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/*
 * Copyright 2008 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.ast;

import com.google.gwt.dev.MinimalRebuildCache;
import com.google.gwt.dev.jjs.Correlation.Literal;
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.impl.codesplitter.FragmentPartitioningResult;
import com.google.gwt.dev.util.StringInterner;
import com.google.gwt.dev.util.log.speedtracer.CompilerEventType;
import com.google.gwt.dev.util.log.speedtracer.SpeedTracerLogger;
import com.google.gwt.dev.util.log.speedtracer.SpeedTracerLogger.Event;
import com.google.gwt.thirdparty.guava.common.base.Function;
import com.google.gwt.thirdparty.guava.common.collect.BiMap;
import com.google.gwt.thirdparty.guava.common.collect.Collections2;
import com.google.gwt.thirdparty.guava.common.collect.HashBiMap;
import com.google.gwt.thirdparty.guava.common.collect.ImmutableList;
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 java.io.IOException;
import java.io.ObjectInputStream;
import java.io.ObjectOutputStream;
import java.io.Serializable;
import java.util.Arrays;
import java.util.Collection;
import java.util.Collections;
import java.util.Comparator;
import java.util.Iterator;
import java.util.LinkedHashSet;
import java.util.List;
import java.util.Map;
import java.util.Set;

/**
 * Root for the AST representing an entire Java program.
 */
public class JProgram extends JNode implements ArrayTypeCreator {

  /**
   * Returns whether a class is a synthetic Prototype class generated by APT or user.
   */
  public boolean isJsTypePrototype(JDeclaredType classType) {
    return typeOracle.isInteropEnabled() && classType instanceof JClassType
        && ((JClassType) classType).isJsPrototypeStub();
  }

  private static final class ArrayTypeComparator implements Comparator, Serializable {
    @Override
    public int compare(JArrayType o1, JArrayType o2) {
      int comp = o1.getDims() - o2.getDims();
      if (comp != 0) {
        return comp;
      }
      return o1.getName().compareTo(o2.getName());
    }
  }

  private static final class TreeStatistics extends JVisitor {
    private int nodeCount = 0;

    public int getNodeCount() {
      return nodeCount;
    }

    @Override
    public boolean visit(JNode x, Context ctx) {
      nodeCount++;
      return true;
    }
  }

  public static final Set CODEGEN_TYPES_SET = Sets.newLinkedHashSet(Arrays.asList(
      "com.google.gwt.lang.Array", "com.google.gwt.lang.Cast",
      "com.google.gwt.lang.RuntimePropertyRegistry", "com.google.gwt.lang.Exceptions",
      "com.google.gwt.lang.LongLib", "com.google.gwt.lang.Stats", "com.google.gwt.lang.Util",
      "java.lang.Object"));

  /*
   * Types which are not referenced by any Java code, but are required to exist
   * after Java optimizations have run in order to be used by backend
   * code-generation. These classes and their members, are considered live
   * by ControlFlowAnalysis, at all times. Immortal types always live in the
   * initial fragment and their definitions are hoisted to appear before all
   * other types. Only static methods and fields are allowed, and no clinits
   * are run. Field initializers must be primitives, literals, or one of
   * JSO.createObject() or JSO.createArray().
   *
   * Classes are inserted into the JsAST in the order they appear in the Set.
   */
  public static final Set IMMORTAL_CODEGEN_TYPES_SET = Sets.newLinkedHashSet(Arrays.asList(
      "com.google.gwt.lang.CollapsedPropertyHolder",
      "com.google.gwt.lang.JavaClassHierarchySetupUtil",
      "com.google.gwt.lang.ModuleUtils"));

  public static final String JAVASCRIPTOBJECT = "com.google.gwt.core.client.JavaScriptObject";

  public static final String CLASS_LITERAL_HOLDER = "com.google.gwt.lang.ClassLiteralHolder";

  /**
   * Types whose entire implementation is synthesized at compile time.
   */
  public static final Set SYNTHETIC_TYPE_NAMES = Sets.newHashSet(CLASS_LITERAL_HOLDER);

  static final Map> traceMethods = Maps.newHashMap();

  private static final Comparator ARRAYTYPE_COMPARATOR = new ArrayTypeComparator();

  private static final int IS_ARRAY = 2;

  private static final int IS_CLASS = 3;

  private static final int IS_INTERFACE = 1;

  private static final int IS_NULL = 0;

  private static final Map primitiveTypes = Maps.newHashMap();

  @Deprecated
  private static final Map primitiveTypesDeprecated = Maps.newHashMap();

  static {
    if (System.getProperty("gwt.coverage") != null) {
      IMMORTAL_CODEGEN_TYPES_SET.add("com.google.gwt.lang.CoverageUtil");
    }
    CODEGEN_TYPES_SET.addAll(IMMORTAL_CODEGEN_TYPES_SET);

    /*
     * The format to trace methods is a colon-separated list of
     * "className.methodName", such as "Hello.onModuleLoad:Foo.bar". You can
     * fully-qualify a class to disambiguate classes, and you can also append
     * the JSNI signature of the method to disambiguate overloads, ala
     * "Foo.bar(IZ)".
     */
    String toTrace = System.getProperty("gwt.jjs.traceMethods");
    if (toTrace != null) {
      String[] split = toTrace.split(":");
      for (String str : split) {
        int pos = str.lastIndexOf('.');
        if (pos > 0) {
          String className = str.substring(0, pos);
          String methodName = str.substring(pos + 1);
          Set set = traceMethods.get(className);
          if (set == null) {
            set = Sets.newHashSet();
            traceMethods.put(className, set);
          }
          set.add(methodName);
        }
      }
    }

    primitiveTypes.put(JPrimitiveType.BOOLEAN.getName(), JPrimitiveType.BOOLEAN);
    primitiveTypes.put(JPrimitiveType.BYTE.getName(), JPrimitiveType.BYTE);
    primitiveTypes.put(JPrimitiveType.CHAR.getName(), JPrimitiveType.CHAR);
    primitiveTypes.put(JPrimitiveType.DOUBLE.getName(), JPrimitiveType.DOUBLE);
    primitiveTypes.put(JPrimitiveType.FLOAT.getName(), JPrimitiveType.FLOAT);
    primitiveTypes.put(JPrimitiveType.INT.getName(), JPrimitiveType.INT);
    primitiveTypes.put(JPrimitiveType.LONG.getName(), JPrimitiveType.LONG);
    primitiveTypes.put(JPrimitiveType.SHORT.getName(), JPrimitiveType.SHORT);
    primitiveTypes.put(JPrimitiveType.VOID.getName(), JPrimitiveType.VOID);

    primitiveTypesDeprecated.put(JPrimitiveType.BOOLEAN.getJsniSignatureName(),
        JPrimitiveType.BOOLEAN);
    primitiveTypesDeprecated.put(JPrimitiveType.BYTE.getJsniSignatureName(), JPrimitiveType.BYTE);
    primitiveTypesDeprecated.put(JPrimitiveType.CHAR.getJsniSignatureName(), JPrimitiveType.CHAR);
    primitiveTypesDeprecated.put(JPrimitiveType.DOUBLE.getJsniSignatureName(),
        JPrimitiveType.DOUBLE);
    primitiveTypesDeprecated.put(JPrimitiveType.FLOAT.getJsniSignatureName(), JPrimitiveType.FLOAT);
    primitiveTypesDeprecated.put(JPrimitiveType.INT.getJsniSignatureName(), JPrimitiveType.INT);
    primitiveTypesDeprecated.put(JPrimitiveType.LONG.getJsniSignatureName(), JPrimitiveType.LONG);
    primitiveTypesDeprecated.put(JPrimitiveType.SHORT.getJsniSignatureName(), JPrimitiveType.SHORT);
    primitiveTypesDeprecated.put(JPrimitiveType.VOID.getJsniSignatureName(), JPrimitiveType.VOID);
  }

  /**
   * Helper to create an assignment, used to initalize fields, etc.
   */
  public static JExpressionStatement createAssignmentStmt(SourceInfo info, JExpression lhs,
      JExpression rhs) {
    JBinaryOperation assign =
        new JBinaryOperation(info, lhs.getType(), JBinaryOperator.ASG, lhs, rhs);
    return assign.makeStatement();
  }

  public static JLocal createLocal(SourceInfo info, String name, JType type, boolean isFinal,
      JMethodBody enclosingMethodBody) {
    assert (name != null);
    assert (type != null);
    assert (enclosingMethodBody != null);
    JLocal x = new JLocal(info, name, type, isFinal, enclosingMethodBody);
    enclosingMethodBody.addLocal(x);
    return x;
  }

  public static JParameter createParameter(SourceInfo info, String name, JType type,
      boolean isFinal, boolean isThis, JMethod enclosingMethod) {
    assert (name != null);
    assert (type != null);
    assert (enclosingMethod != null);

    JParameter x = new JParameter(info, name, type, isFinal, isThis, enclosingMethod);

    enclosingMethod.addParam(x);
    return x;
  }

  public static List deserializeTypes(ObjectInputStream stream) throws IOException,
      ClassNotFoundException {
    @SuppressWarnings("unchecked")
    List types = (List) stream.readObject();
    for (JDeclaredType type : types) {
      type.readMembers(stream);
    }
    for (JDeclaredType type : types) {
      type.readMethodBodies(stream);
    }
    return types;
  }

  public static String getFullName(JMethod method) {
    return method.getEnclosingType().getName() + "." + method.getJsniSignature(false, true);
  }

    public static boolean isClinit(JMethod method) {
    JDeclaredType enclosingType = method.getEnclosingType();
    if ((enclosingType != null) && (method == enclosingType.getClinitMethod())) {
      assert (method.getName().equals("$clinit"));
      return true;
    } else {
      return false;
    }
  }

  public static boolean isTracingEnabled() {
    return traceMethods.size() > 0;
  }

  public static void serializeTypes(List types, ObjectOutputStream stream)
      throws IOException {
    stream.writeObject(types);
    for (JDeclaredType type : types) {
      type.writeMembers(stream);
    }
    for (JDeclaredType type : types) {
      type.writeMethodBodies(stream);
    }
  }

  public final List codeGenTypes = Lists.newArrayList();

  public final List immortalCodeGenTypes = Lists.newArrayList();

  public final JTypeOracle typeOracle;

  /**
   * Special serialization treatment.
   */
  // TODO(stalcup): make this a set, or take special care to make updates unique when lazily loading
  // in types. At the moment duplicates are accumulating.
  private transient List allTypes = Lists.newArrayList();

  private final Map arrayTypes = Maps.newHashMap();

  private Map castMaps;

  private BiMap classLiteralFieldsByType;

  private final List entryMethods = Lists.newArrayList();

  private final Map indexedFields = Maps.newHashMap();

  private final Map indexedMethods = Maps.newHashMap();

  /**
   * An index of types, from type name to type instance.
   */
  private final Map indexedTypes = Maps.newHashMap();

  /**
   * The set of names of types (beyond the basic INDEX_TYPES_SET) whose instance should be indexed
   * when seen.
   */
  private final Set typeNamesToIndex = buildInitialTypeNamesToIndex();

  private final Map instanceToStaticMap = Maps.newIdentityHashMap();

  private String propertyProviderRegistratorTypeSourceName;

  // wrap up .add here, and filter out forced source
  private Set referenceOnlyTypeNames = Sets.newHashSet();

  /**
   * Filled in by ReplaceRunAsync, once the numbers are known.
   */
  private List runAsyncs = Lists.newArrayList();

  private LinkedHashSet initialAsyncSequence = Sets.newLinkedHashSet();

  private List initialFragmentIdSequence = Lists.newArrayList();

  private String runtimeRebindRegistratorTypeName;

  private final Map staticToInstanceMap = Maps.newIdentityHashMap();

  private JClassType typeClass;

  private JInterfaceType typeJavaIoSerializable;

  private JInterfaceType typeJavaLangCloneable;

  private JClassType typeJavaLangEnum;

  private JClassType typeJavaLangObject;

  private final Map typeNameMap = Maps.newHashMap();

  private Map typesByClassLiteralField;

  private JClassType typeSpecialClassLiteralHolder;

  private JClassType typeSpecialJavaScriptObject;

  private JClassType typeString;

  private FragmentPartitioningResult fragmentPartitioningResult;

  /**
   * Set of method that are pinned and should be skipped by optimizations such as
   * inlining, statification and prunned.
   */
  private Set pinnedMethods = Sets.newHashSet();

  /**
   * Returns true if the inliner should try to inline {@code method}.
   */
  public boolean isInliningAllowed(JMethod method) {
    return !pinnedMethods.contains(method) && method.isInliningAllowed();
  }

  /**
   * Returns true if {@link MakeCallsStatic} should try to statify {@code method}.
   */
  public boolean isDevitualizationAllowed(JMethod method) {
    return !pinnedMethods.contains(method);
  }

  /**
   * Add a pinned method.
   */
  public void addPinnedMethod(JMethod method) {
    pinnedMethods.add(method);
  }

  public JProgram(MinimalRebuildCache minimalRebuildCache) {
    super(SourceOrigin.UNKNOWN);
    typeOracle = new JTypeOracle(this, minimalRebuildCache, true);
  }

  public JProgram(MinimalRebuildCache minimalRebuildCache, boolean hasWholeWorldKnowledge) {
    super(SourceOrigin.UNKNOWN);
    typeOracle = new JTypeOracle(this, minimalRebuildCache, hasWholeWorldKnowledge);
  }

  public void addEntryMethod(JMethod entryPoint) {
    assert !entryMethods.contains(entryPoint);
    entryMethods.add(entryPoint);
  }

  /**
   * Adds the given type name to the set of type names (beyond the basic INDEX_TYPES_SET) whose
   * instance should be indexed when seen.
   */
  public void addIndexedTypeName(String typeName) {
    typeNamesToIndex.add(typeName);
  }

  public void addReferenceOnlyType(JDeclaredType type) {
    referenceOnlyTypeNames.add(type.getName());
  }

  public void addType(JDeclaredType type) {
    allTypes.add(type);
    String name = type.getName();
    putIntoTypeMap(name, type);

    if (CODEGEN_TYPES_SET.contains(name)) {
      codeGenTypes.add((JClassType) type);
    }

    if (IMMORTAL_CODEGEN_TYPES_SET.contains(name)) {
      immortalCodeGenTypes.add((JClassType) type);
    }

    if (typeNamesToIndex.contains(name)) {
      indexedTypes.put(type.getShortName(), type);
      for (JMethod method : type.getMethods()) {
        if (!method.isPrivate()) {
          indexedMethods.put(type.getShortName() + '.' + method.getName(), method);
        }
      }
      for (JField field : type.getFields()) {
        indexedFields.put(type.getShortName() + '.' + field.getName(), field);
      }
      if (name.equals("java.lang.Object")) {
        typeJavaLangObject = (JClassType) type;
      } else if (name.equals("java.lang.String")) {
        typeString = (JClassType) type;
      } else if (name.equals("java.lang.Enum")) {
        typeJavaLangEnum = (JClassType) type;
      } else if (name.equals("java.lang.Class")) {
        typeClass = (JClassType) type;
      } else if (name.equals(JAVASCRIPTOBJECT)) {
        typeSpecialJavaScriptObject = (JClassType) type;
      } else if (name.equals(CLASS_LITERAL_HOLDER)) {
        typeSpecialClassLiteralHolder = (JClassType) type;
      } else if (name.equals("java.lang.Cloneable")) {
        typeJavaLangCloneable = (JInterfaceType) type;
      } else if (name.equals("java.io.Serializable")) {
        typeJavaIoSerializable = (JInterfaceType) type;
      }
    }
  }

  /**
   * Return a minimal upper bound of a set of types. That is, a type
   * that is a supertype of all the input types and is as close as possible to the
   * input types.
   *
   * NOTE: Ideally we would like to return the least upper bound but it does not exit as
   * the Java type hierarchy is not really a lattice.
   *
   * Hence, this function depends on the collection order. E.g.
   *
   *                I    O
   *                |\ / \
   *                | A  B
   *                \   /
   *                 \ /
   *                  C
   *
   * where I is an interface an {O,A,B,C} are classes.
   *
   * generalizeTypes({A,C}) could either be I or O.
   *
   * In particular generalizeTypes({I,A,C}) = I and generalizeTypes({A,C,I}) = O.
   *
   */
  public JReferenceType generalizeTypes(Collection types) {
    assert (types != null);
    assert (!types.isEmpty());
    Iterator it = types.iterator();
    JReferenceType curType = it.next();
    while (it.hasNext()) {
      curType = generalizeTypes(curType, it.next());
      if (curType == typeJavaLangObject) {
        break;
      }
    }
    return curType;
  }

  /**
   * Return the least upper bound of two types. That is, the smallest type that
   * is a supertype of both types.
   */
  public JReferenceType generalizeTypes(JReferenceType type1, JReferenceType type2) {
    if (type1 == type2) {
      return type1;
    }

    if (type1 instanceof JNonNullType && type2 instanceof JNonNullType) {
      // Neither can be null.
      type1 = type1.getUnderlyingType();
      type2 = type2.getUnderlyingType();
      return generalizeTypes(type1, type2).getNonNull();
    } else if (type1 instanceof JNonNullType) {
      // type2 can be null, so the result can be null
      type1 = type1.getUnderlyingType();
    } else if (type2 instanceof JNonNullType) {
      // type1 can be null, so the result can be null
      type2 = type2.getUnderlyingType();
    }
    assert !(type1 instanceof JNonNullType);
    assert !(type2 instanceof JNonNullType);

    int classify1 = classifyType(type1);
    int classify2 = classifyType(type2);

    if (classify1 == IS_NULL) {
      return type2;
    }

    if (classify2 == IS_NULL) {
      return type1;
    }

    if (classify1 == classify2) {

      // same basic kind of type
      if (classify1 == IS_INTERFACE) {

        if (typeOracle.canTriviallyCast(type1, type2)) {
          return type2;
        }

        if (typeOracle.canTriviallyCast(type2, type1)) {
          return type1;
        }

        // unrelated
        return typeJavaLangObject;

      } else if (classify1 == IS_ARRAY) {

        JArrayType aType1 = (JArrayType) type1;
        JArrayType aType2 = (JArrayType) type2;
        int dims1 = aType1.getDims();
        int dims2 = aType2.getDims();

        int minDims = Math.min(dims1, dims2);
        /*
         * At a bare minimum, any two arrays generalize to an Object array with
         * one less dim than the lesser of the two; that is, int[][][][] and
         * String[][][] generalize to Object[][]. If minDims is 1, then they
         * just generalize to Object.
         */
        JReferenceType minimalGeneralType;
        if (minDims > 1) {
          minimalGeneralType = getOrCreateArrayType(typeJavaLangObject, minDims - 1);
        } else {
          minimalGeneralType = typeJavaLangObject;
        }

        if (dims1 == dims2) {

          // Try to generalize by leaf types
          JType leafType1 = aType1.getLeafType();
          JType leafType2 = aType2.getLeafType();

          if (!(leafType1 instanceof JReferenceType) || !(leafType2 instanceof JReferenceType)) {
            return minimalGeneralType;
          }

          /*
           * Both are reference types; the result is the generalization of the
           * leaf types combined with the number of dims; that is, Foo[] and
           * Bar[] generalize to X[] where X is the generalization of Foo and
           * Bar.
           */
          JReferenceType leafRefType1 = (JReferenceType) leafType1;
          JReferenceType leafRefType2 = (JReferenceType) leafType2;

          /**
           * Never generalize arrays to arrays of {@link JNonNullType} as null array initialization
           * is not accounted for in {@link TypeTightener}.
           */
          JReferenceType leafGeneralization =
              generalizeTypes(leafRefType1, leafRefType2).getUnderlyingType();
          return getOrCreateArrayType(leafGeneralization, dims1);

        } else {

          // Conflicting number of dims

          // int[][] and Object[] generalize to Object[]
          JArrayType lesser = dims1 < dims2 ? aType1 : aType2;
          if (lesser.getLeafType() == typeJavaLangObject) {
            return lesser;
          }

          // Totally unrelated
          return minimalGeneralType;
        }

      } else {

        assert (classify1 == IS_CLASS);
        JClassType class1 = (JClassType) type1;
        JClassType class2 = (JClassType) type2;

        /*
         * see how far each type is from object; walk the one who's farther up
         * until they're even; then walk them up together until they meet (worst
         * case at Object)
         */
        int distance1 = countSuperTypes(class1);
        int distance2 = countSuperTypes(class2);
        for (; distance1 > distance2; --distance1) {
          class1 = class1.getSuperClass();
        }

        for (; distance1 < distance2; --distance2) {
          class2 = class2.getSuperClass();
        }

        while (class1 != class2) {
          class1 = class1.getSuperClass();
          class2 = class2.getSuperClass();
        }

        return class1;
      }
    } else {

      // different kinds of types
      int lesser = Math.min(classify1, classify2);
      int greater = Math.max(classify1, classify2);

      JReferenceType tLesser = classify1 < classify2 ? type1 : type2;
      JReferenceType tGreater = classify1 > classify2 ? type1 : type2;

      if (lesser == IS_INTERFACE && greater == IS_CLASS) {

        // just see if the class implements the interface
        if (typeOracle.canTriviallyCast(tGreater, tLesser)) {
          return tLesser;
        }

        // unrelated
        return typeJavaLangObject;

      } else if (greater == IS_ARRAY
          && ((tLesser == typeJavaLangCloneable) || (tLesser == typeJavaIoSerializable))) {
        return tLesser;
      } else {

        // unrelated: the best commonality between an interface and array, or
        // between an array and a class is Object
        return typeJavaLangObject;
      }
    }
  }

  /**
   * Returns a sorted list of array types, so the returned set can be iterated
   * over without introducing nondeterminism.
   */
  public List getAllArrayTypes() {
    List result = Lists.newArrayList(arrayTypes.values());
    Collections.sort(result, ARRAYTYPE_COMPARATOR);
    return result;
  }

  /**
   * Returns an expression that evaluates to an array class literal at runtime.
   * 

* Note: This version can only be called after {@link ImplementClassLiteralsAsFields} has been * run. */ public JExpression createArrayClassLiteralExpression(SourceInfo sourceInfo, JClassLiteral leafTypeClassLiteral, int dimensions) { JField leafTypeClassLiteralField = leafTypeClassLiteral.getField(); assert leafTypeClassLiteralField != null : "Array leaf type must have a class literal field; " + "either ImplementClassLiteralsAsField has not run yet or or there is an error computing" + "live class literals."; return new JMethodCall(sourceInfo, null, getIndexedMethod("Array.getClassLiteralForArray"), new JFieldRef(sourceInfo, null, leafTypeClassLiteralField, leafTypeClassLiteralField.getEnclosingType()), getLiteralInt(dimensions)); } public Map getCastMap() { return Collections.unmodifiableMap(castMaps); } public JCastMap getCastMap(JReferenceType referenceType) { // ensure jsonCastableTypeMaps has been initialized // it might not have been if the ImplementCastsAndTypeChecks has not been run if (castMaps == null) { initTypeInfo(null); } return castMaps.get(referenceType); } public JField getClassLiteralField(JType type) { return classLiteralFieldsByType.get( typeOracle.isJavaScriptObject(type) ? getJavaScriptObject() : type); } public List getDeclaredTypes() { return allTypes; } public List getEntryMethods() { return entryMethods; } public int getFragmentCount() { // Initial fragment is the +1. return runAsyncs.size() + 1; } public FragmentPartitioningResult getFragmentPartitioningResult() { return fragmentPartitioningResult; } // TODO(stalcup): this is a blatant bug. there's no unambiguous way to convert from binary name to // source name. JProgram needs to index types both ways. public JDeclaredType getFromTypeMap(String qualifiedBinaryOrSourceName) { String srcTypeName = qualifiedBinaryOrSourceName.replace('$', '.'); return typeNameMap.get(srcTypeName); } public JField getIndexedField(String string) { JField field = indexedFields.get(string); if (field == null) { throw new InternalCompilerException("Unable to locate index field: " + string); } return field; } public Collection getIndexedFields() { return Collections.unmodifiableCollection(indexedFields.values()); } public JMethod getIndexedMethod(String string) { JMethod method = indexedMethods.get(string); if (method == null) { throw new InternalCompilerException("Unable to locate index method: " + string); } return method; } public Collection getIndexedMethods() { return Collections.unmodifiableCollection(indexedMethods.values()); } public JMethod getIndexedMethodOrNull(String string) { return indexedMethods.get(string); } public JDeclaredType getIndexedType(String string) { JDeclaredType type = indexedTypes.get(string); if (type == null) { throw new InternalCompilerException("Unable to locate index type: " + string); } return type; } public Collection getIndexedTypes() { return Collections.unmodifiableCollection(indexedTypes.values()); } public LinkedHashSet getInitialAsyncSequence() { return initialAsyncSequence; } public List getInitialFragmentIdSequence() { return initialFragmentIdSequence; } public JClassType getJavaScriptObject() { return typeSpecialJavaScriptObject; } public JLiteral getLiteral(Object value) { if (value instanceof String) { return getStringLiteral(SourceOrigin.UNKNOWN, (String) value); } if (value instanceof Integer) { return getLiteralInt((Integer) value); } throw new IllegalArgumentException("Argument must be a String or an Integer but was " + value); } public JBooleanLiteral getLiteralBoolean(boolean value) { return JBooleanLiteral.get(value); } public JCharLiteral getLiteralChar(char value) { return JCharLiteral.get(value); } public JDoubleLiteral getLiteralDouble(double d) { return JDoubleLiteral.get(d); } public JFloatLiteral getLiteralFloat(double f) { return JFloatLiteral.get(f); } public JIntLiteral getLiteralInt(int value) { return JIntLiteral.get(value); } public JLongLiteral getLiteralLong(long value) { return JLongLiteral.get(value); } public JNullLiteral getLiteralNull() { return JNullLiteral.INSTANCE; } public JStringLiteral getStringLiteral(SourceInfo sourceInfo, String s) { sourceInfo.addCorrelation(sourceInfo.getCorrelator().by(Literal.STRING)); return new JStringLiteral(sourceInfo, StringInterner.get().intern(s), typeString); } public List getModuleDeclaredTypes() { List moduleDeclaredTypes = Lists.newArrayList(); for (JDeclaredType type : allTypes) { if (isReferenceOnly(type)) { continue; } moduleDeclaredTypes.add(type); } return moduleDeclaredTypes; } public int getNodeCount() { Event countEvent = SpeedTracerLogger.start(CompilerEventType.OPTIMIZE, "phase", "countNodes"); TreeStatistics treeStats = new TreeStatistics(); treeStats.accept(this); int numNodes = treeStats.getNodeCount(); countEvent.end(); return numNodes; } public JField getNullField() { return JField.NULL_FIELD; } public JMethod getNullMethod() { return JMethod.NULL_METHOD; } public String getPropertyProviderRegistratorTypeSourceName() { return propertyProviderRegistratorTypeSourceName; } public List getRunAsyncs() { return runAsyncs; } public int getCommonAncestorFragmentId(int thisFragmentId, int thatFragmentId) { return fragmentPartitioningResult.getCommonAncestorFragmentId(thisFragmentId, thatFragmentId); } public String getRuntimeRebindRegistratorTypeSourceName() { return runtimeRebindRegistratorTypeName; } public Collection getSubclasses(JType type) { return Collections2.transform(typeOracle.getSubTypeNames(type.getName()), new Function() { public JType apply(String typeName) { return getFromTypeMap(typeName); } } ); } public JMethod getStaticImpl(JMethod method) { JMethod staticImpl = instanceToStaticMap.get(method); assert staticImpl == null || staticImpl.getEnclosingType().getMethods().contains(staticImpl); return staticImpl; } public JArrayType getTypeArray(JType elementType) { JArrayType arrayType = arrayTypes.get(elementType); if (arrayType == null) { arrayType = new JArrayType(elementType); arrayTypes.put(elementType, arrayType); } return arrayType; } // TODO(dankurka): Why does JProgram synthezise array types on the fly // Look into refactoring JProgram to get rid of this responsibility @Override public JArrayType getOrCreateArrayType(JType leafType, int dimensions) { assert dimensions > 0; assert (!(leafType instanceof JArrayType)); JArrayType result = getTypeArray(leafType); while (dimensions > 1) { result = getTypeArray(result); --dimensions; } return result; } public JType getTypeByClassLiteralField(JField field) { return typesByClassLiteralField.get(field); } public JClassType getTypeClassLiteralHolder() { return typeSpecialClassLiteralHolder; } /** * Returns the JType corresponding to a JSNI type reference. */ public JType getTypeFromJsniRef(String className) { int dim = 0; while (className.endsWith("[]")) { dim++; className = className.substring(0, className.length() - 2); } JType type = primitiveTypes.get(className); if (type == null) { type = getFromTypeMap(className); } // TODO(deprecation): remove support for this. if (type == null) { type = primitiveTypesDeprecated.get(className); } if (type == null || dim == 0) { return type; } else { return getOrCreateArrayType(type, dim); } } public JClassType getTypeJavaLangClass() { return typeClass; } public JClassType getTypeJavaLangEnum() { return typeJavaLangEnum; } public JClassType getTypeJavaLangObject() { return typeJavaLangObject; } public JClassType getTypeJavaLangString() { return typeString; } public Set getTypeNamesToIndex() { return typeNamesToIndex; } public JNullType getTypeNull() { return JNullType.INSTANCE; } public JPrimitiveType getTypePrimitiveBoolean() { return JPrimitiveType.BOOLEAN; } public JPrimitiveType getTypePrimitiveByte() { return JPrimitiveType.BYTE; } public JPrimitiveType getTypePrimitiveChar() { return JPrimitiveType.CHAR; } public JPrimitiveType getTypePrimitiveDouble() { return JPrimitiveType.DOUBLE; } public JPrimitiveType getTypePrimitiveFloat() { return JPrimitiveType.FLOAT; } public JPrimitiveType getTypePrimitiveInt() { return JPrimitiveType.INT; } public JPrimitiveType getTypePrimitiveLong() { return JPrimitiveType.LONG; } public JPrimitiveType getTypePrimitiveShort() { return JPrimitiveType.SHORT; } public JPrimitiveType getTypeVoid() { return JPrimitiveType.VOID; } public void initTypeInfo(Map castMapForType) { castMaps = castMapForType; if (castMaps == null) { castMaps = Maps.newIdentityHashMap(); } } public boolean isJavaLangString(JType type) { return type == typeString || type == typeString.getNonNull(); } public boolean isReferenceOnly(JDeclaredType type) { if (type != null) { return referenceOnlyTypeNames.contains(type.getName()); } return false; } public boolean isStaticImpl(JMethod method) { return staticToInstanceMap.containsKey(method); } public static JInterfaceType maybeGetJsTypeFromPrototype(JDeclaredType classType) { if (classType == null) { return null; } if (classType instanceof JClassType && ((JClassType) classType).isJsPrototypeStub()) { for (JInterfaceType intf : classType.getImplements()) { if (intf.isJsType() && intf.getJsPrototype() != null) { return intf; } } } return null; } /** * If the type is a JSO or an array of JSOs it returns cggcc.JavaScriptObject or an array of * cggcc.JavaScriptObject respectively; otherwise returns {@code type}. */ public JType normalizeJsoType(JType type) { type = type.getUnderlyingType(); if (type instanceof JArrayType) { return getOrCreateArrayType(normalizeJsoType(((JArrayType) type).getLeafType()), ((JArrayType) type).getDims()); } if (typeOracle.isJavaScriptObject(type)) { return getJavaScriptObject(); } return type; } public void putIntoTypeMap(String qualifiedBinaryName, JDeclaredType type) { // Make it into a source type name. String srcTypeName = qualifiedBinaryName.replace('$', '.'); typeNameMap.put(srcTypeName, type); } public void putStaticImpl(JMethod method, JMethod staticImpl) { instanceToStaticMap.put(method, staticImpl); staticToInstanceMap.put(staticImpl, method); if (method.isTrace()) { staticImpl.setTrace(); } } public void recordClassLiteralFields(Map classLiteralFields) { this.classLiteralFieldsByType = HashBiMap.create(classLiteralFields); this.typesByClassLiteralField = classLiteralFieldsByType.inverse(); } public void removeStaticImplMapping(JMethod staticImpl) { JMethod instanceMethod = staticToInstanceMap.remove(staticImpl); if (instanceMethod != null) { instanceToStaticMap.remove(instanceMethod); } } public void removeReferenceOnlyType(JDeclaredType type) { referenceOnlyTypeNames.remove(type.getName()); } public void setFragmentPartitioningResult(FragmentPartitioningResult result) { fragmentPartitioningResult = result; } public void setInitialFragmentIdSequence(List initialFragmentIdSequence) { this.initialFragmentIdSequence = initialFragmentIdSequence; } public void setRunAsyncs(List runAsyncs) { this.runAsyncs = ImmutableList.copyOf(runAsyncs); } public void setInitialAsyncSequence(LinkedHashSet initialAsyncSequence) { assert this.initialAsyncSequence.isEmpty(); initialFragmentIdSequence = Lists.newArrayList(); // TODO(rluble): hack for now the initial fragments correspond to the initial runAsyncIds. initialFragmentIdSequence.addAll( Collections2.transform(initialAsyncSequence, new Function() { @Override public Integer apply(JRunAsync runAsync) { return runAsync.getRunAsyncId(); } })); this.initialAsyncSequence = initialAsyncSequence; } public void setPropertyProviderRegistratorTypeSourceName( String propertyProviderRegistratorTypeSourceName) { this.propertyProviderRegistratorTypeSourceName = propertyProviderRegistratorTypeSourceName; } public void setRuntimeRebindRegistratorTypeName(String runtimeRebindRegistratorTypeName) { this.runtimeRebindRegistratorTypeName = runtimeRebindRegistratorTypeName; } /** * If {@code method} is a static impl method, returns the instance method * that {@code method} is the implementation of. Otherwise, returns{@code null}. */ public JMethod instanceMethodForStaticImpl(JMethod method) { return staticToInstanceMap.get(method); } /** * Return the greatest lower bound of two types. That is, return the largest * type that is a subtype of both inputs. */ public JReferenceType strongerType(JReferenceType type1, JReferenceType type2) { if (type1 == type2) { return type1; } if (type1 instanceof JNullType || type2 instanceof JNullType) { return JNullType.INSTANCE; } if (type1 instanceof JNonNullType != type2 instanceof JNonNullType) { // If either is non-nullable, the result should be non-nullable. return strongerType(type1.getNonNull(), type2.getNonNull()); } if (typeOracle.canTriviallyCast(type1, type2)) { return type1; } if (typeOracle.canTriviallyCast(type2, type1)) { return type2; } // cannot determine a strong type, just return the first one (this makes two // "unrelated" interfaces work correctly in TypeTightener return type1; } @Override public void traverse(JVisitor visitor, Context ctx) { if (visitor.visit(this, ctx)) { visitModuleTypes(visitor); } visitor.endVisit(this, ctx); } /** * Builds the starter set of type names that should be indexed when seen during addType(). This * set is a thread safe instance variable and external logic is free to modify it as further * requirements are discovered. */ private static Set buildInitialTypeNamesToIndex() { Set typeNamesToIndex = Sets.newHashSet(); typeNamesToIndex.addAll(ImmutableList.of("java.io.Serializable", "java.lang.Object", "java.lang.String", "java.lang.Class", "java.lang.CharSequence", "java.lang.Cloneable", "java.lang.Comparable", "java.lang.Enum", "java.lang.Iterable", "java.util.Iterator", "java.lang.AssertionError", "java.lang.Boolean", "java.lang.Byte", "java.lang.Character", "java.lang.Short", "java.lang.Integer", "java.lang.Long", "java.lang.Float", "java.lang.Double", "java.lang.Throwable", "com.google.gwt.core.client.GWT", JAVASCRIPTOBJECT, "com.google.gwt.lang.RuntimeRebinder", CLASS_LITERAL_HOLDER, "com.google.gwt.core.client.RunAsyncCallback", "com.google.gwt.core.client.impl.AsyncFragmentLoader", "com.google.gwt.core.client.impl.Impl", "com.google.gwt.core.client.prefetch.RunAsyncCode")); typeNamesToIndex.addAll(CODEGEN_TYPES_SET); return typeNamesToIndex; } public void visitAllTypes(JVisitor visitor) { visitor.accept(allTypes); } public void visitModuleTypes(JVisitor visitor) { for (JDeclaredType type : allTypes) { if (isReferenceOnly(type)) { continue; } visitor.accept(type); } } private int classifyType(JReferenceType type) { assert !(type instanceof JNonNullType); if (type instanceof JNullType) { return IS_NULL; } else if (type instanceof JInterfaceType) { return IS_INTERFACE; } else if (type instanceof JArrayType) { return IS_ARRAY; } else if (type instanceof JClassType) { return IS_CLASS; } throw new InternalCompilerException("Unknown reference type"); } private int countSuperTypes(JClassType type) { int count = 0; while ((type = type.getSuperClass()) != null) { ++count; } return count; } /** * See notes in {@link #writeObject(ObjectOutputStream)}. * * @see #writeObject(ObjectOutputStream) */ private void readObject(ObjectInputStream stream) throws IOException, ClassNotFoundException { allTypes = deserializeTypes(stream); stream.defaultReadObject(); } /** * Serializing the Java AST is a multi-step process to avoid blowing out the * stack. * *

    *
  1. Write all declared types in a lightweight manner to establish object * identity for types
  2. *
  3. Write all fields; write all methods in a lightweight manner to * establish object identity for methods
  4. *
  5. Write all method bodies
  6. *
  7. Write everything else, which will mostly refer to already-serialized * objects.
  8. *
  9. Write the bodies of the entry methods (unlike all other methods, these * are not contained by any type.
  10. *
* * The goal of this process to to avoid "running away" with the stack. Without * special logic here, lots of things would reference types, method body code * would reference both types and other methods, and really, really long * recursion chains would result. */ private void writeObject(ObjectOutputStream stream) throws IOException { serializeTypes(allTypes, stream); stream.defaultWriteObject(); } }




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