Sets, bags, and mixes

ErrorsCollection
Unordered collections of unique and weighted objects in Raku

The six collection classes are Set, SetHash, Bag, BagHash, Mix and MixHash. They all share similar semantics.

In a nutshell, these classes hold, in general, unordered collections of objects, much like an object hash. The QuantHash role is the role that is implemented by all of these classes: therefore they are also referenced as `QuantHash`

es.

`Set`

and `SetHash`

also implement the Setty role, `Bag`

and `BagHash`

implement the Baggy role, `Mix`

and `MixHash`

implement the Mixy role (which itself implements the `Baggy`

role).

Sets only consider if objects in the collection are present or not, bags can hold several objects of the same kind, and mixes also allow fractional (and negative) weights. The regular versions are immutable, the *-Hash* versions are mutable.

Let's elaborate on that. If you want to collect objects in a container but you do not care about the order of these objects, Raku provides these *unordered* collection types. Being unordered, these containers can be more efficient than Lists or Arrays for looking up elements or dealing with repeated items.

On the other hand, if you want to get the contained objects (elements) **without duplicates** and you only care *whether* an element is in the collection or not, you can use a Set or SetHash.

If you want to get rid of duplicates but still preserve order, take a look at the unique routine for Lists.

If you want to keep track of the **number of times each object appeared**, you can use a Bag or BagHash. In these `Baggy`

containers each element has a weight (an unsigned integer) indicating the number of times the same object has been included in the collection.

The types Mix and MixHash are similar to Bag and BagHash, but they also allow **fractional and negative weights**.

Set, Bag, and Mix are *immutable* types. Use the mutable variants SetHash, BagHash, and MixHash if you want to add or remove elements after the container has been constructed.

For one thing, as far as they are concerned, identical objects refer to the same element – where identity is determined using the WHICH method (i.e. the same way that the === operator checks identity). For value types like `Str`

, this means having the same value; for reference types like `Array`

, it means referring to the same object instance.

Secondly, they provide a Hash-like interface where the actual elements of the collection (which can be objects of any type) are the 'keys', and the associated weights are the 'values':

type of $a | value of $a{$b} if $b is an element | value of $a{$b} if $b is not an element |
---|---|---|

Set / SetHash | True | False |

Bag / BagHash | a positive integer | 0 |

Mix / MixHash | a non-zero real number | 0 |

There are several infix operators devoted to performing common operations using `QuantHash`

semantics. Since that is a mouthful, these operators are usually referred to as "set operators".

This does **not** mean that the parameters of these operators must always be `Set`

, or even a more generic `QuantHash`

. It just means that the logic that is applied to the operators is the logic of Set Theory.

These infixes can be written using the Unicode character that represents the function (like `∈`

or `∪`

), or with an equivalent ASCII version (like `(elem)`

or `(|)`

).

So explicitly using `Set`

(or `Bag`

or `Mix`

) objects with these infixes is unnecessary. All set operators work with all possible arguments, including (since 6.d) those that are not explicitly set-like. If necessary, a coercion will take place internally: but in many cases that is not actually needed.

However, if a `Bag`

or `Mix`

is one of the parameters to these set operators, then the semantics will be upgraded to that type (where `Mix`

supersedes `Bag`

if both types happen to be used).

`Bool`

Returns `True`

if `$a`

is an **element** of `$b`

, else `False`

. More information, Wikipedia definition.

Returns `True`

if `$a`

is **not** an element of `$b`

, else `False`

. More information, Wikipedia definition.

Returns `True`

if `$a`

**contains** `$b`

as an element, else `False`

. More information, Wikipedia definition.

Returns `True`

if `$a`

does **not** contain `$b`

, else `False`

. More information, Wikipedia definition.

Returns `True`

if `$a`

is a **subset** or is equal to `$b`

, else `False`

. More information, Wikipedia definition.

Returns `True`

if `$a`

is **not** a **subset** nor equal to `$b`

, else `False`

. More information, Wikipedia definition.

Returns `True`

if `$a`

is a **strict subset** of `$b`

, else `False`

. More information, Wikipedia definition.

Returns `True`

if `$a`

is **not** a **strict subset** of `$b`

, else `False`

. More information, Wikipedia definition.

Returns `True`

if `$a`

is a **superset** of or equal to `$b`

, else `False`

. More information, Wikipedia definition.

Returns `True`

if `$a`

is **not** a **superset** nor equal to `$b`

, else `False`

. More information, Wikipedia definition.

Returns `True`

if `$a`

is a **strict superset** of `$b`

, else `False`

. More information, Wikipedia definition.

Returns `True`

if `$a`

is **not** a **strict superset** of `$b`

, else `False`

. More information, Wikipedia definition.

Returns `True`

if `$a`

and `$b`

are **identical**, else `False`

. More information, Wikipedia definition.

Returns `True`

if `$a`

and `$b`

are **not identical**, else `False`

. More information, Wikipedia definition.

`QuantHash`

Returns the **union** of all its arguments. More information, Wikipedia definition.

Returns the **intersection** of all of its arguments. More information, Wikipedia definition.

Returns the **set difference** of all its arguments. More information, Wikipedia definition.

Returns the **symmetric set difference** of all its arguments. More information, Wikipedia definition.

`Baggy`

Returns the Baggy **multiplication** of its arguments. More information.

Returns the Baggy **addition** of its arguments. More information.

The empty set. More information, Wikipedia definition.