s'\n", implMethodSignature); ****/ stmts.append(stmt); } private JCExpression eqTest(Type argType, JCExpression arg1, JCExpression arg2) { JCBinary testExpr = make.Binary(JCTree.Tag.EQ, arg1, arg2); testExpr.operator = rs.resolveBinaryOperator(null, JCTree.Tag.EQ, attrEnv, argType, argType); testExpr.setType(syms.booleanType); return testExpr; } private JCExpression deserTest(JCExpression prev, String func, String lit) { MethodType eqmt = new MethodType(List.of(syms.objectType), syms.booleanType, List.<Type>nil(), syms.methodClass); Symbol eqsym = rs.resolveQualifiedMethod(null, attrEnv, syms.objectType, names.equals, List.of(syms.objectType), List.<Type>nil()); JCMethodInvocation eqtest = make.Apply( List.<JCExpression>nil(), make.Select(deserGetter(func, syms.stringType), eqsym).setType(eqmt), List.<JCExpression>of(make.Literal(lit))); eqtest.setType(syms.booleanType); JCBinary compound = make.Binary(JCTree.Tag.AND, prev, eqtest); compound.operator = rs.resolveBinaryOperator(null, JCTree.Tag.AND, attrEnv, syms.booleanType, syms.booleanType); compound.setType(syms.booleanType); return compound; } private JCExpression deserGetter(String func, Type type) { return deserGetter(func, type, List.<Type>nil(), List.<JCExpression>nil()); } private JCExpression deserGetter(String func, Type type, List<Type> argTypes, List<JCExpression> args) { MethodType getmt = new MethodType(argTypes, type, List.<Type>nil(), syms.methodClass); Symbol getsym = rs.resolveQualifiedMethod(null, attrEnv, syms.serializedLambdaType, names.fromString(func), argTypes, List.<Type>nil()); return make.Apply( List.<JCExpression>nil(), make.Select(make.Ident(kInfo.deserParamSym).setType(syms.serializedLambdaType), getsym).setType(getmt), args).setType(type); } /** * Create new synthetic method with given flags, name, type, owner */ private MethodSymbol makePrivateSyntheticMethod(long flags, Name name, Type type, Symbol owner) { return new MethodSymbol(flags | SYNTHETIC | PRIVATE, name, type, owner); } /** * Create new synthetic variable with given flags, name, type, owner */ private VarSymbol makeSyntheticVar(long flags, String name, Type type, Symbol owner) { return makeSyntheticVar(flags, names.fromString(name), type, owner); } /** * Create new synthetic variable with given flags, name, type, owner */ private VarSymbol makeSyntheticVar(long flags, Name name, Type type, Symbol owner) { return new VarSymbol(flags | SYNTHETIC, name, type, owner); } /** * Set varargsElement field on a given tree (must be either a new class tree * or a method call tree) */ private void setVarargsIfNeeded(JCTree tree, Type varargsElement) { if (varargsElement != null) { switch (tree.getTag()) { case APPLY: ((JCMethodInvocation)tree).varargsElement = varargsElement; break; case NEWCLASS: ((JCNewClass)tree).varargsElement = varargsElement; break; default: throw new AssertionError(); } } } /** * Convert method/constructor arguments by inserting appropriate cast * as required by type-erasure - this is needed when bridging a lambda/method * reference, as the bridged signature might require downcast to be compatible * with the generated signature. */ private List<JCExpression> convertArgs(Symbol meth, List<JCExpression> args, Type varargsElement) { Assert.check(meth.kind == Kinds.MTH); List<Type> formals = types.erasure(meth.type).getParameterTypes(); if (varargsElement != null) { Assert.check((meth.flags() & VARARGS) != 0); } return transTypes.translateArgs(args, formals, varargsElement, attrEnv); } // </editor-fold> /** * Generate an adapter method "bridge" for a method reference which cannot * be used directly. */ private class MemberReferenceBridger { private final JCMemberReference tree; private final ReferenceTranslationContext localContext; private final ListBuffer<JCExpression> args = new ListBuffer<>(); private final ListBuffer<JCVariableDecl> params = new ListBuffer<>(); MemberReferenceBridger(JCMemberReference tree, ReferenceTranslationContext localContext) { this.tree = tree; this.localContext = localContext; } /** * Generate the bridge */ JCMethodDecl bridge() { int prevPos = make.pos; try { make.at(tree); Type samDesc = localContext.bridgedRefSig(); List<Type> samPTypes = samDesc.getParameterTypes(); //an extra argument is prepended to the signature of the bridge in case //the member reference is an instance method reference (in which case //the receiver expression is passed to the bridge itself). Type recType = null; switch (tree.kind) { case IMPLICIT_INNER: recType = tree.sym.owner.type.getEnclosingType(); break; case BOUND: recType = tree.getQualifierExpression().type; break; case UNBOUND: recType = samPTypes.head; samPTypes = samPTypes.tail; break; } //generate the parameter list for the bridged member reference - the //bridge signature will match the signature of the target sam descriptor VarSymbol rcvr = (recType == null) ? null : addParameter("rec$", recType, false); List<Type> refPTypes = tree.sym.type.getParameterTypes(); int refSize = refPTypes.size(); int samSize = samPTypes.size(); // Last parameter to copy from referenced method int last = localContext.needsVarArgsConversion() ? refSize - 1 : refSize; List<Type> l = refPTypes; // Use parameter types of the referenced method, excluding final var args for (int i = 0; l.nonEmpty() && i < last; ++i) { addParameter("x$" + i, l.head, true); l = l.tail; } // Flatten out the var args for (int i = last; i < samSize; ++i) { addParameter("xva$" + i, tree.varargsElement, true); } //generate the bridge method declaration JCMethodDecl bridgeDecl = make.MethodDef(make.Modifiers(localContext.bridgeSym.flags()), localContext.bridgeSym.name, make.QualIdent(samDesc.getReturnType().tsym), List.<JCTypeParameter>nil(), params.toList(), tree.sym.type.getThrownTypes() == null ? List.<JCExpression>nil() : make.Types(tree.sym.type.getThrownTypes()), null, null); bridgeDecl.sym = (MethodSymbol) localContext.bridgeSym; bridgeDecl.type = localContext.bridgeSym.type = types.createMethodTypeWithParameters(samDesc, TreeInfo.types(params.toList())); //bridge method body generation - this can be either a method call or a //new instance creation expression, depending on the member reference kind JCExpression bridgeExpr = (tree.getMode() == ReferenceMode.INVOKE) ? bridgeExpressionInvoke(makeReceiver(rcvr)) : bridgeExpressionNew(); //the body is either a return expression containing a method call, //or the method call itself, depending on whether the return type of //the bridge is non-void/void. bridgeDecl.body = makeLambdaExpressionBody(bridgeExpr, bridgeDecl); return bridgeDecl; } finally { make.at(prevPos); } } //where private JCExpression makeReceiver(VarSymbol rcvr) { if (rcvr == null) return null; JCExpression rcvrExpr = make.Ident(rcvr); Type rcvrType = tree.sym.enclClass().type; if (!rcvr.type.tsym.isSubClass(rcvrType.tsym, types)) { rcvrExpr = make.TypeCast(make.Type(rcvrType), rcvrExpr).setType(rcvrType); } return rcvrExpr; } /** * determine the receiver of the bridged method call - the receiver can * be either the synthetic receiver parameter or a type qualifier; the * original qualifier expression is never used here, as it might refer * to symbols not available in the static context of the bridge */ private JCExpression bridgeExpressionInvoke(JCExpression rcvr) { JCExpression qualifier = tree.sym.isStatic() ? make.Type(tree.sym.owner.type) : (rcvr != null) ? rcvr : tree.getQualifierExpression(); //create the qualifier expression JCFieldAccess select = make.Select(qualifier, tree.sym.name); select.sym = tree.sym; select.type = tree.sym.erasure(types); //create the method call expression JCExpression apply = make.Apply(List.<JCExpression>nil(), select, convertArgs(tree.sym, args.toList(), tree.varargsElement)). setType(tree.sym.erasure(types).getReturnType()); apply = transTypes.coerce(apply, localContext.generatedRefSig().getReturnType()); setVarargsIfNeeded(apply, tree.varargsElement); return apply; } /** * the enclosing expression is either 'null' (no enclosing type) or set * to the first bridge synthetic parameter */ private JCExpression bridgeExpressionNew() { if (tree.kind == ReferenceKind.ARRAY_CTOR) { //create the array creation expression JCNewArray newArr = make.NewArray( make.Type(types.elemtype(tree.getQualifierExpression().type)), List.of(make.Ident(params.first())), null); newArr.type = tree.getQualifierExpression().type; return newArr; } else { JCExpression encl = null; switch (tree.kind) { case UNBOUND: case IMPLICIT_INNER: encl = make.Ident(params.first()); } //create the instance creation expression JCNewClass newClass = make.NewClass(encl, List.<JCExpression>nil(), make.Type(tree.getQualifierExpression().type), convertArgs(tree.sym, args.toList(), tree.varargsElement), null); newClass.constructor = tree.sym; newClass.constructorType = tree.sym.erasure(types); newClass.type = tree.getQualifierExpression().type; setVarargsIfNeeded(newClass, tree.varargsElement); return newClass; } } private VarSymbol addParameter(String name, Type p, boolean genArg) { VarSymbol vsym = new VarSymbol(0, names.fromString(name), p, localContext.bridgeSym); params.append(make.VarDef(vsym, null)); if (genArg) { args.append(make.Ident(vsym)); } return vsym; } } /** * Bridges a member reference - this is needed when: * * Var args in the referenced method need to be flattened away * * super is used */ private void bridgeMemberReference(JCMemberReference tree, ReferenceTranslationContext localContext) { kInfo.addMethod(new MemberReferenceBridger(tree, localContext).bridge()); } private MethodType typeToMethodType(Type mt) { Type type = types.erasure(mt); return new MethodType(type.getParameterTypes(), type.getReturnType(), type.getThrownTypes(), syms.methodClass); } /** * Generate an indy method call to the meta factory */ private JCExpression makeMetafactoryIndyCall(TranslationContext<?> context, int refKind, Symbol refSym, List<JCExpression> indy_args) { JCFunctionalExpression tree = context.tree; //determine the static bsm args MethodSymbol samSym = (MethodSymbol) types.findDescriptorSymbol(tree.type.tsym); List<Object> staticArgs = List.<Object>of( typeToMethodType(samSym.type), new Pool.MethodHandle(refKind, refSym, types), typeToMethodType(tree.getDescriptorType(types))); //computed indy arg types ListBuffer<Type> indy_args_types = new ListBuffer<>(); for (JCExpression arg : indy_args) { indy_args_types.append(arg.type); } //finally, compute the type of the indy call MethodType indyType = new MethodType(indy_args_types.toList(), tree.type, List.<Type>nil(), syms.methodClass); Name metafactoryName = context.needsAltMetafactory() ? names.altMetafactory : names.metafactory; if (context.needsAltMetafactory()) { ListBuffer<Object> markers = new ListBuffer<>(); for (Type t : tree.targets.tail) { if (t.tsym != syms.serializableType.tsym) { markers.append(t.tsym); } } int flags = context.isSerializable() ? FLAG_SERIALIZABLE : 0; boolean hasMarkers = markers.nonEmpty(); boolean hasBridges = context.bridges.nonEmpty(); if (hasMarkers) { flags |= FLAG_MARKERS; } if (hasBridges) { flags |= FLAG_BRIDGES; } staticArgs = staticArgs.append(flags); if (hasMarkers) { staticArgs = staticArgs.append(markers.length()); staticArgs = staticArgs.appendList(markers.toList()); } if (hasBridges) { staticArgs = staticArgs.append(context.bridges.length() - 1); for (Symbol s : context.bridges) { Type s_erasure = s.erasure(types); if (!types.isSameType(s_erasure, samSym.erasure(types))) { staticArgs = staticArgs.append(s.erasure(types)); } } } if (context.isSerializable()) { addDeserializationCase(refKind, refSym, tree.type, samSym, tree, staticArgs, indyType); } } return makeIndyCall(tree, syms.lambdaMetafactory, metafactoryName, staticArgs, indyType, indy_args, samSym.name); } /** * Generate an indy method call with given name, type and static bootstrap * arguments types */ private JCExpression makeIndyCall(DiagnosticPosition pos, Type site, Name bsmName, List<Object> staticArgs, MethodType indyType, List<JCExpression> indyArgs, Name methName) { int prevPos = make.pos; try { make.at(pos); List<Type> bsm_staticArgs = List.of(syms.methodHandleLookupType, syms.stringType, syms.methodTypeType).appendList(bsmStaticArgToTypes(staticArgs)); Symbol bsm = rs.resolveInternalMethod(pos, attrEnv, site, bsmName, bsm_staticArgs, List.<Type>nil()); DynamicMethodSymbol dynSym = new DynamicMethodSymbol(methName, syms.noSymbol, bsm.isStatic() ? ClassFile.REF_invokeStatic : ClassFile.REF_invokeVirtual, (MethodSymbol)bsm, indyType, staticArgs.toArray()); JCFieldAccess qualifier = make.Select(make.QualIdent(site.tsym), bsmName); qualifier.sym = dynSym; qualifier.type = indyType.getReturnType(); JCMethodInvocation proxyCall = make.Apply(List.<JCExpression>nil(), qualifier, indyArgs); proxyCall.type = indyType.getReturnType(); return proxyCall; } finally { make.at(prevPos); } } //where private List<Type> bsmStaticArgToTypes(List<Object> args) { ListBuffer<Type> argtypes = new ListBuffer<>(); for (Object arg : args) { argtypes.append(bsmStaticArgToType(arg)); } return argtypes.toList(); } private Type bsmStaticArgToType(Object arg) { Assert.checkNonNull(arg); if (arg instanceof ClassSymbol) { return syms.classType; } else if (arg instanceof Integer) { return syms.intType; } else if (arg instanceof Long) { return syms.longType; } else if (arg instanceof Float) { return syms.floatType; } else if (arg instanceof Double) { return syms.doubleType; } else if (arg instanceof String) { return syms.stringType; } else if (arg instanceof Pool.MethodHandle) { return syms.methodHandleType; } else if (arg instanceof MethodType) { return syms.methodTypeType; } else { Assert.error("bad static arg " + arg.getClass()); return null; } } /** * Get the opcode associated with this method reference */ private int referenceKind(Symbol refSym) { if (refSym.isConstructor()) { return ClassFile.REF_newInvokeSpecial; } else { if (refSym.isStatic()) { return ClassFile.REF_invokeStatic; } else if ((refSym.flags() & PRIVATE) != 0) { return ClassFile.REF_invokeSpecial; } else if (refSym.enclClass().isInterface()) { return ClassFile.REF_invokeInterface; } else { return ClassFile.REF_invokeVirtual; } } } // <editor-fold defaultstate="collapsed" desc="Lambda/reference analyzer"> /** * This visitor collects information about translation of a lambda expression. * More specifically, it keeps track of the enclosing contexts and captured locals * accessed by the lambda being translated (as well as other useful info). * It also translates away problems for LambdaToMethod. */ class LambdaAnalyzerPreprocessor extends TreeTranslator { /** the frame stack - used to reconstruct translation info about enclosing scopes */ private List<Frame> frameStack; /** * keep the count of lambda expression (used to generate unambiguous * names) */ private int lambdaCount = 0; /** * keep the count of lambda expression defined in given context (used to * generate unambiguous names for serializable lambdas) */ private Map<String, Integer> serializableLambdaCounts = new HashMap<String, Integer>(); private Map<Symbol, JCClassDecl> localClassDefs; /** * maps for fake clinit symbols to be used as owners of lambda occurring in * a static var init context */ private Map<ClassSymbol, Symbol> clinits = new HashMap<ClassSymbol, Symbol>(); private JCClassDecl analyzeAndPreprocessClass(JCClassDecl tree) { frameStack = List.nil(); localClassDefs = new HashMap<Symbol, JCClassDecl>(); return translate(tree); } @Override public void visitBlock(JCBlock tree) { List<Frame> prevStack = frameStack; try { if (frameStack.nonEmpty() && frameStack.head.tree.hasTag(CLASSDEF)) { frameStack = frameStack.prepend(new Frame(tree)); } super.visitBlock(tree); } finally { frameStack = prevStack; } } @Override public void visitClassDef(JCClassDecl tree) { List<Frame> prevStack = frameStack; Map<String, Integer> prevSerializableLambdaCount = serializableLambdaCounts; Map<ClassSymbol, Symbol> prevClinits = clinits; DiagnosticSource prevSource = log.currentSource(); try { log.useSource(tree.sym.sourcefile); serializableLambdaCounts = new HashMap<String, Integer>(); prevClinits = new HashMap<ClassSymbol, Symbol>(); if (tree.sym.owner.kind == MTH) { localClassDefs.put(tree.sym, tree); } if (directlyEnclosingLambda() != null) { tree.sym.owner = owner(); if (tree.sym.hasOuterInstance()) { //if a class is defined within a lambda, the lambda must capture //its enclosing instance (if any) TranslationContext<?> localContext = context(); while (localContext != null) { if (localContext.tree.getTag() == LAMBDA) { ((LambdaTranslationContext)localContext) .addSymbol(tree.sym.type.getEnclosingType().tsym, CAPTURED_THIS); } localContext = localContext.prev; } } } frameStack = frameStack.prepend(new Frame(tree)); super.visitClassDef(tree); } finally { log.useSource(prevSource.getFile()); frameStack = prevStack; serializableLambdaCounts = prevSerializableLambdaCount; clinits = prevClinits; } } @Override public void visitIdent(JCIdent tree) { if (context() != null && lambdaIdentSymbolFilter(tree.sym)) { if (tree.sym.kind == VAR && tree.sym.owner.kind == MTH && tree.type.constValue() == null) { TranslationContext<?> localContext = context(); while (localContext != null) { if (localContext.tree.getTag() == LAMBDA) { JCTree block = capturedDecl(localContext.depth, tree.sym); if (block == null) break; ((LambdaTranslationContext)localContext) .addSymbol(tree.sym, CAPTURED_VAR); } localContext = localContext.prev; } } else if (tree.sym.owner.kind == TYP) { TranslationContext<?> localContext = context(); while (localContext != null) { if (localContext.tree.hasTag(LAMBDA)) { JCTree block = capturedDecl(localContext.depth, tree.sym); if (block == null) break; switch (block.getTag()) { case CLASSDEF: JCClassDecl cdecl = (JCClassDecl)block; ((LambdaTranslationContext)localContext) .addSymbol(cdecl.sym, CAPTURED_THIS); break; default: Assert.error("bad block kind"); } } localContext = localContext.prev; } } } super.visitIdent(tree); } @Override public void visitLambda(JCLambda tree) { List<Frame> prevStack = frameStack; try { LambdaTranslationContext context = (LambdaTranslationContext)makeLambdaContext(tree); frameStack = frameStack.prepend(new Frame(tree)); for (JCVariableDecl param : tree.params) { context.addSymbol(param.sym, PARAM); frameStack.head.addLocal(param.sym); } contextMap.put(tree, context); super.visitLambda(tree); context.complete(); } finally { frameStack = prevStack; } } @Override public void visitMethodDef(JCMethodDecl tree) { List<Frame> prevStack = frameStack; try { frameStack = frameStack.prepend(new Frame(tree)); super.visitMethodDef(tree); } finally { frameStack = prevStack; } } @Override public void visitNewClass(JCNewClass tree) { if (lambdaNewClassFilter(context(), tree)) { TranslationContext<?> localContext = context(); while (localContext != null) { if (localContext.tree.getTag() == LAMBDA) { ((LambdaTranslationContext)localContext) .addSymbol(tree.type.getEnclosingType().tsym, CAPTURED_THIS); } localContext = localContext.prev; } } if (context() != null && tree.type.tsym.owner.kind == MTH) { LambdaTranslationContext lambdaContext = (LambdaTranslationContext)context(); captureLocalClassDefs(tree.type.tsym, lambdaContext); } super.visitNewClass(tree); } //where void captureLocalClassDefs(Symbol csym, final LambdaTranslationContext lambdaContext) { JCClassDecl localCDef = localClassDefs.get(csym); if (localCDef != null && localCDef.pos < lambdaContext.tree.pos) { BasicFreeVarCollector fvc = lower.new BasicFreeVarCollector() { @Override void addFreeVars(ClassSymbol c) { captureLocalClassDefs(c, lambdaContext); } @Override void visitSymbol(Symbol sym) { if (sym.kind == VAR && sym.owner.kind == MTH && ((VarSymbol)sym).getConstValue() == null) { TranslationContext<?> localContext = context(); while (localContext != null) { if (localContext.tree.getTag() == LAMBDA) { JCTree block = capturedDecl(localContext.depth, sym); if (block == null) break; ((LambdaTranslationContext)localContext).addSymbol(sym, CAPTURED_VAR); } localContext = localContext.prev; } } } }; fvc.scan(localCDef); } } /** * Method references to local class constructors, may, if the local * class references local variables, have implicit constructor * parameters added in Lower; As a result, the invokedynamic bootstrap * information added in the LambdaToMethod pass will have the wrong * signature. Hooks between Lower and LambdaToMethod have been added to * handle normal "new" in this case. This visitor converts potentially * effected method references into a lambda containing a normal "new" of * the class. * * @param tree */ @Override public void visitReference(JCMemberReference tree) { if (tree.getMode() == ReferenceMode.NEW && tree.kind != ReferenceKind.ARRAY_CTOR && tree.sym.owner.isLocal()) { MethodSymbol consSym = (MethodSymbol) tree.sym; List<Type> ptypes = ((MethodType) consSym.type).getParameterTypes(); Type classType = consSym.owner.type; // Build lambda parameters // partially cloned from TreeMaker.Params until 8014021 is fixed Symbol owner = owner(); ListBuffer<JCVariableDecl> paramBuff = new ListBuffer<JCVariableDecl>(); int i = 0; for (List<Type> l = ptypes; l.nonEmpty(); l = l.tail) { paramBuff.append(make.Param(make.paramName(i++), l.head, owner)); } List<JCVariableDecl> params = paramBuff.toList(); // Make new-class call JCNewClass nc = makeNewClass(classType, make.Idents(params)); nc.pos = tree.pos; // Make lambda holding the new-class call JCLambda slam = make.Lambda(params, nc); slam.targets = tree.targets; slam.type = tree.type; slam.pos = tree.pos; // Now it is a lambda, process as such visitLambda(slam); } else { super.visitReference(tree); contextMap.put(tree, makeReferenceContext(tree)); } } @Override public void visitSelect(JCFieldAccess tree) { if (context() != null && tree.sym.kind == VAR && (tree.sym.name == names._this || tree.sym.name == names._super)) { // A select of this or super means, if we are in a lambda, // we much have an instance context TranslationContext<?> localContext = context(); while (localContext != null) { if (localContext.tree.hasTag(LAMBDA)) { JCClassDecl clazz = (JCClassDecl)capturedDecl(localContext.depth, tree.sym); if (clazz == null) break; ((LambdaTranslationContext)localContext).addSymbol(clazz.sym, CAPTURED_THIS); } localContext = localContext.prev; } } super.visitSelect(tree); } @Override public void visitVarDef(JCVariableDecl tree) { TranslationContext<?> context = context(); LambdaTranslationContext ltc = (context != null && context instanceof LambdaTranslationContext)? (LambdaTranslationContext)context : null; if (ltc != null) { if (frameStack.head.tree.hasTag(LAMBDA)) { ltc.addSymbol(tree.sym, LOCAL_VAR); } // Check for type variables (including as type arguments). // If they occur within class nested in a lambda, mark for erasure Type type = tree.sym.asType(); if (inClassWithinLambda() && !types.isSameType(types.erasure(type), type)) { ltc.addSymbol(tree.sym, TYPE_VAR); } } List<Frame> prevStack = frameStack; try { if (tree.sym.owner.kind == MTH) { frameStack.head.addLocal(tree.sym); } frameStack = frameStack.prepend(new Frame(tree)); super.visitVarDef(tree); } finally { frameStack = prevStack; } } private Name lambdaName() { return names.lambda.append(names.fromString("" + lambdaCount++)); } /** * For a serializable lambda, generate a name which maximizes name * stability across deserialization. * @param owner * @return Name to use for the synthetic lambda method name */ private Name serializedLambdaName(Symbol owner) { StringBuilder buf = new StringBuilder(); buf.append(names.lambda); // Append the name of the method enclosing the lambda. String methodName = owner.name.toString(); if (methodName.equals("<clinit>")) methodName = "static"; else if (methodName.equals("<init>")) methodName = "new"; buf.append(methodName); buf.append('$'); // Append a hash of the enclosing method signature to differentiate // overloaded enclosing methods. For lambdas enclosed in lambdas, // the generated lambda method will not have type yet, but the // enclosing method's name will have been generated with this same // method, so it will be unique and never be overloaded. Assert.check(owner.type != null || directlyEnclosingLambda() != null); if (owner.type != null) { int methTypeHash = methodSig(owner.type).hashCode(); buf.append(Integer.toHexString(methTypeHash)); } buf.append('$'); // The above appended name components may not be unique, append a // count based on the above name components. String temp = buf.toString(); Integer count = serializableLambdaCounts.get(temp); if (count == null) { count = 0; } buf.append(count++); serializableLambdaCounts.put(temp, count); return names.fromString(buf.toString()); } /** * Return a valid owner given the current declaration stack * (required to skip synthetic lambda symbols) */ private Symbol owner() { return owner(false); } @SuppressWarnings("fallthrough") private Symbol owner(boolean skipLambda) { List<Frame> frameStack2 = frameStack; while (frameStack2.nonEmpty()) { switch (frameStack2.head.tree.getTag()) { case VARDEF: if (((JCVariableDecl)frameStack2.head.tree).sym.isLocal()) { frameStack2 = frameStack2.tail; break; } JCClassDecl cdecl = (JCClassDecl)frameStack2.tail.head.tree; return initSym(cdecl.sym, ((JCVariableDecl)frameStack2.head.tree).sym.flags() & STATIC); case BLOCK: JCClassDecl cdecl2 = (JCClassDecl)frameStack2.tail.head.tree; return initSym(cdecl2.sym, ((JCBlock)frameStack2.head.tree).flags & STATIC); case CLASSDEF: return ((JCClassDecl)frameStack2.head.tree).sym; case METHODDEF: return ((JCMethodDecl)frameStack2.head.tree).sym; case LAMBDA: if (!skipLambda) return ((LambdaTranslationContext)contextMap .get(frameStack2.head.tree)).translatedSym; default: frameStack2 = frameStack2.tail; } } Assert.error(); return null; } private Symbol initSym(ClassSymbol csym, long flags) { boolean isStatic = (flags & STATIC) != 0; if (isStatic) { //static clinits are generated in Gen - so we need to fake them Symbol clinit = clinits.get(csym); if (clinit == null) { clinit = makePrivateSyntheticMethod(STATIC, names.clinit, new MethodType(List.<Type>nil(), syms.voidType, List.<Type>nil(), syms.methodClass), csym); clinits.put(csym, clinit); } return clinit; } else { //get the first constructor and treat it as the instance init sym for (Symbol s : csym.members_field.getElementsByName(names.init)) { return s; } } Assert.error("init not found"); return null; } private JCTree directlyEnclosingLambda() { if (frameStack.isEmpty()) { return null; } List<Frame> frameStack2 = frameStack; while (frameStack2.nonEmpty()) { switch (frameStack2.head.tree.getTag()) { case CLASSDEF: case METHODDEF: return null; case LAMBDA: return frameStack2.head.tree; default: frameStack2 = frameStack2.tail; } } Assert.error(); return null; } private boolean inClassWithinLambda() { if (frameStack.isEmpty()) { return false; } List<Frame> frameStack2 = frameStack; boolean classFound = false; while (frameStack2.nonEmpty()) { switch (frameStack2.head.tree.getTag()) { case LAMBDA: return classFound; case CLASSDEF: classFound = true; frameStack2 = frameStack2.tail; break; default: frameStack2 = frameStack2.tail; } } // No lambda return false; } /** * Return the declaration corresponding to a symbol in the enclosing * scope; the depth parameter is used to filter out symbols defined * in nested scopes (which do not need to undergo capture). */ private JCTree capturedDecl(int depth, Symbol sym) { int currentDepth = frameStack.size() - 1; for (Frame block : frameStack) { switch (block.tree.getTag()) { case CLASSDEF: ClassSymbol clazz = ((JCClassDecl)block.tree).sym; if (sym.isMemberOf(clazz, types)) { return currentDepth > depth ? null : block.tree; } break; case VARDEF: if (((JCVariableDecl)block.tree).sym == sym && sym.owner.kind == MTH) { //only locals are captured return currentDepth > depth ? null : block.tree; } break; case BLOCK: case METHODDEF: case LAMBDA: if (block.locals != null && block.locals.contains(sym)) { return currentDepth > depth ? null : block.tree; } break; default: Assert.error("bad decl kind " + block.tree.getTag()); } currentDepth--; } return null; } private TranslationContext<?> context() { for (Frame frame : frameStack) { TranslationContext<?> context = contextMap.get(frame.tree); if (context != null) { return context; } } return null; } /** * This is used to filter out those identifiers that needs to be adjusted * when translating away lambda expressions */ private boolean lambdaIdentSymbolFilter(Symbol sym) { return (sym.kind == VAR || sym.kind == MTH) && !sym.isStatic() && sym.name != names.init; } /** * This is used to filter out those new class expressions that need to * be qualified with an enclosing tree */ private boolean lambdaNewClassFilter(TranslationContext<?> context, JCNewClass tree) { if (context != null && tree.encl == null && tree.def == null && !tree.type.getEnclosingType().hasTag(NONE)) { Type encl = tree.type.getEnclosingType(); Type current = context.owner.enclClass().type; while (!current.hasTag(NONE)) { if (current.tsym.isSubClass(encl.tsym, types)) { return true; } current = current.getEnclosingType(); } return false; } else { return false; } } private TranslationContext<JCLambda> makeLambdaContext(JCLambda tree) { return new LambdaTranslationContext(tree); } private TranslationContext<JCMemberReference> makeReferenceContext(JCMemberReference tree) { return new ReferenceTranslationContext(tree); } private class Frame { final JCTree tree; List<Symbol> locals; public Frame(JCTree tree) { this.tree = tree; } void addLocal(Symbol sym) { if (locals == null) { locals = List.nil(); } locals = locals.prepend(sym); } } /** * This class is used to store important information regarding translation of * lambda expression/method references (see subclasses). */ private abstract class TranslationContext<T extends JCFunctionalExpression> { /** the underlying (untranslated) tree */ T tree; /** points to the adjusted enclosing scope in which this lambda/mref expression occurs */ Symbol owner; /** the depth of this lambda expression in the frame stack */ int depth; /** the enclosing translation context (set for nested lambdas/mref) */ TranslationContext<?> prev; /** list of methods to be bridged by the meta-factory */ List<Symbol> bridges; TranslationContext(T tree) { this.tree = tree; this.owner = owner(); this.depth = frameStack.size() - 1; this.prev = context(); ClassSymbol csym = types.makeFunctionalInterfaceClass(attrEnv, names.empty, tree.targets, ABSTRACT | INTERFACE); this.bridges = types.functionalInterfaceBridges(csym); } /** does this functional expression need to be created using alternate metafactory? */ boolean needsAltMetafactory() { return tree.targets.length() > 1 || isSerializable() || bridges.length() > 1; } /** does this functional expression require serialization support? */ boolean isSerializable() { for (Type target : tree.targets) { if (types.asSuper(target, syms.serializableType.tsym) != null) { return true; } } return false; } } /** * This class retains all the useful information about a lambda expression; * the contents of this class are filled by the LambdaAnalyzer visitor, * and the used by the main translation routines in order to adjust references * to captured locals/members, etc. */ private class LambdaTranslationContext extends TranslationContext<JCLambda> { /** variable in the enclosing context to which this lambda is assigned */ Symbol self; /** map from original to translated lambda parameters */ Map<Symbol, Symbol> lambdaParams = new LinkedHashMap<Symbol, Symbol>(); /** map from original to translated lambda locals */ Map<Symbol, Symbol> lambdaLocals = new LinkedHashMap<Symbol, Symbol>(); /** map from variables in enclosing scope to translated synthetic parameters */ Map<Symbol, Symbol> capturedLocals = new LinkedHashMap<Symbol, Symbol>(); /** map from class symbols to translated synthetic parameters (for captured member access) */ Map<Symbol, Symbol> capturedThis = new LinkedHashMap<Symbol, Symbol>(); /** map from original to translated lambda locals */ Map<Symbol, Symbol> typeVars = new LinkedHashMap<Symbol, Symbol>(); /** the synthetic symbol for the method hoisting the translated lambda */ Symbol translatedSym; List<JCVariableDecl> syntheticParams; LambdaTranslationContext(JCLambda tree) { super(tree); Frame frame = frameStack.head; if (frame.tree.hasTag(VARDEF)) { self = ((JCVariableDecl)frame.tree).sym; } Name name = isSerializable() ? serializedLambdaName(owner) : lambdaName(); this.translatedSym = makePrivateSyntheticMethod(0, name, null, owner.enclClass()); if (dumpLambdaToMethodStats) { log.note(tree, "lambda.stat", needsAltMetafactory(), translatedSym); } } /** * Translate a symbol of a given kind into something suitable for the * synthetic lambda body */ Symbol translate(Name name, final Symbol sym, LambdaSymbolKind skind) { Symbol ret; switch (skind) { case CAPTURED_THIS: ret = sym; // self represented break; case TYPE_VAR: // Just erase the type var ret = new VarSymbol(sym.flags(), name, types.erasure(sym.type), sym.owner); /* this information should also be kept for LVT generation at Gen * a Symbol with pos < startPos won't be tracked. */ ((VarSymbol)ret).pos = ((VarSymbol)sym).pos; break; case CAPTURED_VAR: ret = new VarSymbol(SYNTHETIC | FINAL, name, types.erasure(sym.type), translatedSym) { @Override public Symbol baseSymbol() { //keep mapping with original captured symbol return sym; } }; break; default: ret = makeSyntheticVar(FINAL, name, types.erasure(sym.type), translatedSym); } if (ret != sym) { ret.setDeclarationAttributes(sym.getRawAttributes()); ret.setTypeAttributes(sym.getRawTypeAttributes()); } return ret; } void addSymbol(Symbol sym, LambdaSymbolKind skind) { Map<Symbol, Symbol> transMap = null; Name preferredName; switch (skind) { case CAPTURED_THIS: transMap = capturedThis; preferredName = names.fromString("encl$" + capturedThis.size()); break; case CAPTURED_VAR: transMap = capturedLocals; preferredName = names.fromString("cap$" + capturedLocals.size()); break; case LOCAL_VAR: transMap = lambdaLocals; preferredName = sym.name; break; case PARAM: transMap = lambdaParams; preferredName = sym.name; break; case TYPE_VAR: transMap = typeVars; preferredName = sym.name; break; default: throw new AssertionError(); } if (!transMap.containsKey(sym)) { transMap.put(sym, translate(preferredName, sym, skind)); } } Map<Symbol, Symbol> getSymbolMap(LambdaSymbolKind... skinds) { LinkedHashMap<Symbol, Symbol> translationMap = new LinkedHashMap<Symbol, Symbol>(); for (LambdaSymbolKind skind : skinds) { switch (skind) { case CAPTURED_THIS: translationMap.putAll(capturedThis); break; case CAPTURED_VAR: translationMap.putAll(capturedLocals); break; case LOCAL_VAR: translationMap.putAll(lambdaLocals); break; case PARAM: translationMap.putAll(lambdaParams); break; case TYPE_VAR: translationMap.putAll(typeVars); break; default: throw new AssertionError(); } } return translationMap; } /** * The translatedSym is not complete/accurate until the analysis is * finished. Once the analysis is finished, the translatedSym is * "completed" -- updated with type information, access modifiers, * and full parameter list. */ void complete() { if (syntheticParams != null) { return; } boolean inInterface = translatedSym.owner.isInterface(); boolean thisReferenced = !getSymbolMap(CAPTURED_THIS).isEmpty(); // If instance access isn't needed, make it static. // Interface instance methods must be default methods. // Lambda methods are private synthetic. translatedSym.flags_field = SYNTHETIC | PRIVATE | (thisReferenced? (inInterface? DEFAULT : 0) : STATIC); //compute synthetic params ListBuffer<JCVariableDecl> params = new ListBuffer<>(); // The signature of the method is augmented with the following // synthetic parameters: // // 1) reference to enclosing contexts captured by the lambda expression // 2) enclosing locals captured by the lambda expression for (Symbol thisSym : getSymbolMap(CAPTURED_VAR, PARAM).values()) { params.append(make.VarDef((VarSymbol) thisSym, null)); } syntheticParams = params.toList(); //prepend synthetic args to translated lambda method signature translatedSym.type = types.createMethodTypeWithParameters( generatedLambdaSig(), TreeInfo.types(syntheticParams)); } Type generatedLambdaSig() { return types.erasure(tree.getDescriptorType(types)); } } /** * This class retains all the useful information about a method reference; * the contents of this class are filled by the LambdaAnalyzer visitor, * and the used by the main translation routines in order to adjust method * references (i.e. in case a bridge is needed) */ private class ReferenceTranslationContext extends TranslationContext<JCMemberReference> { final boolean isSuper; final Symbol bridgeSym; ReferenceTranslationContext(JCMemberReference tree) { super(tree); this.isSuper = tree.hasKind(ReferenceKind.SUPER); this.bridgeSym = needsBridge() ? makePrivateSyntheticMethod(isSuper ? 0 : STATIC, lambdaName().append(names.fromString("$bridge")), null, owner.enclClass()) : null; if (dumpLambdaToMethodStats) { String key = bridgeSym == null ? "mref.stat" : "mref.stat.1"; log.note(tree, key, needsAltMetafactory(), bridgeSym); } } /** * Get the opcode associated with this method reference */ int referenceKind() { return LambdaToMethod.this.referenceKind(needsBridge() ? bridgeSym : tree.sym); } boolean needsVarArgsConversion() { return tree.varargsElement != null; } /** * @return Is this an array operation like clone() */ boolean isArrayOp() { return tree.sym.owner == syms.arrayClass; } boolean isPrivateConstructor() { //hack needed to workaround 292 bug (8005122) //when 292 issue is fixed we should simply remove this return tree.sym.name == names.init && (tree.sym.flags() & PRIVATE) != 0; } boolean receiverAccessible() { //hack needed to workaround 292 bug (7087658) //when 292 issue is fixed we should remove this and change the backend //code to always generate a method handle to an accessible method return tree.ownerAccessible; } /** * Does this reference needs a bridge (i.e. var args need to be * expanded or "super" is used) */ final boolean needsBridge() { return isSuper || needsVarArgsConversion() || isArrayOp() || isPrivateConstructor() || !receiverAccessible(); } Type generatedRefSig() { return types.erasure(tree.sym.type); } Type bridgedRefSig() { return types.erasure(types.findDescriptorSymbol(tree.targets.head.tsym).type); } } } // </editor-fold> enum LambdaSymbolKind { CAPTURED_VAR, CAPTURED_THIS, LOCAL_VAR, PARAM, TYPE_VAR; } /** * **************************************************************** * Signature Generation * **************************************************************** */ private String methodSig(Type type) { L2MSignatureGenerator sg = new L2MSignatureGenerator(); sg.assembleSig(type); return sg.toString(); } private String classSig(Type type) { L2MSignatureGenerator sg = new L2MSignatureGenerator(); sg.assembleClassSig(type); return sg.toString(); } /** * Signature Generation */ private class L2MSignatureGenerator extends Types.SignatureGenerator { /** * An output buffer for type signatures. */ StringBuilder sb = new StringBuilder(); L2MSignatureGenerator() { super(types); } @Override protected void append(char ch) { sb.append(ch); } @Override protected void append(byte[] ba) { sb.append(new String(ba)); } @Override protected void append(Name name) { sb.append(name.toString()); } @Override public String toString() { return sb.toString(); } } }