Return id e
Equations
- Lean.Meta.mkId e = do let type ← Lean.Meta.inferType e let u ← Lean.Meta.getLevel type pure (Lean.mkApp2 (Lean.mkConst `id [u]) type e)
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Given e s.t. inferType e is definitionally equal to expectedType, return
term @id expectedType e.
Equations
- Lean.Meta.mkExpectedTypeHint e expectedType = do let u ← Lean.Meta.getLevel expectedType pure (Lean.mkApp2 (Lean.mkConst `id [u]) expectedType e)
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mkLetFun x v e creates the encoding for the let_fun x := v; e expression.
The expression x can either be a free variable or a metavariable, and the function suitably abstracts x in e.
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Return a = b.
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- Lean.Meta.mkEq a b = do let aType ← Lean.Meta.inferType a let u ← Lean.Meta.getLevel aType pure (Lean.mkApp3 (Lean.mkConst `Eq [u]) aType a b)
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Return HEq a b.
Equations
- Lean.Meta.mkHEq a b = do let aType ← Lean.Meta.inferType a let bType ← Lean.Meta.inferType b let u ← Lean.Meta.getLevel aType pure (Lean.mkApp4 (Lean.mkConst `HEq [u]) aType a bType b)
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Return a proof of a = a.
Equations
- Lean.Meta.mkEqRefl a = do let aType ← Lean.Meta.inferType a let u ← Lean.Meta.getLevel aType pure (Lean.mkApp2 (Lean.mkConst `Eq.refl [u]) aType a)
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Return a proof of HEq a a.
Equations
- Lean.Meta.mkHEqRefl a = do let aType ← Lean.Meta.inferType a let u ← Lean.Meta.getLevel aType pure (Lean.mkApp2 (Lean.mkConst `HEq.refl [u]) aType a)
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Given hp : P and nhp : Not P returns an instance of type e.
Equations
- Lean.Meta.mkAbsurd e hp hnp = do let p ← Lean.Meta.inferType hp let u ← Lean.Meta.getLevel e pure (Lean.mkApp4 (Lean.mkConst `absurd [u]) p e hp hnp)
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Given h : False, return an instance of type e.
Equations
- Lean.Meta.mkFalseElim e h = do let u ← Lean.Meta.getLevel e pure (Lean.mkApp2 (Lean.mkConst `False.elim [u]) e h)
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Given h : a = b, returns a proof of b = a.
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Given h₁ : a = b and h₂ : b = c returns a proof of a = c.
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Similar to mkEqTrans, but arguments can be none.
none is treated as a reflexivity proof.
Equations
- Lean.Meta.mkEqTrans? none none = pure none
- Lean.Meta.mkEqTrans? none (some h) = pure (some h)
- Lean.Meta.mkEqTrans? (some h) none = pure (some h)
- Lean.Meta.mkEqTrans? (some h₁) (some h₂) = do let a ← Lean.Meta.mkEqTrans h₁ h₂ pure (some a)
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If e is @Eq.refl α a, return a.
Equations
- Lean.Meta.isRefl? e = if e.isAppOfArity `Eq.refl 2 = true then some e.appArg! else none
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If e is @congrArg α β a b f h, return α, f and h.
Also works if e can be turned into such an application (e.g. congrFun).
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Given f : α → β and h : a = b, returns a proof of f a = f b.
Given h : f = g and a : α, returns a proof of f a = g a.
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Given h₁ : f = g and h₂ : a = b, returns a proof of f a = g b.
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Return the application constName xs.
It tries to fill the implicit arguments before the last element in xs.
Remark:
mkAppM `arbitrary #[α] returns @arbitrary.{u} α without synthesizing
the implicit argument occurring after α.
Given a x : ([Decidable p] → Bool) × Nat, mkAppM `Prod.fst #[x] returns @Prod.fst ([Decidable p] → Bool) Nat x.
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Similar to mkAppM, but takes an Expr instead of a constant name.
Equations
- Lean.Meta.mkAppM' f xs = do let fType ← Lean.Meta.inferType f Lean.Meta.withAppBuilderTrace f xs (Lean.Meta.withNewMCtxDepth (Lean.Meta.mkAppMArgs f fType xs))
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Similar to mkAppM, but it allows us to specify which arguments are provided explicitly using Option type.
Example:
Given Pure.pure {m : Type u → Type v} [Pure m] {α : Type u} (a : α) : m α,
mkAppOptM `Pure.pure #[m, none, none, a]
returns a Pure.pure application if the instance Pure m can be synthesized, and the universe match.
Note that,
mkAppM `Pure.pure #[a]
fails because the only explicit argument (a : α) is not sufficient for inferring the remaining arguments,
we would need the expected type.
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Similar to mkAppOptM, but takes an Expr instead of a constant name.
Equations
- Lean.Meta.mkAppOptM' f xs = do let fType ← Lean.Meta.inferType f Lean.Meta.withAppBuilderTrace f xs (Lean.Meta.withNewMCtxDepth (Lean.Meta.mkAppOptMAux f xs 0 #[] 0 #[] fType))
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- Lean.Meta.mkEqMP eqProof pr = Lean.Meta.mkAppM `Eq.mp #[eqProof, pr]
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Equations
- Lean.Meta.mkEqMPR eqProof pr = Lean.Meta.mkAppM `Eq.mpr #[eqProof, pr]
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Given a monad and e : α, makes pure e.
Equations
- Lean.Meta.mkPure monad e = Lean.Meta.mkAppOptM `Pure.pure #[some monad, none, none, some e]
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mkProjection s fieldName returns an expression for accessing field fieldName of the structure s.
Remark: fieldName may be a subfield of s.
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Equations
- Lean.Meta.mkArrayLit type xs = do let u ← Lean.Meta.getDecLevel type let listLit ← Lean.Meta.mkListLit type xs pure (Lean.mkApp (Lean.mkApp (Lean.mkConst `List.toArray [u]) type) listLit)
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Equations
- Lean.Meta.mkNone type = do let u ← Lean.Meta.getDecLevel type pure (Lean.mkApp (Lean.mkConst `Option.none [u]) type)
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Equations
- Lean.Meta.mkSome type value = do let u ← Lean.Meta.getDecLevel type pure (Lean.mkApp2 (Lean.mkConst `Option.some [u]) type value)
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Equations
- Lean.Meta.mkSorry type synthetic = do let u ← Lean.Meta.getLevel type pure (Lean.mkApp2 (Lean.mkConst `sorryAx [u]) type (Lean.toExpr synthetic))
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Return Decidable.decide p
Equations
- Lean.Meta.mkDecide p = Lean.Meta.mkAppOptM `Decidable.decide #[some p, none]
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Return a proof for p : Prop using decide p
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Return Inhabited.default α
Equations
- Lean.Meta.mkDefault α = Lean.Meta.mkAppOptM `Inhabited.default #[some α, none]
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Return @Classical.ofNonempty α _
Equations
- Lean.Meta.mkOfNonempty α = Lean.Meta.mkAppOptM `Classical.ofNonempty #[some α, none]
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Return sorryAx type
Equations
- Lean.Meta.mkSyntheticSorry type = do let __do_lift ← Lean.Meta.getLevel type pure (Lean.mkApp2 (Lean.mkConst `sorryAx [__do_lift]) type (Lean.mkConst `Bool.true))
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Return let_congr h₁ h₂
Equations
- Lean.Meta.mkLetCongr h₁ h₂ = Lean.Meta.mkAppM `let_congr #[h₁, h₂]
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Return let_val_congr b h
Equations
- Lean.Meta.mkLetValCongr b h = Lean.Meta.mkAppM `let_val_congr #[b, h]
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Return let_body_congr a h
Equations
- Lean.Meta.mkLetBodyCongr a h = Lean.Meta.mkAppM `let_body_congr #[a, h]
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Return eq_false h
h must have type definitionally equal to ¬ p in the current
reducibility setting.
Equations
- Lean.Meta.mkEqFalse h = Lean.Meta.mkAppM `eq_false #[h]
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Return eq_false' h
h must have type definitionally equal to p → False in the current
reducibility setting.
Equations
- Lean.Meta.mkEqFalse' h = Lean.Meta.mkAppM `eq_false' #[h]
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Equations
- Lean.Meta.mkImpCongr h₁ h₂ = Lean.Meta.mkAppM `implies_congr #[h₁, h₂]
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Equations
- Lean.Meta.mkImpCongrCtx h₁ h₂ = Lean.Meta.mkAppM `implies_congr_ctx #[h₁, h₂]
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Equations
- Lean.Meta.mkImpDepCongrCtx h₁ h₂ = Lean.Meta.mkAppM `implies_dep_congr_ctx #[h₁, h₂]
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Equations
- Lean.Meta.mkForallCongr h = Lean.Meta.mkAppM `forall_congr #[h]
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Return instance for [Monad m] if there is one
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Return (n : type), a numeric literal of type type. The method fails if we don't have an instance OfNat type n
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Return a + b using a heterogeneous +. This method assumes a and b have the same type.
Equations
- Lean.Meta.mkAdd a b = Lean.Meta.mkBinaryOp `HAdd `HAdd.hAdd a b
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Return a - b using a heterogeneous -. This method assumes a and b have the same type.
Equations
- Lean.Meta.mkSub a b = Lean.Meta.mkBinaryOp `HSub `HSub.hSub a b
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Return a * b using a heterogeneous *. This method assumes a and b have the same type.
Equations
- Lean.Meta.mkMul a b = Lean.Meta.mkBinaryOp `HMul `HMul.hMul a b
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Return a ≤ b. This method assumes a and b have the same type.
Equations
- Lean.Meta.mkLE a b = Lean.Meta.mkBinaryRel `LE `LE.le a b
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Return a < b. This method assumes a and b have the same type.
Equations
- Lean.Meta.mkLT a b = Lean.Meta.mkBinaryRel `LT `LT.lt a b
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Given h : a = b, return a proof for a ↔ b.
Equations
- Lean.Meta.mkIffOfEq h = if h.isAppOfArity `propext 3 = true then pure h.appArg! else Lean.Meta.mkAppM `Iff.of_eq #[h]