A
Map
is an object that maps keys to values. A map cannot contain duplicate keys: Each key can map to at most one value. It models the mathematical function abstraction. The Map
interface follows.
public interface Map<K,V> { // Basic operations V put(K key, V value); V get(Object key); V remove(Object key); boolean containsKey(Object key); boolean containsValue(Object value); int size(); boolean isEmpty(); // Bulk operations void putAll(Map<? extends K, ? extends V> m); void clear(); // Collection Views public Set<K> keySet(); public Collection<V> values(); public Set<Map.Entry<K,V>> entrySet(); // Interface for entrySet elements public interface Entry { K getKey(); V getValue(); V setValue(V value); } }
The Java platform contains three general-purpose Map
implementations:
HashMap
,
TreeMap
, and
LinkedHashMap
. Their behavior and performance are precisely analogous to HashSet
, TreeSet
, and LinkedHashSet
, as described in
The Set Interface section. Also, Hashtable
was retrofitted to implement Map
.
If you've used Hashtable
, you're already familiar with the general basics of Map
. (Of course, Map
is an interface, while Hashtable
is a concrete implementation.) The following are the major differences:
Map
provides Collection
views instead of direct support for iteration via Enumeration
objects. Collection
views greatly enhance the expressiveness of the interface, as discussed later in this section.Map
allows you to iterate over keys, values, or key-value pairs; Hashtable
does not provide the third option.Map
provides a safe way to remove entries in the midst of iteration; Hashtable
did not.Finally, Map
fixes a minor deficiency in the Hashtable
interface. Hashtable
has a method called contains
, which returns true
if the Hashtable
contains a given value. Given its name, you'd expect this method to return true
if the Hashtable
contained a given key, because the key is the primary access mechanism for a Hashtable
. The Map
interface eliminates this source of confusion by renaming the method containsValue
. Also, this improves the interface's consistency containsValue
parallels containsKey
.
The basic operations of Map
(put
, get
, containsKey
, containsValue
, size
, and isEmpty
) behave exactly like their counterparts in Hashtable
. The
following program
generates a frequency table of the words found in its argument list. The frequency table maps each word to the number of times it occurs in the argument list.
import java.util.*; public class Freq { public static void main(String[] args) { Map<String, Integer> m = new HashMap<String, Integer>(); // Initialize frequency table from command line for (String a : args) { Integer freq = m.get(a); m.put(a, (freq == null) ? 1 : freq + 1); } System.out.println(m.size() + " distinct words:"); System.out.println(m); } }
The only tricky thing about this program is the second argument of the put
statement. That argument is a conditional expression that has the effect of setting the frequency to one if the word has never been seen before or one more than its current value if the word has already been seen. Try running this program with the command:
java Freq if it is to be it is up to me to delegate
The program yields the following output.
8 distinct words: {to=3, delegate=1, be=1, it=2, up=1, if=1, me=1, is=2}
Suppose you'd prefer to see the frequency table in alphabetical order. All you have to do is change the implementation type of the Map
from HashMap
to TreeMap
. Making this four-character change causes the program to generate the following output from the same command line.
8 distinct words: {be=1, delegate=1, if=1, is=2, it=2, me=1, to=3, up=1}
Similarly, you could make the program print the frequency table in the order the words first appear on the command line simply by changing the implementation type of the map to LinkedHashMap
. Doing so results in the following output.
8 distinct words: {if=1, it=2, is=2, to=3, be=1, up=1, me=1, delegate=1}
This flexibility provides a potent illustration of the power of an interface-based framework.
Like the
Set
and
List
interfaces, Map
strengthens the requirements on the equals
and hashCode
methods so that two Map
objects can be compared for logical equality without regard to their implementation types. Two Map
instances are equal if they represent the same key-value mappings.
By convention, all general-purpose Map
implementations provide constructors that take a Map
object and initialize the new Map
to contain all the key-value mappings in the specified Map
. This standard Map
conversion constructor is entirely analogous to the standard Collection
constructor: It allows the caller to create a Map
of a desired implementation type that initially contains all of the mappings in another Map
, regardless of the other Map
's implementation type. For example, suppose you have a Map
, named m
. The following one-liner creates a new HashMap
initially containing all of the same key-value mappings as m
.
Map<K, V> copy = new HashMap<K, V>(m);
The clear
operation does exactly what you would think it could do: It removes all the mappings from the Map
. The putAll
operation is the Map
analogue of the Collection
interface's addAll
operation. In addition to its obvious use of dumping one Map
into another, it has a second, more subtle use. Suppose a Map
is used to represent a collection of attribute-value pairs; the putAll
operation, in combination with the Map
conversion constructor, provides a neat way to implement attribute map creation with default values. The following is a static factory method that demonstrates this technique.
static <K, V> Map<K, V> newAttributeMap( Map<K, V>defaults, Map<K, V> overrides) { Map<K, V> result = new HashMap<K, V>(defaults); result.putAll(overrides); return result; }
The Collection
view methods allow a Map
to be viewed as a Collection
in these three ways:
keySet
the Set
of keys contained in the Map
.values
The Collection
of values contained in the Map
. This Collection
is not a Set
, because multiple keys can map to the same value.entrySet
the Set
of key-value pairs contained in the Map
. The Map
interface provides a small nested interface called Map.Entry
, the type of the elements in this Set
.The Collection
views provide the only means to iterate over a Map
. This example illustrates the standard idiom for iterating over the keys in a Map
with a for-each
construct:
for (KeyType key : m.keySet()) System.out.println(key);
and with an iterator
:
// Filter a map based on some // property of its keys. for (Iterator<Type> it = m.keySet().iterator(); it.hasNext(); ) if (it.next().isBogus()) it.remove();
The idiom for iterating over values is analogous. Following is the idiom for iterating over key-value pairs.
for (Map.Entry<KeyType, ValType> e : m.entrySet()) System.out.println(e.getKey() + ": " + e.getValue());
At first, many people worry that these idioms may be slow because the Map
has to create a new Collection
instance each time a Collection
view operation is called. Rest easy: There's no reason that a Map
cannot always return the same object each time it is asked for a given Collection
view. This is precisely what all the Map
implementations in java.util
do.
With all three Collection
views, calling an Iterator
's remove
operation removes the associated entry from the backing Map
, assuming that the backing Map
supports element removal to begin with. This is illustrated by the preceding filtering idiom.
With the entrySet
view, it is also possible to change the value associated with a key by calling a Map.Entry
's setValue
method during iteration (again, assuming the Map
supports value modification to begin with). Note that these are the only safe ways to modify a Map
during iteration; the behavior is unspecified if the underlying Map
is modified in any other way while the iteration is in progress.
The Collection
views support element removal in all its many forms remove
, removeAll
, retainAll
, and clear
operations, as well as the Iterator.remove
operation. (Yet again, this assumes that the backing Map
supports element removal.)
The Collection
views do not support element addition under any circumstances. It would make no sense for the keySet
and values
views, and it's unnecessary for the entrySet
view, because the backing Map
's put
and putAll
methods provide the same functionality.
When applied to the Collection
views, bulk operations (containsAll
, removeAll
, and retainAll
) are surprisingly potent tools. For starters, suppose you want to know whether one Map
is a submap of another that is, whether the first Map
contains all the key-value mappings in the second. The following idiom does the trick.
if (m1.entrySet().containsAll(m2.entrySet())) { ... }
Along similar lines, suppose you want to know whether two Map
objects contain mappings for all of the same keys.
if (m1.keySet().equals(m2.keySet())) { ... }
Suppose you have a Map
that represents a collection of attribute-value pairs, and two Set
s representing required attributes and permissible attributes. (The permissible attributes include the required attributes.) The following snippet determines whether the attribute map conforms to these constraints and prints a detailed error message if it doesn't.
static <K, V> boolean validate(Map<K, V> attrMap, Set<K> requiredAttrs, Set<K>permittedAttrs) { boolean valid = true; Set<K> attrs = attrMap.keySet(); if(!attrs.containsAll(requiredAttrs)) { Set<K> missing = new HashSet<K>(requiredAttrs); missing.removeAll(attrs); System.out.println("Missing attributes: " + missing); valid = false; } if (!permittedAttrs.containsAll(attrs)) { Set<K> illegal = new HashSet<K>(attrs); illegal.removeAll(permittedAttrs); System.out.println("Illegal attributes: " + illegal); valid = false; } return valid; }
Suppose you want to know all the keys common to two Map
objects.
Set<KeyType>commonKeys = new HashSet<KeyType>(m1.keySet()); commonKeys.retainAll(m2.keySet());
A similar idiom gets you the common values.
All the idioms presented thus far have been nondestructive; that is, they don't modify the backing Map
. Here are a few that do. Suppose you want to remove all of the key-value pairs that one Map
has in common with another.
m1.entrySet().removeAll(m2.entrySet());
Suppose you want to remove from one Map
all of the keys that have mappings in another.
m1.keySet().removeAll(m2.keySet());
What happens when you start mixing keys and values in the same bulk operation? Suppose you have a Map
, managers
, that maps each employee in a company to the employee's manager. We'll be deliberately vague about the types of the key and the value objects. It doesn't matter, as long as they're the same. Now suppose you want to know who all the "individual contributors" (or nonmanagers) are. The following snippet tells you exactly what you want to know.
Set<Employee> individualContributors = new HashSet<Employee>(managers.keySet()); individualContributors.removeAll(managers.values());
Suppose you want to fire all the employees who report directly to some manager, Simon.
Employee simon = ... ; managers.values().removeAll(Collections.singleton(simon));
Note that this idiom makes use of Collections.singleton
, a static factory method that returns an immutable Set
with the single, specified element.
Once you've done this, you may have a bunch of employees whose managers no longer work for the company (if any of Simon's direct-reports were themselves managers). The following code will tell you which employees have managers who no longer works for the company.
Map<Employee, Employee> m = new HashMap<Employee, Employee>(managers); m.values().removeAll(managers.keySet()); Set<Employee> slackers = m.keySet();
This example is a bit tricky. First, it makes a temporary copy of the Map
, and it removes from the temporary copy all entries whose (manager) value is a key in the original Map
. Remember that the original Map
has an entry for each employee. Thus, the remaining entries in the temporary Map
comprise all the entries from the original Map
whose (manager) values are no longer employees. The keys in the temporary copy, then, represent precisely the employees that we're looking for.
There are many more idioms like the ones contained in this section, but it would be impractical and tedious to list them all. Once you get the hang of it, it's not that difficult to come up with the right one when you need it.
A multimap is like a Map
but it can map each key to multiple values. The Java Collections Framework doesn't include an interface for multimaps because they aren't used all that commonly. It's a fairly simple matter to use a Map
whose values are List
instances as a multimap. This technique is demonstrated in the next code example, which reads a word list containing one word per line (all lowercase) and prints out all the anagram groups that meet a size criterion. An anagram group is a bunch of words, all of which contain exactly the same letters but in a different order. The program takes two arguments on the command line: (1) the name of the dictionary file and (2) the minimum size of anagram group to print out. Anagram groups containing fewer words than the specified minimum are not printed.
There is a standard trick for finding anagram groups: For each word in the dictionary, alphabetize the letters in the word (that is, reorder the word's letters into alphabetical order) and put an entry into a multimap, mapping the alphabetized word to the original word. For example, the word bad causes an entry mapping abd into bad to be put into the multimap. A moment's reflection will show that all the words to which any given key maps form an anagram group. It's a simple matter to iterate over the keys in the multimap, printing out each anagram group that meets the size constraint.
The following program
is a straightforward implementation of this technique.
import java.util.*; import java.io.*; public class Anagrams { public static void main(String[] args) { int minGroupSize = Integer.parseInt(args[1]); // Read words from file and put into a simulated multimap Map<String, List<String>> m = new HashMap<String, List<String>>(); try { Scanner s = new Scanner(new File(args[0])); while (s.hasNext()) { String word = s.next(); String alpha = alphabetize(word); List<String> l = m.get(alpha); if (l == null) m.put(alpha, l=new ArrayList<String>()); l.add(word); } } catch (IOException e) { System.err.println(e); System.exit(1); } // Print all permutation groups above size threshold for (List<String> l : m.values()) if (l.size() >= minGroupSize) System.out.println(l.size() + ": " + l); } private static String alphabetize(String s) { char[] a = s.toCharArray(); Arrays.sort(a); return new String(a); } }
Running this program on a 173,000-word dictionary file with a minimum anagram group size of eight produces the following output.
9: [estrin, inerts, insert, inters, niters, nitres, sinter, triens, trines] 8: [lapse, leaps, pales, peals, pleas, salep, sepal, spale] 8: [aspers, parses, passer, prases, repass, spares, sparse, spears] 10: [least, setal, slate, stale, steal, stela, taels, tales, teals, tesla] 8: [enters, nester, renest, rentes, resent, tenser, ternes, treens] 8: [arles, earls, lares, laser, lears, rales, reals, seral] 8: [earings, erasing, gainers, reagins, regains, reginas, searing, seringa] 8: [peris, piers, pries, prise, ripes, speir, spier, spire] 12: [apers, apres, asper, pares, parse, pears, prase, presa, rapes, reaps, spare, spear] 11: [alerts, alters, artels, estral, laster, ratels, salter, slater, staler, stelar, talers] 9: [capers, crapes, escarp, pacers, parsec, recaps, scrape, secpar, spacer] 9: [palest, palets, pastel, petals, plates, pleats, septal, staple, tepals] 9: [anestri, antsier, nastier, ratines, retains, retinas, retsina, stainer, stearin] 8: [ates, east, eats, etas, sate, seat, seta, teas] 8: [carets, cartes, caster, caters, crates, reacts, recast, traces]
Many of these words seem a bit bogus, but that's not the program's fault; they're in the dictionary file.
Here's the
dictionary file
we used.
It was derived from the Public Domain ENABLE benchmark reference word list.