Modules over a ring #
In this file we define
Module R M
: an additive commutative monoidM
is aModule
over aSemiring R
if forr : R
andx : M
their "scalar multiplication"r • x : M
is defined, and the operation•
satisfies some natural associativity and distributivity axioms similar to those on a ring.
Implementation notes #
In typical mathematical usage, our definition of Module
corresponds to "semimodule", and the
word "module" is reserved for Module R M
where R
is a Ring
and M
an AddCommGroup
.
If R
is a Field
and M
an AddCommGroup
, M
would be called an R
-vector space.
Since those assumptions can be made by changing the typeclasses applied to R
and M
,
without changing the axioms in Module
, mathlib calls everything a Module
.
In older versions of mathlib3, we had separate abbreviations for semimodules and vector spaces.
This caused inference issues in some cases, while not providing any real advantages, so we decided
to use a canonical Module
typeclass throughout.
Tags #
semimodule, module, vector space
A module is a generalization of vector spaces to a scalar semiring.
It consists of a scalar semiring R
and an additive monoid of "vectors" M
,
connected by a "scalar multiplication" operation r • x : M
(where r : R
and x : M
) with some natural associativity and
distributivity axioms similar to those on a ring.
- smul : R → M → M
Scalar multiplication distributes over addition from the right.
Scalar multiplication by zero gives zero.
Instances
Scalar multiplication by zero gives zero.
A module over a semiring automatically inherits a MulActionWithZero
structure.
Equations
- Module.toMulActionWithZero = let __src := inferInstance; MulActionWithZero.mk ⋯ ⋯
Pullback a Module
structure along an injective additive monoid homomorphism.
See note [reducible non-instances].
Equations
- Function.Injective.module R f hf smul = let __src := Function.Injective.distribMulAction f hf smul; Module.mk ⋯ ⋯
Instances For
Pushforward a Module
structure along a surjective additive monoid homomorphism.
See note [reducible non-instances].
Equations
- Function.Surjective.module R f hf smul = Module.mk ⋯ ⋯
Instances For
Push forward the action of R
on M
along a compatible surjective map f : R →+* S
.
See also Function.Surjective.mulActionLeft
and Function.Surjective.distribMulActionLeft
.
Equations
- Function.Surjective.moduleLeft f hf hsmul = let __src := Function.Surjective.distribMulActionLeft (↑f) hf hsmul; Module.mk ⋯ ⋯
Instances For
Compose a Module
with a RingHom
, with action f s • m
.
See note [reducible non-instances].
Equations
- Module.compHom M f = let __src := MulActionWithZero.compHom M f.toMonoidWithZeroHom; let __src_1 := DistribMulAction.compHom M ↑f; Module.mk ⋯ ⋯
Instances For
(•)
as an AddMonoidHom
.
This is a stronger version of DistribMulAction.toAddMonoidEnd
Equations
- Module.toAddMonoidEnd R M = let __src := DistribMulAction.toAddMonoidEnd R M; { toMonoidHom := __src, map_zero' := ⋯, map_add' := ⋯ }
Instances For
A convenience alias for Module.toAddMonoidEnd
as an AddMonoidHom
, usually to allow the
use of AddMonoidHom.flip
.
Equations
- smulAddHom R M = (Module.toAddMonoidEnd R M).toAddMonoidHom
Instances For
Equations
- AddCommGroup.intModule M = Module.mk ⋯ ⋯
A variant of Module.ext
that's convenient for term-mode.
An AddCommMonoid
that is a Module
over a Ring
carries a natural AddCommGroup
structure.
See note [reducible non-instances].
Equations
- Module.addCommMonoidToAddCommGroup R = let __src := inferInstance; AddCommGroup.mk ⋯
Instances For
A module over a Subsingleton
semiring is a Subsingleton
. We cannot register this
as an instance because Lean has no way to guess R
.
A semiring is Nontrivial
provided that there exists a nontrivial module over this semiring.
Like Semiring.toModule
, but multiplies on the right.
Equations
- Semiring.toOppositeModule = let __src := MonoidWithZero.toOppositeMulActionWithZero R; Module.mk ⋯ ⋯
A ring homomorphism f : R →+* M
defines a module structure by r • x = f r * x
.
Equations
- f.toModule = Module.compHom S f
Instances For
If the module action of R
on S
is compatible with multiplication on S
, then
fun x ↦ x • 1
is a ring homomorphism from R
to S
.
This is the RingHom
version of MonoidHom.smulOneHom
.
When R
is commutative, usually algebraMap
should be preferred.
Equations
- RingHom.smulOneHom = let __spread.0 := MonoidHom.smulOneHom; { toMonoidHom := __spread.0, map_zero' := ⋯, map_add' := ⋯ }
Instances For
A homomorphism between semirings R and S can be equivalently specified by a R-module structure on S such that S/S/R is a scalar tower.
Equations
- One or more equations did not get rendered due to their size.
Instances For
Convert back any exotic ℕ
-smul to the canonical instance. This should not be needed since in
mathlib all AddCommMonoid
s should normally have exactly one ℕ
-module structure by design.
All ℕ
-module structures are equal. Not an instance since in mathlib all AddCommMonoid
should normally have exactly one ℕ
-module structure by design.
Equations
- AddCommMonoid.natModule.unique = { default := inferInstance, uniq := ⋯ }
Instances For
Equations
- ⋯ = ⋯
Convert back any exotic ℤ
-smul to the canonical instance. This should not be needed since in
mathlib all AddCommGroup
s should normally have exactly one ℤ
-module structure by design.
All ℤ
-module structures are equal. Not an instance since in mathlib all AddCommGroup
should normally have exactly one ℤ
-module structure by design.
Equations
- AddCommGroup.intModule.unique = { default := inferInstance, uniq := ⋯ }
Instances For
Equations
- ⋯ = ⋯
NoZeroSMulDivisors
#
This section defines the NoZeroSMulDivisors
class, and includes some tests
for the vanishing of elements (especially in modules over division rings).
NoZeroSMulDivisors R M
states that a scalar multiple is 0
only if either argument is 0
.
This is a version of saying that M
is torsion free, without assuming R
is zero-divisor free.
The main application of NoZeroSMulDivisors R M
, when M
is a module,
is the result smul_eq_zero
: a scalar multiple is 0
iff either argument is 0
.
It is a generalization of the NoZeroDivisors
class to heterogeneous multiplication.
If scalar multiplication yields zero, either the scalar or the vector was zero.
Instances
Pullback a NoZeroSMulDivisors
instance along an injective function.
Equations
- ⋯ = ⋯
If M
is an R
-module with one and M
has characteristic zero, then R
has characteristic
zero as well. Usually M
is an R
-algebra.
Equations
- ⋯ = ⋯
Only a ring of characteristic zero can can have a non-trivial module without additive or scalar torsion.
Alias of Nat.smul_one_eq_cast
.
Alias of Int.smul_one_eq_cast
.