- natVal: Nat → Lean.Literal
Natural number literal
- strVal: String → Lean.Literal
String literal
Literal values for Expr
.
Instances For
Equations
- Lean.instInhabitedLiteral = { default := Lean.Literal.natVal default }
Equations
- Lean.instBEqLiteral = { beq := Lean.beqLiteral✝ }
Equations
- Lean.instReprLiteral = { reprPrec := Lean.reprLiteral✝ }
Equations
- Lean.Literal.hash x = match x with | Lean.Literal.natVal v => hash v | Lean.Literal.strVal v => hash v
Instances For
Equations
- Lean.instHashableLiteral = { hash := Lean.Literal.hash }
Total order on Expr
literal values.
Natural number values are smaller than string literal values.
Equations
- One or more equations did not get rendered due to their size.
Instances For
Equations
- Lean.instLTLiteral = { lt := fun a b => Lean.Literal.lt a b = true }
Equations
- default: Lean.BinderInfo
Default binder annotation, e.g.
(x : α)
- implicit: Lean.BinderInfo
Implicit binder annotation, e.g.,
{x : α}
- strictImplicit: Lean.BinderInfo
Strict implict binder annotation, e.g.,
{{ x : α }}
- instImplicit: Lean.BinderInfo
Local instance binder annotataion, e.g.,
[Decidable α]
Arguments in forallE binders can be labelled as implicit or explicit.
Each lam
or forallE
binder comes with a binderInfo
argument (stored in ExprData).
This can be set to
default
--(x : α)
implicit
--{x : α}
strict_implicit
--⦃x : α⦄
inst_implicit
--[x : α]
.aux_decl
-- Auxillary definitions are helper methods that Lean generates.aux_decl
is used for_match
,_fun_match
,_let_match
and the self reference that appears in recursive pattern matching.
The difference between implicit {}
and strict-implicit ⦃⦄
is how
implicit arguments are treated that are not followed by explicit arguments.
{}
arguments are applied eagerly, while ⦃⦄
arguments are left partially applied:
def foo {x : Nat} : Nat := x
def bar ⦃x : Nat⦄ : Nat := x
#check foo -- foo : Nat
#check bar -- bar : ⦃x : Nat⦄ → Nat
See also the Lean manual: https://lean-lang.org/lean4/doc/expressions.html#implicit-arguments
Instances For
Equations
- Lean.instInhabitedBinderInfo = { default := Lean.BinderInfo.default }
Equations
- Lean.instBEqBinderInfo = { beq := Lean.beqBinderInfo✝ }
Equations
- Lean.instReprBinderInfo = { reprPrec := Lean.reprBinderInfo✝ }
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- One or more equations did not get rendered due to their size.
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Return true
if the given BinderInfo
does not correspond to an implicit binder annotation
(i.e., implicit
, strictImplicit
, or instImplicit
).
Equations
- Lean.BinderInfo.isExplicit x = match x with | Lean.BinderInfo.implicit => false | Lean.BinderInfo.strictImplicit => false | Lean.BinderInfo.instImplicit => false | x => true
Instances For
Equations
- Lean.instHashableBinderInfo = { hash := Lean.BinderInfo.hash }
Return true
if the given BinderInfo
is an instance implicit annotation (e.g., [Decidable α]
)
Equations
- Lean.BinderInfo.isInstImplicit x = match x with | Lean.BinderInfo.instImplicit => true | x => false
Instances For
Return true
if the given BinderInfo
is a regular implicit annotation (e.g., {α : Type u}
)
Equations
- Lean.BinderInfo.isImplicit x = match x with | Lean.BinderInfo.implicit => true | x => false
Instances For
Return true
if the given BinderInfo
is a strict implicit annotation (e.g., {{α : Type u}}
)
Equations
- Lean.BinderInfo.isStrictImplicit x = match x with | Lean.BinderInfo.strictImplicit => true | x => false
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Expression metadata. Used with the Expr.mdata
constructor.
Equations
Instances For
Cached hash code, cached results, and other data for Expr
.
- hash : 32-bits
- approxDepth : 8-bits -- the approximate depth is used to minimize the number of hash collisions
- hasFVar : 1-bit -- does it contain free variables?
- hasExprMVar : 1-bit -- does it contain metavariables?
- hasLevelMVar : 1-bit -- does it contain level metavariables?
- hasLevelParam : 1-bit -- does it contain level parameters?
- looseBVarRange : 20-bits
Remark: this is mostly an internal datastructure used to implement Expr
,
most will never have to use it.
Equations
Instances For
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Equations
- Lean.instBEqData_1 = { beq := fun a b => a == b }
Equations
- Lean.Expr.Data.approxDepth c = UInt64.toUInt8 (UInt64.land (UInt64.shiftRight c 32) 255)
Instances For
Equations
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Equations
- Lean.Expr.Data.hasFVar c = (UInt64.land (UInt64.shiftRight c 40) 1 == 1)
Instances For
Equations
- Lean.Expr.Data.hasExprMVar c = (UInt64.land (UInt64.shiftRight c 41) 1 == 1)
Instances For
Equations
- Lean.Expr.Data.hasLevelMVar c = (UInt64.land (UInt64.shiftRight c 42) 1 == 1)
Instances For
Equations
- Lean.Expr.Data.hasLevelParam c = (UInt64.land (UInt64.shiftRight c 43) 1 == 1)
Instances For
Equations
- Lean.BinderInfo.toUInt64 x = match x with | Lean.BinderInfo.default => 0 | Lean.BinderInfo.implicit => 1 | Lean.BinderInfo.strictImplicit => 2 | Lean.BinderInfo.instImplicit => 3
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- One or more equations did not get rendered due to their size.
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Optimized version of Expr.mkData
for applications.
Equations
- One or more equations did not get rendered due to their size.
Instances For
Equations
- Lean.Expr.mkDataForBinder h looseBVarRange approxDepth hasFVar hasExprMVar hasLevelMVar hasLevelParam = Lean.Expr.mkData h looseBVarRange approxDepth hasFVar hasExprMVar hasLevelMVar hasLevelParam
Instances For
Equations
- Lean.Expr.mkDataForLet h looseBVarRange approxDepth hasFVar hasExprMVar hasLevelMVar hasLevelParam = Lean.Expr.mkData h looseBVarRange approxDepth hasFVar hasExprMVar hasLevelMVar hasLevelParam
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Equations
- One or more equations did not get rendered due to their size.
- name : Lake.Name
The unique free variable identifier. It is just a hierarchical name,
but we wrap it in FVarId
to make sure they don't get mixed up with MVarId
.
This is not the user-facing name for a free variable. This information is stored
in the local context (LocalContext
). The unique identifiers are generated using
a NameGenerator
.
Instances For
Equations
- Lean.instInhabitedFVarId = { default := { name := default } }
Equations
- Lean.instBEqFVarId = { beq := Lean.beqFVarId✝ }
Equations
- Lean.instHashableFVarId = { hash := Lean.hashFVarId✝ }
Equations
- Lean.instReprFVarId = { reprPrec := fun n p => reprPrec n.name p }
A set of unique free variable identifiers. This is a persistent data structure implemented using red-black trees.
Equations
- Lean.FVarIdSet = Lean.RBTree Lean.FVarId fun x x_1 => Lean.Name.quickCmp x.name x_1.name
Instances For
Equations
- Lean.instForInFVarIdSetFVarId = inferInstanceAs (ForIn m (Lean.RBTree Lean.FVarId fun x x_1 => Lean.Name.quickCmp x.name x_1.name) Lean.FVarId)
Equations
- Lean.FVarIdSet.insert s fvarId = Lean.RBTree.insert s fvarId
Instances For
A set of unique free variable identifiers implemented using hashtables. Hashtables are faster than red-black trees if they are used linearly. They are not persistent data-structures.
Equations
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A mapping from free variable identifiers to values of type α
.
This is a persistent data structure implemented using red-black trees.
Equations
- Lean.FVarIdMap α = Lean.RBMap Lean.FVarId α fun x x_1 => Lean.Name.quickCmp x.name x_1.name
Instances For
Equations
- Lean.FVarIdMap.insert s fvarId a = Lean.RBMap.insert s fvarId a
Instances For
Equations
- Lean.instEmptyCollectionFVarIdMap = inferInstanceAs (EmptyCollection (Lean.RBMap Lean.FVarId α fun x x_1 => Lean.Name.quickCmp x.name x_1.name))
Equations
- Lean.instInhabitedMVarId = { default := { name := default } }
Equations
- Lean.instBEqMVarId = { beq := Lean.beqMVarId✝ }
Equations
- Lean.instHashableMVarId = { hash := Lean.hashMVarId✝ }
Equations
- Lean.instReprMVarId = { reprPrec := Lean.reprMVarId✝ }
Equations
- Lean.instReprMVarId_1 = { reprPrec := fun n p => reprPrec n.name p }
Equations
- Lean.MVarIdSet = Lean.RBTree Lean.MVarId fun x x_1 => Lean.Name.quickCmp x.name x_1.name
Instances For
Equations
- Lean.MVarIdSet.insert s mvarId = Lean.RBTree.insert s mvarId
Instances For
Equations
- Lean.instForInMVarIdSetMVarId = inferInstanceAs (ForIn m (Lean.RBTree Lean.MVarId fun x x_1 => Lean.Name.quickCmp x.name x_1.name) Lean.MVarId)
Equations
- Lean.MVarIdMap α = Lean.RBMap Lean.MVarId α fun x x_1 => Lean.Name.quickCmp x.name x_1.name
Instances For
Equations
- Lean.MVarIdMap.insert s mvarId a = Lean.RBMap.insert s mvarId a
Instances For
Equations
- Lean.instEmptyCollectionMVarIdMap = inferInstanceAs (EmptyCollection (Lean.RBMap Lean.MVarId α fun x x_1 => Lean.Name.quickCmp x.name x_1.name))
Equations
- Lean.instForInMVarIdMapProdMVarId = inferInstanceAs (ForIn m (Lean.RBMap Lean.MVarId α fun x x_1 => Lean.Name.quickCmp x.name x_1.name) (Lean.MVarId × α))
Instances For
- bvar: Nat → Lean.Expr
The
bvar
constructor represents bound variables, i.e. occurrences of a variable in the expression where there is a variable binder above it (i.e. introduced by alam
,forallE
, orletE
).The
deBruijnIndex
parameter is the de-Bruijn index for the bound variable. See here for additional information on de-Bruijn indexes.For example, consider the expression
fun x : Nat => forall y : Nat, x = y
. Thex
andy
variables in the equality expression are constructed usingbvar
and bound to the binders introduced by the earlierlam
andforallE
constructors. Here is the correspondingExpr
representation for the same expression:.lam `x (.const `Nat []) (.forallE `y (.const `Nat []) (.app (.app (.app (.const `Eq [.succ .zero]) (.const `Nat [])) (.bvar 1)) (.bvar 0)) .default) .default
- fvar: Lean.FVarId → Lean.Expr
The
fvar
constructor represent free variables. These /free/ variable occurrences are not bound by an earlierlam
,forallE
, orletE
contructor and its binder exists in a local context only.Note that Lean uses the /locally nameless approach/. See here for additional details.
When "visiting" the body of a binding expression (i.e.
lam
,forallE
, orletE
), bound variables are converted into free variables using a unique identifier, and their user-facing name, type, value (forLetE
), and binder annotation are stored in theLocalContext
. - mvar: Lean.MVarId → Lean.Expr
Metavariables are used to represent "holes" in expressions, and goals in the tactic framework. Metavariable declarations are stored in the
MetavarContext
. Metavariables are used during elaboration, and are not allowed in the kernel, or in the code generator. - sort: Lean.Level → Lean.Expr
- const: Lake.Name → List Lean.Level → Lean.Expr
A (universe polymorphic) constant that has been defined earlier in the module or by another imported module. For example,
@Eq.{1}
is represented asExpr.const `Eq [.succ .zero]
, and@Array.map.{0, 0}
is represented asExpr.const `Array.map [.zero, .zero]
. - app: Lean.Expr → Lean.Expr → Lean.Expr
A function application.
For example, the natural number one, i.e.
Nat.succ Nat.zero
is represented asExpr.app (.const
Nat.succ []) (.const .zero [])` Note that multiple arguments are represented using partial application.For example, the two argument application
f x y
is represented asExpr.app (.app f x) y
. - lam: Lake.Name → Lean.Expr → Lean.Expr → Lean.BinderInfo → Lean.Expr
- forallE: Lake.Name → Lean.Expr → Lean.Expr → Lean.BinderInfo → Lean.Expr
A dependent arrow
(a : α) → β)
(aka forall-expression) whereβ
may dependent ona
. Note that this constructor is also used to represent non-dependent arrows whereβ
does not depend ona
.For example:
forall x : Prop, x ∧ x
:
Expr.forallE `x (.sort .zero) (.app (.app (.const `And []) (.bvar 0)) (.bvar 0)) .default
Expr.forallE `a (.const `Nat []) (.const `Bool []) .default
- letE: Lake.Name → Lean.Expr → Lean.Expr → Lean.Expr → Bool → Lean.Expr
Let-expressions.
IMPORTANT: The
nonDep
flag is for "local" use only. That is, a module should not "trust" its value for any purpose. In the intended use-case, the compiler will set this flag, and be responsible for maintaining it. Other modules may not preserve its value while applying transformations.Given an environment, a metavariable context, and a local context, we say a let-expression
let x : t := v; e
is non-dependent when it is equivalent to(fun x : t => e) v
. Here is an example of a dependent let-expressionlet n : Nat := 2; fun (a : Array Nat n) (b : Array Nat 2) => a = b
is type correct, but(fun (n : Nat) (a : Array Nat n) (b : Array Nat 2) => a = b) 2
is not.The let-expression
let x : Nat := 2; Nat.succ x
is represented asExpr.letE `x (.const `Nat []) (.lit (.natVal 2)) (.app (.const `Nat.succ []) (.bvar 0)) true
- lit: Lean.Literal → Lean.Expr
Natural number and string literal values.
They are not really needed, but provide a more compact representation in memory for these two kinds of literals, and are used to implement efficient reduction in the elaborator and kernel. The "raw" natural number
2
can be represented asExpr.lit (.natVal 2)
. Note that, it is definitionally equal to:Expr.app (.const `Nat.succ []) (.app (.const `Nat.succ []) (.const `Nat.zero []))
- mdata: Lean.MData → Lean.Expr → Lean.Expr
Metadata (aka annotations).
We use annotations to provide hints to the pretty-printer, store references to
Syntax
nodes, position information, and save information for elaboration procedures (e.g., we use theinaccessible
annotation during elaboration to markExpr
s that correspond to inaccessible patterns).Note that
Expr.mdata data e
is definitionally equal toe
. - proj: Lake.Name → Nat → Lean.Expr → Lean.Expr
Projection-expressions. They are redundant, but are used to create more compact terms, speedup reduction, and implement eta for structures. The type of
struct
must be an structure-like inductive type. That is, it has only one constructor, is not recursive, and it is not an inductive predicate. The kernel and elaborators check whether thetypeName
matches the type ofstruct
, and whether the (zero-based) index is valid (i.e., it is smaller than the numbef of constructor fields). When exporting Lean developments to other systems,proj
can be replaced withtypeName
.rec
applications.Example, given
a : Nat x Bool
,a.1
is represented as.proj `Prod 0 a
Lean expressions. This data structure is used in the kernel and elaborator. However, expressions sent to the kernel should not contain metavariables.
Remark: we use the E
suffix (short for Expr
) to avoid collision with keywords.
We considered using «...», but it is too inconvenient to use.
Instances For
Equations
- Lean.instInhabitedExpr = { default := Lean.Expr.bvar default }
Equations
- Lean.instReprExpr = { reprPrec := Lean.reprExpr✝ }
The constructor name for the given expression. This is used for debugging purposes.
Equations
- One or more equations did not get rendered due to their size.
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Equations
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Equations
- Lean.Expr.instHashableExpr = { hash := Lean.Expr.hash }
Return true
if e
contains free variables.
This is a constant time operation.
Equations
Instances For
Return true
if e
contains expression metavariables.
This is a constant time operation.
Equations
Instances For
Return true
if e
contains universe (aka Level
) metavariables.
This is a constant time operation.
Equations
Instances For
Does the expression contain level (aka universe) or expression metavariables? This is a constant time operation.
Equations
- Lean.Expr.hasMVar e = let d := Lean.Expr.data e; Lean.Expr.Data.hasExprMVar d || Lean.Expr.Data.hasLevelMVar d
Instances For
Return true if e
contains universe level parameters.
This is a constant time operation.
Equations
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Return the approximated depth of an expression. This information is used to compute
the expression hash code, and speedup comparisons.
This is a constant time operation. We say it is approximate because it maxes out at 255
.
Equations
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The range of de-Bruijn variables that are loose.
That is, bvars that are not bound by a binder.
For example, bvar i
has range i + 1
and
an expression with no loose bvars has range 0
.
Equations
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Return the binder information if e
is a lambda or forall expression, and .default
otherwise.
Equations
- Lean.Expr.binderInfo e = match e with | Lean.Expr.forallE binderName binderType body bi => bi | Lean.Expr.lam binderName binderType body bi => bi | x => Lean.BinderInfo.default
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Export functions.
Equations
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mkConst declName us
return .const declName us
.
Equations
- Lean.mkConst declName us = Lean.Expr.const declName us
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Return the type of a literal value.
Equations
- Lean.Literal.type x = match x with | Lean.Literal.natVal val => Lean.mkConst `Nat | Lean.Literal.strVal val => Lean.mkConst `String
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Equations
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.fvar fvarId
is now the preferred form.
This function is seldom used, free variables are often automatically created using the
telescope functions (e.g., forallTelescope
and lambdaTelescope
) at MetaM
.
Equations
- Lean.mkFVar fvarId = Lean.Expr.fvar fvarId
Instances For
.mvar mvarId
is now the preferred form.
This function is seldom used, metavariables are often created using functions such
as mkFresheExprMVar
at MetaM
.
Equations
- Lean.mkMVar mvarId = Lean.Expr.mvar mvarId
Instances For
.proj structName idx struct
is now the preferred form.
Equations
- Lean.mkProj structName idx struct = Lean.Expr.proj structName idx struct
Instances For
.lam x t b bi
is now the preferred form.
Equations
- Lean.mkLambda x bi t b = Lean.Expr.lam x t b bi
Instances For
.forallE x t b bi
is now the preferred form.
Equations
- Lean.mkForall x bi t b = Lean.Expr.forallE x t b bi
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Return Unit -> type
. Do not confuse with Thunk type
Equations
- Lean.mkSimpleThunkType type = Lean.mkForall Lean.Name.anonymous Lean.BinderInfo.default (Lean.mkConst `Unit) type
Instances For
Return fun (_ : Unit), e
Equations
- Lean.mkSimpleThunk type = Lean.mkLambda `_ Lean.BinderInfo.default (Lean.mkConst `Unit) type
Instances For
.letE x t v b nonDep
is now the preferred form.
Equations
- Lean.mkLet x t v b nonDep = Lean.Expr.letE x t v b nonDep
Instances For
Equations
- Lean.mkAppB f a b = Lean.mkApp (Lean.mkApp f a) b
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Equations
- Lean.mkApp2 f a b = Lean.mkAppB f a b
Instances For
Equations
- Lean.mkApp3 f a b c = Lean.mkApp (Lean.mkAppB f a b) c
Instances For
Equations
- Lean.mkApp4 f a b c d = Lean.mkAppB (Lean.mkAppB f a b) c d
Instances For
Equations
- Lean.mkApp5 f a b c d e = Lean.mkApp (Lean.mkApp4 f a b c d) e
Instances For
Equations
- Lean.mkApp6 f a b c d e₁ e₂ = Lean.mkAppB (Lean.mkApp4 f a b c d) e₁ e₂
Instances For
Equations
- Lean.mkApp7 f a b c d e₁ e₂ e₃ = Lean.mkApp3 (Lean.mkApp4 f a b c d) e₁ e₂ e₃
Instances For
Equations
- Lean.mkApp8 f a b c d e₁ e₂ e₃ e₄ = Lean.mkApp4 (Lean.mkApp4 f a b c d) e₁ e₂ e₃ e₄
Instances For
Equations
- Lean.mkApp9 f a b c d e₁ e₂ e₃ e₄ e₅ = Lean.mkApp5 (Lean.mkApp4 f a b c d) e₁ e₂ e₃ e₄ e₅
Instances For
Equations
- Lean.mkApp10 f a b c d e₁ e₂ e₃ e₄ e₅ e₆ = Lean.mkApp6 (Lean.mkApp4 f a b c d) e₁ e₂ e₃ e₄ e₅ e₆
Instances For
Return a natural number literal used in the frontend. It is a OfNat.ofNat
application.
Recall that all theorems and definitions containing numeric literals are encoded using
OfNat.ofNat
applications in the frontend.
Equations
- Lean.mkNatLit n = let r := Lean.mkRawNatLit n; Lean.mkApp3 (Lean.mkConst `OfNat.ofNat [Lean.levelZero]) (Lean.mkConst `Nat) r (Lean.mkApp (Lean.mkConst `instOfNatNat) r)
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- Lean.mkLambdaEx n d b bi = Lean.mkLambda n bi d b
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Equations
- Lean.mkForallEx n d b bi = Lean.mkForall n bi d b
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mkAppN f #[a₀, ..., aₙ]
==> f a₀ a₁ .. aₙ
Equations
- Lean.mkAppN f args = Array.foldl Lean.mkApp f args 0 (Array.size args)
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mkAppRange f i j #[a_1, ..., a_i, ..., a_j, ... ]
==> the expression f a_i ... a_{j-1}
Equations
- Lean.mkAppRange f i j args = Lean.mkAppRangeAux j args i f
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Same as mkApp f args
but reversing args
.
Equations
- Lean.mkAppRev fn revArgs = Array.foldr (fun a r => Lean.mkApp r a) fn revArgs (Array.size revArgs)
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A total order for expressions. We say it is quick because it first compares the hashcodes.
A total order for expressions that takes the structure into account (e.g., variable names).
Return true iff a
and b
are alpha equivalent.
Binder annotations are ignored.
Equations
- Lean.Expr.instBEqExpr = { beq := Lean.Expr.eqv }
Return true iff a
and b
are equal.
Binder names and annotations are taking into account.
Return true
if the given expression is a .sort ..
Equations
- Lean.Expr.isSort x = match x with | Lean.Expr.sort u => true | x => false
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Return true
if the given expression is of the form .sort (.succ ..)
.
Equations
- Lean.Expr.isType x = match x with | Lean.Expr.sort (Lean.Level.succ a) => true | x => false
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Return true
if the given expression is of the form .sort (.succ .zero)
.
Equations
- Lean.Expr.isType0 x = match x with | Lean.Expr.sort (Lean.Level.succ Lean.Level.zero) => true | x => false
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Return true
if the given expression is a .sort .zero
Equations
- Lean.Expr.isProp x = match x with | Lean.Expr.sort Lean.Level.zero => true | x => false
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Return true
if the given expression is a bound variable.
Equations
- Lean.Expr.isBVar x = match x with | Lean.Expr.bvar deBruijnIndex => true | x => false
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Return true
if the given expression is a metavariable.
Equations
- Lean.Expr.isMVar x = match x with | Lean.Expr.mvar mvarId => true | x => false
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Return true
if the given expression is a free variable.
Equations
- Lean.Expr.isFVar x = match x with | Lean.Expr.fvar fvarId => true | x => false
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Return true
if the given expression is an application.
Equations
- Lean.Expr.isApp x = match x with | Lean.Expr.app fn arg => true | x => false
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Return true
if the given expression is a projection .proj ..
Equations
- Lean.Expr.isProj x = match x with | Lean.Expr.proj typeName idx struct => true | x => false
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Return true
if the given expression is a constant.
Equations
- Lean.Expr.isConst x = match x with | Lean.Expr.const declName us => true | x => false
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Return true
if the given expression is a constant of the give name.
Examples:
Equations
- Lean.Expr.isConstOf x x = match x, x with | Lean.Expr.const n us, m => n == m | x, x_1 => false
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Return true
if the given expression is a free variable with the given id.
Examples:
isFVarOf (.fvar id) id
istrue
isFVarOf (.fvar id) id'
isfalse
isFVarOf (.sort levelZero) id
isfalse
Equations
- Lean.Expr.isFVarOf x x = match x, x with | Lean.Expr.fvar fvarId, fvarId' => fvarId == fvarId' | x, x_1 => false
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Return true
if the given expression is a forall-expression aka (dependent) arrow.
Equations
- Lean.Expr.isForall x = match x with | Lean.Expr.forallE binderName binderType body binderInfo => true | x => false
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Return true
if the given expression is a lambda abstraction aka anonymous function.
Equations
- Lean.Expr.isLambda x = match x with | Lean.Expr.lam binderName binderType body binderInfo => true | x => false
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Return true
if the given expression is a forall or lambda expression.
Equations
- Lean.Expr.isBinding x = match x with | Lean.Expr.lam binderName binderType body binderInfo => true | Lean.Expr.forallE binderName binderType body binderInfo => true | x => false
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Return true
if the given expression is a let-expression.
Equations
- Lean.Expr.isLet x = match x with | Lean.Expr.letE declName type value body nonDep => true | x => false
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Return true
if the given expression is a metadata.
Equations
- Lean.Expr.isMData x = match x with | Lean.Expr.mdata data expr => true | x => false
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Return true
if the given expression is a literal value.
Equations
- Lean.Expr.isLit x = match x with | Lean.Expr.lit a => true | x => false
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Return the "body" of a forall expression.
Example: let e
be the representation for forall (p : Prop) (q : Prop), p ∧ q
, then
getForallBody e
returns .app (.app (.const `And []) (.bvar 1)) (.bvar 0)
Equations
- Lean.Expr.getForallBody (Lean.Expr.forallE binderName binderType body binderInfo) = Lean.Expr.getForallBody body
- Lean.Expr.getForallBody x = x
Instances For
Equations
- Lean.Expr.getForallBodyMaxDepth (Nat.succ n) (Lean.Expr.forallE binderName binderType b binderInfo) = Lean.Expr.getForallBodyMaxDepth n b
- Lean.Expr.getForallBodyMaxDepth 0 x = x
- Lean.Expr.getForallBodyMaxDepth x x = x
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Given a sequence of nested foralls (a₁ : α₁) → ... → (aₙ : αₙ) → _
,
returns the names [a₁, ... aₙ]
.
Equations
- Lean.Expr.getForallBinderNames (Lean.Expr.forallE binderName binderType body binderInfo) = binderName :: Lean.Expr.getForallBinderNames body
- Lean.Expr.getForallBinderNames x = []
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If the given expression is a sequence of
function applications f a₁ .. aₙ
, return f
.
Otherwise return the input expression.
Equations
- Lean.Expr.getAppFn (Lean.Expr.app fn arg) = Lean.Expr.getAppFn fn
- Lean.Expr.getAppFn x = x
Instances For
Counts the number n
of arguments for an expression f a₁ .. aₙ
.
Equations
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Given f a₁ a₂ ... aₙ
, returns #[a₁, ..., aₙ]
Equations
- Lean.Expr.getAppArgs e = let dummy := Lean.mkSort Lean.levelZero; let nargs := Lean.Expr.getAppNumArgs e; Lean.Expr.getAppArgsAux e (mkArray nargs dummy) (nargs - 1)
Instances For
Equations
- Lean.Expr.withAppAux k (Lean.Expr.app f a) x x = Lean.Expr.withAppAux k f (Array.set! x x a) (x - 1)
- Lean.Expr.withAppAux k x x x = k x x
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Given e = f a₁ a₂ ... aₙ
, returns k f #[a₁, ..., aₙ]
.
Equations
- Lean.Expr.withApp e k = let dummy := Lean.mkSort Lean.levelZero; let nargs := Lean.Expr.getAppNumArgs e; Lean.Expr.withAppAux k e (mkArray nargs dummy) (nargs - 1)
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Given e = fn a₁ ... aₙ
, runs f
on fn
and each of the arguments aᵢ
and
makes a new function application with the results.
Equations
- Lean.Expr.traverseApp f e = Lean.Expr.withApp e fun fn args => Seq.seq (Lean.mkAppN <$> f fn) fun x => Array.mapM f args
Instances For
Equations
- Lean.Expr.getRevArgD (Lean.Expr.app fn a) 0 x = a
- Lean.Expr.getRevArgD (Lean.Expr.app f arg) (Nat.succ i) x = Lean.Expr.getRevArgD f i x
- Lean.Expr.getRevArgD x x x = x
Instances For
Equations
- Lean.Expr.getRevArg! (Lean.Expr.app fn a) 0 = a
- Lean.Expr.getRevArg! (Lean.Expr.app f arg) (Nat.succ i) = Lean.Expr.getRevArg! f i
- Lean.Expr.getRevArg! x x = panicWithPosWithDecl "Lean.Expr" "Lean.Expr.getRevArg!" 972 20 "invalid index"
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Given f a₀ a₁ ... aₙ
, returns the i
th argument or panics if out of bounds.
Equations
- Lean.Expr.getArg! e i n = Lean.Expr.getRevArg! e (n - i - 1)
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Given f a₀ a₁ ... aₙ
, returns the i
th argument or returns v₀
if out of bounds.
Equations
- Lean.Expr.getArgD e i v₀ n = Lean.Expr.getRevArgD e (n - i - 1) v₀
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Given f a₀ a₁ ... aₙ
, returns true if f
is a constant with name n
.
Equations
- Lean.Expr.isAppOf e n = match Lean.Expr.getAppFn e with | Lean.Expr.const c us => c == n | x => false
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Given f a₁ ... aᵢ
, returns true if f
is a constant
with name n
and has the correct number of arguments.
Equations
- Lean.Expr.isAppOfArity (Lean.Expr.const c us) x 0 = (c == x)
- Lean.Expr.isAppOfArity (Lean.Expr.app f arg) x (Nat.succ a) = Lean.Expr.isAppOfArity f x a
- Lean.Expr.isAppOfArity x x x = false
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Similar to isAppOfArity
but skips Expr.mdata
.
Equations
- Lean.Expr.isAppOfArity' (Lean.Expr.mdata data b) x x = Lean.Expr.isAppOfArity' b x x
- Lean.Expr.isAppOfArity' (Lean.Expr.const c us) x 0 = (c == x)
- Lean.Expr.isAppOfArity' (Lean.Expr.app f arg) x (Nat.succ a) = Lean.Expr.isAppOfArity' f x a
- Lean.Expr.isAppOfArity' x x x = false
Instances For
Equations
- Lean.Expr.appFn! x = match x with | Lean.Expr.app f arg => f | x => panicWithPosWithDecl "Lean.Expr" "Lean.Expr.appFn!" 1006 15 "application expected"
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Equations
- Lean.Expr.appArg! x = match x with | Lean.Expr.app fn a => a | x => panicWithPosWithDecl "Lean.Expr" "Lean.Expr.appArg!" 1010 15 "application expected"
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Equations
- Lean.Expr.appFn!' (Lean.Expr.mdata data b) = Lean.Expr.appFn!' b
- Lean.Expr.appFn!' (Lean.Expr.app f arg) = f
- Lean.Expr.appFn!' x = panicWithPosWithDecl "Lean.Expr" "Lean.Expr.appFn!'" 1015 17 "application expected"
Instances For
Equations
- Lean.Expr.appArg!' (Lean.Expr.mdata data b) = Lean.Expr.appArg!' b
- Lean.Expr.appArg!' (Lean.Expr.app f arg) = arg
- Lean.Expr.appArg!' x = panicWithPosWithDecl "Lean.Expr" "Lean.Expr.appArg!'" 1020 17 "application expected"
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Equations
- Lean.Expr.sortLevel! x = match x with | Lean.Expr.sort u => u | x => panicWithPosWithDecl "Lean.Expr" "Lean.Expr.sortLevel!" 1024 14 "sort expected"
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Equations
- Lean.Expr.litValue! x = match x with | Lean.Expr.lit v => v | x => panicWithPosWithDecl "Lean.Expr" "Lean.Expr.litValue!" 1028 13 "literal expected"
Instances For
Equations
- Lean.Expr.isNatLit x = match x with | Lean.Expr.lit (Lean.Literal.natVal val) => true | x => false
Instances For
Equations
- Lean.Expr.natLit? x = match x with | Lean.Expr.lit (Lean.Literal.natVal v) => some v | x => none
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Equations
- Lean.Expr.isStringLit x = match x with | Lean.Expr.lit (Lean.Literal.strVal val) => true | x => false
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Equations
- Lean.Expr.isCharLit e = (Lean.Expr.isAppOfArity e `Char.ofNat 1 && Lean.Expr.isNatLit (Lean.Expr.appArg! e))
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Equations
- Lean.Expr.constName! x = match x with | Lean.Expr.const n us => n | x => panicWithPosWithDecl "Lean.Expr" "Lean.Expr.constName!" 1047 17 "constant expected"
Instances For
Equations
- Lean.Expr.constName? x = match x with | Lean.Expr.const n us => some n | x => none
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Equations
- Lean.Expr.bvarIdx! x = match x with | Lean.Expr.bvar idx => idx | x => panicWithPosWithDecl "Lean.Expr" "Lean.Expr.bvarIdx!" 1059 16 "bvar expected"
Instances For
Equations
- Lean.Expr.fvarId! x = match x with | Lean.Expr.fvar n => n | x => panicWithPosWithDecl "Lean.Expr" "Lean.Expr.fvarId!" 1063 14 "fvar expected"
Instances For
Equations
- Lean.Expr.mvarId! x = match x with | Lean.Expr.mvar n => n | x => panicWithPosWithDecl "Lean.Expr" "Lean.Expr.mvarId!" 1067 14 "mvar expected"
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- Lean.Expr.consumeMData (Lean.Expr.mdata data expr) = Lean.Expr.consumeMData expr
- Lean.Expr.consumeMData x = x
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Return true
if e
is a non-dependent arrow.
Remark: the following function assumes e
does not have loose bound variables.
Equations
- Lean.Expr.isArrow e = match e with | Lean.Expr.forallE binderName binderType b binderInfo => !Lean.Expr.hasLooseBVars b | x => false
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Return true if e
contains the loose bound variable bvarIdx
in an explicit parameter, or in the range if tryRange == true
.
Equations
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- Lean.Expr.hasLooseBVarInExplicitDomain x x x = (x && Lean.Expr.hasLooseBVar x x)
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inferImplicit e numParams considerRange
updates the first numParams
parameter binder annotations of the e
forall type.
It marks any parameter with an explicit binder annotation if there is another explicit arguments that depends on it or
the resulting type if considerRange == true
.
Remark: we use this function to infer the bind annotations of inductive datatype constructors, and structure projections.
When the {}
annotation is used in these commands, we set considerRange == false
.
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Similar to instantiate
, but consider only the variables xs
in the range [beginIdx, endIdx)
.
Function panics if beginIdx <= endIdx <= xs.size
does not hold.
Similar to instantiateRev
, but consider only the variables xs
in the range [beginIdx, endIdx)
.
Function panics if beginIdx <= endIdx <= xs.size
does not hold.
Replace occurrences of the free variable fvar
in e
with v
Equations
- Lean.Expr.replaceFVar e fvar v = Lean.Expr.instantiate1 (Lean.Expr.abstract e #[fvar]) v
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Replace occurrences of the free variable fvarId
in e
with v
Equations
- Lean.Expr.replaceFVarId e fvarId v = Lean.Expr.replaceFVar e (Lean.mkFVar fvarId) v
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Replace occurrences of the free variables fvars
in e
with vs
Equations
- Lean.Expr.replaceFVars e fvars vs = Lean.Expr.instantiateRev (Lean.Expr.abstract e fvars) vs
Instances For
Equations
- Lean.Expr.instToStringExpr = { toString := Lean.Expr.dbgToString }
Returns true when the expression does not have any sub-expressions.
Equations
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Equations
- Lean.mkDecIsTrue pred proof = Lean.mkAppB (Lean.mkConst `Decidable.isTrue) pred proof
Instances For
Equations
- Lean.mkDecIsFalse pred proof = Lean.mkAppB (Lean.mkConst `Decidable.isFalse) pred proof
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- Lean.instInhabitedExprStructEq = { default := { val := default } }
Equations
- Lean.instCoeExprExprStructEq = { coe := Lean.ExprStructEq.mk }
Equations
- Lean.ExprStructEq.beq x x = match x, x with | { val := e₁ }, { val := e₂ } => Lean.Expr.equal e₁ e₂
Instances For
Equations
- Lean.ExprStructEq.hash x = match x with | { val := e } => Lean.Expr.hash e
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Equations
- Lean.ExprStructEq.instToStringExprStructEq = { toString := fun e => toString e.val }
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mkAppRevRange f b e args == mkAppRev f (revArgs.extract b e)
Equations
- Lean.Expr.mkAppRevRange f beginIdx endIdx revArgs = Lean.Expr.mkAppRevRangeAux revArgs beginIdx f endIdx
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If f
is a lambda expression, than "beta-reduce" it using revArgs
.
This function is often used with getAppRev
or withAppRev
.
Examples:
betaRev (fun x y => t x y) #[]
==>fun x y => t x y
betaRev (fun x y => t x y) #[a]
==>fun y => t a y
betaRev (fun x y => t x y) #[a, b]
==>t b a
betaRev (fun x y => t x y) #[a, b, c, d]
==>t d c b a
Supposet
is(fun x y => t x y) a b c d
, thenargs := t.getAppRev
is#[d, c, b, a]
, andbetaRev (fun x y => t x y) #[d, c, b, a]
ist a b c d
.
If useZeta
is true, the function also performs zeta-reduction (reduction of let binders) to create further
opportunities for beta reduction.
Equations
- Lean.Expr.betaRev f revArgs useZeta preserveMData = if (Array.size revArgs == 0) = true then f else let sz := Array.size revArgs; Lean.Expr.betaRev.go revArgs useZeta preserveMData sz f 0
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Apply the given arguments to f
, beta-reducing if f
is a
lambda expression. See docstring for betaRev
for examples.
Equations
- Lean.Expr.beta f args = Lean.Expr.betaRev f (Array.reverse args) false
Instances For
Return true if the given expression is the function of an expression that is target for (head) beta reduction.
If useZeta = true
, then let
-expressions are visited. That is, it assumes
that zeta-reduction (aka let-expansion) is going to be used.
See isHeadBetaTarget
.
Equations
- Lean.Expr.isHeadBetaTargetFn useZeta (Lean.Expr.lam binderName binderType b binderInfo) = true
- Lean.Expr.isHeadBetaTargetFn useZeta (Lean.Expr.letE declName type v b nonDep) = (useZeta && Lean.Expr.isHeadBetaTargetFn useZeta b)
- Lean.Expr.isHeadBetaTargetFn useZeta (Lean.Expr.mdata k b) = Lean.Expr.isHeadBetaTargetFn useZeta b
- Lean.Expr.isHeadBetaTargetFn useZeta x = false
Instances For
(fun x => e) a
==> e[x/a]
.
Equations
- Lean.Expr.headBeta e = let f := Lean.Expr.getAppFn e; if Lean.Expr.isHeadBetaTargetFn false f = true then Lean.Expr.betaRev f (Lean.Expr.getAppRevArgs e) false else e
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Return true if the given expression is a target for (head) beta reduction.
If useZeta = true
, then let
-expressions are visited. That is, it assumes
that zeta-reduction (aka let-expansion) is going to be used.
Equations
- Lean.Expr.isHeadBetaTarget e useZeta = (Lean.Expr.isApp e && Lean.Expr.isHeadBetaTargetFn useZeta (Lean.Expr.getAppFn e))
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If e
is of the form (fun x₁ ... xₙ => f x₁ ... xₙ)
and f
does not contain x₁
, ..., xₙ
,
then return some f
. Otherwise, return none
.
It assumes e
does not have loose bound variables.
Remark: ₙ
may be 0
Equations
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Similar to etaExpanded?
, but only succeeds if ₙ ≥ 1
.
Equations
- Lean.Expr.etaExpandedStrict? x = match x with | Lean.Expr.lam binderName binderType b binderInfo => Lean.Expr.etaExpandedAux b 1 | x => none
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Return some e'
if e
is of the form optParam _ e'
Equations
- Lean.Expr.getOptParamDefault? e = if Lean.Expr.isAppOfArity e `optParam 2 = true then some (Lean.Expr.appArg! e) else none
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Return some e'
if e
is of the form autoParam _ e'
Equations
- Lean.Expr.getAutoParamTactic? e = if Lean.Expr.isAppOfArity e `autoParam 2 = true then some (Lean.Expr.appArg! e) else none
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Return true
if e
is of the form outParam _
Equations
- Lean.Expr.isOutParam e = Lean.Expr.isAppOfArity e `outParam 1
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Return true
if e
is of the form semiOutParam _
Equations
- Lean.Expr.isSemiOutParam e = Lean.Expr.isAppOfArity e `semiOutParam 1
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Return true
if e
is of the form optParam _ _
Equations
- Lean.Expr.isOptParam e = Lean.Expr.isAppOfArity e `optParam 2
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Return true
if e
is of the form autoParam _ _
Equations
- Lean.Expr.isAutoParam e = Lean.Expr.isAppOfArity e `autoParam 2
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Remove outParam
, optParam
, and autoParam
applications/annotations from e
.
Note that it does not remove nested annotations.
Examples:
- Given
e
of the formoutParam (optParam Nat b)
,consumeTypeAnnotations e = b
. - Given
e
of the formNat → outParam (optParam Nat b)
,consumeTypeAnnotations e = e
.
Remove metadata annotations and outParam
, optParam
, and autoParam
applications/annotations from e
.
Note that it does not remove nested annotations.
Examples:
- Given
e
of the formoutParam (optParam Nat b)
,cleanupAnnotations e = b
. - Given
e
of the formNat → outParam (optParam Nat b)
,cleanupAnnotations e = e
.
Return true iff e
contains a free variable which statisfies p
.
Equations
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Return true
if e
contains the given free variable.
Equations
- Lean.Expr.containsFVar e fvarId = Lean.Expr.hasAnyFVar e fun x => x == fvarId
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The update functions try to avoid allocating new values using pointer equality.
Note that if the update*!
functions are used under a match-expression,
the compiler will eliminate the double-match.
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- Lean.Expr.updateFn (Lean.Expr.app f a) x = Lean.Expr.updateApp! (Lean.Expr.app f a) (Lean.Expr.updateFn f x) a
- Lean.Expr.updateFn x x = x
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Eta reduction. If e
is of the form (fun x => f x)
, then return f
.
Annotate e
with the given option.
The information is stored using metadata around e
.
Equations
- Lean.Expr.setOption e optionName val = Lean.mkMData (Lean.KVMap.set Lean.MData.empty optionName val) e
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Annotate e
with pp.explicit := flag
The delaborator uses pp
options.
Equations
- Lean.Expr.setPPExplicit e flag = Lean.Expr.setOption e `pp.explicit flag
Instances For
Annotate e
with pp.universes := flag
The delaborator uses pp
options.
Equations
- Lean.Expr.setPPUniverses e flag = Lean.Expr.setOption e `pp.universes flag
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If e
is an application f a_1 ... a_n
annotate f
, a_1
... a_n
with pp.explicit := false
,
and annotate e
with pp.explicit := true
.
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Similar for setAppPPExplicit
, but only annotate children with pp.explicit := false
if
e
does not contain metavariables.
Equations
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Annotate e
with the given annotation name kind
.
It uses metadata to store the annotation.
Equations
- Lean.mkAnnotation kind e = Lean.mkMData (Lean.KVMap.insert Lean.KVMap.empty kind (Lean.DataValue.ofBool true)) e
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Return some e'
if e = mkAnnotation kind e'
Equations
- Lean.annotation? kind e = match e with | Lean.Expr.mdata d b => if (Lean.KVMap.size d == 1 && Lean.KVMap.getBool d kind) = true then some b else none | x => none
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Annotate e
with the let_fun
annotation. This annotation is used as hint for the delaborator.
If e
is of the form (fun x : t => b) v
, then mkLetFunAnnotation e
is delaborated at
let_fun x : t := v; b
Equations
- Lean.mkLetFunAnnotation e = Lean.mkAnnotation `let_fun e
Instances For
Return some e'
if e = mkLetFunAnnotation e'
Equations
- Lean.letFunAnnotation? e = Lean.annotation? `let_fun e
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Return true if e = mkLetFunAnnotation e'
, and e'
is of the form (fun x : t => b) v
Equations
- Lean.isLetFun e = match Lean.letFunAnnotation? e with | none => false | some e => Lean.Expr.isApp e && Lean.Expr.isLambda (Lean.Expr.appFn! e)
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Auxiliary annotation used to mark terms marked with the "inaccessible" annotation .(t)
and
_
in patterns.
Equations
- Lean.mkInaccessible e = Lean.mkAnnotation `_inaccessible e
Instances For
Return some e'
if e = mkInaccessible e'
.
Equations
- Lean.inaccessible? e = Lean.annotation? `_inaccessible e
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During elaboration expressions corresponding to pattern matching terms
are annotated with Syntax
objects. This function returns some (stx, p')
if
p
is the pattern p'
annotated with stx
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Annotate the pattern p
with stx
. This is an auxiliary annotation
for producing better hover information.
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Return some p
if e
is an annotated pattern (inaccessible?
or patternWithRef?
)
Equations
- Lean.patternAnnotation? e = match Lean.inaccessible? e with | some e => some e | x => match Lean.patternWithRef? e with | some (fst, e) => some e | x => none
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Annotate e
with the LHS annotation. The delaborator displays
expressions of the form lhs = rhs
as lhs
when they have this annotation.
This is used to implement the infoview for the conv
mode.
This version of mkLHSGoal
does not check that the argument is an equality.
Equations
- Lean.mkLHSGoalRaw e = Lean.mkAnnotation `_lhsGoal e
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Return some lhs
if e = mkLHSGoal e'
, where e'
is of the form lhs = rhs
.
Equations
- Lean.isLHSGoal? e = match Lean.annotation? `_lhsGoal e with | none => none | some e => if Lean.Expr.isAppOfArity e `Eq 3 = true then some (Lean.Expr.appArg! (Lean.Expr.appFn! e)) else none
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Polymorphic operation for generating unique/fresh free variable identifiers.
It is available in any monad m
that implements the inferface MonadNameGenerator
.
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Polymorphic operation for generating unique/fresh metavariable identifiers.
It is available in any monad m
that implements the inferface MonadNameGenerator
.
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Polymorphic operation for generating unique/fresh universe metavariable identifiers.
It is available in any monad m
that implements the inferface MonadNameGenerator
.