Safe Haskell	Safe-Inferred
Language	Haskell2010

NumHask.Algebra.Group

Description

The Group hierarchy

Synopsis

class Magma a where
- (⊕) :: a -> a -> a
class Magma a => Unital a where
- unit :: a
class Magma a => Associative a
class Magma a => Commutative a
class Magma a => Absorbing a where
- absorb :: a
class Magma a => Invertible a where
- inv :: a -> a
class Magma a => Idempotent a
class (Associative a, Unital a, Invertible a) => Group a
class (Associative a, Unital a, Invertible a, Commutative a) => AbelianGroup a

Documentation

class Magma a where Source #

A Magma is a tuple (T,magma) consisting of

a type a, and
a function (magma) :: T -> T -> T

The mathematical laws for a magma are:

magma is defined for all possible pairs of type T, and
magma is closed in the set of all possible values of type T

or, more tersly,

∀ a, b ∈ T: a ⊕ b ∈ T

These laws are true by construction in haskell: the type signature of ⊕ and the above mathematical laws are synonyms.

Methods

(⊕) :: a -> a -> a infix 3 Source #

Instances

Instances details

Magma a => Magma (Wrapped a) Source #
Instance details Defined in NumHask.Data.Wrapped Methods (⊕) :: Wrapped a -> Wrapped a -> Wrapped a Source #
Magma b => Magma (a -> b) Source #
Instance details Defined in NumHask.Algebra.Group Methods (⊕) :: (a -> b) -> (a -> b) -> a -> b Source #

class Magma a => Unital a where Source #

A Unital Magma is a magma with an identity element (the unit).

unit ⊕ a = a
a ⊕ unit = a

Methods

unit :: a Source #

Instances

Instances details

Unital b => Unital (a -> b) Source #
Instance details Defined in NumHask.Algebra.Group Methods unit :: a -> b Source #

class Magma a => Associative a Source #

An Associative Magma

(a ⊕ b) ⊕ c = a ⊕ (b ⊕ c)

Instances

Instances details

Associative b => Associative (a -> b) Source #
Instance details Defined in NumHask.Algebra.Group

class Magma a => Commutative a Source #

A Commutative Magma is a Magma where the binary operation is commutative.

a ⊕ b = b ⊕ a

Instances

Instances details

Commutative b => Commutative (a -> b) Source #
Instance details Defined in NumHask.Algebra.Group

class Magma a => Absorbing a where Source #

An Absorbing is a Magma with an Absorbing Element

a ⊕ absorb = absorb

Methods

absorb :: a Source #

Instances

Instances details

Absorbing b => Absorbing (a -> b) Source #
Instance details Defined in NumHask.Algebra.Group Methods absorb :: a -> b Source #

class Magma a => Invertible a where Source #

An Invertible Magma

∀ a,b ∈ T: inv a ⊕ (a ⊕ b) = b = (b ⊕ a) ⊕ inv a

Methods

inv :: a -> a Source #

Instances

Instances details

Invertible b => Invertible (a -> b) Source #
Instance details Defined in NumHask.Algebra.Group Methods inv :: (a -> b) -> a -> b Source #

class Magma a => Idempotent a Source #

An Idempotent Magma is a magma where every element is Idempotent.

a ⊕ a = a

Instances

Instances details

Magma a => Idempotent (Wrapped a) Source #
Instance details Defined in NumHask.Data.Wrapped
Idempotent b => Idempotent (a -> b) Source #
Instance details Defined in NumHask.Algebra.Group

class (Associative a, Unital a, Invertible a) => Group a Source #

A Group is a Associative, Unital and Invertible Magma.

Instances

Instances details

(Associative a, Unital a, Invertible a) => Group a Source #
Instance details Defined in NumHask.Algebra.Group

class (Associative a, Unital a, Invertible a, Commutative a) => AbelianGroup a Source #

An Abelian Group is an Associative, Unital, Invertible and Commutative Magma . In other words, it is a Commutative Group

Instances

Instances details

(Associative a, Unital a, Invertible a, Commutative a) => AbelianGroup a Source #
Instance details Defined in NumHask.Algebra.Group