The polymorphic algorithms described here are pieces of reusable functionality provided by the Java platform. All of them come from the
Collections
class, and all take the form of static methods whose first argument is the collection on which the operation is to be performed. The great majority of the algorithms provided by the Java platform operate on
List
instances, but a few of them operate on arbitrary
Collection
instances. This section briefly describes the following algorithms:
The sort
algorithm reorders a List
so that its elements are in ascending order according to an ordering relationship. Two forms of the operation are provided. The simple form takes a List
and sorts it according to its elements' natural ordering. If you're unfamiliar with the concept of natural ordering, read the
Object Ordering section.
The sort
operation uses a slightly optimized merge sort algorithm that is fast and stable:
n log(n)
time and runs substantially faster on nearly sorted lists. Empirical tests showed it to be as fast as a highly optimized quicksort. A quicksort is generally considered to be faster than a merge sort but isn't stable and doesn't guarantee n log(n)
performance.The following
trivial program
prints out its arguments in lexicographic (alphabetical) order.
import java.util.*; public class Sort { public static void main(String[] args) { List<String> list = Arrays.asList(args); Collections.sort(list); System.out.println(list); } }
Let's run the program.
% java Sort i walk the line
The following output is produced.
[i, line, the, walk]
The program was included only to show you that algorithms really are as easy to use as they appear to be.
The second form of sort
takes a
Comparator
in addition to a List
and sorts the elements with the Comparator
. Suppose you want to print out the anagram groups from our earlier example in reverse order of size largest anagram group first. The example that follows shows you how to achieve this with the help of the second form of the sort
method.
Recall that the anagram groups are stored as values in a Map
, in the form of List
instances. The revised printing code iterates through the Map
's values view, putting every List
that passes the minimum-size test into a List
of List
s. Then the code sorts this List
, using a Comparator
that expects List
instances, and implements reverse size-ordering. Finally, the code iterates through the sorted List
, printing its elements (the anagram groups). The following code replaces the printing code at the end of the main
method in the Anagrams
example.
// Make a List of all anagram groups above size threshold. List<List<String>> winners = new ArrayList<List<String>>(); for (List<String> l : m.values()) if (l.size() >= minGroupSize) winners.add(l); // Sort anagram groups according to size Collections.sort(winners, new Comparator<List<String>>() { public int compare(List<String> o1, List<String> o2) { return o2.size() - o1.size(); }}); // Print anagram groups. for (List<String> l : winners) System.out.println(l.size() + ": " + l);
Running
the program
on the
same dictionary
as in
The Map Interface section, with the same minimum anagram group size (eight), produces the following output.
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] 10: [least, setal, slate, stale, steal, stela, taels, tales, teals, tesla] 9: [estrin, inerts, insert, inters, niters, nitres, sinter, triens, trines] 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: [lapse, leaps, pales, peals, pleas, salep, sepal, spale] 8: [aspers, parses, passer, prases, repass, spares, sparse, spears] 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] 8: [ates, east, eats, etas, sate, seat, seta, teas] 8: [carets, cartes, caster, caters, crates, reacts, recast,��traces]
The shuffle
algorithm does the opposite of what sort
does, destroying any trace of order that may have been present in a List
. That is, this algorithm reorders the List
based on input from a source of randomness such that all possible permutations occur with equal likelihood, assuming a fair source of randomness. This algorithm is useful in implementing games of chance. For example, it could be used to shuffle a List
of Card
objects representing a deck. Also, it's useful for generating test cases.
This operation has two forms: one takes a List
and uses a default source of randomness, and the other requires the caller to provide a
Random object to use as a source of randomness. The code for this algorithm is used as an example in the
List
section.
The Collections
class provides five algorithms for doing routine data manipulation on List
objects, all of which are pretty straightforward:
reverse
reverses the order of the elements in a List
.fill
overwrites every element in a List
with the specified value. This operation is useful for reinitializing a List
.copy
takes two arguments, a destination List
and a source List
, and copies the elements of the source into the destination, overwriting its contents. The destination List
must be at least as long as the source. If it is longer, the remaining elements in the destination List
are unaffected.swap
swaps the elements at the specified positions in a List
.addAll
adds all the specified elements to a Collection
. The elements to be added may be specified individually or as an array.The binarySearch
algorithm searches for a specified element in a sorted List
. This algorithm has two forms. The first takes a List
and an element to search for (the "search key"). This form assumes that the List
is sorted in ascending order according to the natural ordering of its elements. The second form takes a Comparator
in addition to the List
and the search key, and assumes that the List
is sorted into ascending order according to the specified Comparator
. The sort
algorithm can be used to sort the List
prior to calling binarySearch
.
The return value is the same for both forms. If the List
contains the search key, its index is returned. If not, the return value is (-(insertion point) - 1)
, where the insertion point is the point at which the value would be inserted into the List
, or the index of the first element greater than the value or list.size()
if all elements in the List
are less than the specified value. This admittedly ugly formula guarantees that the return value will be >= 0
if and only if the search key is found. It's basically a hack to combine a boolean (found)
and an integer (index)
into a single int
return value.
The following idiom, usable with both forms of the binarySearch
operation, looks for the specified search key and inserts it at the appropriate position if it's not already present.
int pos = Collections.binarySearch(list, key); if (pos < 0) l.add(-pos-1);
The frequency and disjoint algorithms test some aspect of the composition of one or more Collections
:
frequency
counts the number of times the specified element occurs in the specified collectiondisjoint
determines whether two Collections
are disjoint; that is, whether they contain no elements in commonThe min
and the max
algorithms return, respectively, the minimum and maximum element contained in a specified Collection
. Both of these operations come in two forms. The simple form takes only a Collection
and returns the minimum (or maximum) element according to the elements' natural ordering. The second form takes a Comparator
in addition to the Collection
and returns the minimum (or maximum) element according to the specified Comparator
.