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/*
 * Copyright 2010 Google Inc.
 *
 * Licensed under the Apache License, Version 2.0 (the "License"); you may not
 * use this file except in compliance with the License. You may obtain a copy of
 * the License at
 *
 * http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
 * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
 * License for the specific language governing permissions and limitations under
 * the License.
 */
package com.google.gwt.dev.jjs.impl;

import com.google.gwt.dev.CompilerContext;
import com.google.gwt.dev.common.InliningMode;
import com.google.gwt.dev.javac.JdtUtil;
import com.google.gwt.dev.javac.JsInteropUtil;
import com.google.gwt.dev.javac.JsniMethod;
import com.google.gwt.dev.jdt.SafeASTVisitor;
import com.google.gwt.dev.jjs.InternalCompilerException;
import com.google.gwt.dev.jjs.SourceInfo;
import com.google.gwt.dev.jjs.SourceOrigin;
import com.google.gwt.dev.jjs.ast.AccessModifier;
import com.google.gwt.dev.jjs.ast.CanHaveSuppressedWarnings;
import com.google.gwt.dev.jjs.ast.HasJsInfo;
import com.google.gwt.dev.jjs.ast.HasJsInfo.JsMemberType;
import com.google.gwt.dev.jjs.ast.JArrayLength;
import com.google.gwt.dev.jjs.ast.JArrayRef;
import com.google.gwt.dev.jjs.ast.JArrayType;
import com.google.gwt.dev.jjs.ast.JAssertStatement;
import com.google.gwt.dev.jjs.ast.JBinaryOperation;
import com.google.gwt.dev.jjs.ast.JBinaryOperator;
import com.google.gwt.dev.jjs.ast.JBlock;
import com.google.gwt.dev.jjs.ast.JBooleanLiteral;
import com.google.gwt.dev.jjs.ast.JBreakStatement;
import com.google.gwt.dev.jjs.ast.JCaseStatement;
import com.google.gwt.dev.jjs.ast.JCastOperation;
import com.google.gwt.dev.jjs.ast.JCharLiteral;
import com.google.gwt.dev.jjs.ast.JClassLiteral;
import com.google.gwt.dev.jjs.ast.JClassType;
import com.google.gwt.dev.jjs.ast.JConditional;
import com.google.gwt.dev.jjs.ast.JConstructor;
import com.google.gwt.dev.jjs.ast.JContinueStatement;
import com.google.gwt.dev.jjs.ast.JDeclarationStatement;
import com.google.gwt.dev.jjs.ast.JDeclaredType;
import com.google.gwt.dev.jjs.ast.JDoStatement;
import com.google.gwt.dev.jjs.ast.JDoubleLiteral;
import com.google.gwt.dev.jjs.ast.JEnumField;
import com.google.gwt.dev.jjs.ast.JEnumType;
import com.google.gwt.dev.jjs.ast.JExpression;
import com.google.gwt.dev.jjs.ast.JExpressionStatement;
import com.google.gwt.dev.jjs.ast.JField;
import com.google.gwt.dev.jjs.ast.JField.Disposition;
import com.google.gwt.dev.jjs.ast.JFieldRef;
import com.google.gwt.dev.jjs.ast.JFloatLiteral;
import com.google.gwt.dev.jjs.ast.JForStatement;
import com.google.gwt.dev.jjs.ast.JIfStatement;
import com.google.gwt.dev.jjs.ast.JInstanceOf;
import com.google.gwt.dev.jjs.ast.JIntLiteral;
import com.google.gwt.dev.jjs.ast.JInterfaceType;
import com.google.gwt.dev.jjs.ast.JLabel;
import com.google.gwt.dev.jjs.ast.JLabeledStatement;
import com.google.gwt.dev.jjs.ast.JLiteral;
import com.google.gwt.dev.jjs.ast.JLocal;
import com.google.gwt.dev.jjs.ast.JLocalRef;
import com.google.gwt.dev.jjs.ast.JLongLiteral;
import com.google.gwt.dev.jjs.ast.JMember;
import com.google.gwt.dev.jjs.ast.JMethod;
import com.google.gwt.dev.jjs.ast.JMethodBody;
import com.google.gwt.dev.jjs.ast.JMethodCall;
import com.google.gwt.dev.jjs.ast.JNewArray;
import com.google.gwt.dev.jjs.ast.JNewInstance;
import com.google.gwt.dev.jjs.ast.JNode;
import com.google.gwt.dev.jjs.ast.JNullLiteral;
import com.google.gwt.dev.jjs.ast.JParameter;
import com.google.gwt.dev.jjs.ast.JParameterRef;
import com.google.gwt.dev.jjs.ast.JPostfixOperation;
import com.google.gwt.dev.jjs.ast.JPrefixOperation;
import com.google.gwt.dev.jjs.ast.JPrimitiveType;
import com.google.gwt.dev.jjs.ast.JProgram;
import com.google.gwt.dev.jjs.ast.JReferenceType;
import com.google.gwt.dev.jjs.ast.JReturnStatement;
import com.google.gwt.dev.jjs.ast.JStatement;
import com.google.gwt.dev.jjs.ast.JStringLiteral;
import com.google.gwt.dev.jjs.ast.JSwitchStatement;
import com.google.gwt.dev.jjs.ast.JThisRef;
import com.google.gwt.dev.jjs.ast.JThrowStatement;
import com.google.gwt.dev.jjs.ast.JTryStatement;
import com.google.gwt.dev.jjs.ast.JType;
import com.google.gwt.dev.jjs.ast.JUnaryOperator;
import com.google.gwt.dev.jjs.ast.JUnsafeTypeCoercion;
import com.google.gwt.dev.jjs.ast.JVariable;
import com.google.gwt.dev.jjs.ast.JWhileStatement;
import com.google.gwt.dev.jjs.ast.js.JMultiExpression;
import com.google.gwt.dev.jjs.ast.js.JsniClassLiteral;
import com.google.gwt.dev.jjs.ast.js.JsniFieldRef;
import com.google.gwt.dev.jjs.ast.js.JsniMethodBody;
import com.google.gwt.dev.jjs.ast.js.JsniMethodRef;
import com.google.gwt.dev.js.JsAbstractSymbolResolver;
import com.google.gwt.dev.js.ast.JsContext;
import com.google.gwt.dev.js.ast.JsExpression;
import com.google.gwt.dev.js.ast.JsFunction;
import com.google.gwt.dev.js.ast.JsModVisitor;
import com.google.gwt.dev.js.ast.JsName;
import com.google.gwt.dev.js.ast.JsNameRef;
import com.google.gwt.dev.js.ast.JsNode;
import com.google.gwt.dev.js.ast.JsParameter;
import com.google.gwt.dev.util.StringInterner;
import com.google.gwt.dev.util.collect.Stack;
import com.google.gwt.thirdparty.guava.common.base.Function;
import com.google.gwt.thirdparty.guava.common.base.Joiner;
import com.google.gwt.thirdparty.guava.common.base.Preconditions;
import com.google.gwt.thirdparty.guava.common.base.Predicate;
import com.google.gwt.thirdparty.guava.common.base.Predicates;
import com.google.gwt.thirdparty.guava.common.collect.Collections2;
import com.google.gwt.thirdparty.guava.common.collect.FluentIterable;
import com.google.gwt.thirdparty.guava.common.collect.Interner;
import com.google.gwt.thirdparty.guava.common.collect.Iterables;
import com.google.gwt.thirdparty.guava.common.collect.Lists;
import com.google.gwt.thirdparty.guava.common.collect.Maps;
import com.google.gwt.thirdparty.guava.common.collect.Sets;
import com.google.gwt.util.regexfilter.WhitelistRegexFilter;

import org.eclipse.jdt.internal.compiler.ast.AND_AND_Expression;
import org.eclipse.jdt.internal.compiler.ast.ASTNode;
import org.eclipse.jdt.internal.compiler.ast.AbstractMethodDeclaration;
import org.eclipse.jdt.internal.compiler.ast.AllocationExpression;
import org.eclipse.jdt.internal.compiler.ast.Annotation;
import org.eclipse.jdt.internal.compiler.ast.AnnotationMethodDeclaration;
import org.eclipse.jdt.internal.compiler.ast.Argument;
import org.eclipse.jdt.internal.compiler.ast.ArrayAllocationExpression;
import org.eclipse.jdt.internal.compiler.ast.ArrayInitializer;
import org.eclipse.jdt.internal.compiler.ast.ArrayReference;
import org.eclipse.jdt.internal.compiler.ast.AssertStatement;
import org.eclipse.jdt.internal.compiler.ast.Assignment;
import org.eclipse.jdt.internal.compiler.ast.BinaryExpression;
import org.eclipse.jdt.internal.compiler.ast.Block;
import org.eclipse.jdt.internal.compiler.ast.BreakStatement;
import org.eclipse.jdt.internal.compiler.ast.CaseStatement;
import org.eclipse.jdt.internal.compiler.ast.CastExpression;
import org.eclipse.jdt.internal.compiler.ast.CharLiteral;
import org.eclipse.jdt.internal.compiler.ast.ClassLiteralAccess;
import org.eclipse.jdt.internal.compiler.ast.Clinit;
import org.eclipse.jdt.internal.compiler.ast.CompilationUnitDeclaration;
import org.eclipse.jdt.internal.compiler.ast.CompoundAssignment;
import org.eclipse.jdt.internal.compiler.ast.ConditionalExpression;
import org.eclipse.jdt.internal.compiler.ast.ConstructorDeclaration;
import org.eclipse.jdt.internal.compiler.ast.ContinueStatement;
import org.eclipse.jdt.internal.compiler.ast.DoStatement;
import org.eclipse.jdt.internal.compiler.ast.DoubleLiteral;
import org.eclipse.jdt.internal.compiler.ast.EmptyStatement;
import org.eclipse.jdt.internal.compiler.ast.EqualExpression;
import org.eclipse.jdt.internal.compiler.ast.ExplicitConstructorCall;
import org.eclipse.jdt.internal.compiler.ast.Expression;
import org.eclipse.jdt.internal.compiler.ast.ExtendedStringLiteral;
import org.eclipse.jdt.internal.compiler.ast.FalseLiteral;
import org.eclipse.jdt.internal.compiler.ast.FieldDeclaration;
import org.eclipse.jdt.internal.compiler.ast.FieldReference;
import org.eclipse.jdt.internal.compiler.ast.FloatLiteral;
import org.eclipse.jdt.internal.compiler.ast.ForStatement;
import org.eclipse.jdt.internal.compiler.ast.ForeachStatement;
import org.eclipse.jdt.internal.compiler.ast.FunctionalExpression;
import org.eclipse.jdt.internal.compiler.ast.IfStatement;
import org.eclipse.jdt.internal.compiler.ast.Initializer;
import org.eclipse.jdt.internal.compiler.ast.InstanceOfExpression;
import org.eclipse.jdt.internal.compiler.ast.IntLiteral;
import org.eclipse.jdt.internal.compiler.ast.LabeledStatement;
import org.eclipse.jdt.internal.compiler.ast.LambdaExpression;
import org.eclipse.jdt.internal.compiler.ast.LocalDeclaration;
import org.eclipse.jdt.internal.compiler.ast.LongLiteral;
import org.eclipse.jdt.internal.compiler.ast.MarkerAnnotation;
import org.eclipse.jdt.internal.compiler.ast.MessageSend;
import org.eclipse.jdt.internal.compiler.ast.MethodDeclaration;
import org.eclipse.jdt.internal.compiler.ast.NameReference;
import org.eclipse.jdt.internal.compiler.ast.NormalAnnotation;
import org.eclipse.jdt.internal.compiler.ast.NullLiteral;
import org.eclipse.jdt.internal.compiler.ast.OR_OR_Expression;
import org.eclipse.jdt.internal.compiler.ast.OperatorIds;
import org.eclipse.jdt.internal.compiler.ast.PostfixExpression;
import org.eclipse.jdt.internal.compiler.ast.PrefixExpression;
import org.eclipse.jdt.internal.compiler.ast.QualifiedAllocationExpression;
import org.eclipse.jdt.internal.compiler.ast.QualifiedNameReference;
import org.eclipse.jdt.internal.compiler.ast.QualifiedSuperReference;
import org.eclipse.jdt.internal.compiler.ast.QualifiedThisReference;
import org.eclipse.jdt.internal.compiler.ast.ReferenceExpression;
import org.eclipse.jdt.internal.compiler.ast.ReturnStatement;
import org.eclipse.jdt.internal.compiler.ast.SingleMemberAnnotation;
import org.eclipse.jdt.internal.compiler.ast.SingleNameReference;
import org.eclipse.jdt.internal.compiler.ast.Statement;
import org.eclipse.jdt.internal.compiler.ast.StringLiteral;
import org.eclipse.jdt.internal.compiler.ast.StringLiteralConcatenation;
import org.eclipse.jdt.internal.compiler.ast.SuperReference;
import org.eclipse.jdt.internal.compiler.ast.SwitchStatement;
import org.eclipse.jdt.internal.compiler.ast.SynchronizedStatement;
import org.eclipse.jdt.internal.compiler.ast.ThisReference;
import org.eclipse.jdt.internal.compiler.ast.ThrowStatement;
import org.eclipse.jdt.internal.compiler.ast.TrueLiteral;
import org.eclipse.jdt.internal.compiler.ast.TryStatement;
import org.eclipse.jdt.internal.compiler.ast.TypeDeclaration;
import org.eclipse.jdt.internal.compiler.ast.TypeReference;
import org.eclipse.jdt.internal.compiler.ast.UnaryExpression;
import org.eclipse.jdt.internal.compiler.ast.UnionTypeReference;
import org.eclipse.jdt.internal.compiler.ast.WhileStatement;
import org.eclipse.jdt.internal.compiler.impl.Constant;
import org.eclipse.jdt.internal.compiler.lookup.AnnotationBinding;
import org.eclipse.jdt.internal.compiler.lookup.BaseTypeBinding;
import org.eclipse.jdt.internal.compiler.lookup.BinaryTypeBinding;
import org.eclipse.jdt.internal.compiler.lookup.Binding;
import org.eclipse.jdt.internal.compiler.lookup.BlockScope;
import org.eclipse.jdt.internal.compiler.lookup.ClassScope;
import org.eclipse.jdt.internal.compiler.lookup.CompilationUnitScope;
import org.eclipse.jdt.internal.compiler.lookup.FieldBinding;
import org.eclipse.jdt.internal.compiler.lookup.IntersectionTypeBinding18;
import org.eclipse.jdt.internal.compiler.lookup.LocalTypeBinding;
import org.eclipse.jdt.internal.compiler.lookup.LocalVariableBinding;
import org.eclipse.jdt.internal.compiler.lookup.MethodBinding;
import org.eclipse.jdt.internal.compiler.lookup.MethodScope;
import org.eclipse.jdt.internal.compiler.lookup.MethodVerifier;
import org.eclipse.jdt.internal.compiler.lookup.NestedTypeBinding;
import org.eclipse.jdt.internal.compiler.lookup.ReferenceBinding;
import org.eclipse.jdt.internal.compiler.lookup.Scope;
import org.eclipse.jdt.internal.compiler.lookup.SourceTypeBinding;
import org.eclipse.jdt.internal.compiler.lookup.SyntheticArgumentBinding;
import org.eclipse.jdt.internal.compiler.lookup.SyntheticMethodBinding;
import org.eclipse.jdt.internal.compiler.lookup.TypeBinding;
import org.eclipse.jdt.internal.compiler.lookup.TypeIds;
import org.eclipse.jdt.internal.compiler.lookup.VariableBinding;
import org.eclipse.jdt.internal.compiler.util.Util;

import java.lang.reflect.Field;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collections;
import java.util.Iterator;
import java.util.List;
import java.util.ListIterator;
import java.util.Map;
import java.util.Map.Entry;
import java.util.Set;

/**
 * Constructs a GWT Java AST from a single isolated compilation unit. The AST is
 * not associated with any {@link com.google.gwt.dev.jjs.ast.JProgram} and will
 * contain unresolved references.
 */
public class GwtAstBuilder {

  public static final String CLINIT_METHOD_NAME = "$clinit";
  public static final String GET_CLASS_METHOD_NAME = "getClass";
  public static final String EQUALS_METHOD_NAME = "equals";
  public static final String HAS_NEXT_METHOD_NAME = "hasNext";
  public static final String HASHCODE_METHOD_NAME = "hashCode";
  public static final String ITERATOR_METHOD_NAME = "iterator";
  public static final String INIT_NAME_METHOD_NAME = "$init";
  public static final String NEXT_METHOD_NAME = "next";
  public static final String ORDINAL_METHOD_NAME = "ordinal";
  public static final String OUTER_LAMBDA_PARAM_NAME = "$$outer_0";
  public static final String STATIC_INIT_METHOD_NAME =  "$" + INIT_NAME_METHOD_NAME;
  public static final String TO_STRING_METHOD_NAME = "toString";
  public static final String VALUE_OF_METHOD_NAME = "valueOf";
  public static final String VALUES_METHOD_NAME = "values";

  public static final int CLINIT_METHOD_INDEX = 0;
  public static final int INIT_METHOD_INDEX = 1;
  public static final int GET_CLASS_METHOD_INDEX = 2;

  /**
   * Visit the JDT AST and produce our own AST. By the end of this pass, the
   * produced AST should contain every piece of information we'll ever need
   * about the code. The JDT nodes should never again be referenced after this.
   */
  class AstVisitor extends SafeASTVisitor {
    /**
     * Collects JSNI references from native method bodies and replaces the ones referring to
     * compile time constants by their corresponding constant value.
     */
    private class JsniReferenceCollector extends JsModVisitor {
      private final JsniMethodBody nativeMethodBody;

      private JsniReferenceCollector(JsniMethodBody nativeMethodBody) {
        this.nativeMethodBody = nativeMethodBody;
      }

      @Override
      public void endVisit(JsNameRef x, JsContext ctx) {
        if (!x.isJsniReference()) {
          return;
        }
        String ident = x.getIdent();
        Binding binding = jsniRefs.get(ident);
        SourceInfo info = x.getSourceInfo();
        assert binding != null;
        if (binding instanceof TypeBinding) {
          JType type = typeMap.get((TypeBinding) binding);
          processClassLiteral(x, info, type, ctx);
        } else if (binding instanceof FieldBinding) {
          FieldBinding fieldBinding = (FieldBinding) binding;
          if (isOptimizableCompileTimeConstant(fieldBinding)) {
            // Replace any compile-time constants with the constant value of the field.
            assert !ctx.isLvalue();
            JExpression constant = getConstant(info, fieldBinding.constant());
            JsExpression result = JjsUtils.translateLiteral((JLiteral) constant);
            assert (result != null);
            ctx.replaceMe(result);
          } else {
            // Normal: create a jsniRef.
            JField field = typeMap.get(fieldBinding);
            processField(x, info, field, ctx);
          }
        } else {
          JMethod method = typeMap.get((MethodBinding) binding);
          processMethod(x, info, method);
        }
      }

      private void processClassLiteral(JsNameRef nameRef, SourceInfo info, JType type,
          JsContext ctx) {
        assert !ctx.isLvalue();
        JsniClassLiteral classLiteral = new JsniClassLiteral(info, nameRef.getIdent(), type);
        nativeMethodBody.addClassRef(classLiteral);
      }

      private void processField(JsNameRef nameRef, SourceInfo info, JField field, JsContext ctx) {
        JsniFieldRef fieldRef =
            new JsniFieldRef(info, nameRef.getIdent(), field, curClass.type, ctx.isLvalue());
        nativeMethodBody.addJsniRef(fieldRef);
      }

      private void processMethod(JsNameRef nameRef, SourceInfo info, JMethod method) {
        JsniMethodRef methodRef =
            new JsniMethodRef(info, nameRef.getIdent(), method, javaLangObject);
        nativeMethodBody.addJsniRef(methodRef);
      }
    }

    /**
     * Resolves the scope of JS identifiers solely within the scope of a method.
     */
    private class JsParameterResolver extends JsAbstractSymbolResolver {
      private final JsFunction jsFunction;

      public JsParameterResolver(JsFunction jsFunction) {
        this.jsFunction = jsFunction;
      }

      @Override
      public void resolveQualifiedName(JsNameRef x) {
      }

      @Override
      protected void resolveUnqualifiedName(JsNameRef x) {
        JsName name = getScope().findExistingName(x.getIdent());

        // Ensure that we're resolving a name from the function's parameters
        JsNode node = name == null ? null : name.getStaticRef();
        if (jsFunction.getParameters().contains(node)) {
          assert node instanceof JsParameter;
          x.resolve(name);
        }
      }
    }

    private final Stack classStack = new Stack();

    private ClassInfo curClass = null;

    private MethodInfo curMethod = null;

    private final Stack methodStack = new Stack();

    private final List nodeStack = Lists.newArrayList();

    @Override
    public void endVisit(AllocationExpression x, BlockScope scope) {
      try {
        SourceInfo info = makeSourceInfo(x);
        List arguments = popCallArguments(info, x.arguments, x.binding);
        pushNewExpression(info, x, null, arguments, scope);
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(AND_AND_Expression x, BlockScope scope) {
      pushBinaryOp(x, JBinaryOperator.AND);
    }

    @Override
    public void endVisit(AnnotationMethodDeclaration x, ClassScope classScope) {
      endVisit((MethodDeclaration) x, classScope);
    }

    @Override
    public void endVisit(ArrayAllocationExpression x, BlockScope scope) {
      try {
        SourceInfo info = makeSourceInfo(x);
        JArrayType type = (JArrayType) typeMap.get(x.resolvedType);

        if (x.initializer != null) {
          // handled by ArrayInitializer.
        } else {
          List dims = performBoxUnboxConversions(pop(x.dimensions), x.dimensions);
          push(JNewArray.createArrayWithDimensionExpressions(info, type, dims));
        }
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(ArrayInitializer x, BlockScope scope) {
      try {
        SourceInfo info = makeSourceInfo(x);
        JArrayType type = (JArrayType) typeMap.get(x.resolvedType);
        List expressions =
            performBoxUnboxConversions(pop(x.expressions), x.expressions);
        push(JNewArray.createArrayWithInitializers(info, type, expressions));
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(ArrayReference x, BlockScope scope) {
      try {
        SourceInfo info = makeSourceInfo(x);
        JExpression position = pop(x.position);
        JExpression receiver = pop(x.receiver);
        push(new JArrayRef(info, receiver, position));
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(AssertStatement x, BlockScope scope) {
      try {
        SourceInfo info = makeSourceInfo(x);
        JExpression exceptionArgument = pop(x.exceptionArgument);
        JExpression assertExpression = pop(x.assertExpression);
        push(new JAssertStatement(info, assertExpression, exceptionArgument));
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(Assignment x, BlockScope scope) {
      pushBinaryOp(x, JBinaryOperator.ASG);
    }

    @Override
    public void endVisit(BinaryExpression x, BlockScope scope) {
      JBinaryOperator op;
      int binOp = (x.bits & ASTNode.OperatorMASK) >> ASTNode.OperatorSHIFT;
      switch (binOp) {
        case OperatorIds.LEFT_SHIFT:
          op = JBinaryOperator.SHL;
          break;
        case OperatorIds.RIGHT_SHIFT:
          op = JBinaryOperator.SHR;
          break;
        case OperatorIds.UNSIGNED_RIGHT_SHIFT:
          op = JBinaryOperator.SHRU;
          break;
        case OperatorIds.PLUS:
          if (javaLangString == typeMap.get(x.resolvedType)) {
            op = JBinaryOperator.CONCAT;
          } else {
            op = JBinaryOperator.ADD;
          }
          break;
        case OperatorIds.MINUS:
          op = JBinaryOperator.SUB;
          break;
        case OperatorIds.REMAINDER:
          op = JBinaryOperator.MOD;
          break;
        case OperatorIds.XOR:
          op = JBinaryOperator.BIT_XOR;
          break;
        case OperatorIds.AND:
          op = JBinaryOperator.BIT_AND;
          break;
        case OperatorIds.MULTIPLY:
          op = JBinaryOperator.MUL;
          break;
        case OperatorIds.OR:
          op = JBinaryOperator.BIT_OR;
          break;
        case OperatorIds.DIVIDE:
          op = JBinaryOperator.DIV;
          break;
        case OperatorIds.LESS_EQUAL:
          op = JBinaryOperator.LTE;
          break;
        case OperatorIds.GREATER_EQUAL:
          op = JBinaryOperator.GTE;
          break;
        case OperatorIds.GREATER:
          op = JBinaryOperator.GT;
          break;
        case OperatorIds.LESS:
          op = JBinaryOperator.LT;
          break;
        default:
          throw translateException(x, new InternalCompilerException(
              "Unexpected operator for BinaryExpression"));
      }
      pushBinaryOp(x, op);
    }

    @Override
    public void endVisit(Block x, BlockScope scope) {
      try {
        SourceInfo info = makeSourceInfo(x);
        JBlock block = popBlock(info, x.statements);
        push(block);
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(BreakStatement x, BlockScope scope) {
      try {
        SourceInfo info = makeSourceInfo(x);
        push(new JBreakStatement(info, getOrCreateLabel(info, x.label)));
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(CaseStatement x, BlockScope scope) {
      try {
        SourceInfo info = makeSourceInfo(x);
        JExpression caseExpression = pop(x.constantExpression);
        if (caseExpression != null && x.constantExpression.resolvedType.isEnum()) {
          caseExpression = synthesizeCallToOrdinal(scope, info, caseExpression);
        }
        push(new JCaseStatement(info, caseExpression));
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(CastExpression x, BlockScope scope) {
      /**
       * Our output of a ((A & I1 & I2) a) looks like this:
       *
       * ((A)(I1)(I2)a).
       */
      try {
        SourceInfo info = makeSourceInfo(x);
        JType[] type = processCastType(x.resolvedType);
        JExpression expression = pop(x.expression);
        push(buildCastOperation(info, type, expression));
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(CharLiteral x, BlockScope scope) {
      try {
        push(JCharLiteral.get(x.constant.charValue()));
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(ClassLiteralAccess x, BlockScope scope) {
      try {
        SourceInfo info = makeSourceInfo(x);
        JType type = typeMap.get(x.targetType);
        push(new JClassLiteral(info, type));
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(CompoundAssignment x, BlockScope scope) {
      JBinaryOperator op;
      switch (x.operator) {
        case OperatorIds.PLUS:
          if (javaLangString == typeMap.get(x.resolvedType)) {
            op = JBinaryOperator.ASG_CONCAT;
          } else {
            op = JBinaryOperator.ASG_ADD;
          }
          break;
        case OperatorIds.MINUS:
          op = JBinaryOperator.ASG_SUB;
          break;
        case OperatorIds.MULTIPLY:
          op = JBinaryOperator.ASG_MUL;
          break;
        case OperatorIds.DIVIDE:
          op = JBinaryOperator.ASG_DIV;
          break;
        case OperatorIds.AND:
          op = JBinaryOperator.ASG_BIT_AND;
          break;
        case OperatorIds.OR:
          op = JBinaryOperator.ASG_BIT_OR;
          break;
        case OperatorIds.XOR:
          op = JBinaryOperator.ASG_BIT_XOR;
          break;
        case OperatorIds.REMAINDER:
          op = JBinaryOperator.ASG_MOD;
          break;
        case OperatorIds.LEFT_SHIFT:
          op = JBinaryOperator.ASG_SHL;
          break;
        case OperatorIds.RIGHT_SHIFT:
          op = JBinaryOperator.ASG_SHR;
          break;
        case OperatorIds.UNSIGNED_RIGHT_SHIFT:
          op = JBinaryOperator.ASG_SHRU;
          break;
        default:
          throw translateException(x, new InternalCompilerException(
              "Unexpected operator for CompoundAssignment"));
      }
      pushBinaryOp(x, op);
    }

    @Override
    public void endVisit(ConditionalExpression x, BlockScope scope) {
      try {
        SourceInfo info = makeSourceInfo(x);
        JType type = typeMap.get(x.resolvedType);
        JExpression valueIfFalse = pop(x.valueIfFalse);
        JExpression valueIfTrue = pop(x.valueIfTrue);
        JExpression condition = pop(x.condition);
        push(new JConditional(info, type, condition, valueIfTrue, valueIfFalse));
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(ConstructorDeclaration x, ClassScope scope) {
      try {
        List statements = pop(x.statements);
        JStatement constructorCall = pop(x.constructorCall);
        JBlock block = curMethod.body.getBlock();
        SourceInfo info = curMethod.method.getSourceInfo();

        /*
         * Determine if we have an explicit this call. The presence of an
         * explicit this call indicates we can skip certain initialization steps
         * (as the callee will perform those steps for us). These skippable
         * steps are 1) assigning synthetic args to fields and 2) running
         * initializers.
         */
        boolean hasExplicitThis = (x.constructorCall != null) && !x.constructorCall.isSuperAccess();

        /*
         * All synthetic fields must be assigned, unless we have an explicit
         * this constructor call, in which case the callee will assign them for
         * us.
         */
        if (!hasExplicitThis) {
          ReferenceBinding declaringClass = (ReferenceBinding) x.binding.declaringClass.erasure();
          if (JdtUtil.isInnerClass(declaringClass)) {
            NestedTypeBinding nestedBinding = (NestedTypeBinding) declaringClass;
            if (nestedBinding.enclosingInstances != null) {
              for (SyntheticArgumentBinding arg : nestedBinding.enclosingInstances) {
                JBinaryOperation asg = assignSyntheticField(info, arg);
                block.addStmt(asg.makeStatement());
              }
            }

            if (nestedBinding.outerLocalVariables != null) {
              for (SyntheticArgumentBinding arg : nestedBinding.outerLocalVariables) {
                JBinaryOperation asg = assignSyntheticField(info, arg);
                block.addStmt(asg.makeStatement());
              }
            }
          }
        }

        if (constructorCall != null) {
          block.addStmt(constructorCall);
        }

        /*
         * Call the synthetic instance initializer method, unless we have an
         * explicit this constructor call, in which case the callee will.
         */
        if (!hasExplicitThis) {
          JMethod initMethod = curClass.type.getInitMethod();
          JMethodCall initCall = new JMethodCall(info, makeThisRef(info), initMethod);
          block.addStmt(initCall.makeStatement());
        }

        // user code (finally!)
        block.addStmts(statements);
        popMethodInfo();
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(ContinueStatement x, BlockScope scope) {
      try {
        SourceInfo info = makeSourceInfo(x);
        push(new JContinueStatement(info, getOrCreateLabel(info, x.label)));
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(DoStatement x, BlockScope scope) {
      try {
        SourceInfo info = makeSourceInfo(x);
        JExpression condition = pop(x.condition);
        JStatement action = pop(x.action);
        push(new JDoStatement(info, condition, action));
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(DoubleLiteral x, BlockScope scope) {
      try {
        push(JDoubleLiteral.get(x.constant.doubleValue()));
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(EmptyStatement x, BlockScope scope) {
      push(null);
    }

    @Override
    public void endVisit(EqualExpression x, BlockScope scope) {
      JBinaryOperator op;
      switch ((x.bits & ASTNode.OperatorMASK) >> ASTNode.OperatorSHIFT) {
        case OperatorIds.EQUAL_EQUAL:
          op = JBinaryOperator.EQ;
          break;
        case OperatorIds.NOT_EQUAL:
          op = JBinaryOperator.NEQ;
          break;
        default:
          throw translateException(x, new InternalCompilerException(
              "Unexpected operator for EqualExpression"));
      }
      pushBinaryOp(x, op);
    }

    @Override
    public void endVisit(ExplicitConstructorCall x, BlockScope scope) {
      try {
        SourceInfo info = makeSourceInfo(x);
        JConstructor ctor = (JConstructor) typeMap.get(x.binding);
        JExpression trueQualifier = makeThisRef(info);
        JMethodCall call = new JMethodCall(info, trueQualifier, ctor);
        List callArgs = popCallArguments(info, x.arguments, x.binding);

        if (curClass.classType.isEnumOrSubclass() != null) {
          // Enums: wire up synthetic name/ordinal params to the super method.
          JParameterRef enumNameRef = curMethod.method.getParams().get(0).makeRef(info);
          call.addArg(enumNameRef);
          JParameterRef enumOrdinalRef = curMethod.method.getParams().get(1).makeRef(info);
          call.addArg(enumOrdinalRef);
        }

        if (x.isSuperAccess()) {
          JExpression qualifier = pop(x.qualification);
          ReferenceBinding superClass = x.binding.declaringClass;
          boolean nestedSuper = JdtUtil.isInnerClass(superClass);
          if (nestedSuper) {
            processSuperCallThisArgs(superClass, call, qualifier, x.qualification);
          }
          call.addArgs(callArgs);
          if (nestedSuper) {
            processSuperCallLocalArgs(superClass, call);
          }
        } else {
          assert (x.qualification == null);
          ReferenceBinding declaringClass = x.binding.declaringClass;
          boolean nested = JdtUtil.isInnerClass(declaringClass);
          if (nested) {
            processThisCallThisArgs(declaringClass, call);
          }
          call.addArgs(callArgs);
          if (nested) {
            processThisCallLocalArgs(declaringClass, call);
          }
        }
        call.setStaticDispatchOnly();
        push(call.makeStatement());
      } catch (Throwable e) {
        throw translateException(x, e);
      } finally {
        scope.methodScope().isConstructorCall = false;
      }
    }

    @Override
    public void endVisit(ExtendedStringLiteral x, BlockScope scope) {
      endVisit((StringLiteral) x, scope);
    }

    @Override
    public void endVisit(FalseLiteral x, BlockScope scope) {
      push(JBooleanLiteral.FALSE);
    }

    @Override
    public void endVisit(FieldDeclaration x, MethodScope scope) {
      try {
        JExpression initialization = pop(x.initialization);
        JField field = typeMap.get(x.binding);
        if (field instanceof JEnumField) {
          // An enum field must be initialized!
          assert (initialization instanceof JNewInstance);
        }

        if (initialization != null) {
          SourceInfo info = makeSourceInfo(x);
          JExpression instance = null;
          if (!x.isStatic()) {
            instance = makeThisRef(info);
          }
          // JDeclarationStatement's ctor sets up the field's initializer.
          JStatement decl =
              new JDeclarationStatement(info, new JFieldRef(info, instance, field, curClass.type),
                  initialization);
          // will either be init or clinit
          curMethod.body.getBlock().addStmt(decl);
        }
        popMethodInfo();
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(FieldReference x, BlockScope scope) {
      try {
        FieldBinding fieldBinding = x.binding;
        SourceInfo info = makeSourceInfo(x);
        JExpression instance = pop(x.receiver);
        JExpression expr = createFieldRef(instance, info, fieldBinding);
        if (x.genericCast != null) {
          JType[] castTypes = processCastType(x.genericCast);
          /*
           * Note, this may result in an invalid AST due to an LHS cast
           * operation. We fix this up in FixAssignmentsToUnboxOrCast.
           */
          expr = maybeCast(castTypes, expr);
        }
        push(expr);
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(FloatLiteral x, BlockScope scope) {
      try {
        push(JFloatLiteral.get(x.constant.floatValue()));
      } catch (Throwable e) {
        throw translateException(x, e);
      }
    }

    @Override
    public void endVisit(ForeachStatement x, BlockScope scope) {
      SourceInfo info = makeSourceInfo(x);

      JBlock body = popBlock(info, x.action);
      JExpression collection = pop(x.collection);
      JDeclarationStatement elementDecl = pop(x.elementVariable);
      assert (elementDecl.initializer == null);

      JLocal elementVar = (JLocal) curMethod.locals.get(x.elementVariable.binding);
      String elementVarName = elementVar.getName();

      JForStatement result;
      if (x.collectionVariable != null) {
        /**
         * 
       * for (final T[] i$array = collection,
       *          int i$index = 0,
       *          final int i$max = i$array.length;
       *      i$index < i$max; ++i$index) {
       *   T elementVar = i$array[i$index];
       *   // user action
       * }
       * 
*/ JLocal arrayVar = JProgram.createLocal(info, elementVarName + "$array", typeMap.get(x.collection.resolvedType), true, curMethod.body); JLocal indexVar = JProgram.createLocal(info, elementVarName + "$index", JPrimitiveType.INT, false, curMethod.body); JLocal maxVar = JProgram.createLocal(info, elementVarName + "$max", JPrimitiveType.INT, true, curMethod.body); List initializers = Lists.newArrayListWithCapacity(3); // T[] i$array = arr initializers.add(makeDeclaration(info, arrayVar, collection)); // int i$index = 0 initializers.add(makeDeclaration(info, indexVar, JIntLiteral.get(0))); // int i$max = i$array.length initializers.add(makeDeclaration(info, maxVar, new JArrayLength(info, arrayVar.makeRef(info)))); // i$index < i$max JExpression condition = new JBinaryOperation(info, JPrimitiveType.BOOLEAN, JBinaryOperator.LT, indexVar.makeRef(info), maxVar.makeRef(info)); // ++i$index JExpression increments = new JPrefixOperation(info, JUnaryOperator.INC, indexVar.makeRef(info)); // T elementVar = i$array[i$index]; elementDecl.initializer = new JArrayRef(info, arrayVar.makeRef(info), indexVar.makeRef(info)); body.addStmt(0, elementDecl); result = new JForStatement(info, initializers, condition, increments, body); } else { /** *
         * for (Iterator<T> i$iterator = collection.iterator(); i$iterator.hasNext();) {
         *   T elementVar = i$iterator.next();
         *   // user action
         * }
         * 
*/ CompilationUnitScope cudScope = scope.compilationUnitScope(); ReferenceBinding javaUtilIterator = scope.getJavaUtilIterator(); ReferenceBinding javaLangIterable = scope.getJavaLangIterable(); MethodBinding iterator = javaLangIterable.getExactMethod(ITERATOR_, NO_TYPES, cudScope); MethodBinding hasNext = javaUtilIterator.getExactMethod(HAS_NEXT_, NO_TYPES, cudScope); MethodBinding next = javaUtilIterator.getExactMethod(NEXT_, NO_TYPES, cudScope); JLocal iteratorVar = JProgram.createLocal(info, (elementVarName + "$iterator"), typeMap .get(javaUtilIterator), false, curMethod.body); List initializers = Lists.newArrayListWithCapacity(1); // Iterator i$iterator = collection.iterator() initializers.add(makeDeclaration(info, iteratorVar, new JMethodCall(info, collection, typeMap.get(iterator)))); // i$iterator.hasNext() JExpression condition = new JMethodCall(info, iteratorVar.makeRef(info), typeMap.get(hasNext)); // T elementVar = (T) i$iterator.next(); elementDecl.initializer = new JMethodCall(info, iteratorVar.makeRef(info), typeMap.get(next)); // Perform any implicit reference type casts (due to generics). // Note this occurs before potential unboxing. if (elementVar.getType() != javaLangObject) { TypeBinding collectionElementType = getCollectionElementTypeBinding(x); JType toType = typeMap.get(collectionElementType); assert (toType instanceof JReferenceType); elementDecl.initializer = maybeCast(toType, elementDecl.initializer); } body.addStmt(0, elementDecl); result = new JForStatement(info, initializers, condition, null, body); } // May need to box or unbox the element assignment. elementDecl.initializer = maybeBoxOrUnbox(elementDecl.initializer, x.elementVariableImplicitWidening); push(result); } @Override public void endVisit(ForStatement x, BlockScope scope) { try { SourceInfo info = makeSourceInfo(x); JStatement action = pop(x.action); // JDT represents the 3rd for component (increments) as a list of statements. These // statements are always expression statements as per JLS 14.14.1 // Here the List is transformed into a more adequate List. List incrementsExpressions = Lists.transform(pop(x.increments), new Function() { @Override public JExpression apply(JStatement statement) { Preconditions.checkArgument(statement instanceof JExpressionStatement); return ((JExpressionStatement) statement).getExpr(); } }); // And turned into a single expression (possibly null if empty). JExpression incrementsExpression = singleExpressionFromExpressionList(info, incrementsExpressions); JExpression condition = pop(x.condition); List initializations = pop(x.initializations); push(new JForStatement(info, initializations, condition, incrementsExpression, action)); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(IfStatement x, BlockScope scope) { try { SourceInfo info = makeSourceInfo(x); JStatement elseStatement = pop(x.elseStatement); JStatement thenStatement = pop(x.thenStatement); JExpression condition = pop(x.condition); push(new JIfStatement(info, condition, thenStatement, elseStatement)); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(Initializer x, MethodScope scope) { try { JBlock block = pop(x.block); if (block != null) { curMethod.body.getBlock().addStmt(block); } popMethodInfo(); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(InstanceOfExpression x, BlockScope scope) { try { SourceInfo info = makeSourceInfo(x); JExpression expr = pop(x.expression); JReferenceType testType = (JReferenceType) typeMap.get(x.type.resolvedType); push(new JInstanceOf(info, testType, expr)); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(IntLiteral x, BlockScope scope) { try { push(JIntLiteral.get(x.constant.intValue())); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(LabeledStatement x, BlockScope scope) { try { JStatement statement = pop(x.statement); if (statement == null) { push(null); return; } SourceInfo info = makeSourceInfo(x); push(new JLabeledStatement(info, getOrCreateLabel(info, x.label), statement)); } catch (Throwable e) { throw translateException(x, e); } } @Override public boolean visit(ReferenceExpression x, BlockScope blockScope) { // T[][][]::new => lambda$n(int x) { return new T[int x][][]; } if (x.isArrayConstructorReference()) { // ensure array[]::new synthetic method (created by JDT) has an associated JMethod JMethod synthMethod = typeMap.get(x.binding); if (synthMethod.getBody() == null) { JMethodBody body = new JMethodBody(synthMethod.getSourceInfo()); List dims = new ArrayList(); JArrayType arrayType = (JArrayType) synthMethod.getType(); JParameter dimParam = synthMethod.getParams().get(0); JExpression dimArgExpr = dimParam.makeRef(dimParam.getSourceInfo()); dims.add(dimArgExpr); JNewArray newArray = JNewArray.createArrayWithDimensionExpressions( synthMethod.getSourceInfo(), arrayType, dims); body.getBlock().addStmt(newArray.makeReturnStatement()); synthMethod.setBody(body); } } if (hasQualifier(x)) { x.lhs.traverse(this, blockScope); } return false; } @Override public boolean visit(LambdaExpression x, BlockScope blockScope) { // Fetch the variables 'captured' by this lambda SyntheticArgumentBinding[] synthArgs = x.outerLocalVariables; // Get the parameter names, captured locals + lambda arguments String paramNames[] = computeCombinedParamNames(x, synthArgs); SourceInfo info = makeSourceInfo(x); // JDT synthesizes a method lambda$n(capture1, capture2, ..., lambda_arg1, lambda_arg2, ...) // Here we create a JMethod from this JMethod lambdaMethod = createMethodFromBinding(info, x.binding, paramNames); // Because the lambda implementations is synthesized as a static method in the // enclosing class, it needs to be adjusted if that class happens to be a JsType. lambdaMethod.setJsMemberInfo(HasJsInfo.JsMemberType.NONE, null, null, false); if (curClass.type.isJsNative()) { lambdaMethod.setJsOverlay(); } JMethodBody methodBody = new JMethodBody(info); lambdaMethod.setBody(methodBody); // We need to push this method on the stack as it introduces a scope, and // expressions in the body need to lookup variable refs like parameters from it pushMethodInfo(new MethodInfo(lambdaMethod, methodBody, x.scope)); pushLambdaExpressionLocalsIntoMethodScope(x, synthArgs, lambdaMethod); // now the body of the lambda is processed return true; } private void pushLambdaExpressionLocalsIntoMethodScope(LambdaExpression x, SyntheticArgumentBinding[] syntheticArguments, JMethod lambdaMethod) { Iterator it = lambdaMethod.getParams().iterator(); if (syntheticArguments != null) { MethodScope scope = x.getScope(); for (SyntheticArgumentBinding sa : syntheticArguments) { VariableBinding[] path = scope.getEmulationPath(sa.actualOuterLocalVariable); assert path.length == 1 && path[0] instanceof LocalVariableBinding; JParameter param = it.next(); curMethod.locals.put((LocalVariableBinding) path[0], param); } for (Argument a : x.arguments) { curMethod.locals.put(a.binding, it.next()); } } } /** * Calculate the names of all the parameters a lambda method will need, that is, the * combination of all captured locals plus all arguments to the lambda expression. */ private String[] computeCombinedParamNames(LambdaExpression x, SyntheticArgumentBinding[] syntheticArguments) { String[] paramNames; paramNames = new String[x.binding.parameters.length]; int numSynthArgs = syntheticArguments != null ? syntheticArguments.length : 0; for (int i = 0; i < paramNames.length; i++) { if (i < numSynthArgs) { paramNames[i] = nameForSyntheticArgument(syntheticArguments[i]); } else { paramNames[i] = nameForArgument(x.arguments, i - numSynthArgs, i); } } return paramNames; } private String nameForArgument(Argument[] arguments, int argIndex, int argPosition) { return new String(arguments[argIndex].name) + "_" + argPosition; } private String nameForSyntheticArgument(SyntheticArgumentBinding synthArg) { return synthArg.actualOuterLocalVariable != null ? intern(intern(synthArg.actualOuterLocalVariable.name) + "_" + synthArg.resolvedPosition) : intern(synthArg.name); } @Override public void endVisit(LambdaExpression x, BlockScope blockScope) { /** * Our output of a (args) -> expression_using_locals(locals) looks like this. * * class Enclosing { * * T lambda$0(locals, args) {...lambda expr } * * class lambda$0$type implements I { * ctor([outer], locals) { ... } * R (args) { return [outer].lambda$0(locals, args); } * } * } * * And replaces the lambda with new lambda$0$Type([outer this], captured locals...). */ // The target accepting this lambda is looking for which type? (e.g. ClickHandler, Runnable) TypeBinding binding = x.expectedType(); // Find the single abstract method of this interface MethodBinding samBinding = binding.getSingleAbstractMethod(blockScope, false); assert (samBinding != null && samBinding.isValidBinding()); // Lookup the JMethod version JMethod interfaceMethod = typeMap.get(samBinding); // And its JInterface container we must implement // There may be more than more JInterface containers to be implemented // if the lambda expression is cast to a IntersectionCastType. JInterfaceType[] funcType; if (binding instanceof IntersectionTypeBinding18) { funcType = processIntersectionTypeForLambda((IntersectionTypeBinding18) binding, blockScope, JdtUtil.signature(samBinding)); } else { funcType = new JInterfaceType[] {(JInterfaceType) typeMap.get(binding)}; } SourceInfo info = makeSourceInfo(x); // Create an inner class to implement the interface and SAM method. // class lambda$0$Type implements T {} String innerLambdaImplementationClassShortName = String.valueOf(x.binding.selector); JClassType innerLambdaClass = createInnerClass( curClass.getClassOrInterface(), innerLambdaImplementationClassShortName, info, funcType); JConstructor ctor = new JConstructor(info, innerLambdaClass, AccessModifier.PRIVATE); // locals captured by the lambda and saved as fields on the anonymous inner class List locals = new ArrayList(); SyntheticArgumentBinding[] synthArgs = x.outerLocalVariables; // create the constructor for the anonymous inner and return the field used to store the // enclosing 'this' which is needed by the SAM method implementation later JField outerField = createLambdaConstructor(x, info, innerLambdaClass, ctor, locals, synthArgs); // the method containing the lambda expression that the anonymous inner class delegates to, // it corresponds directly to the lambda expression itself, produced by JDT as a helper method JMethod lambdaMethod = createLambdaMethod(x); // Now that we've added an implementation method for the lambda, we must create the inner // class method that implements the target interface type that delegates to the target lambda // method JMethod samMethod = new JMethod(info, interfaceMethod.getName(), innerLambdaClass, interfaceMethod.getType(), false, false, true, interfaceMethod.getAccess()); // implements the SAM, e.g. Callback.onCallback(), Runnable.run(), etc createLambdaSamMethod(x, interfaceMethod, info, innerLambdaClass, locals, outerField, lambdaMethod, samMethod); ctor.freezeParamTypes(); samMethod.freezeParamTypes(); // Create necessary bridges. createFunctionalExpressionBridges(innerLambdaClass, x, samMethod); // replace (x,y,z) -> expr with 'new Lambda(args)' replaceLambdaWithInnerClassAllocation(x, info, innerLambdaClass, ctor, synthArgs); popMethodInfo(); // Add the newly generated type newTypes.add(innerLambdaClass); } private void createFunctionalExpressionBridges( JClassType functionalExpressionImplementationClass, FunctionalExpression functionalExpression, JMethod functionalInterfaceAbstractMethod) { if (functionalExpression.getRequiredBridges() != null) { for (MethodBinding methodBinding : functionalExpression.getRequiredBridges()) { // Create bridges. createBridgeMethod(functionalExpressionImplementationClass, methodBinding, functionalInterfaceAbstractMethod); } } } private void createLambdaSamMethod(LambdaExpression x, JMethod interfaceMethod, SourceInfo info, JClassType innerLambdaClass, List locals, JField outerField, JMethod lambdaMethod, JMethod samMethod) { // The parameters to this method will be the same as the Java interface that must be // implemented for (JParameter origParam : interfaceMethod.getParams()) { samMethod.cloneParameter(origParam); } // Create a body like void onClick(ClickEvent e) { OuterClass.lambdaMethod(locals, e); } JMethodBody samMethodBody = new JMethodBody(info); // First we create the method call to the outer lambda method JMethodCall samCall = new JMethodCall(info, x.shouldCaptureInstance ? new JFieldRef(info, new JThisRef(info, innerLambdaClass), outerField, innerLambdaClass) : null, lambdaMethod); // and add any locals that were storing captured outer variables as arguments to the call // first for (JField localField : locals) { samCall.addArg(new JFieldRef(info, new JThisRef(info, innerLambdaClass), localField, innerLambdaClass)); } // and now we propagate the rest of the actual interface method parameters on the end // (e.g. ClickEvent e) for (JParameter param : samMethod.getParams()) { samCall.addArg(param.makeRef(info)); } // we either add a return statement, or don't, depending on what the interface wants samMethodBody.getBlock().addStmt( JjsUtils.makeMethodEndStatement(samMethod.getType(), samCall)); samMethod.setBody(samMethodBody); innerLambdaClass.addMethod(samMethod); } private JField createLambdaConstructor(LambdaExpression x, SourceInfo info, JClassType innerLambdaClass, JConstructor ctor, List locals, SyntheticArgumentBinding[] synthArgs) { // Create a constructor to accept all "captured" locals // CTor([OuterClassRef ref], capture1, capture2) { } JMethodBody ctorBody = new JMethodBody(info); JField outerField = null; // if this lambda refers to fields on the enclosing instance if (x.shouldCaptureInstance) { // ctor($$outer) { this.$$outer = $$outer; } outerField = createAndBindCapturedLambdaParameter(info, OUTER_LAMBDA_PARAM_NAME, innerLambdaClass.getEnclosingType(), ctor, ctorBody); } // Now we add parameters to the ctor // this is the outer instance (if needed), plus any method local variables captured String paramNames[] = new String[x.binding.parameters.length]; int numSynthArgs = synthArgs != null ? synthArgs.length : 0; for (int i = 0; i < paramNames.length; i++) { // Setup params, fields, and ctor assignments for the outer captured vars if (i < numSynthArgs) { paramNames[i] = nameForSyntheticArgument(synthArgs[i]); JType captureType = typeMap.get(synthArgs[i].type); // adds ctor(..., param, ...) { ...this.param = param } JField captureField = createAndBindCapturedLambdaParameter( info, paramNames[i], captureType, ctor, ctorBody); locals.add(captureField); } else { // Record the names of the actual closure arguments, // e.g. (ClickEvent x) -> expr will be 'x' paramNames[i] = nameForArgument(x.arguments, i - numSynthArgs, i); } } ctor.setBody(ctorBody); innerLambdaClass.addMethod(ctor); return outerField; } private JMethod createLambdaMethod(LambdaExpression x) { // First let's get that synthetic method we created in the visit() call on the // containing class? JMethod lambdaMethod = curMethod.method; // And pop off the body nodes of the LambdaExpression that was processed as children // Deal with any boxing/unboxing needed JNode node = pop(); if (node instanceof JExpression) { node = maybeBoxOrUnbox((JExpression) node, (Expression) x.body); } JMethodBody body = (JMethodBody) curMethod.method.getBody(); // and copy those nodes into the body of our synthetic method JStatement lambdaStatement = getOrCreateLambdaStatement(node); body.getBlock().addStmt(lambdaStatement); lambdaMethod.setBody(body); return lambdaMethod; } private void replaceLambdaWithInnerClassAllocation(LambdaExpression x, final SourceInfo info, JClassType innerLambdaClass, JConstructor ctor, SyntheticArgumentBinding[] synthArgs) { // Finally, we replace the LambdaExpression with // new InnerLambdaClass(this, local1, local2, ...); assert ctor.getEnclosingType() == innerLambdaClass; JNewInstance allocLambda = new JNewInstance(info, ctor); // only pass 'this' if lambda refers to fields on outer class if (x.shouldCaptureInstance) { allocLambda.addArg(new JThisRef(info, innerLambdaClass.getEnclosingType())); } for (final SyntheticArgumentBinding sa : synthArgs) { final MethodInfo method = methodStack.peek(); JExpression capturedLocalReference = null; // Find the local variable in the current method context that is referred by the inner // lambda. LocalVariableBinding localVariable = FluentIterable.from(method.locals.keySet()).firstMatch( new Predicate() { @Override public boolean apply(LocalVariableBinding enclosingLocal) { // Either the inner lambda refers directly to the enclosing scope variable, or // it is a capture from an enclosing scope, in which case both synthetic // arguments point to the same outer local variable. return enclosingLocal == sa.actualOuterLocalVariable || (enclosingLocal instanceof SyntheticArgumentBinding) && ((SyntheticArgumentBinding) enclosingLocal).actualOuterLocalVariable == sa.actualOuterLocalVariable; } }).orNull(); if (localVariable != null) { // lambda is capturing a local from the immediate context capturedLocalReference = makeLocalRef(info, localVariable, method); } else { // Local variable not found in current method context. Trying to find corresponding // synthetic field in case if lambda is placed in anonymous/local class // e.g. { int x = 1; new Outer(){ void m (){ Lambda l = () -> x+1;} }; } Entry capturedLocalInOuterClass = FluentIterable.from( curClass.syntheticFields.entrySet()).firstMatch( new Predicate>() { @Override public boolean apply(Entry entry) { return entry.getKey().actualOuterLocalVariable == sa.actualOuterLocalVariable; } }).orNull(); if (capturedLocalInOuterClass != null) { // local from outer scope has already been captured by enclosing class. capturedLocalReference = makeInstanceFieldRef(info, capturedLocalInOuterClass .getValue()); } } assert capturedLocalReference != null; allocLambda.addArg(capturedLocalReference); } // put the result on the stack, and pop out synthetic method from the scope push(allocLambda); } private JField createAndBindCapturedLambdaParameter(SourceInfo info, String paramName, JType captureType, JConstructor ctor, JMethodBody ctorBody) { JField paramField; JParameter param = createLambdaParameter(info, paramName, captureType, ctor); // Plus a field to store it paramField = createLambdaField(info, paramName, captureType, ctor.getEnclosingType()); // Now add the initializers to bind the param to field // this.paramField = param JThisRef thisRef = new JThisRef(info, ctor.getEnclosingType()); JFieldRef paramFieldRef = new JFieldRef(info, thisRef, paramField, ctor.getEnclosingType()); JParameterRef paramRef = param.makeRef(info); ctorBody.getBlock().addStmt( new JBinaryOperation(info, paramFieldRef.getType(), JBinaryOperator.ASG, paramFieldRef, paramRef).makeStatement()); return paramField; } private JField createLambdaField(SourceInfo info, String fieldName, JType fieldType, JClassType enclosingType) { JField outerField; outerField = new JField(info, fieldName, enclosingType, fieldType, false, Disposition.NONE, AccessModifier.PRIVATE); enclosingType.addField(outerField); return outerField; } private JParameter createLambdaParameter(SourceInfo info, String paramName, JType paramType, JConstructor ctor) { return ctor.createFinalParameter(info, paramName, paramType); } private JClassType createInnerClass(JDeclaredType enclosingType, String shortNname, SourceInfo info, JInterfaceType... superInterfaces) { JClassType innerLambdaClass = new JClassType(info, Joiner.on('$').join(enclosingType.getName(), shortNname, "Type"), false, true); innerLambdaClass.setEnclosingType(enclosingType); for (JInterfaceType type : superInterfaces) { innerLambdaClass.addImplements(type); } innerLambdaClass.setSuperClass(javaLangObject); createSyntheticMethod(info, CLINIT_METHOD_NAME, innerLambdaClass, JPrimitiveType.VOID, false, true, true, AccessModifier.PRIVATE); createSyntheticMethod(info, INIT_NAME_METHOD_NAME, innerLambdaClass, JPrimitiveType.VOID, false, false, true, AccessModifier.PRIVATE); // Add a getClass() implementation for all non-Object classes. createSyntheticMethod(info, GwtAstBuilder.GET_CLASS_METHOD_NAME, innerLambdaClass, javaLangClass, false, false, false, AccessModifier.PUBLIC, new JClassLiteral(info, innerLambdaClass).makeReturnStatement()); innerLambdaClass.setClassDisposition(JDeclaredType.NestedClassDisposition.LAMBDA); return innerLambdaClass; } @Override public void endVisit(LocalDeclaration x, BlockScope scope) { try { SourceInfo info = makeSourceInfo(x); JLocal local = (JLocal) curMethod.locals.get(x.binding); assert local != null; JLocalRef localRef = local.makeRef(info); JExpression initialization = pop(x.initialization); push(new JDeclarationStatement(info, localRef, initialization)); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(LongLiteral x, BlockScope scope) { try { push(JLongLiteral.get(x.constant.longValue())); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(MessageSend x, BlockScope scope) { try { SourceInfo info = makeSourceInfo(x); JMethod method = typeMap.get(x.binding); List arguments = popCallArguments(info, x.arguments, x.binding); JExpression receiver = pop(x.receiver); if (x.receiver instanceof ThisReference) { if (method.isStatic()) { // don't bother qualifying it, it's a no-op receiver = null; } else if ((x.bits & ASTNode.DepthMASK) != 0) { // outer method can be reached through emulation if implicit access ReferenceBinding targetType = scope.enclosingSourceType().enclosingTypeAt( (x.bits & ASTNode.DepthMASK) >> ASTNode.DepthSHIFT); receiver = resolveThisReference(info, targetType, true, scope); } else if (x.receiver.sourceStart == 0) { // Synthetic this ref with bad source info; fix the info. JThisRef oldRef = (JThisRef) receiver; receiver = new JThisRef(info, oldRef.getClassType()); } } JMethodCall methodCall = new JMethodCall(info, receiver, method); // On a super ref, don't allow polymorphic dispatch. Oddly enough, // QualifiedSuperReference not derived from SuperReference! boolean isSuperRef = x.receiver instanceof SuperReference || x.receiver instanceof QualifiedSuperReference; if (isSuperRef) { methodCall.setStaticDispatchOnly(); } // The arguments come first. methodCall.addArgs(arguments); if (x.valueCast != null) { JType[] targetTypes = processCastType(x.valueCast); push(isUncheckedGenericMethodCall(x) ? maybeInsertUnsafeTypeCoercion(targetTypes[0], methodCall) : maybeCast(targetTypes, methodCall)); } else { push(methodCall); } } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(MethodDeclaration x, ClassScope scope) { try { if (x.isNative()) { processNativeMethod(x); } else { List statements = pop(x.statements); curMethod.body.getBlock().addStmts(statements); } popMethodInfo(); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(NullLiteral x, BlockScope scope) { push(JNullLiteral.INSTANCE); } @Override public void endVisit(OR_OR_Expression x, BlockScope scope) { pushBinaryOp(x, JBinaryOperator.OR); } @Override public void endVisit(PostfixExpression x, BlockScope scope) { try { SourceInfo info = makeSourceInfo(x); JUnaryOperator op; switch (x.operator) { case OperatorIds.MINUS: op = JUnaryOperator.DEC; break; case OperatorIds.PLUS: op = JUnaryOperator.INC; break; default: throw new InternalCompilerException("Unexpected postfix operator"); } JExpression lhs = pop(x.lhs); push(new JPostfixOperation(info, op, lhs)); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(PrefixExpression x, BlockScope scope) { try { SourceInfo info = makeSourceInfo(x); JUnaryOperator op; switch (x.operator) { case OperatorIds.MINUS: op = JUnaryOperator.DEC; break; case OperatorIds.PLUS: op = JUnaryOperator.INC; break; default: throw new InternalCompilerException("Unexpected prefix operator"); } JExpression lhs = pop(x.lhs); push(new JPrefixOperation(info, op, lhs)); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(QualifiedAllocationExpression x, BlockScope scope) { try { SourceInfo info = makeSourceInfo(x); List arguments = popCallArguments(info, x.arguments, x.binding); pushNewExpression(info, x, x.enclosingInstance(), arguments, scope); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(QualifiedNameReference x, BlockScope scope) { try { JExpression curRef = resolveNameReference(x, scope); if (curRef == null) { push(null); return; } if (x.genericCast != null) { JType castType = typeMap.get(x.genericCast); curRef = maybeCast(castType, curRef); } SourceInfo info = curRef.getSourceInfo(); /* * JDT represents multiple field access as an array of fields, each * qualified by everything to the left. So each subsequent item in * otherBindings takes the current expression as a qualifier. */ if (x.otherBindings != null) { for (int i = 0; i < x.otherBindings.length; ++i) { FieldBinding fieldBinding = x.otherBindings[i]; curRef = createFieldRef(curRef, info, fieldBinding); if (x.otherGenericCasts != null && x.otherGenericCasts[i] != null) { JType castType = typeMap.get(x.otherGenericCasts[i]); curRef = maybeCast(castType, curRef); } } } push(curRef); } catch (Throwable e) { throw translateException(x, e); } } private JExpression createFieldRef(JExpression instance, SourceInfo info, FieldBinding fieldBinding) { if (fieldBinding.declaringClass == null) { // probably array.length if (!LENGTH_FIELD_NAME.equals(String.valueOf(fieldBinding.name))) { throw new InternalCompilerException("Expected [array].length."); } instance = new JArrayLength(info, instance); } else { JField field = typeMap.get(fieldBinding); instance = new JFieldRef(info, instance, field, curClass.type); } return instance; } @Override public void endVisit(QualifiedSuperReference x, BlockScope scope) { try { // Oddly enough, super refs can be modeled as this refs, because // whatever expression they qualify has already been resolved. SourceInfo info = makeSourceInfo(x); ReferenceBinding targetType = (ReferenceBinding) x.qualification.resolvedType.erasure(); if (targetType.isInterface()) { // Java8 super reference to default method from subtype, X.super.someDefaultMethod push(makeThisRef(info)); } else { push(resolveThisReference(info, targetType, true, scope)); } } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(QualifiedThisReference x, BlockScope scope) { try { SourceInfo info = makeSourceInfo(x); ReferenceBinding targetType = (ReferenceBinding) x.qualification.resolvedType; push(resolveThisReference(info, targetType, true, scope)); } catch (Throwable e) { throw translateException(x, e); } } private int nextReferenceExpressionId = 0; @Override public void endVisit(ReferenceExpression x, BlockScope blockScope) { /** * Converts an expression like foo(qualifier::someMethod) into * * class Enclosing { * * [static] T someMethod(locals, args) {...lambda expr } * * class lambda$someMethodType implements I { * ctor([qualifier]) { ... } * R (args) { return [outer]someMethod(args); } * } * } * * and replaces qualifier::someMethod with new lambda$someMethodType([outer this]) * * [x] denotes optional, depending on context of whether outer this scope is needed. */ // Resolve the reference expression to make sure the declaring class of the method is resolved // to the right type. x.resolve(blockScope); // Calculate what type this reference is going to bind to, and what single abstract method TypeBinding binding = x.expectedType(); MethodBinding samBinding = binding.getSingleAbstractMethod(blockScope, false); MethodBinding declarationSamBinding = binding.getSingleAbstractMethod(blockScope, false).original(); // Get the interface method is binds to JMethod interfaceMethod = typeMap.get(declarationSamBinding); JInterfaceType funcType = (JInterfaceType) typeMap.get(binding); SourceInfo info = makeSourceInfo(x); // Get the method that the Type::method is actually referring to MethodBinding referredMethodBinding = x.binding; if (referredMethodBinding instanceof SyntheticMethodBinding) { SyntheticMethodBinding synthRefMethodBinding = (SyntheticMethodBinding) referredMethodBinding; if (synthRefMethodBinding.targetMethod != null) { // generated in cases were a private method in an outer class needed to be called // e.g. outer.access$0 calls some outer.private_method referredMethodBinding = synthRefMethodBinding.targetMethod; // privateCtor::new generates overloaded references with fake args that delegate // to the real ctor (JDT WTF!). Will we ever need to go deeper? if (synthRefMethodBinding.fakePaddedParameters != 0 && synthRefMethodBinding.targetMethod instanceof SyntheticMethodBinding) { referredMethodBinding = ((SyntheticMethodBinding) referredMethodBinding).targetMethod; } } } JMethod referredMethod = typeMap.get(referredMethodBinding); boolean hasQualifier = hasQualifier(x); // Constructors, overloading and generics means that the safest approach is to consider // each different member reference as a different lambda implementation. String lambdaImplementationClassShortName = String.valueOf(nextReferenceExpressionId++) + "methodref$" + (x.binding.isConstructor() ? "ctor" : String.valueOf(x.binding.selector)); List enclosingThisRefs = Lists.newArrayList(); // Create an inner class to hold the implementation of the interface JClassType innerLambdaClass = createInnerClass( curClass.getClassOrInterface(), lambdaImplementationClassShortName, info, funcType); newTypes.add(innerLambdaClass); JConstructor ctor = new JConstructor(info, innerLambdaClass, AccessModifier.PRIVATE); JMethodBody ctorBody = new JMethodBody(info); JThisRef thisRef = new JThisRef(info, innerLambdaClass); JExpression instance = null; List enclosingInstanceFields = new ArrayList(); // If we have a qualifier instance, we have to stash it in the constructor if (hasQualifier) { // this.$$outer = $$outer JField outerField = createAndBindCapturedLambdaParameter(info, OUTER_LAMBDA_PARAM_NAME, referredMethod.getEnclosingType(), ctor, ctorBody); instance = new JFieldRef(info, new JThisRef(info, innerLambdaClass), outerField, innerLambdaClass); } else if (referredMethod instanceof JConstructor) { // the method we are invoking is a constructor and may need enclosing instances passed to // it. // For example, an class Foo { class Inner { Inner(int x) { } } } needs // it's constructor invoked with an enclosing instance, Inner::new // Java8 doesn't allow the qualifified case, e.g. x.new Foo() -> x.Foo::new ReferenceBinding targetBinding = referredMethodBinding.declaringClass; if (targetBinding.syntheticEnclosingInstanceTypes() != null) { for (ReferenceBinding argType : targetBinding.syntheticEnclosingInstanceTypes()) { argType = (ReferenceBinding) argType.erasure(); JExpression enclosingThisRef = resolveThisReference(info, argType, false, blockScope); JField enclosingInstance = createAndBindCapturedLambdaParameter(info, String.valueOf(argType.readableName()).replace('.', '_'), enclosingThisRef.getType(), ctor, ctorBody); enclosingInstanceFields.add(enclosingInstance); enclosingThisRefs.add(enclosingThisRef); } } } ctor.setBody(ctorBody); innerLambdaClass.addMethod(ctor); // Create an implementation of the target interface that invokes the method referred to // void onClick(ClickEvent e) { outer.referredMethod(e); } JMethod samMethod = new JMethod(info, interfaceMethod.getName(), innerLambdaClass, interfaceMethod.getType(), false, false, true, interfaceMethod.getAccess()); for (JParameter origParam : interfaceMethod.getParams()) { samMethod.cloneParameter(origParam); } JMethodBody samMethodBody = new JMethodBody(info); Iterator paramIt = samMethod.getParams().iterator(); // here's where it gets tricky. A method can have an implicit qualifier, e.g. // String::compareToIgnoreCase, it's non-static, it only has one argument, but it binds to // Comparator. // The first argument serves as the qualifier, so for example, the method dispatch looks // like this: int compare(T a, T b) { a.compareTo(b); } if (!hasQualifier && !referredMethod.isStatic() && !referredMethod.isConstructor() && instance == null) { // the instance qualifier is the first parameter in this case. // Needs to be cast the actual type due to generics. instance = new JCastOperation(info, typeMap.get(referredMethodBinding.declaringClass), paramIt.next().makeRef(info)); } JMethodCall samCall = null; if (referredMethod.isConstructor()) { // Constructors must be invoked with JNewInstance samCall = new JNewInstance(info, (JConstructor) referredMethod); for (JField enclosingInstance : enclosingInstanceFields) { samCall.addArg(new JFieldRef(enclosingInstance.getSourceInfo(), thisRef, enclosingInstance, innerLambdaClass)); } } else { // For static methods, instance will be null samCall = new JMethodCall(info, instance, referredMethod); // if super::method, we need static dispatch if (x.lhs instanceof SuperReference) { samCall.setStaticDispatchOnly(); } } // Add the rest of the parameters from the interface method to methodcall // boxing or unboxing and dealing with varargs int paramNumber = 0; // need to build up an array of passed parameters if we have varargs List varArgInitializers = null; int varArg = referredMethodBinding.parameters.length - 1; // interface Foo { m(int x, int y); } bound to reference foo(int... args) // if varargs and incoming param is not already a var-arg, we'll need to convert // trailing args of the target interface into an array boolean isVarargArgumentSuppliedDirectlyAsAnArray = referredMethodBinding.isVarargs() && samBinding.parameters.length == referredMethodBinding.parameters.length && samBinding.parameters[varArg] .isCompatibleWith(referredMethodBinding.parameters[varArg]); if (referredMethodBinding.isVarargs() && !isVarargArgumentSuppliedDirectlyAsAnArray) { varArgInitializers = Lists.newArrayList(); } while (paramIt.hasNext()) { JParameter param = paramIt.next(); JExpression paramExpr = param.makeRef(info); // params may need to be boxed or unboxed TypeBinding destParam = null; int declarationParameterOffset = declarationSamBinding.parameters.length - referredMethodBinding.parameters.length; // The method declared in the functional interface might have more or less parameters than // the method referred by the method reference. In the case of an instance method without // an explicit qualifier (A::m vs instance::m) the method in the functional interface will // have an additional parameter for the instance preceding all the method parameters. // So truncate the value of the index to refer to the right parameter. int declarationParameterIndex = Math.max(0, Math.min( paramNumber + declarationParameterOffset, declarationSamBinding.parameters.length - 1) ); TypeBinding samParameterBinding = declarationSamBinding.parameters[declarationParameterIndex]; // if it is not the trailing param or varargs, or interface method is already varargs if (varArgInitializers == null || !referredMethodBinding.isVarargs() || (paramNumber < varArg)) { destParam = referredMethodBinding.parameters[paramNumber]; paramExpr = boxOrUnboxExpression(paramExpr, samParameterBinding, destParam); samCall.addArg(paramExpr); } else if (!samParameterBinding.isArrayType()) { // else add trailing parameters to var-args initializer list for an array destParam = referredMethodBinding.parameters[varArg].leafComponentType(); paramExpr = boxOrUnboxExpression(paramExpr, samParameterBinding, destParam); varArgInitializers.add(paramExpr); } paramNumber++; } // add trailing new T[] { initializers } var-arg array if (varArgInitializers != null) { JArrayType lastParamType = (JArrayType) typeMap.get( referredMethodBinding.parameters[referredMethodBinding.parameters.length - 1]); JNewArray newArray = JNewArray.createArrayWithInitializers(info, lastParamType, varArgInitializers); samCall.addArg(newArray); } // TODO(rluble): Make this a call to JjsUtils.makeMethodEndStatement once boxing/unboxing // is handled there. if (samMethod.getType() != JPrimitiveType.VOID) { JExpression samExpression = boxOrUnboxExpression(samCall, referredMethodBinding.returnType, declarationSamBinding.returnType); samMethodBody.getBlock().addStmt(maybeBoxOrUnbox(samExpression, x).makeReturnStatement()); } else { samMethodBody.getBlock().addStmt(samCall.makeStatement()); } samMethod.setBody(samMethodBody); innerLambdaClass.addMethod(samMethod); ctor.freezeParamTypes(); samMethod.freezeParamTypes(); createFunctionalExpressionBridges(innerLambdaClass, x, samMethod); JConstructor lambdaCtor = null; for (JMethod method : innerLambdaClass.getMethods()) { if (method instanceof JConstructor) { lambdaCtor = (JConstructor) method; break; } } assert lambdaCtor != null; // Replace the ReferenceExpression qualifier::method with new lambdaType(qualifier) assert lambdaCtor.getEnclosingType() == innerLambdaClass; JNewInstance allocLambda = new JNewInstance(info, lambdaCtor); if (hasQualifier) { JExpression qualifier = (JExpression) pop(); // pop qualifier from stack allocLambda.addArg(qualifier); } else { // you can't simultaneously have a qualifier, and have enclosing inner class refs // because Java8 won't allow a qualified constructor method reference, e.g. x.Foo::new for (JExpression enclosingRef : enclosingThisRefs) { allocLambda.addArg(enclosingRef); } } push(allocLambda); } private JExpression boxOrUnboxExpression(JExpression expr, TypeBinding fromType, TypeBinding toType) { if (fromType == TypeBinding.VOID || toType == TypeBinding.VOID) { return expr; } if (fromType.isBaseType() && !toType.isBaseType()) { return box(expr, JdtUtil.getBaseTypeBinding(curClass.scope, fromType.id)); } if (!fromType.isBaseType() && toType.isBaseType()) { return unbox(expr, JdtUtil.getBaseTypeBinding(curClass.scope, toType.id)); } TypeBinding castToType = fromType.genericCast(toType); if (castToType == null) { return expr; } return new JCastOperation(expr.getSourceInfo(), typeMap.get(castToType), expr); } @Override public void endVisit(ReturnStatement x, BlockScope scope) { try { SourceInfo info = makeSourceInfo(x); JExpression expression = pop(x.expression); push(new JReturnStatement(info, expression)); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(SingleNameReference x, BlockScope scope) { try { JExpression result = resolveNameReference(x, scope); if (result == null) { push(null); return; } if (x.genericCast != null) { JType castType = typeMap.get(x.genericCast); result = maybeCast(castType, result); } push(result); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(StringLiteral x, BlockScope scope) { try { SourceInfo info = makeSourceInfo(x); push(getStringLiteral(info, x.constant.stringValue())); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(StringLiteralConcatenation x, BlockScope scope) { try { SourceInfo info = makeSourceInfo(x); push(getStringLiteral(info, x.constant.stringValue())); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(SuperReference x, BlockScope scope) { try { assert (typeMap.get(x.resolvedType) == curClass.getClassOrInterface().getSuperClass()); // Super refs can be modeled as a this ref. push(makeThisRef(makeSourceInfo(x))); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(SwitchStatement x, BlockScope scope) { try { SourceInfo info = makeSourceInfo(x); JBlock block = popBlock(info, x.statements); JExpression expression = pop(x.expression); if (x.expression.resolvedType.isEnum()) { // synthesize a call to ordinal(). expression = synthesizeCallToOrdinal(scope, info, expression); } push(new JSwitchStatement(info, expression, block)); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(SynchronizedStatement x, BlockScope scope) { try { JBlock block = pop(x.block); JExpression expression = pop(x.expression); block.addStmt(0, expression.makeStatement()); push(block); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(ThisReference x, BlockScope scope) { try { assert typeMap.get(x.resolvedType) == curClass.getClassOrInterface(); push(makeThisRef(makeSourceInfo(x))); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(ThrowStatement x, BlockScope scope) { try { SourceInfo info = makeSourceInfo(x); JExpression exception = pop(x.exception); push(new JThrowStatement(info, exception)); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(TrueLiteral x, BlockScope scope) { push(JBooleanLiteral.TRUE); } @Override public void endVisit(TryStatement x, BlockScope scope) { try { SourceInfo info = makeSourceInfo(x); JBlock finallyBlock = pop(x.finallyBlock); List catchBlocks = pop(x.catchBlocks); JBlock tryBlock = pop(x.tryBlock); if (x.resources.length > 0) { tryBlock = normalizeTryWithResources(info, x, tryBlock); } List catchClauses = Lists.newArrayList(); if (x.catchBlocks != null) { for (int i = 0; i < x.catchArguments.length; i++) { Argument argument = x.catchArguments[i]; JLocal local = (JLocal) curMethod.locals.get(argument.binding); List catchTypes = Lists.newArrayList(); if (argument.type instanceof UnionTypeReference) { // This is a multiexception for (TypeReference type : ((UnionTypeReference) argument.type).typeReferences) { catchTypes.add(typeMap.get(type.resolvedType)); } } else { // Regular exception catchTypes.add(local.getType()); } catchClauses.add(new JTryStatement.CatchClause(catchTypes, local.makeRef(info), catchBlocks.get(i))); } } push(new JTryStatement(info, tryBlock, catchClauses, finallyBlock)); } catch (Throwable e) { throw translateException(x, e); } } private JBlock normalizeTryWithResources(SourceInfo info, TryStatement x, JBlock tryBlock) { /** * Apply the following source transformation: * * try (A1 a1 = new A1(); ... ; An an = new An()) { * ... tryBlock... * } ...catch/finally blocks * * to * * try { * A1 a1 = null; ...; An an = null; * Throwable $exception = null; * try { * a1 = new A1();... ; an = new An(); * ... tryBlock... * } catch (Throwable t) { * $exception = t; * throw t; * } finally { * $exception = Exceptions.safeClose(an, $exception); * ... * $exception = Exceptions.safeClose(a1, $exception); * if ($exception != null) { * throw $exception; * } * } ...catch/finally blocks * */ JBlock outerTryBlock = new JBlock(info); // add resource variables List resourceVariables = Lists.newArrayList(); for (int i = x.resources.length - 1; i >= 0; i--) { // Needs to iterate back to front to be inline with the contents of the stack. JDeclarationStatement resourceDecl = pop(x.resources[i]); JLocal resourceVar = (JLocal) curMethod.locals.get(x.resources[i].binding); resourceVariables.add(0, resourceVar); tryBlock.addStmt(0, resourceDecl); } // add exception variable JLocal exceptionVar = createLocalThrowable(info, "$primary_ex"); outerTryBlock.addStmt(makeDeclaration(info, exceptionVar, JNullLiteral.INSTANCE)); // create catch block List catchClauses = Lists.newArrayListWithCapacity(1); List clauseTypes = Lists.newArrayListWithCapacity(1); clauseTypes.add(javaLangThrowable); // add catch exception variable. JLocal catchVar = createLocalThrowable(info, "$caught_ex"); JBlock catchBlock = new JBlock(info); catchBlock.addStmt(createAssignment(info, javaLangThrowable, exceptionVar, catchVar)); catchBlock.addStmt(new JThrowStatement(info, exceptionVar.makeRef(info))); catchClauses.add(new JTryStatement.CatchClause(clauseTypes, catchVar.makeRef(info), catchBlock)); // create finally block JBlock finallyBlock = new JBlock(info); for (int i = x.resources.length - 1; i >= 0; i--) { finallyBlock.addStmt(createCloseBlockFor(info, resourceVariables.get(i), exceptionVar)); } // if (exception != null) throw exception JExpression exceptionNotNull = new JBinaryOperation(info, JPrimitiveType.BOOLEAN, JBinaryOperator.NEQ, exceptionVar.makeRef(info), JNullLiteral.INSTANCE); finallyBlock.addStmt(new JIfStatement(info, exceptionNotNull, new JThrowStatement(info, exceptionVar.makeRef(info)), null)); // Stitch all together into a inner try block outerTryBlock.addStmt(new JTryStatement(info, tryBlock, catchClauses, finallyBlock)); return outerTryBlock; } private JLocal createLocalThrowable(SourceInfo info, String prefix) { int index = curMethod.body.getLocals().size() + 1; return JProgram.createLocal(info, prefix + "_" + index, javaLangThrowable, false, curMethod.body); } private JStatement createCloseBlockFor( SourceInfo info, JLocal resourceVar, JLocal exceptionVar) { /** * Create the following code: * * $ex = Exceptions.safeClose(resource, $ex); * * which is equivalent to * * if (resource != null) { * try { * resource.close(); * } catch (Throwable t) { * if ($ex == null) { * $ex = t; * } else { * $ex.addSuppressed(t); * } * } */ JMethodCall safeCloseCall = new JMethodCall(info, null, SAFE_CLOSE_METHOD); safeCloseCall.addArg(0, resourceVar.makeRef(info)); safeCloseCall.addArg(1, exceptionVar.makeRef(info)); return new JBinaryOperation(info, javaLangThrowable, JBinaryOperator.ASG, exceptionVar.makeRef(info), safeCloseCall).makeStatement(); } private JStatement createAssignment(SourceInfo info, JType type, JLocal lhs, JLocal rhs) { return new JBinaryOperation(info, type, JBinaryOperator.ASG, lhs.makeRef(info), rhs.makeRef(info)).makeStatement(); } @Override public void endVisit(TypeDeclaration x, ClassScope scope) { endVisit(x); } @Override public void endVisit(TypeDeclaration x, CompilationUnitScope scope) { endVisit(x); } @Override public void endVisit(UnaryExpression x, BlockScope scope) { try { SourceInfo info = makeSourceInfo(x); JUnaryOperator op; int operator = ((x.bits & ASTNode.OperatorMASK) >> ASTNode.OperatorSHIFT); switch (operator) { case OperatorIds.MINUS: op = JUnaryOperator.NEG; break; case OperatorIds.NOT: op = JUnaryOperator.NOT; break; case OperatorIds.PLUS: // Odd case.. useless + operator; just leave the operand on the // stack. return; case OperatorIds.TWIDDLE: op = JUnaryOperator.BIT_NOT; break; default: throw new InternalCompilerException("Unexpected operator for unary expression"); } JExpression expression = pop(x.expression); push(new JPrefixOperation(info, op, expression)); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisit(WhileStatement x, BlockScope scope) { try { SourceInfo info = makeSourceInfo(x); JStatement action = pop(x.action); JExpression condition = pop(x.condition); push(new JWhileStatement(info, condition, action)); } catch (Throwable e) { throw translateException(x, e); } } @Override public void endVisitValid(TypeDeclaration x, BlockScope scope) { endVisit(x); if (!x.binding.isAnonymousType()) { // Class declaration as a statement; insert a dummy statement. push(null); } } @Override public boolean visit(AnnotationMethodDeclaration x, ClassScope classScope) { return visit((MethodDeclaration) x, classScope); } @Override public boolean visit(Argument x, BlockScope scope) { // handled by parents return true; } @Override public boolean visit(Block x, BlockScope scope) { x.statements = reduceToReachable(x.statements); return true; } @Override public boolean visit(ConstructorDeclaration x, ClassScope scope) { try { JConstructor method = (JConstructor) typeMap.get(x.binding); assert !method.isExternal(); JMethodBody body = new JMethodBody(method.getSourceInfo()); method.setBody(body); pushMethodInfo(new MethodInfo(method, body, x.scope)); // Map all arguments. Iterator it = method.getParams().iterator(); // Enum arguments have no mapping. if (curClass.classType.isEnumOrSubclass() != null) { // Skip past name and ordinal. it.next(); it.next(); } // Map synthetic arguments for outer this. ReferenceBinding declaringClass = (ReferenceBinding) x.binding.declaringClass.erasure(); boolean isNested = JdtUtil.isInnerClass(declaringClass); if (isNested) { NestedTypeBinding nestedBinding = (NestedTypeBinding) declaringClass; if (nestedBinding.enclosingInstances != null) { for (SyntheticArgumentBinding argument : nestedBinding.enclosingInstances) { curMethod.locals.put(argument, it.next()); } } } // Map user arguments. if (x.arguments != null) { for (Argument argument : x.arguments) { curMethod.locals.put(argument.binding, it.next()); } } // Map synthetic arguments for locals. if (isNested) { // add synthetic args for locals NestedTypeBinding nestedBinding = (NestedTypeBinding) declaringClass; // add synthetic args for outer this and locals if (nestedBinding.outerLocalVariables != null) { for (SyntheticArgumentBinding argument : nestedBinding.outerLocalVariables) { curMethod.locals.put(argument, it.next()); } } } x.statements = reduceToReachable(x.statements); return true; } catch (Throwable e) { throw translateException(x, e); } } @Override public boolean visit(ExplicitConstructorCall explicitConstructor, BlockScope scope) { scope.methodScope().isConstructorCall = true; return true; } @Override public boolean visit(FieldDeclaration x, MethodScope scope) { try { assert !typeMap.get(x.binding).isExternal(); pushInitializerMethodInfo(x, scope); return true; } catch (Throwable e) { throw translateException(x, e); } } @Override public boolean visit(Initializer x, MethodScope scope) { try { pushInitializerMethodInfo(x, scope); return true; } catch (Throwable e) { throw translateException(x, e); } } @Override public boolean visit(LocalDeclaration x, BlockScope scope) { try { createLocal(x); return true; } catch (Throwable e) { throw translateException(x, e); } } @Override public boolean visit(MarkerAnnotation annotation, BlockScope scope) { return false; } @Override public boolean visit(MethodDeclaration x, ClassScope scope) { try { JMethod method = typeMap.get(x.binding); assert !method.isExternal(); JMethodBody body = null; if (!method.isJsniMethod()) { body = new JMethodBody(method.getSourceInfo()); method.setBody(body); } pushMethodInfo(new MethodInfo(method, body, x.scope)); // Map user arguments. Iterator it = method.getParams().iterator(); if (x.arguments != null) { for (Argument argument : x.arguments) { curMethod.locals.put(argument.binding, it.next()); } } x.statements = reduceToReachable(x.statements); return true; } catch (Throwable e) { throw translateException(x, e); } } @Override public boolean visit(NormalAnnotation annotation, BlockScope scope) { return false; } @Override public boolean visit(SingleMemberAnnotation annotation, BlockScope scope) { return false; } @Override public boolean visit(SwitchStatement x, BlockScope scope) { x.statements = reduceToReachable(x.statements); return true; } @Override public boolean visit(TryStatement x, BlockScope scope) { try { if (x.catchBlocks != null) { for (Argument argument : x.catchArguments) { createLocal(argument); } } return true; } catch (Throwable e) { throw translateException(x, e); } } @Override public boolean visit(TypeDeclaration x, ClassScope scope) { return visit(x); } @Override public boolean visit(TypeDeclaration x, CompilationUnitScope scope) { return visit(x); } @Override public boolean visitValid(TypeDeclaration x, BlockScope scope) { // Local types actually need to be created now. createTypes(x); resolveTypeRefs(x); createMembers(x); return visit(x); } protected void endVisit(TypeDeclaration x) { JDeclaredType type = curClass.type; // Synthesize super clinit calls. if (type instanceof JClassType) { Iterable interfacesToInitialize = Iterables.transform( JdtUtil.getSuperInterfacesRequiringInitialization(x.binding), new Function() { @Override public JInterfaceType apply(ReferenceBinding referenceBinding) { return (JInterfaceType) typeMap.get(referenceBinding); } }); JjsUtils.synthesizeStaticInitializerChain(type, interfacesToInitialize); } // Implement getClass() implementation for all non-Object classes. if (isSyntheticGetClassNeeded(x, type) && !type.isAbstract()) { implementGetClass(type); } if (type instanceof JEnumType) { processEnumType((JEnumType) type); } if (type instanceof JClassType && type.isJsNative()) { maybeImplementJavaLangObjectMethodsOnNativeClass(type); } addBridgeMethods(x.binding); curClass = classStack.pop(); } protected JBlock pop(Block x) { return (x == null) ? null : (JBlock) pop(); } protected JExpression pop(Expression x) { if (x == null) { return null; } JExpression result = (JExpression) pop(); if (result == null) { assert x instanceof NameReference; return null; } result = maybeBoxOrUnbox(result, x); return result; } protected List performBoxUnboxConversions( List result, Expression[] expressions) { for (int i = 0; i < result.size(); i++) { result.set(i, (T) maybeBoxOrUnbox(result.get(i), expressions[i])); } return result; } @SuppressWarnings("unchecked") protected List pop(Expression[] expressions) { if (expressions == null) { return Collections.emptyList(); } return (List) popList(Collections2.filter(Arrays.asList(expressions), Predicates.notNull()).size()); } protected JDeclarationStatement pop(LocalDeclaration decl) { return (decl == null) ? null : (JDeclarationStatement) pop(); } protected JStatement pop(Statement x) { JNode pop = (x == null) ? null : pop(); if (x instanceof Expression) { return maybeBoxOrUnbox((JExpression) pop, (Expression) x).makeStatement(); } return (JStatement) pop; } @SuppressWarnings("unchecked") protected List pop(Statement[] statements) { if (statements == null) { return Collections.emptyList(); } List result = (List) popList(statements.length); int i = 0; for (ListIterator it = result.listIterator(); it.hasNext(); ++i) { Object element = it.next(); if (element == null) { it.remove(); } else if (element instanceof JExpression) { it.set((T) maybeBoxOrUnbox((JExpression) element, (Expression) statements[i]).makeStatement()); } } return result; } protected JBlock popBlock(SourceInfo info, Statement statement) { JStatement stmt = pop(statement); if (stmt instanceof JBlock) { return (JBlock) stmt; } JBlock block = new JBlock(info); if (stmt != null) { block.addStmt(stmt); } return block; } protected JBlock popBlock(SourceInfo info, Statement[] statements) { List stmts = pop(statements); JBlock block = new JBlock(info); block.addStmts(stmts); return block; } protected void pushBinaryOp(Assignment x, JBinaryOperator op) { pushBinaryOp(x, op, x.lhs, x.expression); } protected void pushBinaryOp(BinaryExpression x, JBinaryOperator op) { pushBinaryOp(x, op, x.left, x.right); } protected boolean visit(TypeDeclaration x) { JDeclaredType type = (JDeclaredType) typeMap.get(x.binding); assert !type.isExternal(); classStack.push(curClass); curClass = new ClassInfo(type, x); /* * It's okay to defer creation of synthetic fields, they can't be * referenced until we analyze the code. */ SourceTypeBinding binding = x.binding; if (JdtUtil.isInnerClass(binding)) { // add synthetic fields for outer this and locals assert (type instanceof JClassType); NestedTypeBinding nestedBinding = (NestedTypeBinding) binding; if (nestedBinding.enclosingInstances != null) { for (SyntheticArgumentBinding argument : nestedBinding.enclosingInstances) { createSyntheticField(argument, type, Disposition.THIS_REF); } } if (nestedBinding.outerLocalVariables != null) { for (SyntheticArgumentBinding argument : nestedBinding.outerLocalVariables) { // See InnerClassTest.testOuterThisFromSuperCall(). boolean isReallyThisRef = false; if (argument.actualOuterLocalVariable instanceof SyntheticArgumentBinding) { SyntheticArgumentBinding outer = (SyntheticArgumentBinding) argument.actualOuterLocalVariable; if (outer.matchingField != null) { JField field = typeMap.get(outer.matchingField); if (field.isThisRef()) { isReallyThisRef = true; } } } createSyntheticField(argument, type, isReallyThisRef ? Disposition.THIS_REF : Disposition.FINAL); } } } return true; } /** *

* Add a bridge method to clazzBinding for any method it * inherits that implements an interface method but that has a different * erased signature from the interface method. *

* *

* The need for these bridges was pointed out in issue 3064. The goal is * that virtual method calls through an interface type are translated to * JavaScript that will function correctly. If the interface signature * matches the signature of the implementing method, then nothing special * needs to be done. If they are different, due to the use of generics, then * GenerateJavaScriptAST is careful to do the right thing. There is a * remaining case, though, that GenerateJavaScriptAST is not in a good * position to fix: a method could be inherited from a superclass, used to * implement an interface method that has a different type signature, and * does not have the interface method in its list of overrides. In that * case, a bridge method should be added that overrides the interface method * and then calls the implementation method. *

* *

* This method should only be called once all regular, non-bridge methods * have been installed on the GWT types. *

*/ private void addBridgeMethods(SourceTypeBinding classBinding) { /* * JDT adds bridge methods in all the places GWT needs them. Use JDT's * bridge methods. */ if (classBinding.syntheticMethods() != null) { for (SyntheticMethodBinding syntheticMethodBinding : classBinding.syntheticMethods()) { if (syntheticMethodBinding.purpose == SyntheticMethodBinding.BridgeMethod && !syntheticMethodBinding.isStatic()) { createBridgeMethod(syntheticMethodBinding); } } } } private JBinaryOperation assignSyntheticField(SourceInfo info, SyntheticArgumentBinding arg) { JParameter param = (JParameter) curMethod.locals.get(arg); assert param != null; JField field = curClass.syntheticFields.get(arg); assert field != null; JFieldRef lhs = makeInstanceFieldRef(info, field); return new JBinaryOperation(info, lhs.getType(), JBinaryOperator.ASG, lhs, param.makeRef(info)); } private JExpression box(JExpression original, BaseTypeBinding primitiveType) { return box(original, primitiveType, false); } private JExpression box( JExpression original, BaseTypeBinding primitiveType, boolean doNotAutobox) { // Add a cast to the correct primitive type if needed. JType targetPrimitiveType = typeMap.get(primitiveType); if (original.getType() != targetPrimitiveType) { original = new JCastOperation(original.getSourceInfo(), targetPrimitiveType, original); } if (doNotAutobox) { // Protect the primitive @DoNotAutobox values from optimizations, etc but encapsulating // them in an opaque unsafe coercion to Object. return new JUnsafeTypeCoercion(original.getSourceInfo(), javaLangObject, original); } ClassScope scope = curClass.scope; JMethod boxingMethod = typeMap.get(JdtUtil.getBoxingMethodBinding(scope, primitiveType)); return new JMethodCall(original.getSourceInfo(), null, boxingMethod, original); } private JExpression unbox(JExpression original, BaseTypeBinding primitiveType) { return unbox(original, primitiveType, true); } private JExpression unbox( JExpression original, BaseTypeBinding primitiveType, boolean needsExplicitCast) { ClassScope scope = curClass.scope; if (needsExplicitCast) { // Direct cast from non-boxed-type reference type to a primitive type, // wrap with a cast operation of the (boxed) expected type. JReferenceType boxedType = (JReferenceType) typeMap.get(JdtUtil.getBoxedTypeBinding(scope, primitiveType)); original = new JCastOperation(original.getSourceInfo(), boxedType, original); } JMethod unboxingMethod = typeMap.get(JdtUtil.getUnboxingMethodBinding(scope, primitiveType)); return new JMethodCall(original.getSourceInfo(), original, unboxingMethod); } private void createBridgeMethod(SyntheticMethodBinding jdtBridgeMethod) { JMethod targetMethod = typeMap.get(jdtBridgeMethod.targetMethod); createBridgeMethod(curClass.type, jdtBridgeMethod, targetMethod); } /** * Create a bridge method. It calls a same-named method with the same * arguments, but with a different type signature. */ private JMethod createBridgeMethod( JDeclaredType enclosingType, MethodBinding sourceMethodBinding, JMethod targetMethod) { JType returnType = typeMap.get(sourceMethodBinding.returnType); Iterable parameterTypes = mapTypes(sourceMethodBinding.parameters); Iterable thrownExceptionTypes = mapTypes(sourceMethodBinding.thrownExceptions); SourceInfo info = targetMethod.getSourceInfo(); JMethod bridgeMethod = new JMethod(info, targetMethod.getName(), enclosingType, returnType, false, false, targetMethod.isFinal(), targetMethod.getAccess()); bridgeMethod.setBody(new JMethodBody(info)); if (enclosingType instanceof JInterfaceType) { // Mark bridges created in interfaces as default methods so they are processed correctly // by the rest of the pipeline. bridgeMethod.setDefaultMethod(true); } bridgeMethod.setSynthetic(); enclosingType.addMethod(bridgeMethod); int paramIndex = 0; List implParams = targetMethod.getParams(); for (JType parameterType : parameterTypes) { JParameter parameter = implParams.get(paramIndex++); bridgeMethod.createFinalParameter( parameter.getSourceInfo(), parameter.getName(), parameterType); } for (JClassType thrownException : thrownExceptionTypes) { bridgeMethod.addThrownException(thrownException); } bridgeMethod.freezeParamTypes(); // create a call and pass all arguments through, casting if necessary JMethodCall call = new JMethodCall(info, makeThisRef(info), targetMethod); for (int i = 0; i < bridgeMethod.getParams().size(); i++) { JParameter param = bridgeMethod.getParams().get(i); call.addArg(maybeCast(implParams.get(i).getType(), param.makeRef(info))); } JMethodBody body = (JMethodBody) bridgeMethod.getBody(); if (bridgeMethod.getType() == JPrimitiveType.VOID) { body.getBlock().addStmt(call.makeStatement()); } else { body.getBlock().addStmt(call.makeReturnStatement()); } typeMap.setMethod(sourceMethodBinding, bridgeMethod); return bridgeMethod; } private void writeEnumValuesMethod(JEnumType type, JMethod method) { // return new E[]{A,B,C}; JArrayType enumArrayType = new JArrayType(type); SourceInfo info = type.getSourceInfo(); List initializers = Lists.newArrayList(); for (JEnumField field : type.getEnumList()) { JFieldRef fieldRef = new JFieldRef(info, null, field, type); initializers.add(fieldRef); } JNewArray valuesArrayCopy = JNewArray.createArrayWithInitializers(info, enumArrayType, initializers); if (type.getEnumList().size() > MAX_INLINEABLE_ENUM_SIZE) { // Only inline values() if it is small. method.setInliningMode(InliningMode.DO_NOT_INLINE); } JjsUtils.replaceMethodBody(method, valuesArrayCopy); } private JLocal createLocal(LocalDeclaration x) { LocalVariableBinding b = x.binding; TypeBinding resolvedType = x.type.resolvedType; JType localType; if (resolvedType.constantPoolName() != null) { localType = typeMap.get(resolvedType); } else { // Special case, a statically unreachable local type. localType = JReferenceType.NULL_TYPE; } SourceInfo info = makeSourceInfo(x); JLocal newLocal = JProgram.createLocal(info, intern(x.name), localType, b.isFinal(), curMethod.body); curMethod.locals.put(b, newLocal); return newLocal; } private JField createSyntheticField(SyntheticArgumentBinding arg, JDeclaredType enclosingType, Disposition disposition) { JType type = typeMap.get(arg.type); SourceInfo info = enclosingType.getSourceInfo(); // Construct field name including position because JDT can sometimes create multiple synthetic // fields with the same name. The increased name size won't affect optimized output since // references are pruned and renamed. String fieldName = intern(intern(arg.name) + arg.resolvedPosition); JField field = new JField(info, fieldName, enclosingType, type, false, disposition, AccessModifier.PRIVATE); enclosingType.addField(field); curClass.syntheticFields.put(arg, field); if (arg.matchingField != null) { typeMap.setField(arg.matchingField, field); } return field; } private JExpression getConstant(SourceInfo info, Constant constant) { switch (constant.typeID()) { case TypeIds.T_int: return JIntLiteral.get(constant.intValue()); case TypeIds.T_byte: return JIntLiteral.get(constant.byteValue()); case TypeIds.T_short: return JIntLiteral.get(constant.shortValue()); case TypeIds.T_char: return JCharLiteral.get(constant.charValue()); case TypeIds.T_float: return JFloatLiteral.get(constant.floatValue()); case TypeIds.T_double: return JDoubleLiteral.get(constant.doubleValue()); case Constant.T_boolean: return JBooleanLiteral.get(constant.booleanValue()); case Constant.T_long: return JLongLiteral.get(constant.longValue()); case Constant.T_JavaLangString: return getStringLiteral(info, constant.stringValue()); case Constant.T_null: return JNullLiteral.INSTANCE; default: throw new InternalCompilerException("Unknown Constant type: " + constant.typeID()); } } /** * Get a new label of a particular name, or create a new one if it doesn't * exist already. */ private JLabel getOrCreateLabel(SourceInfo info, char[] name) { if (name == null) { return null; } String sname = intern(name); JLabel jlabel = curMethod.labels.get(sname); if (jlabel == null) { jlabel = new JLabel(info, sname); curMethod.labels.put(sname, jlabel); } return jlabel; } private JStringLiteral getStringLiteral(SourceInfo info, char[] chars) { return new JStringLiteral(info, intern(chars), javaLangString); } private JStringLiteral getStringLiteral(SourceInfo info, String string) { return new JStringLiteral(info, intern(string), javaLangString); } private void implementGetClass(JDeclaredType type) { // TODO(rluble): Object.getClass() should be final our JRE, when that is done, GwtAstBuilder // creates overrides for convenience and should unmark Object.getClass as final for // consistency. JMethod method = type.getMethods().get(GET_CLASS_METHOD_INDEX); assert (GET_CLASS_METHOD_NAME.equals(method.getName())); SourceInfo info = method.getSourceInfo(); if (type.isJsoType()) { // Native types and JSOs get a synthetic get class that return JavaScriptObject.class. // // return Cast.getClass(this) JjsUtils.replaceMethodBody(method, new JMethodCall(info, null, CAST_GET_CLASS_METHOD, new JThisRef(info, type))); } else { JjsUtils.replaceMethodBody(method, new JClassLiteral(info, type)); } } private void maybeImplementJavaLangObjectMethodsOnNativeClass(JDeclaredType type) { maybeCreateSyntheticJavaLangObjectMethodNativeOverride( type, EQUALS_METHOD_NAME, JPrimitiveType.BOOLEAN, javaLangObject); maybeCreateSyntheticJavaLangObjectMethodNativeOverride( type, HASHCODE_METHOD_NAME, JPrimitiveType.INT); maybeCreateSyntheticJavaLangObjectMethodNativeOverride( type, TO_STRING_METHOD_NAME, javaLangString); } private void maybeCreateSyntheticJavaLangObjectMethodNativeOverride( JDeclaredType type, String name, JType returnType, JType... parameterTypes) { SourceInfo info = type.getSourceInfo(); JMethod method = new JMethod(info, name, type, returnType, false, false, false, AccessModifier.PUBLIC); int i = 0; for (JType parameterType : parameterTypes) { method.createParameter(info, "arg" + i++, parameterType); } method.freezeParamTypes(); // Do not mark this methods as synthetic because of the risk of missing some checks in // JsInteropRestrictionChecker where we skip synthetic methods in many of the checks. assert (!method.isSynthetic()); // Creating a method without a body makes it native. assert (method.isJsNative()); final String signature = method.getJsniSignature(false, false); boolean alreadyExists = Iterables.any(type.getMethods(), new Predicate() { @Override public boolean apply(JMethod typeMethod) { return typeMethod.getJsniSignature(false, false).equals(signature); } }); if (alreadyExists) { return; } type.addMethod(method); // This method is declared in a native JsType, make sure JsInfo is populated correctly, by // applying the JsType rules. JsInteropUtil.maybeSetJsInteropProperties(method, shouldExport(method)); assert (method.getJsMemberType() == JsMemberType.METHOD); } private JDeclarationStatement makeDeclaration(SourceInfo info, JLocal local, JExpression value) { return new JDeclarationStatement(info, local.makeRef(info), value); } private JFieldRef makeInstanceFieldRef(SourceInfo info, JField field) { return new JFieldRef(info, makeThisRef(info), field, curClass.classType); } private JExpression makeLocalRef(SourceInfo info, LocalVariableBinding b, MethodInfo method) { return method.locals.get(b).makeRef(info); } private JThisRef makeThisRef(SourceInfo info) { return new JThisRef(info, curClass.getClassOrInterface()); } private JExpression resolveThisReference(SourceInfo info, ReferenceBinding targetType, boolean exactMatch, BlockScope scope) { targetType = (ReferenceBinding) targetType.erasure(); Object[] path = scope.getEmulationPath(targetType, exactMatch, false); if (path == null) { throw new InternalCompilerException("No emulation path."); } if (path == BlockScope.EmulationPathToImplicitThis) { return makeThisRef(info); } JExpression ref; ReferenceBinding type; if (curMethod.scope.isInsideInitializer() && path[0] instanceof SyntheticArgumentBinding) { SyntheticArgumentBinding b = (SyntheticArgumentBinding) path[0]; JField field = curClass.syntheticFields.get(b); assert field != null; ref = makeInstanceFieldRef(info, field); type = (ReferenceBinding) b.type.erasure(); } else if (path[0] instanceof SyntheticArgumentBinding) { SyntheticArgumentBinding b = (SyntheticArgumentBinding) path[0]; JParameter param = (JParameter) curMethod.locals.get(b); assert param != null; ref = param.makeRef(info); type = (ReferenceBinding) b.type.erasure(); } else if (path[0] instanceof FieldBinding) { FieldBinding b = (FieldBinding) path[0]; JField field = typeMap.get(b); assert field != null; ref = makeInstanceFieldRef(info, field); type = (ReferenceBinding) b.type.erasure(); } else { throw new InternalCompilerException("Unknown emulation path."); } for (int i = 1; i < path.length; ++i) { SyntheticMethodBinding b = (SyntheticMethodBinding) path[i]; assert type == b.declaringClass.erasure(); FieldBinding fieldBinding = b.targetReadField; JField field = typeMap.get(fieldBinding); assert field != null; ref = new JFieldRef(info, ref, field, curClass.classType); type = (ReferenceBinding) fieldBinding.type.erasure(); } return ref; } private JExpression maybeBoxOrUnbox(JExpression original, int implicitConversion) { return maybeBoxOrUnbox(original, implicitConversion, false); } private JExpression maybeBoxOrUnbox( JExpression original, int implicitConversion, boolean doNotAutobox) { if (JdtUtil.requiresBoxing(implicitConversion)) { return box(original, JdtUtil.getBoxingPrimitiveType(curClass.scope, implicitConversion), doNotAutobox); } if (JdtUtil.requiresUnboxing(implicitConversion)) { return unbox(original, JdtUtil.getUnboxingPrimitiveType(curClass.scope, implicitConversion), JdtUtil.needsCastBeforeUnbox(curClass.scope, implicitConversion)); } return original; } private JExpression maybeCast(JType[] expected, JExpression expression) { for (JType type : expected) { expression = maybeCast(type, expression); } return expression; } private JExpression maybeCast(JType expected, JExpression expression) { if (expected != expression.getType()) { // Must be a generic cast; insert a cast operation. return new JCastOperation(expression.getSourceInfo(), expected, expression); } return expression; } private JExpression maybeInsertUnsafeTypeCoercion(JType expected, JExpression expression) { if (expected != expression.getType()) { // A generic call marked as @UncheckedCast. return new JUnsafeTypeCoercion(expression.getSourceInfo(), expected, expression); } return expression; } private JNode pop() { return nodeStack.remove(nodeStack.size() - 1); } private List popCallArguments(SourceInfo info, Expression[] arguments, MethodBinding methodBinding) { List args = pop(arguments); for (int i = 0; i < args.size(); i++) { // Account for varargs parameter. int parameterIndex = Math.min(i, methodBinding.parameters.length - 1); args.set(i, maybeBoxOrUnbox( args.get(i), arguments[i].implicitConversion, isDoNotAutoBoxParameter(methodBinding, parameterIndex))); } if (!methodBinding.isVarargs()) { return args; } // Handle the odd var-arg case. if (arguments == null) { // Get writable collection (args is currently Collections.emptyList()). args = Lists.newArrayListWithCapacity(1); } TypeBinding[] params = methodBinding.parameters; int varArg = params.length - 1; // See if there's a single varArg which is already an array. if (args.size() == params.length) { if (arguments[varArg].resolvedType.isCompatibleWith(params[varArg])) { // Already the correct array type. return args; } } // Need to synthesize an appropriately-typed array. List tail = args.subList(varArg, args.size()); List initializers = Lists.newArrayList(tail); tail.clear(); JArrayType lastParamType = (JArrayType) typeMap.get(params[varArg]); JNewArray newArray = JNewArray.createArrayWithInitializers(info, lastParamType, initializers); args.add(newArray); return args; } private boolean isDoNotAutoBoxParameter(MethodBinding methodBinding, int parameterIndex) { AnnotationBinding[][] parameterAnnotations = methodBinding.original().getParameterAnnotations(); return parameterAnnotations != null && parameterAnnotations.length > parameterIndex && parameterAnnotations[parameterIndex] != null && JdtUtil.getAnnotationByName(parameterAnnotations[parameterIndex], "javaemul.internal.annotations.DoNotAutobox") != null; } private List popList(int count) { List tail = nodeStack.subList(nodeStack.size() - count, nodeStack.size()); // Make a copy. List result = Lists.newArrayList(tail); // Causes the tail to be removed. tail.clear(); return result; } private void popMethodInfo() { curMethod = methodStack.pop(); } private void processEnumType(JEnumType type) { // $clinit, $init, getClass, valueOf, values JMethod valueOfMethod = type.getMethods().get(getEnumMethodsStartIndex(type) + VALUE_OF_METHOD_OFFSET); JMethod valuesMethod = type.getMethods().get(getEnumMethodsStartIndex(type) + VALUES_METHOD_OFFSET); { assert VALUE_OF_METHOD_NAME.equals(valueOfMethod.getName()); writeEnumValueOfMethod(type, valueOfMethod, valuesMethod); } { assert VALUES_METHOD_NAME.equals(valuesMethod.getName()); writeEnumValuesMethod(type, valuesMethod); } } private void processNativeMethod(MethodDeclaration x) { JMethod method = curMethod.method; JsniMethod jsniMethod = jsniMethods.get(x); if (jsniMethod == null) { method.setBody(null); return; } SourceInfo info = method.getSourceInfo(); JsFunction jsFunction = jsniMethod.function(); JsniMethodBody body = new JsniMethodBody(info); method.setBody(body); jsFunction.setFromJava(true); body.setFunc(jsFunction); // Resolve locals, params, and JSNI. JsParameterResolver localResolver = new JsParameterResolver(jsFunction); localResolver.accept(jsFunction); JsniReferenceCollector jsniReferenceCollector = new JsniReferenceCollector(body); jsniReferenceCollector.accept(jsFunction); } private void processSuperCallLocalArgs(ReferenceBinding superClass, JMethodCall call) { if (superClass.syntheticOuterLocalVariables() != null) { for (SyntheticArgumentBinding arg : superClass.syntheticOuterLocalVariables()) { // TODO: use emulation path here. // Got to be one of my params JType varType = typeMap.get(arg.type); String varName = intern(arg.name); JParameter param = null; for (JParameter paramIt : curMethod.method.getParams()) { if (varType == paramIt.getType() && varName.equals(paramIt.getName())) { param = paramIt; } } if (param == null) { throw new InternalCompilerException( "Could not find matching local arg for explicit super ctor call."); } call.addArg(param.makeRef(call.getSourceInfo())); } } } // Only called on nested instances constructors (explicitConstructorCalls) that are of the // form: outer.super(...) or super(...) // // Will set outer (in the first case) or the implicit enclosing object reference to // be the first parameter of super(...) private void processSuperCallThisArgs(ReferenceBinding superClass, JMethodCall call, JExpression qualifier, Expression qualification) { // Explicit super calls can only happend inside constructors assert curMethod.scope.isInsideConstructor(); if (superClass.syntheticEnclosingInstanceTypes() != null) { // there can only be ONE immediate enclosing instance. assert superClass.syntheticEnclosingInstanceTypes().length == 1; ReferenceBinding targetType = superClass.syntheticEnclosingInstanceTypes()[0]; if (qualification != null) { // Outer object is the qualifier. call.addArg(qualifier); } else { // Get implicit outer object. call.addArg( resolveThisReference(call.getSourceInfo(), targetType, false, curMethod.scope)); } } } private void processThisCallLocalArgs(ReferenceBinding binding, JMethodCall call) { if (binding.syntheticOuterLocalVariables() != null) { for (SyntheticArgumentBinding arg : binding.syntheticOuterLocalVariables()) { JParameter param = (JParameter) curMethod.locals.get(arg); assert param != null; call.addArg(param.makeRef(call.getSourceInfo())); } } } private void processThisCallThisArgs(ReferenceBinding binding, JMethodCall call) { if (binding.syntheticEnclosingInstanceTypes() != null) { Iterator paramIt = curMethod.method.getParams().iterator(); if (curClass.classType.isEnumOrSubclass() != null) { // Skip past the enum args. paramIt.next(); paramIt.next(); } for (@SuppressWarnings("unused") ReferenceBinding argType : binding.syntheticEnclosingInstanceTypes()) { JParameter param = paramIt.next(); call.addArg(param.makeRef(call.getSourceInfo())); } } } private void push(JNode node) { nodeStack.add(node); } private void pushBinaryOp(Expression x, JBinaryOperator op, Expression lhs, Expression rhs) { try { JType type = typeMap.get(x.resolvedType); SourceInfo info = makeSourceInfo(x); JExpression exprArg2 = pop(rhs); JExpression exprArg1 = pop(lhs); push(new JBinaryOperation(info, type, op, exprArg1, exprArg2)); } catch (Throwable e) { throw translateException(x, e); } } private void pushInitializerMethodInfo(FieldDeclaration x, MethodScope scope) { JMethod initMethod; if (x.isStatic()) { initMethod = curClass.type.getClinitMethod(); } else { initMethod = curClass.type.getInitMethod(); } pushMethodInfo(new MethodInfo(initMethod, (JMethodBody) initMethod.getBody(), scope)); } private void pushMethodInfo(MethodInfo newInfo) { methodStack.push(curMethod); curMethod = newInfo; } private void pushNewExpression(SourceInfo info, AllocationExpression x, Expression qualifier, List arguments, BlockScope scope) { TypeBinding typeBinding = x.resolvedType; if (typeBinding.constantPoolName() == null) { /* * Weird case: if JDT determines that this local class is totally * uninstantiable, it won't bother allocating a local name. */ push(JNullLiteral.INSTANCE); return; } assert typeBinding.isClass() || typeBinding.isEnum(); MethodBinding b = x.binding; assert b.isConstructor(); JConstructor ctor = (JConstructor) typeMap.get(b); JMethodCall call = new JNewInstance(info, ctor); JExpression qualExpr = pop(qualifier); // Enums: hidden arguments for the name and id. if (x.enumConstant != null) { call.addArgs(getStringLiteral(info, x.enumConstant.name), JIntLiteral .get(x.enumConstant.binding.original().id)); } // Synthetic args for inner classes ReferenceBinding targetBinding = (ReferenceBinding) b.declaringClass.erasure(); boolean isNested = JdtUtil.isInnerClass(targetBinding); if (isNested) { // Synthetic this args for inner classes if (targetBinding.syntheticEnclosingInstanceTypes() != null) { ReferenceBinding checkedTargetType = targetBinding.isAnonymousType() ? (ReferenceBinding) targetBinding.superclass() .erasure() : targetBinding; ReferenceBinding targetEnclosingType = checkedTargetType.enclosingType(); for (ReferenceBinding argType : targetBinding.syntheticEnclosingInstanceTypes()) { argType = (ReferenceBinding) argType.erasure(); if (qualifier != null && argType == targetEnclosingType) { call.addArg(qualExpr); } else { JExpression thisRef = resolveThisReference(info, argType, false, scope); call.addArg(thisRef); } } } } // Plain old regular user arguments call.addArgs(arguments); // Synthetic args for inner classes if (isNested) { // Synthetic locals for local classes if (targetBinding.syntheticOuterLocalVariables() != null) { for (SyntheticArgumentBinding arg : targetBinding.syntheticOuterLocalVariables()) { LocalVariableBinding targetVariable = arg.actualOuterLocalVariable; VariableBinding[] path = scope.getEmulationPath(targetVariable); assert path.length == 1; if (curMethod.scope.isInsideInitializer() && path[0] instanceof SyntheticArgumentBinding) { SyntheticArgumentBinding sb = (SyntheticArgumentBinding) path[0]; JField field = curClass.syntheticFields.get(sb); assert field != null; call.addArg(makeInstanceFieldRef(info, field)); } else if (path[0] instanceof LocalVariableBinding) { JExpression localRef = makeLocalRef(info, (LocalVariableBinding) path[0], curMethod); call.addArg(localRef); } else if (path[0] instanceof FieldBinding) { JField field = typeMap.get((FieldBinding) path[0]); assert field != null; call.addArg(makeInstanceFieldRef(info, field)); } else { throw new InternalCompilerException("Unknown emulation path."); } } } } push(call); } /** * Don't process unreachable statements, because JDT doesn't always fully * resolve them, which can crash us. */ private Statement[] reduceToReachable(Statement[] statements) { if (statements == null) { return null; } int reachableCount = 0; for (Statement statement : statements) { if ((statement.bits & ASTNode.IsReachable) != 0) { ++reachableCount; } } if (reachableCount == statements.length) { return statements; } Statement[] newStatments = new Statement[reachableCount]; int index = 0; for (Statement statement : statements) { if ((statement.bits & ASTNode.IsReachable) != 0) { newStatments[index++] = statement; } } return newStatments; } private JExpression resolveNameReference(NameReference x, BlockScope scope) { SourceInfo info = makeSourceInfo(x); Binding binding = x.binding; if (isOptimizableCompileTimeConstant(binding)) { return getConstant(info, x.constant); } JExpression result = null; if (binding instanceof LocalVariableBinding) { LocalVariableBinding b = (LocalVariableBinding) binding; MethodScope nearestMethodScope = scope instanceof MethodScope ? (MethodScope) scope : scope.enclosingMethodScope(); if ((x.bits & ASTNode.DepthMASK) != 0 || nearestMethodScope.isLambdaScope()) { VariableBinding[] path = scope.getEmulationPath(b); if (path == null) { /* * Don't like this, but in rare cases (e.g. the variable is only * ever used as an unnecessary qualifier) JDT provides no emulation * to the desired variable. */ // throw new InternalCompilerException("No emulation path."); return null; } assert path.length == 1; if (curMethod.scope.isInsideInitializer() && path[0] instanceof SyntheticArgumentBinding) { SyntheticArgumentBinding sb = (SyntheticArgumentBinding) path[0]; JField field = curClass.syntheticFields.get(sb); assert field != null; result = makeInstanceFieldRef(info, field); } else if (path[0] instanceof LocalVariableBinding) { result = makeLocalRef(info, (LocalVariableBinding) path[0], curMethod); } else if (path[0] instanceof FieldBinding) { FieldBinding fb = (FieldBinding) path[0]; assert curClass.typeDecl.binding.isCompatibleWith(x.actualReceiverType.erasure()); JField field = typeMap.get(fb); assert field != null; result = makeInstanceFieldRef(info, field); } else { throw new InternalCompilerException("Unknown emulation path."); } } else { result = makeLocalRef(info, b, curMethod); } } else if (binding instanceof FieldBinding) { FieldBinding b = ((FieldBinding) x.binding).original(); JField field = typeMap.get(b); assert field != null; JExpression thisRef = null; if (!b.isStatic()) { thisRef = resolveThisReference(info, (ReferenceBinding) x.actualReceiverType, false, scope); } result = new JFieldRef(info, thisRef, field, curClass.type); } else { return null; } assert result != null; return result; } private JExpression maybeBoxOrUnbox(JExpression result, Expression x) { return maybeBoxOrUnbox(result, x.implicitConversion); } private JExpression synthesizeCallToOrdinal(BlockScope scope, SourceInfo info, JExpression expression) { ReferenceBinding javaLangEnum = scope.getJavaLangEnum(); MethodBinding ordinal = javaLangEnum.getMethods(ORDINAL_)[0]; expression = new JMethodCall(info, expression, typeMap.get(ordinal)); return expression; } private void writeEnumValueOfMethod(JEnumType type, JMethod method, JMethod valuesMethod) { JField mapField; TypeBinding mapType; ReferenceBinding enumType = curCud.scope.getJavaLangEnum(); { /* * Make an inner class to hold a lazy-init name-value map. We use a * class to take advantage of its clinit. * * class Map { $MAP = Enum.createValueOfMap(values()); } */ SourceInfo info = type.getSourceInfo(); JClassType mapClass = new JClassType(info, intern(type.getName() + "$Map"), false, true); mapClass.setSuperClass(javaLangObject); mapClass.setEnclosingType(type); newTypes.add(mapClass); MethodBinding[] createValueOfMapBindings = enumType.getMethods(CREATE_VALUE_OF_MAP_); if (createValueOfMapBindings.length == 0) { throw new RuntimeException( "Unexpectedly unable to access Enum.createValueOfMap via reflection. " + "Likely a dependency on the com.google.gwt.user.User module is missing."); } MethodBinding createValueOfMapBinding = createValueOfMapBindings[0]; mapType = createValueOfMapBinding.returnType; mapField = new JField(info, "$MAP", mapClass, typeMap.get(mapType), true, Disposition.FINAL, AccessModifier.PRIVATE); mapClass.addField(mapField); JMethodCall call = new JMethodCall(info, null, typeMap.get(createValueOfMapBinding)); call.addArg(new JMethodCall(info, null, valuesMethod)); JFieldRef mapRef = new JFieldRef(info, null, mapField, mapClass); JDeclarationStatement declStmt = new JDeclarationStatement(info, mapRef, call); JMethod clinit = createSyntheticMethod(info, "$clinit", mapClass, JPrimitiveType.VOID, false, true, true, AccessModifier.PRIVATE); JBlock clinitBlock = ((JMethodBody) clinit.getBody()).getBlock(); clinitBlock.addStmt(declStmt); } /* * return Enum.valueOf(Enum$Map.Map.$MAP, name); */ { SourceInfo info = method.getSourceInfo(); MethodBinding valueOfBinding = enumType.getExactMethod(VALUE_OF_, new TypeBinding[]{ mapType, curCud.scope.getJavaLangString()}, curCud.scope); assert valueOfBinding != null; JFieldRef mapRef = new JFieldRef(info, null, mapField, type); JParameterRef nameRef = method.getParams().get(0).makeRef(info); JMethodCall call = new JMethodCall(info, null, typeMap.get(valueOfBinding)); call.addArgs(mapRef, nameRef); JjsUtils.replaceMethodBody(method, call); } } private JCastOperation buildCastOperation(SourceInfo info, JType[] castTypes, JExpression expression) { return buildCastOperation(info, castTypes, expression, 0); } private JCastOperation buildCastOperation(SourceInfo info, JType[] castTypes, JExpression expression, int idx) { if (idx == castTypes.length - 1) { return new JCastOperation(info, castTypes[idx], expression); } else { return new JCastOperation(info, castTypes[idx], buildCastOperation(info, castTypes, expression, idx + 1)); } } private JReferenceType[] processIntersectionCastType(IntersectionTypeBinding18 type) { JReferenceType[] castTypes = new JReferenceType[type.intersectingTypes.length]; int i = 0; for (ReferenceBinding intersectingTypeBinding : type.intersectingTypes) { JType intersectingType = typeMap.get(intersectingTypeBinding); assert (intersectingType instanceof JReferenceType); castTypes[i++] = ((JReferenceType) intersectingType); } return castTypes; } private JType[] processCastType(TypeBinding type) { if (type instanceof IntersectionTypeBinding18) { return processIntersectionCastType((IntersectionTypeBinding18) type); } else { return new JType[] {typeMap.get(type)}; } } private JInterfaceType[] processIntersectionTypeForLambda(IntersectionTypeBinding18 type, BlockScope scope, String samSignature) { List interfaces = Lists.newArrayList(); for (ReferenceBinding intersectingTypeBinding : type.intersectingTypes) { if (shouldImplements(intersectingTypeBinding, scope, samSignature)) { JType intersectingType = typeMap.get(intersectingTypeBinding); assert (intersectingType instanceof JInterfaceType); interfaces.add(((JInterfaceType) intersectingType)); } } return Iterables.toArray(interfaces, JInterfaceType.class); } private boolean isFunctionalInterfaceWithMethod(ReferenceBinding referenceBinding, Scope scope, String samSignature) { if (!referenceBinding.isInterface()) { return false; } MethodBinding abstractMethod = referenceBinding.getSingleAbstractMethod(scope, false); return abstractMethod != null && abstractMethod.isValidBinding() && JdtUtil.signature(abstractMethod).equals(samSignature); } private boolean isInterfaceHasNoAbstractMethod(ReferenceBinding referenceBinding, Scope scope) { List abstractMethods = getInterfaceAbstractMethods(referenceBinding, scope); return abstractMethods != null && abstractMethods.size() == 0; } private boolean shouldImplements(ReferenceBinding referenceBinding, Scope scope, String samSignature) { return isFunctionalInterfaceWithMethod(referenceBinding, scope, samSignature) || isInterfaceHasNoAbstractMethod(referenceBinding, scope); } /** * Collect all abstract methods in an interface and its super interfaces. * * In the case of multiple inheritance like this, * * interface I {m();} * interface J {default m();} * interface K extends I, J{} * * the abstract methods of K include m(); */ private List getInterfaceAbstractMethods(ReferenceBinding referenceBinding, Scope scope) { if (!referenceBinding.isInterface() || !referenceBinding.isValidBinding()) { return null; } List abstractMethods = Lists.newLinkedList(); // add all abstract methods from super interfaces. for (ReferenceBinding superInterface : referenceBinding.superInterfaces()) { List abstractMethodsFromSupers = getInterfaceAbstractMethods(superInterface, scope); if (abstractMethodsFromSupers != null && abstractMethodsFromSupers.size() > 0) { abstractMethods.addAll(abstractMethodsFromSupers); } } for (MethodBinding method : referenceBinding.methods()) { if (method == null || method.isStatic() || method.redeclaresPublicObjectMethod(scope)) { continue; } // remove the overridden methods in the super interfaces. for (MethodBinding abstractMethodFromSupers : abstractMethods) { if (MethodVerifier.doesMethodOverride(method, abstractMethodFromSupers, scope.environment())) { abstractMethods.remove(abstractMethodFromSupers); } } // add method to abstract methods if it is not a default method. if (!method.isDefaultMethod()) { abstractMethods.add(method); } } return abstractMethods; } } private Iterable mapTypes(TypeBinding[] types) { return FluentIterable.from(Arrays.asList(types)).transform( new Function() { @Override public T apply(TypeBinding typeBinding) { return (T) typeMap.get(typeBinding.erasure()); } }); } static class ClassInfo { public final JClassType classType; public final ClassScope scope; public final Map syntheticFields = Maps.newIdentityHashMap(); public final JDeclaredType type; public final TypeDeclaration typeDecl; public ClassInfo(JDeclaredType type, TypeDeclaration x) { this.type = type; this.classType = (type instanceof JClassType) ? (JClassType) type : null; this.typeDecl = x; this.scope = x.scope; } public JDeclaredType getClassOrInterface() { return classType == null ? type : classType; } } static class CudInfo { public final CompilationUnitScope scope; public final int[] separatorPositions; public final CompilationUnitDeclaration cud; public CudInfo(CompilationUnitDeclaration cud) { separatorPositions = cud.compilationResult().getLineSeparatorPositions(); scope = cud.scope; this.cud = cud; } } static class MethodInfo { public final JMethodBody body; public final Map labels = Maps.newHashMap(); public final Map locals = Maps.newIdentityHashMap(); public final JMethod method; public final MethodScope scope; public MethodInfo(JMethod method, JMethodBody methodBody, MethodScope methodScope) { this.method = method; this.body = methodBody; this.scope = methodScope; } } /** * Manually tracked version count. */ private static final long AST_VERSION = 3; private static final int MAX_INLINEABLE_ENUM_SIZE = 10; private static final String CREATE_VALUE_OF_MAP_METHOD_NAME = "createValueOfMap"; private static final String LENGTH_FIELD_NAME = "length"; private static final char[] CREATE_VALUE_OF_MAP_ = CREATE_VALUE_OF_MAP_METHOD_NAME.toCharArray(); private static final char[] VALUE_OF_ = VALUE_OF_METHOD_NAME.toCharArray(); private static final char[] VALUES_ = VALUES_METHOD_NAME.toCharArray(); private static final char[] ORDINAL_ = ORDINAL_METHOD_NAME.toCharArray(); private static final char[] NEXT_ = NEXT_METHOD_NAME.toCharArray(); private static final char[] ITERATOR_ = ITERATOR_METHOD_NAME.toCharArray(); private static final char[] HAS_NEXT_ = HAS_NEXT_METHOD_NAME.toCharArray(); private static final TypeBinding[] NO_TYPES = new TypeBinding[0]; private static final Interner stringInterner = StringInterner.get(); static { InternalCompilerException.preload(); } /** * Returns a serialization version number. Used to determine if the AST * contained within cached compilation units is compatible with the current * version of GWT. */ public static long getSerializationVersion() { // TODO(zundel): something much awesomer. return AST_VERSION; } static Disposition getFieldDisposition(FieldBinding binding) { Disposition disposition; if (isCompileTimeConstant(binding)) { disposition = Disposition.COMPILE_TIME_CONSTANT; } else if (binding.isFinal()) { disposition = Disposition.FINAL; } else if (binding.isVolatile()) { disposition = Disposition.VOLATILE; } else { disposition = Disposition.NONE; } return disposition; } static String intern(char[] cs) { return intern(String.valueOf(cs)); } static String intern(String s) { return stringInterner.intern(s); } /** * Creates the statement that will constitute the method body implementing a lambda expression. *

* Lambda expressions might be represented in the JDT AST as Java expressions or Java statements. */ private static JStatement getOrCreateLambdaStatement(JNode node) { if (node instanceof JStatement) { return (JStatement) node; } assert node instanceof JExpression; JExpression expression = (JExpression) node; return JjsUtils.makeMethodEndStatement(expression.getType(), expression); } private boolean isOptimizableCompileTimeConstant(Binding binding) { if (binding instanceof LocalVariableBinding && ((LocalVariableBinding) binding).constant() != Constant.NotAConstant) { // Propagate constants in local variables regardless whether we are optimizing compile time // constants or not. This is necessary as the JDT will not compute an emulation path for a // local constant referred in a nested class closure. return true; } if (!(binding instanceof FieldBinding)) { return false; } FieldBinding fieldBinding = (FieldBinding) binding; return (compilerContext.getOptions().shouldJDTInlineCompileTimeConstants() || isBinaryBinding(fieldBinding.declaringClass)) && isCompileTimeConstant(fieldBinding); } private static boolean isCompileTimeConstant(FieldBinding binding) { assert !binding.isFinal() || !binding.isVolatile(); boolean isCompileTimeConstant = binding.isStatic() && binding.isFinal() && binding.constant() != Constant.NotAConstant; assert !isCompileTimeConstant || binding.type.isBaseType() || (binding.type.id == TypeIds.T_JavaLangString); return isCompileTimeConstant; } private boolean isBinaryBinding(ReferenceBinding binding) { if (binding instanceof BinaryTypeBinding) { // Is it really a BinaryBinding? If a source resource exists, the BinaryTypeBinding is // considered a source type binding. return !compilerContext.getMinimalRebuildCache().isSourceCompilationUnit( JdtUtil.getDefiningCompilationUnitType(binding)); } return false; } CudInfo curCud = null; JClassType javaLangClass = null; JClassType javaLangObject = null; JClassType javaLangString = null; JClassType javaLangThrowable = null; Map jsniMethods; Map jsniRefs; final ReferenceMapper typeMap = new ReferenceMapper(); private final AstVisitor astVisitor = new AstVisitor(); private List newTypes; private String sourceMapPath; private CompilerContext compilerContext; private boolean generateJsInteropExports; private WhitelistRegexFilter jsInteropExportFilter; /** * Externalized class and method form for Exceptions.safeClose() to provide support * for try-with-resources. * * The externalized form will be resolved during AST stitching. */ private static JMethod SAFE_CLOSE_METHOD = JMethod.getExternalizedMethod("com.google.gwt.lang.Exceptions", "safeClose(Ljava/lang/AutoCloseable;Ljava/lang/Throwable;)Ljava/lang/Throwable;", true); private static JMethod CAST_GET_CLASS_METHOD = JMethod.getExternalizedMethod("com.google.gwt.lang.Cast", "getClass(Ljava/lang/Object;)Ljava/lang/Class;", true); private List processImpl() { CompilationUnitDeclaration cud = curCud.cud; if (cud.types == null) { return Collections.emptyList(); } for (TypeDeclaration typeDecl : cud.types) { createTypes(typeDecl); } // Now that types exist, cache Object, String, etc. javaLangObject = (JClassType) typeMap.get(cud.scope.getJavaLangObject()); javaLangString = (JClassType) typeMap.get(cud.scope.getJavaLangString()); javaLangClass = (JClassType) typeMap.get(cud.scope.getJavaLangClass()); javaLangThrowable = (JClassType) typeMap.get(cud.scope.getJavaLangThrowable()); for (TypeDeclaration typeDecl : cud.types) { // Resolve super type / interface relationships. resolveTypeRefs(typeDecl); } for (TypeDeclaration typeDecl : cud.types) { // Create fields and empty methods. createMembers(typeDecl); } for (TypeDeclaration typeDecl : cud.types) { // Build the code. typeDecl.traverse(astVisitor, cud.scope); } return newTypes; } private GwtAstBuilder(CompilationUnitDeclaration cud, String sourceMapPath, Map jsniMethods, Map jsniRefs, CompilerContext compilerContext) { this.sourceMapPath = sourceMapPath; this.jsniRefs = jsniRefs; this.jsniMethods = jsniMethods; this.compilerContext = compilerContext; this.generateJsInteropExports = compilerContext.getOptions().shouldGenerateJsInteropExports(); this.jsInteropExportFilter = compilerContext.getOptions().getJsInteropExportFilter(); this.newTypes = Lists.newArrayList(); this.curCud = new CudInfo(cud); } private boolean shouldExport(JMember member) { return generateJsInteropExports && (jsInteropExportFilter.isEmpty() || jsInteropExportFilter.isIncluded(member.getQualifiedName())); } /** * Builds all the GWT AST nodes that correspond to one Java source file. * * @param cud The compiled form of the Java source from the JDT. * @param sourceMapPath the path that should be included in a sourcemap. * @param jsniMethods Native methods to add to the AST. * @param jsniRefs Map from JSNI references to their JDT definitions. * @param compilerContext the compiler context. * @return All the types seen in this source file. */ public static List process(CompilationUnitDeclaration cud, String sourceMapPath, Map jsniMethods, Map jsniRefs, CompilerContext compilerContext) { return new GwtAstBuilder(cud, sourceMapPath, jsniMethods, jsniRefs, compilerContext) .processImpl(); } SourceInfo makeSourceInfo(AbstractMethodDeclaration x) { int startLine = Util.getLineNumber(x.sourceStart, curCud.separatorPositions, 0, curCud.separatorPositions.length - 1); return SourceOrigin.create(x.sourceStart, x.bodyEnd, startLine, sourceMapPath); } SourceInfo makeSourceInfo(ASTNode x) { int startLine = Util.getLineNumber(x.sourceStart, curCud.separatorPositions, 0, curCud.separatorPositions.length - 1); return SourceOrigin.create(x.sourceStart, x.sourceEnd, startLine, sourceMapPath); } InternalCompilerException translateException(ASTNode node, Throwable e) { if (e instanceof VirtualMachineError) { // Always rethrow VM errors (an attempt to wrap may fail). throw (VirtualMachineError) e; } InternalCompilerException ice; if (e instanceof InternalCompilerException) { ice = (InternalCompilerException) e; } else { ice = new InternalCompilerException("Error constructing Java AST", e); } if (node != null) { ice.addNode(node.getClass().getName(), node.toString(), makeSourceInfo(node)); } return ice; } private void createField(FieldDeclaration x) { if (x instanceof Initializer) { return; } SourceInfo info = makeSourceInfo(x); FieldBinding binding = x.binding; JType type = typeMap.get(binding.type); JDeclaredType enclosingType = (JDeclaredType) typeMap.get(binding.declaringClass); JField field; if (x.initialization != null && x.initialization instanceof AllocationExpression && ((AllocationExpression) x.initialization).enumConstant != null) { field = new JEnumField(info, intern(binding.name), binding.original().id, (JEnumType) enclosingType, (JClassType) type, AccessModifier.fromFieldBinding(binding)); } else { field = new JField(info, intern(binding.name), enclosingType, type, binding.isStatic(), getFieldDisposition(binding), AccessModifier.fromFieldBinding(binding)); } enclosingType.addField(field); JsInteropUtil.maybeSetJsInteropProperties(field, shouldExport(field), x.annotations); processSuppressedWarnings(field, x.annotations); typeMap.setField(binding, field); } private void createMembers(TypeDeclaration x) { SourceTypeBinding binding = x.binding; JDeclaredType type = (JDeclaredType) typeMap.get(binding); SourceInfo info = type.getSourceInfo(); try { /** * We emulate static initializers and instance initializers as methods. As * in other cases, this gives us: simpler AST, easier to optimize, more * like output JavaScript. Clinit is always in slot 0, init (if it exists) * is always in slot 1. */ assert type.getMethods().size() == CLINIT_METHOD_INDEX; createSyntheticMethod(info, CLINIT_METHOD_NAME, type, JPrimitiveType.VOID, false, true, true, AccessModifier.PRIVATE); if (type instanceof JClassType) { assert type.getMethods().size() == INIT_METHOD_INDEX; createSyntheticMethod(info, INIT_NAME_METHOD_NAME, type, JPrimitiveType.VOID, false, false, true, AccessModifier.PRIVATE); // Add a getClass() implementation for all non-Object, non-String classes. if (isSyntheticGetClassNeeded(x, type)) { assert type.getMethods().size() == GET_CLASS_METHOD_INDEX; createSyntheticMethod(info, GET_CLASS_METHOD_NAME, type, javaLangClass, type.isAbstract(), false, false, AccessModifier.PUBLIC); } } if (type instanceof JEnumType) { { assert type.getMethods().size() == getEnumMethodsStartIndex(type) + VALUE_OF_METHOD_OFFSET; MethodBinding valueOfBinding = binding.getExactMethod(VALUE_OF_, new TypeBinding[]{x.scope.getJavaLangString()}, curCud.scope); assert valueOfBinding != null; createMethodFromBinding(info, valueOfBinding, new String[] {"name"}); } { assert type.getMethods().size() == getEnumMethodsStartIndex(type) + VALUES_METHOD_OFFSET; MethodBinding valuesBinding = binding.getExactMethod(VALUES_, NO_TYPES, curCud.scope); assert valuesBinding != null; createMethodFromBinding(info, valuesBinding, null); } } if (x.fields != null) { for (FieldDeclaration field : x.fields) { createField(field); } } if (x.methods != null) { for (AbstractMethodDeclaration method : x.methods) { createMethod(method); } } if (x.memberTypes != null) { for (TypeDeclaration memberType : x.memberTypes) { createMembers(memberType); } } } catch (Throwable e) { throw getInternalCompilerException(x, e); } } private static boolean isSyntheticGetClassNeeded( TypeDeclaration typeDeclaration, JDeclaredType type) { // TODO(rluble): We should check whether getClass is implemented by type and only // instead of blacklisting. return type.getSuperClass() != null && !JdtUtil.isJsoSubclass(typeDeclaration.binding) && !type.isJsNative(); } private static final int VALUE_OF_METHOD_OFFSET = 0; private static final int VALUES_METHOD_OFFSET = 1; private static int getEnumMethodsStartIndex(JType type) { assert type instanceof JEnumType; if (type.isJsNative()) { return GET_CLASS_METHOD_INDEX; } return GET_CLASS_METHOD_INDEX + 1; } private void createMethod(AbstractMethodDeclaration x) { if (x instanceof Clinit) { return; } SourceInfo info = makeSourceInfo(x); MethodBinding b = x.binding; ReferenceBinding declaringClass = (ReferenceBinding) b.declaringClass.erasure(); Set alreadyNamedVariables = Sets.newHashSet(); JDeclaredType enclosingType = (JDeclaredType) typeMap.get(declaringClass); assert !enclosingType.isExternal(); JMethod method; boolean isNested = JdtUtil.isInnerClass(declaringClass); if (x.isConstructor()) { method = new JConstructor(info, (JClassType) enclosingType, AccessModifier.fromMethodBinding(b)); if (x.isDefaultConstructor()) { ((JConstructor) method).setDefaultConstructor(); } if (x.binding.declaringClass.isEnum()) { // Enums have hidden arguments for name and value method.createFinalParameter(info, "enum$name", typeMap.get(x.scope.getJavaLangString())); method.createFinalParameter(info, "enum$ordinal", JPrimitiveType.INT); } // add synthetic args for outer this if (isNested) { NestedTypeBinding nestedBinding = (NestedTypeBinding) declaringClass; if (nestedBinding.enclosingInstances != null) { for (int i = 0; i < nestedBinding.enclosingInstances.length; ++i) { SyntheticArgumentBinding arg = nestedBinding.enclosingInstances[i]; String argName = String.valueOf(arg.name); if (alreadyNamedVariables.contains(argName)) { argName += "_" + i; } createParameter(info, arg, argName, method, false); alreadyNamedVariables.add(argName); } } } } else { method = new JMethod(info, intern(b.selector), enclosingType, typeMap.get(b.returnType), b .isAbstract(), b.isStatic(), b.isFinal(), AccessModifier.fromMethodBinding(b)); } // User args. createParameters(method, x); if (x.isConstructor()) { if (isNested) { // add synthetic args for locals NestedTypeBinding nestedBinding = (NestedTypeBinding) declaringClass; // add synthetic args for outer this and locals if (nestedBinding.outerLocalVariables != null) { for (int i = 0; i < nestedBinding.outerLocalVariables.length; ++i) { SyntheticArgumentBinding arg = nestedBinding.outerLocalVariables[i]; String argName = String.valueOf(arg.name); if (alreadyNamedVariables.contains(argName)) { argName += "_" + i; } createParameter(info, arg, argName, method, false); alreadyNamedVariables.add(argName); } } } } mapExceptions(method, b); if (b.isSynthetic()) { method.setSynthetic(); } if (b.isDefaultMethod()) { method.setDefaultMethod(true); } enclosingType.addMethod(method); processAnnotations(x, method); typeMap.setMethod(b, method); } private void processAnnotations(AbstractMethodDeclaration x, JMethod method) { maybeAddMethodSpecialization(x, method); maybeSetInliningMode(x, method); maybeSetHasNoSideEffects(x, method); JsInteropUtil.maybeSetJsInteropProperties(method, shouldExport(method), x.annotations); processSuppressedWarnings(method, x.annotations); } private void processAnnotations(JParameter parameter, Annotation... annotations) { JsInteropUtil.maybeSetJsInteropProperties(parameter, annotations); processSuppressedWarnings(parameter, annotations); } private void processSuppressedWarnings(CanHaveSuppressedWarnings x, Annotation... annotations) { x.setSuppressedWarnings(JdtUtil.getSuppressedWarnings(annotations)); } private static boolean isUncheckedGenericMethodCall(MessageSend messageSend) { if (messageSend.binding.genericMethod() != null) { return JdtUtil.getAnnotationByName(messageSend.binding().getAnnotations(), "javaemul.internal.annotations.UncheckedCast") != null; } return false; } private static void maybeSetInliningMode(AbstractMethodDeclaration x, JMethod method) { if (JdtUtil.getAnnotationByName( x.annotations, "javaemul.internal.annotations.DoNotInline") != null) { method.setInliningMode(InliningMode.DO_NOT_INLINE); } else if (JdtUtil.getAnnotationByName( x.annotations, "javaemul.internal.annotations.ForceInline") != null) { method.setInliningMode(InliningMode.FORCE_INLINE); } } private static void maybeSetHasNoSideEffects(AbstractMethodDeclaration x, JMethod method) { if (JdtUtil.getAnnotationByName( x.annotations, "javaemul.internal.annotations.HasNoSideEffects") != null) { method.setHasSideEffects(false); } } private void maybeAddMethodSpecialization(AbstractMethodDeclaration x, JMethod method) { AnnotationBinding specializeAnnotation = JdtUtil.getAnnotationByName( x.annotations, "javaemul.internal.annotations.SpecializeMethod"); if (specializeAnnotation == null) { return; } TypeBinding[] params = JdtUtil.getAnnotationParameterTypeBindingArray(specializeAnnotation, "params"); assert params != null : "params is a mandatory field"; List paramTypes = Lists.newArrayList(mapTypes(params)); TypeBinding returns = JdtUtil.getAnnotationParameterTypeBinding(specializeAnnotation, "returns"); JType returnsType = returns == null ? null : typeMap.get(returns); String targetMethod = JdtUtil.getAnnotationParameterString(specializeAnnotation, "target"); assert targetMethod != null : "target is a mandatory parameter"; method.setSpecialization(paramTypes, returnsType, targetMethod); } private void createParameter(SourceInfo info, LocalVariableBinding binding, boolean isVarargs, JMethod method, Annotation... annotations) { createParameter(info, binding, intern(binding.name), method, isVarargs, annotations); } private void createParameter(SourceInfo info, LocalVariableBinding binding, String name, JMethod method, boolean isVarargs, Annotation... annotations) { JParameter parameter = method.createParameter(info, name, typeMap.get(binding.type), binding.isFinal(), isVarargs); processAnnotations(parameter, annotations); } private void createParameters(JMethod method, AbstractMethodDeclaration x) { if (x.arguments != null) { for (Argument argument : x.arguments) { SourceInfo info = makeSourceInfo(argument); LocalVariableBinding binding = argument.binding; boolean isVarargs = x.binding.isVarargs() && argument == x.arguments[x.arguments.length - 1]; createParameter(info, binding, isVarargs, method, argument.annotations); } } method.freezeParamTypes(); } private JMethod createSyntheticMethod(SourceInfo info, String name, JDeclaredType enclosingType, JType returnType, boolean isAbstract, boolean isStatic, boolean isFinal, AccessModifier access, JStatement ... statements) { JMethod method = new JMethod(info, name, enclosingType, returnType, isAbstract, isStatic, isFinal, access); method.freezeParamTypes(); method.setSynthetic(); JMethodBody body = new JMethodBody(info); for (JStatement statement : statements) { body.getBlock().addStmt(statement); } method.setBody(body); enclosingType.addMethod(method); return method; } private JMethod createMethodFromBinding(SourceInfo info, MethodBinding binding, String[] paramNames) { JMethod method = typeMap.createMethod(info, binding, paramNames); assert !method.isExternal(); method.setBody(new JMethodBody(info)); JsInteropUtil.maybeSetJsInteropProperties(method, shouldExport(method)); typeMap.setMethod(binding, method); return method; } private void createTypes(TypeDeclaration x) { SourceInfo info = makeSourceInfo(x); try { SourceTypeBinding binding = x.binding; String name; if (binding instanceof LocalTypeBinding) { char[] localName = binding.constantPoolName(); name = new String(localName).replace('/', '.'); } else { name = JdtUtil.asDottedString(binding.compoundName); } name = intern(name); JDeclaredType type; if (binding.isClass()) { type = new JClassType(info, name, binding.isAbstract(), binding.isFinal()); } else if (binding.isInterface() || binding.isAnnotationType()) { type = new JInterfaceType(info, name); } else if (binding.isEnum()) { if (binding.isAnonymousType()) { // Don't model an enum subclass as a JEnumType. type = new JClassType(info, name, false, true); } else { type = new JEnumType(info, name, binding.isAbstract()); } } else { throw new InternalCompilerException("ReferenceBinding is not a class, interface, or enum."); } JsInteropUtil.maybeSetJsInteropProperties(type, x.annotations); processSuppressedWarnings(type, x.annotations); JdtUtil.setClassDispositionFromBinding(binding, type); typeMap.setSourceType(binding, type); newTypes.add(type); if (x.memberTypes != null) { for (TypeDeclaration memberType : x.memberTypes) { createTypes(memberType); } } } catch (Throwable e) { InternalCompilerException ice = translateException(null, e); StringBuffer sb = new StringBuffer(); x.printHeader(0, sb); ice.addNode(x.getClass().getName(), sb.toString(), info); throw ice; } } private void mapExceptions(JMethod method, MethodBinding binding) { for (ReferenceBinding thrownBinding : binding.thrownExceptions) { JClassType type = (JClassType) typeMap.get(thrownBinding); method.addThrownException(type); } } private void resolveTypeRefs(TypeDeclaration x) { SourceTypeBinding binding = x.binding; JDeclaredType type = (JDeclaredType) typeMap.get(binding); try { ReferenceBinding superClassBinding = binding.superclass(); if (type instanceof JClassType && superClassBinding != null) { assert (binding.superclass().isClass() || binding.superclass().isEnum()); JClassType superClass = (JClassType) typeMap.get(superClassBinding); ((JClassType) type).setSuperClass(superClass); } ReferenceBinding[] superInterfaces = binding.superInterfaces(); for (ReferenceBinding superInterfaceBinding : superInterfaces) { assert (superInterfaceBinding.isInterface()); JInterfaceType superInterface = (JInterfaceType) typeMap.get(superInterfaceBinding); type.addImplements(superInterface); } ReferenceBinding enclosingBinding = binding.enclosingType(); if (enclosingBinding != null) { type.setEnclosingType((JDeclaredType) typeMap.get(enclosingBinding)); } if (x.memberTypes != null) { for (TypeDeclaration memberType : x.memberTypes) { resolveTypeRefs(memberType); } } } catch (Throwable e) { throw getInternalCompilerException(x, e); } } private InternalCompilerException getInternalCompilerException(TypeDeclaration x, Throwable e) { JDeclaredType type = (JDeclaredType) typeMap.get(x.binding); InternalCompilerException ice = translateException(null, e); StringBuffer sb = new StringBuffer(); x.printHeader(0, sb); ice.addNode(x.getClass().getName(), sb.toString(), type.getSourceInfo()); return ice; } /** * Returns the list of expressions as a single expression; returns {@code null} if the list * is empty. */ private static JExpression singleExpressionFromExpressionList(SourceInfo info, List incrementsExpressions) { switch (incrementsExpressions.size()) { case 0: return null; case 1: return incrementsExpressions.get(0); default: return new JMultiExpression(info, incrementsExpressions); } } private boolean hasQualifier(ReferenceExpression x) { return !x.isTypeAccess(); } private TypeBinding getCollectionElementTypeBinding(ForeachStatement x) { return (TypeBinding) accessPrivateField(JdtPrivateHacks.collectionElementTypeField, x); } private Object accessPrivateField(Field field, ASTNode astNode) { try { return field.get(astNode); } catch (IllegalAccessException e) { throw translateException(astNode, e); } } static class JdtPrivateHacks { /** * Reflective access to {@link ForeachStatement#collectionElementType}. */ private static final Field collectionElementTypeField; static { try { collectionElementTypeField = ForeachStatement.class.getDeclaredField("collectionElementType"); collectionElementTypeField.setAccessible(true); } catch (Exception e) { throw new RuntimeException( "Unexpectedly unable to access ForeachStatement.collectionElementType via reflection", e); } } } }





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