Combinatoricslib3 Save Abandoned

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This is a new implementation of the combinatorics library for Java. The previous versions of the library can be found here

3.3.3 - the latest stable release version

The latest release of the library is v3.3.3. It is available through The Maven Central Repository here. Add the following section into your pom.xml file.

<dependency>
    <groupId>com.github.dpaukov</groupId>
    <artifactId>combinatoricslib3</artifactId>
    <version>3.3.3</version>
</dependency>

Examples

You can check out an example project to see how to use the library combinatoricslib3-example

3.4.0 - current version under development

1. Simple combinations
2. Combinations with repetitions
3. Simple permutations
4. Permutations with repetitions
5. k-Permutations
6. Subsets
7. Integer partitions
8. Cartesian product

1. Simple combinations

A simple k-combination of a finite set S is a subset of k distinct elements of S. Specifying a subset does not arrange them in a particular order. As an example, a poker hand can be described as a 5-combination of cards from a 52-card deck: the 5 cards of the hand are all distinct, and the order of the cards in the hand does not matter.

Let's generate all 3-combination of the set of 5 colors (red, black, white, green, blue).

   Generator.combination("red", "black", "white", "green", "blue")
       .simple(3)
       .stream()
       .forEach(System.out::println);

And the result of 10 combinations

   [red, black, white]
   [red, black, green]
   [red, black, blue]
   [red, white, green]
   [red, white, blue]
   [red, green, blue]
   [black, white, green]
   [black, white, blue]
   [black, green, blue]
   [white, green, blue]

2. Combinations with repetitions

A k-multicombination or k-combination with repetition of a finite set S is given by a sequence of k not necessarily distinct elements of S, where order is not taken into account.

As an example. Suppose there are 2 types of fruits (apple and orange) at a grocery store, and you want to buy 3 pieces of fruit. You could select

• (apple, apple, apple)
• (apple, apple, orange)
• (apple, orange, orange)
• (orange, orange, orange)

   Generator.combination("apple", "orange")
       .multi(3)
       .stream()
       .forEach(System.out::println);

And the result will be:

   [apple, apple, apple]
   [apple, apple, orange]
   [apple, orange, orange]
   [orange, orange, orange]

3. Simple permutations

A permutation is an ordering of a set in the context of all possible orderings. For example, the set containing the first three digits, 123, has six permutations: 123, 132, 213, 231, 312, and 321.

This is an example of the permutations of the 3 string items (apple, orange, cherry):

   Generator.permutation("apple", "orange", "cherry")
       .simple()
       .stream()
       .forEach(System.out::println);

   [apple, orange, cherry]
   [apple, cherry, orange]
   [cherry, apple, orange]
   [cherry, orange, apple]
   [orange, cherry, apple]
   [orange, apple, cherry]

This generator can produce the permutations even if an initial vector has duplicates. For example, all permutations of (1, 1, 2, 2):

   Generator.permutation(1, 1, 2, 2)
       .simple()
       .stream()
       .forEach(System.out::println);

The result does not have duplicates. All permutations are distinct by default.

   [1, 1, 2, 2]
   [1, 2, 1, 2]
   [1, 2, 2, 1]
   [2, 1, 1, 2]
   [2, 1, 2, 1]
   [2, 2, 1, 1]

Notice that we have 6 permutations here instead of 24. If you still need all permutations, you should call method simple(PermutationGenerator.TreatDuplicatesAs.IDENTICAL).

4. Permutations with repetitions

Permutation may have more elements than slots. For example, all possible permutation of 12 in three slots are: 111, 211, 121, 221, 112, 212, 122, and 222.

Let's generate all possible permutations with repetitions of 3 elements from the set of apple and orange.

   Generator.permutation("apple", "orange")
        .withRepetitions(3)
        .stream()
        .forEach(System.out::println);

And the list of all 8 permutations

   [apple, apple, apple]
   [orange, apple, apple]
   [apple, orange, apple]
   [orange, orange, apple]
   [apple, apple, orange]
   [orange, apple, orange]
   [apple, orange, orange]
   [orange, orange, orange]

5. k-Permutations

You can generate k-permutations with and without repetitions using the combination and permutation generators together. For example, 2-permutations without repetitions of the list (1, 2, 3):

    Generator.combination(1, 2, 3)
       .simple(2)
       .stream()
       .forEach(combination -> Generator.permutation(combination)
          .simple()
          .forEach(System.out::println));

This will print six 2-permutations of (1, 2, 3):

   [1, 2]
   [2, 1]
   [1, 3]
   [3, 1]
   [2, 3]
   [3, 2]

Similarly, you can get 2-Permutations with repetitions of the list (1, 2, 3):

    Generator.combination(1, 2, 3)
       .multi(2)
       .stream()
       .forEach(combination -> Generator.permutation(combination)
           .simple()
           .forEach(System.out::println));

This will print all nine 2-permutations of (1, 2, 3):

   [1, 1]
   [1, 2]
   [2, 1]
   [1, 3]
   [3, 1]
   [2, 2]
   [2, 3]
   [3, 2]
   [3, 3]

6. Subsets

A set A is a subset of a set B if A is "contained" inside B. A and B may coincide. The relationship of one set being a subset of another is called inclusion or sometimes containment.

Examples:

The set (1, 2) is a proper subset of (1, 2, 3). Any set is a subset of itself, but not a proper subset. The empty set, denoted by ∅, is also a subset of any given set X. All subsets of (1, 2, 3) are:

• ()
• (1)
• (2)
• (1, 2)
• (3)
• (1, 3)
• (2, 3)
• (1, 2, 3)

Here is a piece of code that generates all possible subsets of (one, two, three)

   Generator.subset("one", "two", "three")
        .simple()
        .stream()
        .forEach(System.out::println);

And the list of all 8 subsets

   []
   [one]
   [two]
   [one, two]
   [three]
   [one, three]
   [two, three]
   [one, two, three]

7. Integer Partitions

In number theory, a partition of a positive integer n is a way of writing n as a sum of positive integers. Two sums that differ only in the order of their summands are considered to be the same partition; if order matters then the sum becomes a composition. A summand in a partition is also called a part.

The partitions of 5 are listed below:

• 1 + 1 + 1 + 1 + 1
• 2 + 1 + 1 + 1
• 2 + 2 + 1
• 3 + 1 + 1
• 3 + 2
• 4 + 1
• 5

Let's generate all possible partitions of 5:

   Generator.partition(5)
       .stream()
       .forEach(System.out::println);

And the result of all 7 integer possible partitions:

   [1, 1, 1, 1, 1]
   [2, 1, 1, 1]
   [2, 2, 1]
   [3, 1, 1]
   [3, 2]
   [4, 1]
   [5]

8. Cartesian Product

In set theory, a Cartesian Product A × B is the set of all ordered pairs (a, b) where a ∈ A and b ∈ B.

As an example, suppose there are 2 sets of number, (1, 2, 3) and (4, 5, 6), and you want to get the Cartesian product of the two sets.

Source: Cartesian Product

       Generator.cartesianProduct(Arrays.asList(1, 2, 3), Arrays.asList(4, 5, 6))
           .stream()
           .forEach(System.out::println);

And the result will be:

   [1, 4]
   [1, 5]
   [1, 6]
   [2, 4]
   [2, 5]
   [2, 6]
   [3, 4]
   [3, 5]
   [3, 6]