/- Copyright (c) 2022 Newell Jensen. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Newell Jensen, Thomas Murrills -/ prelude import Lean.Meta.Tactic.Apply import Lean.Elab.Tactic.Basic import Lean.Meta.Tactic.Refl /-! # `rfl` tactic extension for reflexive relations This extends the `rfl` tactic so that it works on any reflexive relation, provided the reflexivity lemma has been marked as `@[refl]`. -/ namespace Lean.Meta.Rfl open Lean Meta /-- Discrimation tree settings for the `refl` extension. -/ def reflExt.config : WhnfCoreConfig := {} /-- Environment extensions for `refl` lemmas -/ initialize reflExt : SimpleScopedEnvExtension (Name × Array DiscrTree.Key) (DiscrTree Name) ← registerSimpleScopedEnvExtension { addEntry := fun dt (n, ks) => dt.insertCore ks n initial := {} } initialize registerBuiltinAttribute { name := `refl descr := "reflexivity relation" add := fun decl _ kind => MetaM.run' do let declTy := (← getConstInfo decl).type let (_, _, targetTy) ← withReducible <| forallMetaTelescopeReducing declTy let fail := throwError "@[refl] attribute only applies to lemmas proving x ∼ x, got {declTy}" let .app (.app rel lhs) rhs := targetTy | fail if let .app (.const ``Eq [_]) _ := rel then throwError "@[refl] attribute may not be used on `Eq.refl`." unless ← withNewMCtxDepth <| isDefEq lhs rhs do fail let key ← DiscrTree.mkPath rel reflExt.config reflExt.add (decl, key) kind } open Elab Tactic /-- `MetaM` version of the `rfl` tactic. This tactic applies to a goal whose target has the form `x ~ x`, where `~` is a reflexive relation other than `=`, that is, a relation which has a reflexive lemma tagged with the attribute @[refl]. -/ def _root_.Lean.MVarId.applyRfl (goal : MVarId) : MetaM Unit := do let .app (.app rel _) _ ← whnfR <|← instantiateMVars <|← goal.getType | throwError "reflexivity lemmas only apply to binary relations, not{ indentExpr (← goal.getType)}" if let .app (.const ``Eq [_]) _ := rel then throwError "MVarId.applyRfl does not solve `=` goals. Use `MVarId.refl` instead." else let s ← saveState let mut ex? := none for lem in ← (reflExt.getState (← getEnv)).getMatch rel reflExt.config do try let gs ← goal.apply (← mkConstWithFreshMVarLevels lem) if gs.isEmpty then return () else logError <| MessageData.tagged `Tactic.unsolvedGoals <| m!"unsolved goals\n{ goalsToMessageData gs}" catch e => ex? := ex? <|> (some (← saveState, e)) -- stash the first failure of `apply` s.restore if let some (sErr, e) := ex? then sErr.restore throw e else throwError "rfl failed, no lemma with @[refl] applies" /-- Helper theorem for `Lean.MVarId.liftReflToEq`. -/ private theorem rel_of_eq_and_refl {α : Sort _} {R : α → α → Prop} {x y : α} (hxy : x = y) (h : R x x) : R x y := hxy ▸ h /-- Convert a goal of the form `x ~ y` into the form `x = y`, where `~` is a reflexive relation, that is, a relation which has a reflexive lemma tagged with the attribute `@[refl]`. If this can't be done, returns the original `MVarId`. -/ def _root_.Lean.MVarId.liftReflToEq (mvarId : MVarId) : MetaM MVarId := do mvarId.checkNotAssigned `liftReflToEq let .app (.app rel _) _ ← withReducible mvarId.getType' | return mvarId if rel.isAppOf `Eq then -- No need to lift Eq to Eq return mvarId for lem in ← (reflExt.getState (← getEnv)).getMatch rel reflExt.config do let res ← observing? do -- First create an equality relating the LHS and RHS -- and reduce the goal to proving that LHS is related to LHS. let [mvarIdEq, mvarIdR] ← mvarId.apply (← mkConstWithFreshMVarLevels ``rel_of_eq_and_refl) | failure -- Then fill in the proof of the latter by reflexivity. let [] ← mvarIdR.apply (← mkConstWithFreshMVarLevels lem) | failure return mvarIdEq if let some mvarIdEq := res then return mvarIdEq return mvarId end Lean.Meta.Rfl