Note about Mathlib/Init/
#
The files in Mathlib/Init
are leftovers from the port from Mathlib3.
(They contain content moved from lean3 itself that Mathlib needed but was not moved to lean4.)
We intend to move all the content of these files out into the main Mathlib
directory structure.
Contributions assisting with this are appreciated.
#align
statements without corresponding declarations
(i.e. because the declaration is in Batteries or Lean) can be left here.
These will be deleted soon so will not significantly delay deleting otherwise empty Init
files.
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.instMembership = { mem := Set.Mem }
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.instFunctor = { map := @Set.image, mapConst := fun {α β : Type u_1} => Set.image ∘ Function.const β }
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.