HepLean Documentation

Mathlib.Algebra.Group.Operations

Typeclasses for algebraic operations #

Notation typeclass for Inv, the multiplicative analogue of Neg.

We also introduce notation classes SMul and VAdd for multiplicative and additive actions.

SMul is typically, but not exclusively, used for scalar multiplication-like operators. See the module Algebra.AddTorsor for a motivating example for the name VAdd (vector addition).

Notation #

class HVAdd (α : Type u) (β : Type v) (γ : outParam (Type w)) :
Type (max (max u v) w)

The notation typeclass for heterogeneous additive actions. This enables the notation a +ᵥ b : γ where a : α, b : β.

  • hVAdd : αβγ

    a +ᵥ b computes the sum of a and b. The meaning of this notation is type-dependent.

Instances
    class HSMul (α : Type u) (β : Type v) (γ : outParam (Type w)) :
    Type (max (max u v) w)

    The notation typeclass for heterogeneous scalar multiplication. This enables the notation a • b : γ where a : α, b : β.

    It is assumed to represent a left action in some sense. The notation a • b is augmented with a macro (below) to have it elaborate as a left action. Only the b argument participates in the elaboration algorithm: the algorithm uses the type of b when calculating the type of the surrounding arithmetic expression and it tries to insert coercions into b to get some b' such that a • b' has the same type as b'. See the module documentation near the macro for more details.

    • hSMul : αβγ

      a • b computes the product of a and b. The meaning of this notation is type-dependent, but it is intended to be used for left actions.

    Instances
      class VAdd (G : Type u) (P : Type v) :
      Type (max u v)

      Type class for the +ᵥ notation.

      • vadd : GPP

        a +ᵥ b computes the sum of a and b. The meaning of this notation is type-dependent, but it is intended to be used for left actions.

      Instances
        class VSub (G : outParam (Type u_1)) (P : Type u_2) :
        Type (max u_1 u_2)

        Type class for the -ᵥ notation.

        • vsub : PPG

          a -ᵥ b computes the difference of a and b. The meaning of this notation is type-dependent, but it is intended to be used for additive torsors.

        Instances
          class SMul (M : Type u) (α : Type v) :
          Type (max u v)

          Typeclass for types with a scalar multiplication operation, denoted (\bu)

          • smul : Mαα

            a • b computes the product of a and b. The meaning of this notation is type-dependent, but it is intended to be used for left actions.

          Instances
            theorem VAdd.ext {G : Type u} {P : Type v} {x y : VAdd G P} (vadd : VAdd.vadd = VAdd.vadd) :
            x = y
            theorem SMul.ext {M : Type u} {α : Type v} {x y : SMul M α} (smul : SMul.smul = SMul.smul) :
            x = y

            a +ᵥ b computes the sum of a and b. The meaning of this notation is type-dependent.

            Equations
            Instances For

              a -ᵥ b computes the difference of a and b. The meaning of this notation is type-dependent, but it is intended to be used for additive torsors.

              Equations
              Instances For

                a • b computes the product of a and b. The meaning of this notation is type-dependent, but it is intended to be used for left actions.

                Equations
                Instances For

                  We have a macro to make x • y notation participate in the expression tree elaborator, like other arithmetic expressions such as +, *, /, ^, =, inequalities, etc. The macro is using the leftact% elaborator introduced in this RFC.

                  As a concrete example of the effect of this macro, consider

                  variable [Ring R] [AddCommMonoid M] [Module R M] (r : R) (N : Submodule R M) (m : M) (n : N)
                  #check m + r • n
                  

                  Without the macro, the expression would elaborate as m + ↑(r • n : ↑N) : M. With the macro, the expression elaborates as m + r • (↑n : M) : M. To get the first interpretation, one can write m + (r • n :).

                  Here is a quick review of the expression tree elaborator:

                  1. It builds up an expression tree of all the immediately accessible operations that are marked with binop%, unop%, leftact%, rightact%, binrel%, etc.
                  2. It elaborates every leaf term of this tree (without an expected type, so as if it were temporarily wrapped in (... :)).
                  3. Using the types of each elaborated leaf, it computes a supremum type they can all be coerced to, if such a supremum exists.
                  4. It inserts coercions around leaf terms wherever needed.

                  The hypothesis is that individual expression trees tend to be calculations with respect to a single algebraic structure.

                  Note(kmill): If we were to remove HSMul and switch to using SMul directly, then the expression tree elaborator would not be able to insert coercions within the right operand; they would likely appear as ↑(x • y) rather than x • ↑y, unlike other arithmetic operations.

                  @[defaultInstance 1000]
                  instance instHSMul {α : Type u_1} {β : Type u_2} [SMul α β] :
                  HSMul α β β
                  Equations
                  • instHSMul = { hSMul := SMul.smul }
                  @[defaultInstance 1000]
                  instance instHVAdd {α : Type u_1} {β : Type u_2} [VAdd α β] :
                  HVAdd α β β
                  Equations
                  • instHVAdd = { hVAdd := VAdd.vadd }
                  theorem SMul.smul_eq_hSMul {α : Type u_1} {β : Type u_2} [SMul α β] :
                  SMul.smul = HSMul.hSMul
                  theorem VAdd.vadd_eq_hVAdd {α : Type u_1} {β : Type u_2} [VAdd α β] :
                  VAdd.vadd = HVAdd.hVAdd
                  class Inv (α : Type u) :

                  Class of types that have an inversion operation.

                  • inv : αα

                    Invert an element of α.

                  Instances

                    Invert an element of α.

                    Equations
                    Instances For
                      @[simp]
                      theorem mul_dite {α : Type u_2} (P : Prop) [Decidable P] [Mul α] (a : α) (b : Pα) (c : ¬Pα) :
                      (a * if h : P then b h else c h) = if h : P then a * b h else a * c h
                      theorem add_dite {α : Type u_2} (P : Prop) [Decidable P] [Add α] (a : α) (b : Pα) (c : ¬Pα) :
                      (a + if h : P then b h else c h) = if h : P then a + b h else a + c h
                      @[simp]
                      theorem mul_ite {α : Type u_2} (P : Prop) [Decidable P] [Mul α] (a b c : α) :
                      (a * if P then b else c) = if P then a * b else a * c
                      theorem add_ite {α : Type u_2} (P : Prop) [Decidable P] [Add α] (a b c : α) :
                      (a + if P then b else c) = if P then a + b else a + c
                      @[simp]
                      theorem dite_mul {α : Type u_2} (P : Prop) [Decidable P] [Mul α] (a : Pα) (b : ¬Pα) (c : α) :
                      (if h : P then a h else b h) * c = if h : P then a h * c else b h * c
                      theorem dite_add {α : Type u_2} (P : Prop) [Decidable P] [Add α] (a : Pα) (b : ¬Pα) (c : α) :
                      (if h : P then a h else b h) + c = if h : P then a h + c else b h + c
                      @[simp]
                      theorem ite_mul {α : Type u_2} (P : Prop) [Decidable P] [Mul α] (a b c : α) :
                      (if P then a else b) * c = if P then a * c else b * c
                      theorem ite_add {α : Type u_2} (P : Prop) [Decidable P] [Add α] (a b c : α) :
                      (if P then a else b) + c = if P then a + c else b + c
                      theorem dite_mul_dite {α : Type u_2} (P : Prop) [Decidable P] [Mul α] (a : Pα) (b : ¬Pα) (c : Pα) (d : ¬Pα) :
                      ((if h : P then a h else b h) * if h : P then c h else d h) = if h : P then a h * c h else b h * d h
                      theorem dite_add_dite {α : Type u_2} (P : Prop) [Decidable P] [Add α] (a : Pα) (b : ¬Pα) (c : Pα) (d : ¬Pα) :
                      ((if h : P then a h else b h) + if h : P then c h else d h) = if h : P then a h + c h else b h + d h
                      theorem ite_mul_ite {α : Type u_2} (P : Prop) [Decidable P] [Mul α] (a b c d : α) :
                      ((if P then a else b) * if P then c else d) = if P then a * c else b * d
                      theorem ite_add_ite {α : Type u_2} (P : Prop) [Decidable P] [Add α] (a b c d : α) :
                      ((if P then a else b) + if P then c else d) = if P then a + c else b + d
                      theorem div_dite {α : Type u_2} (P : Prop) [Decidable P] [Div α] (a : α) (b : Pα) (c : ¬Pα) :
                      (a / if h : P then b h else c h) = if h : P then a / b h else a / c h
                      theorem sub_dite {α : Type u_2} (P : Prop) [Decidable P] [Sub α] (a : α) (b : Pα) (c : ¬Pα) :
                      (a - if h : P then b h else c h) = if h : P then a - b h else a - c h
                      theorem div_ite {α : Type u_2} (P : Prop) [Decidable P] [Div α] (a b c : α) :
                      (a / if P then b else c) = if P then a / b else a / c
                      theorem sub_ite {α : Type u_2} (P : Prop) [Decidable P] [Sub α] (a b c : α) :
                      (a - if P then b else c) = if P then a - b else a - c
                      theorem dite_div {α : Type u_2} (P : Prop) [Decidable P] [Div α] (a : Pα) (b : ¬Pα) (c : α) :
                      (if h : P then a h else b h) / c = if h : P then a h / c else b h / c
                      theorem dite_sub {α : Type u_2} (P : Prop) [Decidable P] [Sub α] (a : Pα) (b : ¬Pα) (c : α) :
                      (if h : P then a h else b h) - c = if h : P then a h - c else b h - c
                      theorem ite_div {α : Type u_2} (P : Prop) [Decidable P] [Div α] (a b c : α) :
                      (if P then a else b) / c = if P then a / c else b / c
                      theorem ite_sub {α : Type u_2} (P : Prop) [Decidable P] [Sub α] (a b c : α) :
                      (if P then a else b) - c = if P then a - c else b - c
                      theorem dite_div_dite {α : Type u_2} (P : Prop) [Decidable P] [Div α] (a : Pα) (b : ¬Pα) (c : Pα) (d : ¬Pα) :
                      ((if h : P then a h else b h) / if h : P then c h else d h) = if h : P then a h / c h else b h / d h
                      theorem dite_sub_dite {α : Type u_2} (P : Prop) [Decidable P] [Sub α] (a : Pα) (b : ¬Pα) (c : Pα) (d : ¬Pα) :
                      ((if h : P then a h else b h) - if h : P then c h else d h) = if h : P then a h - c h else b h - d h
                      theorem ite_div_ite {α : Type u_2} (P : Prop) [Decidable P] [Div α] (a b c d : α) :
                      ((if P then a else b) / if P then c else d) = if P then a / c else b / d
                      theorem ite_sub_ite {α : Type u_2} (P : Prop) [Decidable P] [Sub α] (a b c d : α) :
                      ((if P then a else b) - if P then c else d) = if P then a - c else b - d