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https://github.com/idris-lang/Idris2.git
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155 lines
5.8 KiB
Idris
155 lines
5.8 KiB
Idris
module Control.Algebra
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infixl 6 <->
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infixl 7 <.>
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public export
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interface Semigroup ty => SemigroupV ty where
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semigroupOpIsAssociative : (l, c, r : ty) ->
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l <+> (c <+> r) = (l <+> c) <+> r
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public export
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interface (Monoid ty, SemigroupV ty) => MonoidV ty where
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monoidNeutralIsNeutralL : (l : ty) -> l <+> neutral {ty} = l
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monoidNeutralIsNeutralR : (r : ty) -> neutral {ty} <+> r = r
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||| Sets equipped with a single binary operation that is associative,
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||| along with a neutral element for that binary operation and
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||| inverses for all elements. Satisfies the following laws:
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|||
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||| + Associativity of `<+>`:
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||| forall a b c, a <+> (b <+> c) == (a <+> b) <+> c
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||| + Neutral for `<+>`:
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||| forall a, a <+> neutral == a
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||| forall a, neutral <+> a == a
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||| + Inverse for `<+>`:
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||| forall a, a <+> inverse a == neutral
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||| forall a, inverse a <+> a == neutral
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public export
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interface MonoidV ty => Group ty where
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inverse : ty -> ty
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groupInverseIsInverseR : (r : ty) -> inverse r <+> r = neutral {ty}
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(<->) : Group ty => ty -> ty -> ty
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(<->) left right = left <+> (inverse right)
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||| Sets equipped with a single binary operation that is associative
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||| and commutative, along with a neutral element for that binary
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||| operation and inverses for all elements. Satisfies the following
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||| laws:
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|||
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||| + Associativity of `<+>`:
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||| forall a b c, a <+> (b <+> c) == (a <+> b) <+> c
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||| + Commutativity of `<+>`:
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||| forall a b, a <+> b == b <+> a
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||| + Neutral for `<+>`:
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||| forall a, a <+> neutral == a
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||| forall a, neutral <+> a == a
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||| + Inverse for `<+>`:
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||| forall a, a <+> inverse a == neutral
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||| forall a, inverse a <+> a == neutral
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public export
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interface Group ty => AbelianGroup ty where
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groupOpIsCommutative : (l, r : ty) -> l <+> r = r <+> l
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||| A homomorphism is a mapping that preserves group structure.
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public export
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interface (Group a, Group b) => GroupHomomorphism a b where
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to : a -> b
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toGroup : (x, y : a) ->
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to (x <+> y) = (to x) <+> (to y)
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||| Sets equipped with two binary operations, one associative and
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||| commutative supplied with a neutral element, and the other
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||| associative, with distributivity laws relating the two operations.
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||| Satisfies the following laws:
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|||
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||| + Associativity of `<+>`:
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||| forall a b c, a <+> (b <+> c) == (a <+> b) <+> c
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||| + Commutativity of `<+>`:
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||| forall a b, a <+> b == b <+> a
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||| + Neutral for `<+>`:
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||| forall a, a <+> neutral == a
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||| forall a, neutral <+> a == a
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||| + Inverse for `<+>`:
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||| forall a, a <+> inverse a == neutral
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||| forall a, inverse a <+> a == neutral
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||| + Associativity of `<.>`:
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||| forall a b c, a <.> (b <.> c) == (a <.> b) <.> c
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||| + Distributivity of `<.>` and `<+>`:
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||| forall a b c, a <.> (b <+> c) == (a <.> b) <+> (a <.> c)
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||| forall a b c, (a <+> b) <.> c == (a <.> c) <+> (b <.> c)
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public export
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interface Group ty => Ring ty where
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(<.>) : ty -> ty -> ty
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ringOpIsAssociative : (l, c, r : ty) ->
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l <.> (c <.> r) = (l <.> c) <.> r
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ringOpIsDistributiveL : (l, c, r : ty) ->
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l <.> (c <+> r) = (l <.> c) <+> (l <.> r)
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ringOpIsDistributiveR : (l, c, r : ty) ->
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(l <+> c) <.> r = (l <.> r) <+> (c <.> r)
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||| Sets equipped with two binary operations, one associative and
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||| commutative supplied with a neutral element, and the other
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||| associative supplied with a neutral element, with distributivity
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||| laws relating the two operations. Satisfies the following laws:
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|||
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||| + Associativity of `<+>`:
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||| forall a b c, a <+> (b <+> c) == (a <+> b) <+> c
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||| + Commutativity of `<+>`:
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||| forall a b, a <+> b == b <+> a
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||| + Neutral for `<+>`:
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||| forall a, a <+> neutral == a
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||| forall a, neutral <+> a == a
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||| + Inverse for `<+>`:
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||| forall a, a <+> inverse a == neutral
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||| forall a, inverse a <+> a == neutral
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||| + Associativity of `<.>`:
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||| forall a b c, a <.> (b <.> c) == (a <.> b) <.> c
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||| + Neutral for `<.>`:
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||| forall a, a <.> unity == a
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||| forall a, unity <.> a == a
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||| + Distributivity of `<.>` and `<+>`:
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||| forall a b c, a <.> (b <+> c) == (a <.> b) <+> (a <.> c)
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||| forall a b c, (a <+> b) <.> c == (a <.> c) <+> (b <.> c)
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public export
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interface Ring ty => RingWithUnity ty where
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unity : ty
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unityIsRingIdL : (l : ty) -> l <.> unity = l
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unityIsRingIdR : (r : ty) -> unity <.> r = r
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||| Sets equipped with two binary operations – both associative,
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||| commutative and possessing a neutral element – and distributivity
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||| laws relating the two operations. All elements except the additive
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||| identity should have a multiplicative inverse. Should (but may
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||| not) satisfy the following laws:
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|||
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||| + Associativity of `<+>`:
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||| forall a b c, a <+> (b <+> c) == (a <+> b) <+> c
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||| + Commutativity of `<+>`:
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||| forall a b, a <+> b == b <+> a
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||| + Neutral for `<+>`:
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||| forall a, a <+> neutral == a
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||| forall a, neutral <+> a == a
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||| + Inverse for `<+>`:
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||| forall a, a <+> inverse a == neutral
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||| forall a, inverse a <+> a == neutral
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||| + Associativity of `<.>`:
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||| forall a b c, a <.> (b <.> c) == (a <.> b) <.> c
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||| + Unity for `<.>`:
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||| forall a, a <.> unity == a
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||| forall a, unity <.> a == a
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||| + InverseM of `<.>`, except for neutral
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||| forall a /= neutral, a <.> inverseM a == unity
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||| forall a /= neutral, inverseM a <.> a == unity
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||| + Distributivity of `<.>` and `<+>`:
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||| forall a b c, a <.> (b <+> c) == (a <.> b) <+> (a <.> c)
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||| forall a b c, (a <+> b) <.> c == (a <.> c) <+> (b <.> c)
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public export
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interface RingWithUnity ty => Field ty where
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inverseM : (x : ty) -> Not (x = neutral {ty}) -> ty
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