Syntax quotation for terms.
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Syntax quotation for (sequences of) commands.
The identical syntax for term quotations takes priority,
so ambiguous quotations like `($x $y) will be parsed as an application,
not two commands. Use `($x:command $y:command) instead.
Multiple commands will be put in a `null node,
but a single command will not (so that you can directly
match against a quotation in a command kind's elaborator).
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/-! <text> -/ defines a module docstring that can be displayed by documentation generation
tools. The string is associated with the corresponding position in the file. It can be used
multiple times in the same file.
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declModifiers is the collection of modifiers on a declaration:
- a doc comment
/-- ... -/ - a list of attributes
@[attr1, attr2] - a visibility specifier,
privateorprotected noncomputableunsafepartialornonrec
All modifiers are optional, and have to come in the listed order.
nestedDeclModifiers is the same as declModifiers, but attributes are printed
on the same line as the declaration. It is used for declarations nested inside other syntax,
such as inductive constructors, structure projections, and let rec / where definitions.
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declId matches foo or foo.{u,v}: an identifier possibly followed by a list of universe names
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declSig matches the signature of a declaration with required type: a list of binders and then : type
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optDeclSig matches the signature of a declaration with optional type: a list of binders and then possibly : type
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Right-hand side of a := in a declaration, a term.
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declVal matches the right-hand side of a declaration, one of:
:= expr(a "simple declaration")- a sequence of
| pat => expr(a declaration by equations), shorthand for amatch whereand then a sequence offield := valueinitializers, shorthand for a structure constructor
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In Lean, every concrete type other than the universes
and every type constructor other than dependent arrows
is an instance of a general family of type constructions known as inductive types.
It is remarkable that it is possible to construct a substantial edifice of mathematics
based on nothing more than the type universes, dependent arrow types, and inductive types;
everything else follows from those.
Intuitively, an inductive type is built up from a specified list of constructors.
For example, List α is the list of elements of type α, and is defined as follows:
inductive List (α : Type u) where
| nil
| cons (head : α) (tail : List α)
A list of elements of type α is either the empty list, nil,
or an element head : α followed by a list tail : List α.
See Inductive types
for more information.
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A section/end pair delimits the scope of variable, include, open, set_option, and localcommands. Sections can be nested.section <id>provides a label to the section that has to appear with the matchingend. In either case, the end` can be omitted, in which case the section is
closed at the end of the file.
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namespace <id> opens a section with label <id> that influences naming and name resolution inside
the section:
- Declarations names are prefixed:
def seventeen : ℕ := 17inside a namespaceNatis given the full nameNat.seventeen. - Names introduced by
exportdeclarations are also prefixed by the identifier. - All names starting with
<id>.become available in the namespace without the prefix. These names are preferred over names introduced by outer namespaces oropen. - Within a namespace, declarations can be
protected, which excludes them from the effects of opening the namespace.
As with section, namespaces can be nested and the scope of a namespace is terminated by a
corresponding end <id> or the end of the file.
namespace also acts like section in delimiting the scope of variable, open, and other scoped commands.
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Declares one or more typed variables, or modifies whether already-declared variables are implicit.
Introduces variables that can be used in definitions within the same namespace or section block.
When a definition mentions a variable, Lean will add it as an argument of the definition. This is
useful in particular when writing many definitions that have parameters in common (see below for an
example).
Variable declarations have the same flexibility as regular function parameters. In particular they
can be [explicit, implicit][binder docs], or [instance implicit][tpil classes] (in which case they
can be anonymous). This can be changed, for instance one can turn explicit variable x into an
implicit one with variable {x}. Note that currently, you should avoid changing how variables are
bound and declare new variables at the same time; see [issue 2789] for more on this topic.
In theorem bodies (i.e. proofs), variables are not included based on usage in order to ensure that
changes to the proof cannot change the statement of the overall theorem. Instead, variables are only
available to the proof if they have been mentioned in the theorem header or in an include command
or are instance implicit and depend only on such variables.
See Variables and Sections from Theorem Proving in Lean for a more detailed discussion.
(Variables and Sections on Theorem Proving in Lean) [tpil classes]: https://lean-lang.org/theorem_proving_in_lean4/type_classes.html (Type classes on Theorem Proving in Lean) [binder docs]: https://leanprover-community.github.io/mathlib4_docs/Lean/Expr.html#Lean.BinderInfo (Documentation for the BinderInfo type) [issue 2789]: https://github.com/leanprover/lean4/issues/2789 (Issue 2789 on github)
Examples #
section
variable
{α : Type u} -- implicit
(a : α) -- explicit
[instBEq : BEq α] -- instance implicit, named
[Hashable α] -- instance implicit, anonymous
def isEqual (b : α) : Bool :=
a == b
#check isEqual
-- isEqual.{u} {α : Type u} (a : α) [instBEq : BEq α] (b : α) : Bool
variable
{a} -- `a` is implicit now
def eqComm {b : α} := a == b ↔ b == a
#check eqComm
-- eqComm.{u} {α : Type u} {a : α} [instBEq : BEq α] {b : α} : Prop
end
The following shows a typical use of variable to factor out definition arguments:
variable (Src : Type)
structure Logger where
trace : List (Src × String)
#check Logger
-- Logger (Src : Type) : Type
namespace Logger
-- switch `Src : Type` to be implicit until the `end Logger`
variable {Src}
def empty : Logger Src where
trace := []
#check empty
-- Logger.empty {Src : Type} : Logger Src
variable (log : Logger Src)
def len :=
log.trace.length
#check len
-- Logger.len {Src : Type} (log : Logger Src) : Nat
variable (src : Src) [BEq Src]
-- at this point all of `log`, `src`, `Src` and the `BEq` instance can all become arguments
def filterSrc :=
log.trace.filterMap
fun (src', str') => if src' == src then some str' else none
#check filterSrc
-- Logger.filterSrc {Src : Type} (log : Logger Src) (src : Src) [inst✝ : BEq Src] : List String
def lenSrc :=
log.filterSrc src |>.length
#check lenSrc
-- Logger.lenSrc {Src : Type} (log : Logger Src) (src : Src) [inst✝ : BEq Src] : Nat
end Logger
The following example demonstrates availability of variables in proofs:
variable
{α : Type} -- available in the proof as indirectly mentioned through `a`
[ToString α] -- available in the proof as `α` is included
(a : α) -- available in the proof as mentioned in the header
{β : Type} -- not available in the proof
[ToString β] -- not available in the proof
theorem ex : a = a := rfl
After elaboration of the proof, the following warning will be generated to highlight the unused hypothesis:
included section variable '[ToString α]' is not used in 'ex', consider excluding it
In such cases, the offending variable declaration should be moved down or into a section so that only theorems that do depend on it follow it until the end of the section.
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Declares one or more universe variables.
universe u v
Prop, Type, Type u and Sort u are types that classify other types, also known as
universes. In Type u and Sort u, the variable u stands for the universe's level, and a
universe at level u can only classify universes that are at levels lower than u. For more
details on type universes, please refer to the relevant chapter of Theorem Proving in Lean.
Just as type arguments allow polymorphic definitions to be used at many different types, universe
parameters, represented by universe variables, allow a definition to be used at any required level.
While Lean mostly handles universe levels automatically, declaring them explicitly can provide more
control when writing signatures. The universe keyword allows the declared universe variables to be
used in a collection of definitions, and Lean will ensure that these definitions use them
consistently.
/- Explicit type-universe parameter. -/
def id₁.{u} (α : Type u) (a : α) := a
/- Implicit type-universe parameter, equivalent to `id₁`.
Requires option `autoImplicit true`, which is the default. -/
def id₂ (α : Type u) (a : α) := a
/- Explicit standalone universe variable declaration, equivalent to `id₁` and `id₂`. -/
universe u
def id₃ (α : Type u) (a : α) := a
On a more technical note, using a universe variable only in the right-hand side of a definition causes an error if the universe has not been declared previously.
def L₁.{u} := List (Type u)
-- def L₂ := List (Type u) -- error: `unknown universe level 'u'`
universe u
def L₃ := List (Type u)
Examples #
universe u v w
structure Pair (α : Type u) (β : Type v) : Type (max u v) where
a : α
b : β
#check Pair.{v, w}
-- Pair : Type v → Type w → Type (max v w)
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Displays all available tactic tags, with documentation.
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set_option <id> <value> sets the option <id> to <value>. Depending on the type of the option,
the value can be true, false, a string, or a numeral. Options are used to configure behavior of
Lean as well as user-defined extensions. The setting is active until the end of the current section
or namespace or the end of the file.
Auto-completion is available for <id> to list available options.
set_option <id> <value> in <command> sets the option for just a single command:
set_option pp.all true in
#check 1 + 1
Similarly, set_option <id> <value> in can also be used inside terms and tactics to set an option
only in a single term or tactic.
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Adds names from other namespaces to the current namespace.
The command export Some.Namespace (name₁ name₂) makes name₁ and name₂:
- visible in the current namespace without prefix
Some.Namespace, likeopen, and - visible from outside the current namespace
NasN.name₁andN.name₂.
Examples #
namespace Morning.Sky
def star := "venus"
end Morning.Sky
namespace Evening.Sky
export Morning.Sky (star)
-- `star` is now in scope
#check star
end Evening.Sky
-- `star` is visible in `Evening.Sky`
#check Evening.Sky.star
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Makes names from other namespaces visible without writing the namespace prefix.
Names that are made available with open are visible within the current section or namespace
block. This makes referring to (type) definitions and theorems easier, but note that it can also
make [scoped instances], notations, and attributes from a different namespace available.
The open command can be used in a few different ways:
open Some.Namespace.Path1 Some.Namespace.Path2makes all non-protected names inSome.Namespace.Path1andSome.Namespace.Path2available without the prefix, so thatSome.Namespace.Path1.xandSome.Namespace.Path2.ycan be referred to by writing onlyxandy.open Some.Namespace.Path hiding def1 def2opens all non-protected names inSome.Namespace.Pathexceptdef1anddef2.open Some.Namespace.Path (def1 def2)only makesSome.Namespace.Path.def1andSome.Namespace.Path.def2available without the full prefix, soSome.Namespace.Path.def3would be unaffected.This works even if
def1anddef2areprotected.open Some.Namespace.Path renaming def1 → def1', def2 → def2'same asopen Some.Namespace.Path (def1 def2)butdef1/def2's names are changed todef1'/def2'.This works even if
def1anddef2areprotected.open scoped Some.Namespace.Path1 Some.Namespace.Path2only opens [scoped instances], notations, and attributes fromNamespace1andNamespace2; it does not make any other name available.open <any of the open shapes above> inmakes the namesopen-ed visible only in the next command or expression.
Examples #
/-- SKI combinators https://en.wikipedia.org/wiki/SKI_combinator_calculus -/
namespace Combinator.Calculus
def I (a : α) : α := a
def K (a : α) : β → α := fun _ => a
def S (x : α → β → γ) (y : α → β) (z : α) : γ := x z (y z)
end Combinator.Calculus
section
-- open everything under `Combinator.Calculus`, *i.e.* `I`, `K` and `S`,
-- until the section ends
open Combinator.Calculus
theorem SKx_eq_K : S K x = I := rfl
end
-- open everything under `Combinator.Calculus` only for the next command (the next `theorem`, here)
open Combinator.Calculus in
theorem SKx_eq_K' : S K x = I := rfl
section
-- open only `S` and `K` under `Combinator.Calculus`
open Combinator.Calculus (S K)
theorem SKxy_eq_y : S K x y = y := rfl
-- `I` is not in scope, we have to use its full path
theorem SKxy_eq_Iy : S K x y = Combinator.Calculus.I y := rfl
end
section
open Combinator.Calculus
renaming
I → identity,
K → konstant
#check identity
#check konstant
end
section
open Combinator.Calculus
hiding S
#check I
#check K
end
section
namespace Demo
inductive MyType
| val
namespace N1
scoped infix:68 " ≋ " => BEq.beq
scoped instance : BEq MyType where
beq _ _ := true
def Alias := MyType
end N1
end Demo
-- bring `≋` and the instance in scope, but not `Alias`
open scoped Demo.N1
#check Demo.MyType.val == Demo.MyType.val
#check Demo.MyType.val ≋ Demo.MyType.val
-- #check Alias -- unknown identifier 'Alias'
end
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Adds a docstring to an existing declaration, replacing any existing docstring.
The provided docstring should be written as a docstring for the add_decl_doc command, as in
/-- My new docstring -/
add_decl_doc oldDeclaration
This is useful for auto-generated declarations for which there is no place to write a docstring in the source code.
Parent projections in structures are an example of this:
structure Triple (α β γ : Type) extends Prod α β where
thrd : γ
/-- Extracts the first two projections of a triple. -/
add_decl_doc Triple.toProd
Documentation can only be added to declarations in the same module.
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Register a tactic tag, saving its user-facing name and docstring.
Tactic tags can be used by documentation generation tools to classify related tactics.
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Add more documentation as an extension of the documentation for a given tactic.
The extended documentation is placed in the command's docstring. It is shown as part of a bulleted list, so it should be brief.
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This is an auxiliary command for generation constructor injectivity theorems for
inductive types defined at Prelude.lean.
It is meant for bootstrapping purposes only.
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include eeny meeny instructs Lean to include the section variables eeny and meeny in all
theorems in the remainder of the current section, differing from the default behavior of
conditionally including variables based on use in the theorem header. Other commands are
not affected. include is usually followed by in theorem ... to limit the inclusion
to the subsequent declaration.
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omit instructs Lean to not include a variable previously included. Apart from variable names, it
can also refer to typeclass instance variables by type using the syntax omit [TypeOfInst], in
which case all instance variables that unify with the given type are omitted. omit should usually
only be used in conjunction with in in order to keep the section structure simple.
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No-op parser used as syntax kind for attaching remaining whitespace at the end of the input.
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declModifiers is the collection of modifiers on a declaration:
- a doc comment
/-- ... -/ - a list of attributes
@[attr1, attr2] - a visibility specifier,
privateorprotected noncomputableunsafepartialornonrec
All modifiers are optional, and have to come in the listed order.
nestedDeclModifiers is the same as declModifiers, but attributes are printed
on the same line as the declaration. It is used for declarations nested inside other syntax,
such as inductive constructors, structure projections, and let rec / where definitions.
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declModifiers is the collection of modifiers on a declaration:
- a doc comment
/-- ... -/ - a list of attributes
@[attr1, attr2] - a visibility specifier,
privateorprotected noncomputableunsafepartialornonrec
All modifiers are optional, and have to come in the listed order.
nestedDeclModifiers is the same as declModifiers, but attributes are printed
on the same line as the declaration. It is used for declarations nested inside other syntax,
such as inductive constructors, structure projections, and let rec / where definitions.
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set_option opt val in e is like set_option opt val but scoped to a single term.
It sets the option opt to the value val in the term e.
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set_option opt val in tacs (the tactic) acts like set_option opt val at the command level,
but it sets the option only within the tactics tacs.
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