Sets #
This file sets up the theory of sets whose elements have a given type.
Main definitions #
Given a type X
and a predicate p : X → Prop
:
Set X
: the type of sets whose elements have typeX
{a : X | p a} : Set X
: the set of all elements ofX
satisfyingp
{a | p a} : Set X
: a more concise notation for{a : X | p a}
{f x y | (x : X) (y : Y)} : Set Z
: a more concise notation for{z : Z | ∃ x y, f x y = z}
{a ∈ S | p a} : Set X
: givenS : Set X
, the subset ofS
consisting of its elements satisfyingp
.
Implementation issues #
As in Lean 3, Set X := X → Prop
I didn't call this file Data.Set.Basic because it contains core Lean 3
stuff which happens before mathlib3's data.set.basic .
This file is a port of the core Lean 3 file lib/lean/library/init/data/set.lean
.
Equations
- Set.instMembershipSet = { mem := Set.Mem }
The subset relation on sets. s ⊆ t
means that all elements of s
are elements of t
.
Note that you should not use this definition directly, but instead write s ⊆ t
.
Equations
- Set.Subset s₁ s₂ = ∀ ⦃a : α⦄, a ∈ s₁ → a ∈ s₂
Instances For
Equations
- One or more equations did not get rendered due to their size.
Instances For
Equations
- One or more equations did not get rendered due to their size.
Instances For
{ f x y | (x : X) (y : Y) }
is notation for the set of elements f x y
constructed from the
binders x
and y
, equivalent to {z : Z | ∃ x y, f x y = z}
.
If f x y
is a single identifier, it must be parenthesized to avoid ambiguity with {x | p x}
;
for instance, {(x) | (x : Nat) (y : Nat) (_hxy : x = y^2)}
.
Equations
- One or more equations did not get rendered due to their size.
Instances For
{ pat : X | p }
is notation for pattern matching in set-builder notation, wherepat
is a pattern that is matched by all objects of typeX
andp
is a proposition that can refer to variables in the pattern. It is the set of all objects of typeX
which, when matched with the patternpat
, makep
come out true.{ pat | p }
is the same, but in the case when the typeX
can be inferred.
For example, { (m, n) : ℕ × ℕ | m * n = 12 }
denotes the set of all ordered pairs of
natural numbers whose product is 12.
Note that if the type ascription is left out and p
can be interpreted as an extended binder,
then the extended binder interpretation will be used. For example, { n + 1 | n < 3 }
will
be interpreted as { x : Nat | ∃ n < 3, n + 1 = x }
rather than using pattern matching.
Equations
- One or more equations did not get rendered due to their size.
Instances For
{ pat : X | p }
is notation for pattern matching in set-builder notation, wherepat
is a pattern that is matched by all objects of typeX
andp
is a proposition that can refer to variables in the pattern. It is the set of all objects of typeX
which, when matched with the patternpat
, makep
come out true.{ pat | p }
is the same, but in the case when the typeX
can be inferred.
For example, { (m, n) : ℕ × ℕ | m * n = 12 }
denotes the set of all ordered pairs of
natural numbers whose product is 12.
Note that if the type ascription is left out and p
can be interpreted as an extended binder,
then the extended binder interpretation will be used. For example, { n + 1 | n < 3 }
will
be interpreted as { x : Nat | ∃ n < 3, n + 1 = x }
rather than using pattern matching.
Equations
- One or more equations did not get rendered due to their size.
Instances For
Pretty printing for set-builder notation with pattern matching.
Equations
- One or more equations did not get rendered due to their size.
Instances For
The universal set on a type α
is the set containing all elements of α
.
This is conceptually the "same as" α
(in set theory, it is actually the same), but type theory
makes the distinction that α
is a type while Set.univ
is a term of type Set α
. Set.univ
can
itself be coerced to a type ↥Set.univ
which is in bijection with (but distinct from) α
.
Instances For
Set.insert a s
is the set {a} ∪ s
.
Note that you should not use this definition directly, but instead write insert a s
(which is
mediated by the Insert
typeclass).
Equations
- Set.insert a s = {b : α | b = a ∨ b ∈ s}
Instances For
The singleton of an element a
is the set with a
as a single element.
Note that you should not use this definition directly, but instead write {a}
.
Equations
- Set.singleton a = {b : α | b = a}
Instances For
𝒫 s
is the set of all subsets of s
.
Equations
- Set.term𝒫_ = Lean.ParserDescr.node `Set.term𝒫_ 100 (Lean.ParserDescr.binary `andthen (Lean.ParserDescr.symbol "𝒫") (Lean.ParserDescr.cat `term 100))
Instances For
Equations
- Set.instFunctorSet = { map := @Set.image, mapConst := fun {α β : Type u_1} => Set.image ∘ Function.const β }
Equations
The property s.Nonempty
expresses the fact that the set s
is not empty. It should be used
in theorem assumptions instead of ∃ x, x ∈ s
or s ≠ ∅
as it gives access to a nice API thanks
to the dot notation.
Equations
- Set.Nonempty s = ∃ (x : α), x ∈ s