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Google HTTP Client Library for Java. Functionality that works on all supported Java platforms, including Java 7 (or higher) desktop (SE) and web (EE), Android, and Google App Engine.

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/*
 * Copyright (c) 2011 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.api.client.util;

import java.lang.reflect.Array;
import java.lang.reflect.GenericArrayType;
import java.lang.reflect.ParameterizedType;
import java.lang.reflect.Type;
import java.lang.reflect.TypeVariable;
import java.lang.reflect.WildcardType;
import java.math.BigDecimal;
import java.math.BigInteger;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collection;
import java.util.Collections;
import java.util.HashSet;
import java.util.List;
import java.util.Map;
import java.util.SortedMap;
import java.util.TreeMap;
import java.util.TreeSet;
import java.util.concurrent.ConcurrentHashMap;

/**
 * Utilities for working with key/value data based on the {@link Key} annotation.
 *
 * @since 1.4
 * @author Yaniv Inbar
 */
public class Data {

  // NOTE: create new instances to avoid cache, e.g. new String()

  /** The single instance of the magic null object for a {@link Boolean}. */
  @SuppressWarnings("deprecation")
  public static final Boolean NULL_BOOLEAN = new Boolean(true);

  /** The single instance of the magic null object for a {@link String}. */
  @SuppressWarnings("deprecation")
  public static final String NULL_STRING = new String();

  /** The single instance of the magic null object for a {@link Character}. */
  @SuppressWarnings("deprecation")
  public static final Character NULL_CHARACTER = new Character((char) 0);

  /** The single instance of the magic null object for a {@link Byte}. */
  @SuppressWarnings("deprecation")
  public static final Byte NULL_BYTE = new Byte((byte) 0);

  /** The single instance of the magic null object for a {@link Short}. */
  @SuppressWarnings("deprecation")
  public static final Short NULL_SHORT = new Short((short) 0);

  /** The single instance of the magic null object for a {@link Integer}. */
  @SuppressWarnings("deprecation")
  public static final Integer NULL_INTEGER = new Integer(0);

  /** The single instance of the magic null object for a {@link Float}. */
  @SuppressWarnings("deprecation")
  public static final Float NULL_FLOAT = new Float(0);

  /** The single instance of the magic null object for a {@link Long}. */
  @SuppressWarnings("deprecation")
  public static final Long NULL_LONG = new Long(0);

  /** The single instance of the magic null object for a {@link Double}. */
  @SuppressWarnings("deprecation")
  public static final Double NULL_DOUBLE = new Double(0);

  /** The single instance of the magic null object for a {@link BigInteger}. */
  @SuppressWarnings("deprecation")
  public static final BigInteger NULL_BIG_INTEGER = new BigInteger("0");

  /** The single instance of the magic null object for a {@link BigDecimal}. */
  @SuppressWarnings("deprecation")
  public static final BigDecimal NULL_BIG_DECIMAL = new BigDecimal("0");

  /** The single instance of the magic null object for a {@link DateTime}. */
  public static final DateTime NULL_DATE_TIME = new DateTime(0);

  /** Cache of the magic null object for the given Java class. */
  private static final ConcurrentHashMap, Object> NULL_CACHE =
      new ConcurrentHashMap, Object>();

  static {
    // special cases for some primitives
    NULL_CACHE.put(Boolean.class, NULL_BOOLEAN);
    NULL_CACHE.put(String.class, NULL_STRING);
    NULL_CACHE.put(Character.class, NULL_CHARACTER);
    NULL_CACHE.put(Byte.class, NULL_BYTE);
    NULL_CACHE.put(Short.class, NULL_SHORT);
    NULL_CACHE.put(Integer.class, NULL_INTEGER);
    NULL_CACHE.put(Float.class, NULL_FLOAT);
    NULL_CACHE.put(Long.class, NULL_LONG);
    NULL_CACHE.put(Double.class, NULL_DOUBLE);
    NULL_CACHE.put(BigInteger.class, NULL_BIG_INTEGER);
    NULL_CACHE.put(BigDecimal.class, NULL_BIG_DECIMAL);
    NULL_CACHE.put(DateTime.class, NULL_DATE_TIME);
  }

  /**
   * Returns the single instance of the magic object that represents the "null" value for the given
   * Java class (including array or enum).
   *
   * @param objClass class of the object needed
   * @return magic object instance that represents the "null" value (not Java {@code null})
   * @throws IllegalArgumentException if unable to create a new instance
   */
  public static  T nullOf(Class objClass) {
    // ConcurrentMap.computeIfAbsent is explicitly NOT used in the following logic. The
    // ConcurrentHashMap implementation of that method BLOCKS if the mappingFunction triggers
    // modification of the map which createNullInstance can do depending on the state of class
    // loading.
    Object result = NULL_CACHE.get(objClass);
    if (result == null) {
      // If nullOf is called concurrently for the same class createNullInstance may be executed
      // multiple times. However putIfAbsent ensures that no matter what the concurrent access
      // pattern looks like callers always get a singleton instance returned. Since
      // createNullInstance has no side-effects beyond triggering class loading this multiple-call
      // pattern is safe.
      Object newValue = createNullInstance(objClass);
      result = NULL_CACHE.putIfAbsent(objClass, newValue);
      if (result == null) {
        result = newValue;
      }
    }
    @SuppressWarnings("unchecked")
    T tResult = (T) result;
    return tResult;
  }

  private static Object createNullInstance(Class objClass) {
    if (objClass.isArray()) {
      // arrays are special because we need to compute both the dimension and component type
      int dims = 0;
      Class componentType = objClass;
      do {
        componentType = componentType.getComponentType();
        dims++;
      } while (componentType.isArray());
      return Array.newInstance(componentType, new int[dims]);
    }
    if (objClass.isEnum()) {
      // enum requires look for constant with @NullValue
      FieldInfo fieldInfo = ClassInfo.of(objClass).getFieldInfo(null);
      Preconditions.checkNotNull(
          fieldInfo, "enum missing constant with @NullValue annotation: %s", objClass);
      @SuppressWarnings({"unchecked", "rawtypes"})
      Enum e = fieldInfo.enumValue();
      return e;
    }
    // other classes are simpler
    return Types.newInstance(objClass);
  }

  /**
   * Returns whether the given object is the magic object that represents the null value of its
   * class.
   *
   * @param object object or {@code null}
   * @return whether it is the magic null value or {@code false} for {@code null} input
   */
  public static boolean isNull(Object object) {
    // don't call nullOf because will throw IllegalArgumentException if cannot create instance
    return object != null && object == NULL_CACHE.get(object.getClass());
  }

  /**
   * Returns the map to use for the given data that is treated as a map from string key to some
   * value.
   *
   * 

If the input is {@code null}, it returns an empty map. If the input is a map, it simply * returns the input. Otherwise, it will create a map view using reflection that is backed by the * object, so that any changes to the map will be reflected on the object. The map keys of that * map view are based on the {@link Key} annotation, and null is not a possible map value, * although the magic null instance is possible (see {@link #nullOf(Class)} and {@link * #isNull(Object)}). Iteration order of the data keys is based on the sorted (ascending) key * names of the declared fields. Note that since the map view is backed by the object, and that * the object may change, many methods in the map view must recompute the field values using * reflection, for example {@link Map#size()} must check the number of non-null fields. * * @param data any key value data, represented by an object or a map, or {@code null} * @return key/value map to use */ public static Map mapOf(Object data) { if (data == null || isNull(data)) { return Collections.emptyMap(); } if (data instanceof Map) { @SuppressWarnings("unchecked") Map result = (Map) data; return result; } Map result = new DataMap(data, false); return result; } /** * Returns a deep clone of the given key/value data, such that the result is a completely * independent copy. * *

This should not be used directly in the implementation of {@code Object.clone()}. Instead * use {@link #deepCopy(Object, Object)} for that purpose. * *

Final fields cannot be changed and therefore their value won't be copied. * * @param data key/value data object or map to clone or {@code null} for a {@code null} return * value * @return deep clone or {@code null} for {@code null} input */ @SuppressWarnings("unchecked") public static T clone(T data) { // don't need to clone primitive if (data == null || Data.isPrimitive(data.getClass())) { return data; } if (data instanceof GenericData) { return (T) ((GenericData) data).clone(); } T copy; Class dataClass = data.getClass(); if (dataClass.isArray()) { copy = (T) Array.newInstance(dataClass.getComponentType(), Array.getLength(data)); } else if (data instanceof ArrayMap) { copy = (T) ((ArrayMap) data).clone(); } else if ("java.util.Arrays$ArrayList".equals(dataClass.getName())) { // Arrays$ArrayList does not have a zero-arg constructor, so it has to handled specially. // Arrays.asList(x).toArray() may or may not have the same runtime type as x. // https://bugs.openjdk.java.net/browse/JDK-6260652 Object[] arrayCopy = ((List) data).toArray(); deepCopy(arrayCopy, arrayCopy); copy = (T) Arrays.asList(arrayCopy); return copy; } else { copy = (T) Types.newInstance(dataClass); } deepCopy(data, copy); return copy; } /** * Makes a deep copy of the given source object into the destination object that is assumed to be * constructed using {@code Object.clone()}. * *

Example usage of this method in {@code Object.clone()}: * *

   * @Override
   * public MyObject clone() {
   * try {
   * @SuppressWarnings("unchecked")
   * MyObject result = (MyObject) super.clone();
   * Data.deepCopy(this, result);
   * return result;
   * } catch (CloneNotSupportedException e) {
   * throw new IllegalStateException(e);
   * }
   * }
   * 
* *

Final fields cannot be changed and therefore their value won't be copied. * * @param src source object * @param dest destination object of identical type as source object, and any contained arrays * must be the same length */ public static void deepCopy(Object src, Object dest) { Class srcClass = src.getClass(); Preconditions.checkArgument(srcClass == dest.getClass()); if (srcClass.isArray()) { // clone array Preconditions.checkArgument(Array.getLength(src) == Array.getLength(dest)); int index = 0; for (Object value : Types.iterableOf(src)) { Array.set(dest, index++, clone(value)); } } else if (Collection.class.isAssignableFrom(srcClass)) { // clone collection @SuppressWarnings("unchecked") Collection srcCollection = (Collection) src; if (ArrayList.class.isAssignableFrom(srcClass)) { @SuppressWarnings("unchecked") ArrayList destArrayList = (ArrayList) dest; destArrayList.ensureCapacity(srcCollection.size()); } @SuppressWarnings("unchecked") Collection destCollection = (Collection) dest; for (Object srcValue : srcCollection) { destCollection.add(clone(srcValue)); } } else { // clone generic data or a non-map Object boolean isGenericData = GenericData.class.isAssignableFrom(srcClass); if (isGenericData || !Map.class.isAssignableFrom(srcClass)) { ClassInfo classInfo = isGenericData ? ((GenericData) src).classInfo : ClassInfo.of(srcClass); for (String fieldName : classInfo.names) { FieldInfo fieldInfo = classInfo.getFieldInfo(fieldName); // skip final fields if (!fieldInfo.isFinal()) { // generic data already has primitive types copied by clone() if (!isGenericData || !fieldInfo.isPrimitive()) { Object srcValue = fieldInfo.getValue(src); if (srcValue != null) { fieldInfo.setValue(dest, clone(srcValue)); } } } } } else if (ArrayMap.class.isAssignableFrom(srcClass)) { // clone array map @SuppressWarnings("unchecked") ArrayMap destMap = (ArrayMap) dest; @SuppressWarnings("unchecked") ArrayMap srcMap = (ArrayMap) src; int size = srcMap.size(); for (int i = 0; i < size; i++) { Object srcValue = srcMap.getValue(i); destMap.set(i, clone(srcValue)); } } else { // clone map @SuppressWarnings("unchecked") Map destMap = (Map) dest; @SuppressWarnings("unchecked") Map srcMap = (Map) src; for (Map.Entry srcEntry : srcMap.entrySet()) { destMap.put(srcEntry.getKey(), clone(srcEntry.getValue())); } } } } /** * Returns whether the given type is one of the supported primitive classes like number and * date/time, or is a wildcard of one. * *

A primitive class is any class for whom {@link Class#isPrimitive()} is true, as well as any * classes of type: {@link Character}, {@link String}, {@link Integer}, {@link Long}, {@link * Short}, {@link Byte}, {@link Float}, {@link Double}, {@link BigInteger}, {@link BigDecimal}, * {@link Boolean}, and {@link DateTime}. * * @param type type or {@code null} for {@code false} result * @return whether it is a primitive */ public static boolean isPrimitive(Type type) { // TODO(yanivi): support java.net.URI as primitive type? if (type instanceof WildcardType) { type = Types.getBound((WildcardType) type); } if (!(type instanceof Class)) { return false; } Class typeClass = (Class) type; return typeClass.isPrimitive() || typeClass == Character.class || typeClass == String.class || typeClass == Integer.class || typeClass == Long.class || typeClass == Short.class || typeClass == Byte.class || typeClass == Float.class || typeClass == Double.class || typeClass == BigInteger.class || typeClass == BigDecimal.class || typeClass == DateTime.class || typeClass == Boolean.class; } /** * Returns whether to given value is {@code null} or its class is primitive as defined by {@link * Data#isPrimitive(Type)}. */ public static boolean isValueOfPrimitiveType(Object fieldValue) { return fieldValue == null || Data.isPrimitive(fieldValue.getClass()); } /** * Parses the given string value based on the given primitive type. * *

Types are parsed as follows: * *

    *
  • {@link Void}: null *
  • {@code null} or is assignable from {@link String} (like {@link Object}): no parsing *
  • {@code char} or {@link Character}: {@link String#charAt(int) String.charAt}(0) (requires * length to be exactly 1) *
  • {@code boolean} or {@link Boolean}: {@link Boolean#valueOf(String)} *
  • {@code byte} or {@link Byte}: {@link Byte#valueOf(String)} *
  • {@code short} or {@link Short}: {@link Short#valueOf(String)} *
  • {@code int} or {@link Integer}: {@link Integer#valueOf(String)} *
  • {@code long} or {@link Long}: {@link Long#valueOf(String)} *
  • {@code float} or {@link Float}: {@link Float#valueOf(String)} *
  • {@code double} or {@link Double}: {@link Double#valueOf(String)} *
  • {@link BigInteger}: {@link BigInteger#BigInteger(String) BigInteger(String)} *
  • {@link BigDecimal}: {@link BigDecimal#BigDecimal(String) BigDecimal(String)} *
  • {@link DateTime}: {@link DateTime#parseRfc3339(String)} *
* *

Note that this may not be the right behavior for some use cases. * * @param type primitive type or {@code null} to parse as a string * @param stringValue string value to parse or {@code null} for {@code null} result * @return parsed object or {@code null} for {@code null} input * @throws IllegalArgumentException if the given class is not a primitive class */ public static Object parsePrimitiveValue(Type type, String stringValue) { Class primitiveClass = type instanceof Class ? (Class) type : null; if (type == null || primitiveClass != null) { if (primitiveClass == Void.class) { return null; } if (stringValue == null || primitiveClass == null || primitiveClass.isAssignableFrom(String.class)) { return stringValue; } if (primitiveClass == Character.class || primitiveClass == char.class) { if (stringValue.length() != 1) { throw new IllegalArgumentException( "expected type Character/char but got " + primitiveClass); } return stringValue.charAt(0); } if (primitiveClass == Boolean.class || primitiveClass == boolean.class) { return Boolean.valueOf(stringValue); } if (primitiveClass == Byte.class || primitiveClass == byte.class) { return Byte.valueOf(stringValue); } if (primitiveClass == Short.class || primitiveClass == short.class) { return Short.valueOf(stringValue); } if (primitiveClass == Integer.class || primitiveClass == int.class) { return Integer.valueOf(stringValue); } if (primitiveClass == Long.class || primitiveClass == long.class) { return Long.valueOf(stringValue); } if (primitiveClass == Float.class || primitiveClass == float.class) { return Float.valueOf(stringValue); } if (primitiveClass == Double.class || primitiveClass == double.class) { return Double.valueOf(stringValue); } if (primitiveClass == DateTime.class) { return DateTime.parseRfc3339(stringValue); } if (primitiveClass == BigInteger.class) { return new BigInteger(stringValue); } if (primitiveClass == BigDecimal.class) { return new BigDecimal(stringValue); } if (primitiveClass.isEnum()) { if (!ClassInfo.of(primitiveClass).names.contains(stringValue)) { throw new IllegalArgumentException( String.format("given enum name %s not part of " + "enumeration", stringValue)); } @SuppressWarnings({"unchecked", "rawtypes"}) Enum result = ClassInfo.of(primitiveClass).getFieldInfo(stringValue).enumValue(); return result; } } throw new IllegalArgumentException("expected primitive class, but got: " + type); } /** * Returns a new collection instance for the given type. * *

Creates a new collection instance specified for the first input collection class that * matches as follows: * *

    *
  • {@code null} or an array or assignable from {@link ArrayList} (like {@link List} or * {@link Collection} or {@link Object}): returns an {@link ArrayList} *
  • assignable from {@link HashSet}: returns a {@link HashSet} *
  • assignable from {@link TreeSet}: returns a {@link TreeSet} *
  • else: calls {@link Types#newInstance(Class)} *
* * @param type type or {@code null} for {@link ArrayList}. * @return new collection instance * @throws ClassCastException if result is does not extend {@link Collection} */ public static Collection newCollectionInstance(Type type) { if (type instanceof WildcardType) { type = Types.getBound((WildcardType) type); } if (type instanceof ParameterizedType) { type = ((ParameterizedType) type).getRawType(); } Class collectionClass = type instanceof Class ? (Class) type : null; if (type == null || type instanceof GenericArrayType || collectionClass != null && (collectionClass.isArray() || collectionClass.isAssignableFrom(ArrayList.class))) { return new ArrayList(); } if (collectionClass == null) { throw new IllegalArgumentException("unable to create new instance of type: " + type); } if (collectionClass.isAssignableFrom(HashSet.class)) { return new HashSet(); } if (collectionClass.isAssignableFrom(TreeSet.class)) { return new TreeSet(); } @SuppressWarnings("unchecked") Collection result = (Collection) Types.newInstance(collectionClass); return result; } /** * Returns a new instance of a map based on the given field class. * *

Creates a new map instance specified for the first input map class that matches as follows: * *

    *
  • {@code null} or assignable from {@link ArrayMap} (like {@link Map} or {@link Object}): * returns an {@link ArrayMap} *
  • assignable from {@link TreeMap} (like {@link SortedMap}): returns a {@link TreeMap} *
  • else: calls {@link Types#newInstance(Class)} *
* * @param mapClass field class * @throws ClassCastException if result is does not extend {@link Map} */ public static Map newMapInstance(Class mapClass) { if (mapClass == null || mapClass.isAssignableFrom(ArrayMap.class)) { return ArrayMap.create(); } if (mapClass.isAssignableFrom(TreeMap.class)) { return new TreeMap(); } @SuppressWarnings("unchecked") Map result = (Map) Types.newInstance(mapClass); return result; } /** * Aggressively resolves the given type in such a way that the resolved type is not a wildcard * type or a type variable, returning {@code Object.class} if the type variable cannot be * resolved. * * @param context context list, ordering from least specific to most specific type context, for * example container class and then its field * @param type type or {@code null} for {@code null} result * @return resolved type (which may be class, parameterized type, or generic array type, but not * wildcard type or type variable) or {@code null} for {@code null} input */ public static Type resolveWildcardTypeOrTypeVariable(List context, Type type) { // first deal with a wildcard, e.g. ? extends Number if (type instanceof WildcardType) { type = Types.getBound((WildcardType) type); } // next deal with a type variable T while (type instanceof TypeVariable) { // resolve the type variable Type resolved = Types.resolveTypeVariable(context, (TypeVariable) type); if (resolved != null) { type = resolved; } // if unable to fully resolve the type variable, use its bounds, e.g. T extends Number if (type instanceof TypeVariable) { type = ((TypeVariable) type).getBounds()[0]; } // loop in case T extends U and U is also a type variable } return type; } }