Principal ideal rings and principal ideal domains #
A principal ideal ring (PIR) is a ring in which all left ideals are principal. A principal ideal domain (PID) is an integral domain which is a principal ideal ring.
Main definitions #
Note that for principal ideal domains, one should use
[IsDomain R] [IsPrincipalIdealRing R]
. There is no explicit definition of a PID.
Theorems about PID's are in the principal_ideal_ring
namespace.
IsPrincipalIdealRing
: a predicate on rings, saying that every left ideal is principal.generator
: a generator of a principal ideal (or more generally submodule)to_unique_factorization_monoid
: a PID is a unique factorization domain
Main results #
to_maximal_ideal
: a non-zero prime ideal in a PID is maximal.EuclideanDomain.to_principal_ideal_domain
: a Euclidean domain is a PID.
- principal' : ∃ a, S = Submodule.span R {a}
An R
-submodule of M
is principal if it is generated by one element.
Instances
Equations
Equations
- principal : ∀ (S : Ideal R), Submodule.IsPrincipal S
A ring is a principal ideal ring if all (left) ideals are principal.
Instances
generator I
, if I
is a principal submodule, is an x ∈ M
such that span R {x} = I
Equations
- Submodule.IsPrincipal.generator S = Classical.choose (_ : ∃ a, S = Submodule.span R {a})
Instances For
factors a
is a multiset of irreducible elements whose product is a
, up to units
Equations
- PrincipalIdealRing.factors a = if h : a = 0 then ∅ else Classical.choose (_ : ∃ f, (∀ (b : R), b ∈ f → Irreducible b) ∧ Associated (Multiset.prod f) a)
Instances For
If a RingHom
maps all units and all factors of an element a
into a submonoid s
, then it
also maps a
into that submonoid.
A principal ideal domain has unique factorization
The surjective image of a principal ideal ring is again a principal ideal ring.
nonPrincipals R
is the set of all ideals of R
that are not principal ideals.
Equations
- nonPrincipals R = {I | ¬Submodule.IsPrincipal I}
Instances For
Any chain in the set of non-principal ideals has an upper bound which is non-principal. (Namely, the union of the chain is such an upper bound.)
If all prime ideals in a commutative ring are principal, so are all other ideals.