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android-review.linaro.org / platform / external / guava / refs/tags/android-4.0.3_r1.1 / . / src / com / google / common / collect / Maps.java
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/*
* Copyright (C) 2007 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.common.collect;
import com.google.common.annotations.GwtCompatible;
import com.google.common.base.Function;
import com.google.common.base.Joiner.MapJoiner;
import com.google.common.base.Objects;
import com.google.common.base.Predicate;
import com.google.common.base.Predicates;
import java.io.Serializable;
import java.util.AbstractCollection;
import java.util.AbstractMap;
import java.util.AbstractSet;
import java.util.Collection;
import java.util.Collections;
import java.util.Comparator;
import java.util.EnumMap;
import java.util.Enumeration;
import java.util.HashMap;
import java.util.IdentityHashMap;
import java.util.Iterator;
import java.util.LinkedHashMap;
import java.util.Map;
import java.util.Map.Entry;
import java.util.Properties;
import java.util.Set;
import java.util.SortedMap;
import java.util.TreeMap;
import javax.annotation.Nullable;
import static com.google.common.base.Preconditions.checkArgument;
import static com.google.common.base.Preconditions.checkNotNull;
/**
* Static utility methods pertaining to {@link Map} instances. Also see this
* class's counterparts {@link Lists} and {@link Sets}.
*
* @author Kevin Bourrillion
* @author Mike Bostock
* @author Isaac Shum
* @since 2010.01.04 <b>stable</b> (imported from Google Collections Library)
*/
@GwtCompatible
public final class Maps {
private Maps() {}
/**
* Creates a <i>mutable</i>, empty {@code HashMap} instance.
*
* <p><b>Note:</b> if mutability is not required, use {@link
* ImmutableMap#of()} instead.
*
* <p><b>Note:</b> if {@code K} is an {@code enum} type, use {@link
* #newEnumMap} instead.
*
* @return a new, empty {@code HashMap}
*/
public static <K, V> HashMap<K, V> newHashMap() {
return new HashMap<K, V>();
}
/**
* Creates a {@code HashMap} instance with enough capacity to hold the
* specified number of elements without rehashing.
*
* @param expectedSize the expected size
* @return a new, empty {@code HashMap} with enough
* capacity to hold {@code expectedSize} elements without rehashing
* @throws IllegalArgumentException if {@code expectedSize} is negative
*/
public static <K, V> HashMap<K, V> newHashMapWithExpectedSize(
int expectedSize) {
/*
* The HashMap is constructed with an initialCapacity that's greater than
* expectedSize. The larger value is necessary because HashMap resizes
* its internal array if the map size exceeds loadFactor * initialCapacity.
*/
return new HashMap<K, V>(capacity(expectedSize));
}
/**
* Returns an appropriate value for the "capacity" (in reality, "minimum
* table size") parameter of a {@link HashMap} constructor, such that the
* resulting table will be between 25% and 50% full when it contains
* {@code expectedSize} entries.
*
* @throws IllegalArgumentException if {@code expectedSize} is negative
*/
static int capacity(int expectedSize) {
checkArgument(expectedSize >= 0);
return Math.max(expectedSize * 2, 16);
}
/**
* Creates a <i>mutable</i> {@code HashMap} instance with the same mappings as
* the specified map.
*
* <p><b>Note:</b> if mutability is not required, use {@link
* ImmutableMap#copyOf(Map)} instead.
*
* <p><b>Note:</b> if {@code K} is an {@link Enum} type, use {@link
* #newEnumMap} instead.
*
* @param map the mappings to be placed in the new map
* @return a new {@code HashMap} initialized with the mappings from
* {@code map}
*/
public static <K, V> HashMap<K, V> newHashMap(
Map<? extends K, ? extends V> map) {
return new HashMap<K, V>(map);
}
/**
* Creates a <i>mutable</i>, empty, insertion-ordered {@code LinkedHashMap}
* instance.
*
* <p><b>Note:</b> if mutability is not required, use {@link
* ImmutableMap#of()} instead.
*
* @return a new, empty {@code LinkedHashMap}
*/
public static <K, V> LinkedHashMap<K, V> newLinkedHashMap() {
return new LinkedHashMap<K, V>();
}
/**
* Creates a <i>mutable</i>, insertion-ordered {@code LinkedHashMap} instance
* with the same mappings as the specified map.
*
* <p><b>Note:</b> if mutability is not required, use {@link
* ImmutableMap#copyOf(Map)} instead.
*
* @param map the mappings to be placed in the new map
* @return a new, {@code LinkedHashMap} initialized with the
* mappings from {@code map}
*/
public static <K, V> LinkedHashMap<K, V>
newLinkedHashMap(Map<? extends K, ? extends V> map) {
return new LinkedHashMap<K, V>(map);
}
/**
* Creates a <i>mutable</i>, empty {@code TreeMap} instance using the natural
* ordering of its elements.
*
* <p><b>Note:</b> if mutability is not required, use {@link
* ImmutableSortedMap#of()} instead.
*
* @return a new, empty {@code TreeMap}
*/
@SuppressWarnings("unchecked") // eclipse doesn't like the raw Comparable
public static <K extends Comparable, V> TreeMap<K, V> newTreeMap() {
return new TreeMap<K, V>();
}
/**
* Creates a <i>mutable</i> {@code TreeMap} instance with the same mappings as
* the specified map and using the same ordering as the specified map.
*
* <p><b>Note:</b> if mutability is not required, use {@link
* ImmutableSortedMap#copyOfSorted(SortedMap)} instead.
*
* @param map the sorted map whose mappings are to be placed in the new map
* and whose comparator is to be used to sort the new map
* @return a new {@code TreeMap} initialized with the mappings from {@code
* map} and using the comparator of {@code map}
*/
public static <K, V> TreeMap<K, V> newTreeMap(SortedMap<K, ? extends V> map) {
return new TreeMap<K, V>(map);
}
/**
* Creates a <i>mutable</i>, empty {@code TreeMap} instance using the given
* comparator.
*
* <p><b>Note:</b> if mutability is not required, use {@code
* ImmutableSortedMap.orderedBy(comparator).build()} instead.
*
* @param comparator the comparator to sort the keys with
* @return a new, empty {@code TreeMap}
*/
public static <C, K extends C, V> TreeMap<K, V> newTreeMap(
@Nullable Comparator<C> comparator) {
// Ideally, the extra type parameter "C" shouldn't be necessary. It is a
// work-around of a compiler type inference quirk that prevents the
// following code from being compiled:
// Comparator<Class<?>> comparator = null;
// Map<Class<? extends Throwable>, String> map = newTreeMap(comparator);
return new TreeMap<K, V>(comparator);
}
/**
* Creates an {@code EnumMap} instance.
*
* @param type the key type for this map
* @return a new, empty {@code EnumMap}
*/
public static <K extends Enum<K>, V> EnumMap<K, V> newEnumMap(Class<K> type) {
return new EnumMap<K, V>(checkNotNull(type));
}
/**
* Creates an {@code EnumMap} with the same mappings as the specified map.
*
* @param map the map from which to initialize this {@code EnumMap}
* @return a new {@code EnumMap} initialized with the mappings from {@code
* map}
* @throws IllegalArgumentException if {@code m} is not an {@code EnumMap}
* instance and contains no mappings
*/
public static <K extends Enum<K>, V> EnumMap<K, V> newEnumMap(
Map<K, ? extends V> map) {
return new EnumMap<K, V>(map);
}
/**
* Creates an {@code IdentityHashMap} instance.
*
* @return a new, empty {@code IdentityHashMap}
*/
public static <K, V> IdentityHashMap<K, V> newIdentityHashMap() {
return new IdentityHashMap<K, V>();
}
/**
* Returns a synchronized (thread-safe) bimap backed by the specified bimap.
* In order to guarantee serial access, it is critical that <b>all</b> access
* to the backing bimap is accomplished through the returned bimap.
*
* <p>It is imperative that the user manually synchronize on the returned map
* when accessing any of its collection views: <pre> {@code
*
* BiMap<Long, String> map = Maps.synchronizedBiMap(
* HashBiMap.<Long, String>create());
* ...
* Set<Long> set = map.keySet(); // Needn't be in synchronized block
* ...
* synchronized (map) { // Synchronizing on map, not set!
* Iterator<Long> it = set.iterator(); // Must be in synchronized block
* while (it.hasNext()) {
* foo(it.next());
* }
* }}</pre>
*
* Failure to follow this advice may result in non-deterministic behavior.
*
* <p>The returned bimap will be serializable if the specified bimap is
* serializable.
*
* @param bimap the bimap to be wrapped in a synchronized view
* @return a sychronized view of the specified bimap
*/
public static <K, V> BiMap<K, V> synchronizedBiMap(BiMap<K, V> bimap) {
return Synchronized.biMap(bimap, null);
}
/**
* Computes the difference between two maps. This difference is an immutable
* snapshot of the state of the maps at the time this method is called. It
* will never change, even if the maps change at a later time.
*
* <p>Since this method uses {@code HashMap} instances internally, the keys of
* the supplied maps must be well-behaved with respect to
* {@link Object#equals} and {@link Object#hashCode}.
*
* <p><b>Note:</b>If you only need to know whether two maps have the same
* mappings, call {@code left.equals(right)} instead of this method.
*
* @param left the map to treat as the "left" map for purposes of comparison
* @param right the map to treat as the "right" map for purposes of comparison
* @return the difference between the two maps
*/
public static <K, V> MapDifference<K, V> difference(
Map<? extends K, ? extends V> left, Map<? extends K, ? extends V> right) {
Map<K, V> onlyOnLeft = newHashMap();
Map<K, V> onlyOnRight = new HashMap<K, V>(right); // will whittle it down
Map<K, V> onBoth = newHashMap();
Map<K, MapDifference.ValueDifference<V>> differences = newHashMap();
boolean eq = true;
for (Entry<? extends K, ? extends V> entry : left.entrySet()) {
K leftKey = entry.getKey();
V leftValue = entry.getValue();
if (right.containsKey(leftKey)) {
V rightValue = onlyOnRight.remove(leftKey);
if (Objects.equal(leftValue, rightValue)) {
onBoth.put(leftKey, leftValue);
} else {
eq = false;
differences.put(leftKey, new ValueDifferenceImpl<V>(
leftValue, rightValue));
}
} else {
eq = false;
onlyOnLeft.put(leftKey, leftValue);
}
}
boolean areEqual = eq && onlyOnRight.isEmpty();
return new MapDifferenceImpl<K, V>(
areEqual, onlyOnLeft, onlyOnRight, onBoth, differences);
}
private static class MapDifferenceImpl<K, V>
implements MapDifference<K, V> {
final boolean areEqual;
final Map<K, V> onlyOnLeft;
final Map<K, V> onlyOnRight;
final Map<K, V> onBoth;
final Map<K, ValueDifference<V>> differences;
MapDifferenceImpl(boolean areEqual, Map<K, V> onlyOnLeft,
Map<K, V> onlyOnRight, Map<K, V> onBoth,
Map<K, ValueDifference<V>> differences) {
this.areEqual = areEqual;
this.onlyOnLeft = Collections.unmodifiableMap(onlyOnLeft);
this.onlyOnRight = Collections.unmodifiableMap(onlyOnRight);
this.onBoth = Collections.unmodifiableMap(onBoth);
this.differences = Collections.unmodifiableMap(differences);
}
public boolean areEqual() {
return areEqual;
}
public Map<K, V> entriesOnlyOnLeft() {
return onlyOnLeft;
}
public Map<K, V> entriesOnlyOnRight() {
return onlyOnRight;
}
public Map<K, V> entriesInCommon() {
return onBoth;
}
public Map<K, ValueDifference<V>> entriesDiffering() {
return differences;
}
@Override public boolean equals(Object object) {
if (object == this) {
return true;
}
if (object instanceof MapDifference) {
MapDifference<?, ?> other = (MapDifference<?, ?>) object;
return entriesOnlyOnLeft().equals(other.entriesOnlyOnLeft())
&& entriesOnlyOnRight().equals(other.entriesOnlyOnRight())
&& entriesInCommon().equals(other.entriesInCommon())
&& entriesDiffering().equals(other.entriesDiffering());
}
return false;
}
@Override public int hashCode() {
return Objects.hashCode(entriesOnlyOnLeft(), entriesOnlyOnRight(),
entriesInCommon(), entriesDiffering());
}
@Override public String toString() {
if (areEqual) {
return "equal";
}
StringBuilder result = new StringBuilder("not equal");
if (!onlyOnLeft.isEmpty()) {
result.append(": only on left=").append(onlyOnLeft);
}
if (!onlyOnRight.isEmpty()) {
result.append(": only on right=").append(onlyOnRight);
}
if (!differences.isEmpty()) {
result.append(": value differences=").append(differences);
}
return result.toString();
}
}
static class ValueDifferenceImpl<V>
implements MapDifference.ValueDifference<V> {
private final V left;
private final V right;
ValueDifferenceImpl(@Nullable V left, @Nullable V right) {
this.left = left;
this.right = right;
}
public V leftValue() {
return left;
}
public V rightValue() {
return right;
}
@Override public boolean equals(@Nullable Object object) {
if (object instanceof MapDifference.ValueDifference<?>) {
MapDifference.ValueDifference<?> that =
(MapDifference.ValueDifference<?>) object;
return Objects.equal(this.left, that.leftValue())
&& Objects.equal(this.right, that.rightValue());
}
return false;
}
@Override public int hashCode() {
return Objects.hashCode(left, right);
}
@Override public String toString() {
return "(" + left + ", " + right + ")";
}
}
/**
* Returns an immutable map for which the {@link Map#values} are the given
* elements in the given order, and each key is the product of invoking a
* supplied function on its corresponding value.
*
* @param values the values to use when constructing the {@code Map}
* @param keyFunction the function used to produce the key for each value
* @return a map mapping the result of evaluating the function {@code
* keyFunction} on each value in the input collection to that value
* @throws IllegalArgumentException if {@code keyFunction} produces the same
* key for more than one value in the input collection
* @throws NullPointerException if any elements of {@code values} is null, or
* if {@code keyFunction} produces {@code null} for any value
*/
// TODO: consider returning a bimap, whose inverse view does lookups by
// invoking the function.
public static <K, V> ImmutableMap<K, V> uniqueIndex(
Iterable<V> values, Function<? super V, K> keyFunction) {
checkNotNull(keyFunction);
ImmutableMap.Builder<K, V> builder = ImmutableMap.builder();
for (V value : values) {
builder.put(keyFunction.apply(value), value);
}
return builder.build();
}
/**
* Creates an {@code ImmutableMap<String, String>} from a {@code Properties}
* instance. Properties normally derive from {@code Map<Object, Object>}, but
* they typically contain strings, which is awkward. This method lets you get
* a plain-old-{@code Map} out of a {@code Properties}.
*
* @param properties a {@code Properties} object to be converted
* @return an immutable map containing all the entries in
* {@code properties}
* @throws ClassCastException if any key in {@code Properties} is not a
* {@code String}
* @throws NullPointerException if any key or value in {@code Properties} is
* null.
*/
public static ImmutableMap<String, String>
fromProperties(Properties properties) {
ImmutableMap.Builder<String, String> builder = ImmutableMap.builder();
for (Enumeration<?> e = properties.propertyNames(); e.hasMoreElements();) {
String key = (String) e.nextElement();
builder.put(key, properties.getProperty(key));
}
return builder.build();
}
/**
* Returns an immutable map entry with the specified key and value. The {@link
* Entry#setValue} operation throws an {@link UnsupportedOperationException}.
*
* <p>The returned entry is serializable.
*
* @param key the key to be associated with the returned entry
* @param value the value to be associated with the returned entry
*/
public static <K, V> Entry<K, V> immutableEntry(
@Nullable final K key, @Nullable final V value) {
return new ImmutableEntry<K, V>(key, value);
}
/**
* Returns an unmodifiable view of the specified set of entries. The {@link
* Entry#setValue} operation throws an {@link UnsupportedOperationException},
* as do any operations that would modify the returned set.
*
* @param entrySet the entries for which to return an unmodifiable view
* @return an unmodifiable view of the entries
*/
static <K, V> Set<Entry<K, V>> unmodifiableEntrySet(
final Set<Entry<K, V>> entrySet) {
return new UnmodifiableEntrySet<K, V>(Collections.unmodifiableSet(
entrySet));
}
/**
* Returns an unmodifiable view of the specified map entry. The {@link
* Entry#setValue} operation throws an {@link UnsupportedOperationException}.
* This also has the side-effect of redefining {@code equals} to comply with
* the Entry contract, to avoid a possible nefarious implementation of
* equals.
*
* @param entry the entry for which to return an unmodifiable view
* @return an unmodifiable view of the entry
*/
private static <K, V> Entry<K, V> unmodifiableEntry(final Entry<K, V> entry) {
checkNotNull(entry);
return new AbstractMapEntry<K, V>() {
@Override public K getKey() {
return entry.getKey();
}
@Override public V getValue() {
return entry.getValue();
}
};
}
/** @see Multimaps#unmodifiableEntries */
static class UnmodifiableEntries<K, V>
extends ForwardingCollection<Entry<K, V>> {
private final Collection<Entry<K, V>> entries;
UnmodifiableEntries(Collection<Entry<K, V>> entries) {
this.entries = entries;
}
@Override protected Collection<Entry<K, V>> delegate() {
return entries;
}
@Override public Iterator<Entry<K, V>> iterator() {
final Iterator<Entry<K, V>> delegate = super.iterator();
return new ForwardingIterator<Entry<K, V>>() {
@Override public Entry<K, V> next() {
return unmodifiableEntry(super.next());
}
@Override protected Iterator<Entry<K, V>> delegate() {
return delegate;
}
};
}
// See java.util.Collections.UnmodifiableEntrySet for details on attacks.
@Override public Object[] toArray() {
return ObjectArrays.toArrayImpl(this);
}
@Override public <T> T[] toArray(T[] array) {
return ObjectArrays.toArrayImpl(this, array);
}
@Override public boolean contains(Object o) {
return containsEntryImpl(delegate(), o);
}
@Override public boolean containsAll(Collection<?> c) {
return Collections2.containsAll(this, c);
}
}
/** @see Maps#unmodifiableEntrySet(Set) */
static class UnmodifiableEntrySet<K, V>
extends UnmodifiableEntries<K, V>
implements Set<Entry<K, V>> {
UnmodifiableEntrySet(Set<Entry<K, V>> entries) {
super(entries);
}
// See java.util.Collections.UnmodifiableEntrySet for details on attacks.
@Override public boolean equals(@Nullable Object object) {
return Collections2.setEquals(this, object);
}
@Override public int hashCode() {
return Sets.hashCodeImpl(this);
}
}
/**
* Returns an unmodifiable view of the specified bimap. This method allows
* modules to provide users with "read-only" access to internal bimaps. Query
* operations on the returned bimap "read through" to the specified bimap, and
* attemps to modify the returned map, whether direct or via its collection
* views, result in an {@code UnsupportedOperationException}.
*
* <p>The returned bimap will be serializable if the specified bimap is
* serializable.
*
* @param bimap the bimap for which an unmodifiable view is to be returned
* @return an unmodifiable view of the specified bimap
*/
public static <K, V> BiMap<K, V> unmodifiableBiMap(
BiMap<? extends K, ? extends V> bimap) {
return new UnmodifiableBiMap<K, V>(bimap, null);
}
/** @see Maps#unmodifiableBiMap(BiMap) */
private static class UnmodifiableBiMap<K, V>
extends ForwardingMap<K, V> implements BiMap<K, V>, Serializable {
final Map<K, V> unmodifiableMap;
final BiMap<? extends K, ? extends V> delegate;
transient BiMap<V, K> inverse;
transient Set<V> values;
UnmodifiableBiMap(BiMap<? extends K, ? extends V> delegate,
@Nullable BiMap<V, K> inverse) {
unmodifiableMap = Collections.<K, V>unmodifiableMap(delegate);
this.delegate = delegate;
this.inverse = inverse;
}
@Override protected Map<K, V> delegate() {
return unmodifiableMap;
}
public V forcePut(K key, V value) {
throw new UnsupportedOperationException();
}
public BiMap<V, K> inverse() {
BiMap<V, K> result = inverse;
return (result == null)
? inverse = new UnmodifiableBiMap<V, K>(delegate.inverse(), this)
: result;
}
@Override public Set<V> values() {
Set<V> result = values;
return (result == null)
? values = Collections.<V>unmodifiableSet(delegate.values())
: result;
}
private static final long serialVersionUID = 0;
}
/**
* Implements {@code Collection.contains} safely for forwarding collections of
* map entries. If {@code o} is an instance of {@code Map.Entry}, it is
* wrapped using {@link #unmodifiableEntry} to protect against a possible
* nefarious equals method.
*
* <p>Note that {@code c} is the backing (delegate) collection, rather than
* the forwarding collection.
*
* @param c the delegate (unwrapped) collection of map entries
* @param o the object that might be contained in {@code c}
* @return {@code true} if {@code c} contains {@code o}
*/
static <K, V> boolean containsEntryImpl(Collection<Entry<K, V>> c, Object o) {
if (!(o instanceof Entry)) {
return false;
}
return c.contains(unmodifiableEntry((Entry<?, ?>) o));
}
/**
* Implements {@code Collection.remove} safely for forwarding collections of
* map entries. If {@code o} is an instance of {@code Map.Entry}, it is
* wrapped using {@link #unmodifiableEntry} to protect against a possible
* nefarious equals method.
*
* <p>Note that {@code c} is backing (delegate) collection, rather than the
* forwarding collection.
*
* @param c the delegate (unwrapped) collection of map entries
* @param o the object to remove from {@code c}
* @return {@code true} if {@code c} was changed
*/
static <K, V> boolean removeEntryImpl(Collection<Entry<K, V>> c, Object o) {
if (!(o instanceof Entry)) {
return false;
}
return c.remove(unmodifiableEntry((Entry<?, ?>) o));
}
/**
* Returns a view of a map where each value is transformed by a function. All
* other properties of the map, such as iteration order, are left intact. For
* example, the code:
* <pre> {@code
*
* Map<String, Integer> map = ImmutableMap.of("a", 4, "b", 9);
* Function<Integer, Double> sqrt = new Function<Integer, Double>() {
* public Double apply(Integer in) {
* return Math.sqrt((int) in);
* }
* };
* Map<String, Double> transformed = Maps.transformValues(sqrt, map);
* System.out.println(transformed);}</pre>
*
* ... prints {@code {a=2.0, b=3.0}}.
*
* <p>Changes in the underlying map are reflected in this view. Conversely,
* this view supports removal operations, and these are reflected in the
* underlying map.
*
* <p>It's acceptable for the underlying map to contain null keys, and even
* null values provided that the function is capable of accepting null input.
* The transformed map might contain null values, if the function sometimes
* gives a null result.
*
* <p>The returned map is not thread-safe or serializable, even if the
* underlying map is.
*
* <p>The function is applied lazily, invoked when needed. This is necessary
* for the returned map to be a view, but it means that the function will be
* applied many times for bulk operations like {@link Map#containsValue} and
* {@code Map.toString()}. For this to perform well, {@code function} should
* be fast. To avoid lazy evaluation when the returned map doesn't need to be
* a view, copy the returned map into a new map of your choosing.
*/
public static <K, V1, V2> Map<K, V2> transformValues(
Map<K, V1> fromMap, Function<? super V1, V2> function) {
return new TransformedValuesMap<K, V1, V2>(fromMap, function);
}
private static class TransformedValuesMap<K, V1, V2>
extends AbstractMap<K, V2> {
final Map<K, V1> fromMap;
final Function<? super V1, V2> function;
TransformedValuesMap(Map<K, V1> fromMap, Function<? super V1, V2> function)
{
this.fromMap = checkNotNull(fromMap);
this.function = checkNotNull(function);
}
@Override public int size() {
return fromMap.size();
}
@Override public boolean containsKey(Object key) {
return fromMap.containsKey(key);
}
@Override public V2 get(Object key) {
V1 value = fromMap.get(key);
return (value != null || fromMap.containsKey(key))
? function.apply(value) : null;
}
@Override public V2 remove(Object key) {
return fromMap.containsKey(key)
? function.apply(fromMap.remove(key))
: null;
}
@Override public void clear() {
fromMap.clear();
}
EntrySet entrySet;
@Override public Set<Entry<K, V2>> entrySet() {
EntrySet result = entrySet;
if (result == null) {
entrySet = result = new EntrySet();
}
return result;
}
class EntrySet extends AbstractSet<Entry<K, V2>> {
@Override public int size() {
return TransformedValuesMap.this.size();
}
@Override public Iterator<Entry<K, V2>> iterator() {
final Iterator<Entry<K, V1>> mapIterator
= fromMap.entrySet().iterator();
return new Iterator<Entry<K, V2>>() {
public boolean hasNext() {
return mapIterator.hasNext();
}
public Entry<K, V2> next() {
final Entry<K, V1> entry = mapIterator.next();
return new AbstractMapEntry<K, V2>() {
@Override public K getKey() {
return entry.getKey();
}
@Override public V2 getValue() {
return function.apply(entry.getValue());
}
};
}
public void remove() {
mapIterator.remove();
}
};
}
@Override public void clear() {
fromMap.clear();
}
@Override public boolean contains(Object o) {
if (!(o instanceof Entry)) {
return false;
}
Entry<?, ?> entry = (Entry<?, ?>) o;
Object entryKey = entry.getKey();
Object entryValue = entry.getValue();
V2 mapValue = TransformedValuesMap.this.get(entryKey);
if (mapValue != null) {
return mapValue.equals(entryValue);
}
return entryValue == null && containsKey(entryKey);
}
@Override public boolean remove(Object o) {
if (contains(o)) {
Entry<?, ?> entry = (Entry<?, ?>) o;
Object key = entry.getKey();
fromMap.remove(key);
return true;
}
return false;
}
}
}
/**
* Returns a map containing the mappings in {@code unfiltered} whose keys
* satisfy a predicate. The returned map is a live view of {@code unfiltered};
* changes to one affect the other.
*
* <p>The resulting map's {@code keySet()}, {@code entrySet()}, and {@code
* values()} views have iterators that don't support {@code remove()}, but all
* other methods are supported by the map and its views. The map's {@code
* put()} and {@code putAll()} methods throw an {@link
* IllegalArgumentException} if a key that doesn't satisfy the predicate is
* provided.
*
* <p>When methods such as {@code removeAll()} and {@code clear()} are called
* on the filtered map or its views, only mappings whose keys satisfy the
* filter will be removed from the underlying map.
*
* <p>The returned map isn't threadsafe or serializable, even if {@code
* unfiltered} is.
*
* <p>Many of the filtered map's methods, such as {@code size()},
* iterate across every key/value mapping in the underlying map and determine
* which satisfy the filter. When a live view is <i>not</i> needed, it may be
* faster to copy the filtered map and use the copy.
*/
public static <K, V> Map<K, V> filterKeys(
Map<K, V> unfiltered, final Predicate<? super K> keyPredicate) {
checkNotNull(keyPredicate);
Predicate<Entry<K, V>> entryPredicate = new Predicate<Entry<K, V>>() {
public boolean apply(Entry<K, V> input) {
return keyPredicate.apply(input.getKey());
}
};
return (unfiltered instanceof AbstractFilteredMap)
? filterFiltered((AbstractFilteredMap<K, V>) unfiltered, entryPredicate)
: new FilteredKeyMap<K, V>(
checkNotNull(unfiltered), keyPredicate, entryPredicate);
}
/**
* Returns a map containing the mappings in {@code unfiltered} whose values
* satisfy a predicate. The returned map is a live view of {@code unfiltered};
* changes to one affect the other.
*
* <p>The resulting map's {@code keySet()}, {@code entrySet()}, and {@code
* values()} views have iterators that don't support {@code remove()}, but all
* other methods are supported by the map and its views. The {@link Map#put},
* {@link Map#putAll}, and {@link Entry#setValue} methods throw an {@link
* IllegalArgumentException} if a value that doesn't satisfy the predicate is
* provided.
*
* <p>When methods such as {@code removeAll()} and {@code clear()} are called
* on the filtered map or its views, only mappings whose values satisfy the
* filter will be removed from the underlying map.
*
* <p>The returned map isn't threadsafe or serializable, even if {@code
* unfiltered} is.
*
* <p>Many of the filtered map's methods, such as {@code size()},
* iterate across every key/value mapping in the underlying map and determine
* which satisfy the filter. When a live view is <i>not</i> needed, it may be
* faster to copy the filtered map and use the copy.
*/
public static <K, V> Map<K, V> filterValues(
Map<K, V> unfiltered, final Predicate<? super V> valuePredicate) {
checkNotNull(valuePredicate);
Predicate<Entry<K, V>> entryPredicate = new Predicate<Entry<K, V>>() {
public boolean apply(Entry<K, V> input) {
return valuePredicate.apply(input.getValue());
}
};
return filterEntries(unfiltered, entryPredicate);
}
/**
* Returns a map containing the mappings in {@code unfiltered} that satisfy a
* predicate. The returned map is a live view of {@code unfiltered}; changes
* to one affect the other.
*
* <p>The resulting map's {@code keySet()}, {@code entrySet()}, and {@code
* values()} views have iterators that don't support {@code remove()}, but all
* other methods are supported by the map and its views. The map's {@code
* put()} and {@code putAll()} methods throw an {@link
* IllegalArgumentException} if a key/value pair that doesn't satisfy the
* predicate is provided. Similarly, the map's entries have a {@link
* Entry#setValue} method that throws an {@link IllegalArgumentException} when
* the existing key and the provided value don't satisfy the predicate.
*
* <p>When methods such as {@code removeAll()} and {@code clear()} are called
* on the filtered map or its views, only mappings that satisfy the filter
* will be removed from the underlying map.
*
* <p>The returned map isn't threadsafe or serializable, even if {@code
* unfiltered} is.
*
* <p>Many of the filtered map's methods, such as {@code size()},
* iterate across every key/value mapping in the underlying map and determine
* which satisfy the filter. When a live view is <i>not</i> needed, it may be
* faster to copy the filtered map and use the copy.
*/
public static <K, V> Map<K, V> filterEntries(
Map<K, V> unfiltered, Predicate<? super Entry<K, V>> entryPredicate) {
checkNotNull(entryPredicate);
return (unfiltered instanceof AbstractFilteredMap)
? filterFiltered((AbstractFilteredMap<K, V>) unfiltered, entryPredicate)
: new FilteredEntryMap<K, V>(checkNotNull(unfiltered), entryPredicate);
}
/**
* Support {@code clear()}, {@code removeAll()}, and {@code retainAll()} when
* filtering a filtered map.
*/
private static <K, V> Map<K, V> filterFiltered(
AbstractFilteredMap<K, V> map,
Predicate<? super Entry<K, V>> entryPredicate) {
Predicate<Entry<K, V>> predicate
= Predicates.and(map.predicate, entryPredicate);
return new FilteredEntryMap<K, V>(map.unfiltered, predicate);
}
private static abstract class AbstractFilteredMap<K, V>
extends AbstractMap<K, V> {
final Map<K, V> unfiltered;
final Predicate<? super Entry<K, V>> predicate;
AbstractFilteredMap(Map<K, V> unfiltered,
Predicate<? super Entry<K, V>> predicate) {
this.unfiltered = unfiltered;
this.predicate = predicate;
}
boolean apply(Object key, V value) {
// This method is called only when the key is in the map, implying that
// key is a K.
@SuppressWarnings("unchecked")
K k = (K) key;
return predicate.apply(Maps.immutableEntry(k, value));
}
@Override public V put(K key, V value) {
checkArgument(apply(key, value));
return unfiltered.put(key, value);
}
@Override public void putAll(Map<? extends K, ? extends V> map) {
for (Entry<? extends K, ? extends V> entry : map.entrySet()) {
checkArgument(apply(entry.getKey(), entry.getValue()));
}
unfiltered.putAll(map);
}
@Override public boolean containsKey(Object key) {
return unfiltered.containsKey(key) && apply(key, unfiltered.get(key));
}
@Override public V get(Object key) {
V value = unfiltered.get(key);
return ((value != null) && apply(key, value)) ? value : null;
}
@Override public boolean isEmpty() {
return entrySet().isEmpty();
}
@Override public V remove(Object key) {
return containsKey(key) ? unfiltered.remove(key) : null;
}
Collection<V> values;
@Override public Collection<V> values() {
Collection<V> result = values;
return (result == null) ? values = new Values() : result;
}
class Values extends AbstractCollection<V> {
@Override public Iterator<V> iterator() {
final Iterator<Entry<K, V>> entryIterator = entrySet().iterator();
return new UnmodifiableIterator<V>() {
public boolean hasNext() {
return entryIterator.hasNext();
}
public V next() {
return entryIterator.next().getValue();
}
};
}
@Override public int size() {
return entrySet().size();
}
@Override public void clear() {
entrySet().clear();
}
@Override public boolean isEmpty() {
return entrySet().isEmpty();
}
@Override public boolean remove(Object o) {
Iterator<Entry<K, V>> iterator = unfiltered.entrySet().iterator();
while (iterator.hasNext()) {
Entry<K, V> entry = iterator.next();
if (Objects.equal(o, entry.getValue()) && predicate.apply(entry)) {
iterator.remove();
return true;
}
}
return false;
}
@Override public boolean removeAll(Collection<?> collection) {
checkNotNull(collection);
boolean changed = false;
Iterator<Entry<K, V>> iterator = unfiltered.entrySet().iterator();
while (iterator.hasNext()) {
Entry<K, V> entry = iterator.next();
if (collection.contains(entry.getValue()) && predicate.apply(entry)) {
iterator.remove();
changed = true;
}
}
return changed;
}
@Override public boolean retainAll(Collection<?> collection) {
checkNotNull(collection);
boolean changed = false;
Iterator<Entry<K, V>> iterator = unfiltered.entrySet().iterator();
while (iterator.hasNext()) {
Entry<K, V> entry = iterator.next();
if (!collection.contains(entry.getValue())
&& predicate.apply(entry)) {
iterator.remove();
changed = true;
}
}
return changed;
}
@Override public Object[] toArray() {
// creating an ArrayList so filtering happens once
return Lists.newArrayList(iterator()).toArray();
}
@Override public <T> T[] toArray(T[] array) {
return Lists.newArrayList(iterator()).toArray(array);
}
}
}
private static class FilteredKeyMap<K, V> extends AbstractFilteredMap<K, V> {
Predicate<? super K> keyPredicate;
FilteredKeyMap(Map<K, V> unfiltered, Predicate<? super K> keyPredicate,
Predicate<Entry<K, V>> entryPredicate) {
super(unfiltered, entryPredicate);
this.keyPredicate = keyPredicate;
}
Set<Entry<K, V>> entrySet;
@Override public Set<Entry<K, V>> entrySet() {
Set<Entry<K, V>> result = entrySet;
return (result == null)
? entrySet = Sets.filter(unfiltered.entrySet(), predicate)
: result;
}
Set<K> keySet;
@Override public Set<K> keySet() {
Set<K> result = keySet;
return (result == null)
? keySet = Sets.filter(unfiltered.keySet(), keyPredicate)
: result;
}
// The cast is called only when the key is in the unfiltered map, implying
// that key is a K.
@SuppressWarnings("unchecked")
@Override public boolean containsKey(Object key) {
return unfiltered.containsKey(key) && keyPredicate.apply((K) key);
}
}
private static class FilteredEntryMap<K, V>
extends AbstractFilteredMap<K, V> {
/**
* Entries in this set satisfy the predicate, but they don't validate the
* input to {@code Entry.setValue()}.
*/
final Set<Entry<K, V>> filteredEntrySet;
FilteredEntryMap(Map<K, V> unfiltered,
Predicate<? super Entry<K, V>> entryPredicate) {
super(unfiltered, entryPredicate);
filteredEntrySet = Sets.filter(unfiltered.entrySet(), predicate);
}
Set<Entry<K, V>> entrySet;
@Override public Set<Entry<K, V>> entrySet() {
Set<Entry<K, V>> result = entrySet;
return (result == null) ? entrySet = new EntrySet() : result;
}
private class EntrySet extends ForwardingSet<Entry<K, V>> {
@Override protected Set<Entry<K, V>> delegate() {
return filteredEntrySet;
}
@Override public Iterator<Entry<K, V>> iterator() {
final Iterator<Entry<K, V>> iterator = filteredEntrySet.iterator();
return new UnmodifiableIterator<Entry<K, V>>() {
public boolean hasNext() {
return iterator.hasNext();
}
public Entry<K, V> next() {
final Entry<K, V> entry = iterator.next();
return new ForwardingMapEntry<K, V>() {
@Override protected Entry<K, V> delegate() {
return entry;
}
@Override public V setValue(V value) {
checkArgument(apply(entry.getKey(), value));
return super.setValue(value);
}
};
}
};
}
}
Set<K> keySet;
@Override public Set<K> keySet() {
Set<K> result = keySet;
return (result == null) ? keySet = new KeySet() : result;
}
private class KeySet extends AbstractSet<K> {
@Override public Iterator<K> iterator() {
final Iterator<Entry<K, V>> iterator = filteredEntrySet.iterator();
return new UnmodifiableIterator<K>() {
public boolean hasNext() {
return iterator.hasNext();
}
public K next() {
return iterator.next().getKey();
}
};
}
@Override public int size() {
return filteredEntrySet.size();
}
@Override public void clear() {
filteredEntrySet.clear();
}
@Override public boolean contains(Object o) {
return containsKey(o);
}
@Override public boolean remove(Object o) {
if (containsKey(o)) {
unfiltered.remove(o);
return true;
}
return false;
}
@Override public boolean removeAll(Collection<?> collection) {
checkNotNull(collection); // for GWT
boolean changed = false;
for (Object obj : collection) {
changed |= remove(obj);
}
return changed;
}
@Override public boolean retainAll(Collection<?> collection) {
checkNotNull(collection); // for GWT
boolean changed = false;
Iterator<Entry<K, V>> iterator = unfiltered.entrySet().iterator();
while (iterator.hasNext()) {
Entry<K, V> entry = iterator.next();
if (!collection.contains(entry.getKey()) && predicate.apply(entry)) {
iterator.remove();
changed = true;
}
}
return changed;
}
@Override public Object[] toArray() {
// creating an ArrayList so filtering happens once
return Lists.newArrayList(iterator()).toArray();
}
@Override public <T> T[] toArray(T[] array) {
return Lists.newArrayList(iterator()).toArray(array);
}
}
}
/**
* {@code AbstractMap} extension that implements {@link #isEmpty()} as {@code
* entrySet().isEmpty()} instead of {@code size() == 0} to speed up
* implementations where {@code size()} is O(n), and it delegates the {@code
* isEmpty()} methods of its key set and value collection to this
* implementation.
*/
@GwtCompatible
abstract static class ImprovedAbstractMap<K, V>
extends AbstractMap<K, V> {
/**
* Creates the entry set to be returned by {@link #entrySet()}. This method
* is invoked at most once on a given map, at the time when {@code
* entrySet} is first called.
*/
protected abstract Set<Entry<K, V>> createEntrySet();
private transient Set<Entry<K, V>> entrySet;
@Override public Set<Entry<K, V>> entrySet() {
Set<Entry<K, V>> result = entrySet;
if (result == null) {
entrySet = result = createEntrySet();
}
return result;
}
private transient Set<K> keySet;
@Override public Set<K> keySet() {
Set<K> result = keySet;
if (result == null) {
final Set<K> delegate = super.keySet();
keySet = result = new ForwardingSet<K>() {
@Override protected Set<K> delegate() {
return delegate;
}
@Override public boolean isEmpty() {
return ImprovedAbstractMap.this.isEmpty();
}
};
}
return result;
}
private transient Collection<V> values;
@Override public Collection<V> values() {
Collection<V> result = values;
if (result == null) {
final Collection<V> delegate = super.values();
values = result = new ForwardingCollection<V>() {
@Override protected Collection<V> delegate() {
return delegate;
}
@Override public boolean isEmpty() {
return ImprovedAbstractMap.this.isEmpty();
}
};
}
return result;
}
/**
* Returns {@code true} if this map contains no key-value mappings.
*
* <p>The implementation returns {@code entrySet().isEmpty()}.
*
* @return {@code true} if this map contains no key-value mappings
*/
@Override public boolean isEmpty() {
return entrySet().isEmpty();
}
}
static final MapJoiner standardJoiner
= Collections2.standardJoiner.withKeyValueSeparator("=");
/**
* Delegates to {@link Map#get}. Returns {@code null} on {@code
* ClassCastException}.
*/
static <V> V safeGet(Map<?, V> map, Object key) {
try {
return map.get(key);
} catch (ClassCastException e) {
return null;
}
}
/**
* Delegates to {@link Map#containsKey}. Returns {@code false} on {@code
* ClassCastException}
*/
static boolean safeContainsKey(Map<?, ?> map, Object key) {
try {
return map.containsKey(key);
} catch (ClassCastException e) {
return false;
}
}
}