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|
import Lean
import Mathlib.Tactic.Core
import Mathlib.Tactic.LeftRight
import Base.UtilsBase
/-
Mathlib tactics:
- rcases: https://leanprover-community.github.io/mathlib_docs/tactics.html#rcases
- split_ifs: https://leanprover-community.github.io/mathlib_docs/tactics.html#split_ifs
- norm_num: https://leanprover-community.github.io/mathlib_docs/tactics.html#norm_num
- should we use linarith or omega?
- hint: https://leanprover-community.github.io/mathlib_docs/tactics.html#hint
- classical: https://leanprover-community.github.io/mathlib_docs/tactics.html#classical
-/
/-
TODO:
- we want an easier to use cases:
- keeps in the goal an equation of the shape: `t = case`
- if called on Prop terms, uses Classical.em
Actually, the cases from mathlib seems already quite powerful
(https://leanprover-community.github.io/mathlib_docs/tactics.html#cases)
For instance: cases h : e
Also: **casesm**
- better split tactic
- we need conversions to operate on the head of applications.
Actually, something like this works:
```
conv at Hl =>
apply congr_fun
simp [fix_fuel_P]
```
Maybe we need a rpt ... ; focus?
- simplifier/rewriter have a strange behavior sometimes
-/
namespace List
-- TODO: I could not find this function??
@[simp] def flatten {a : Type u} : List (List a) → List a
| [] => []
| x :: ls => x ++ flatten ls
end List
-- TODO: move?
@[simp]
theorem neq_imp {α : Type u} {x y : α} (h : ¬ x = y) : ¬ y = x := by intro; simp_all
namespace Lean
namespace LocalContext
open Lean Lean.Elab Command Term Lean.Meta
-- Small utility: return the list of declarations in the context, from
-- the last to the first.
def getAllDecls (lctx : Lean.LocalContext) : MetaM (List Lean.LocalDecl) :=
lctx.foldrM (fun d ls => do let d ← instantiateLocalDeclMVars d; pure (d :: ls)) []
-- Return the list of declarations in the context, but filter the
-- declarations which are considered as implementation details
def getDecls (lctx : Lean.LocalContext) : MetaM (List Lean.LocalDecl) := do
let ls ← lctx.getAllDecls
pure (ls.filter (fun d => not d.isImplementationDetail))
end LocalContext
end Lean
namespace Utils
open Lean Elab Term Meta Tactic
-- Useful helper to explore definitions and figure out the variant
-- of their sub-expressions.
def explore_term (incr : String) (e : Expr) : MetaM Unit :=
match e with
| .bvar _ => do logInfo m!"{incr}bvar: {e}"; return ()
| .fvar _ => do logInfo m!"{incr}fvar: {e}"; return ()
| .mvar _ => do logInfo m!"{incr}mvar: {e}"; return ()
| .sort _ => do logInfo m!"{incr}sort: {e}"; return ()
| .const _ _ => do logInfo m!"{incr}const: {e}"; return ()
| .app fn arg => do
logInfo m!"{incr}app: {e}"
explore_term (incr ++ " ") fn
explore_term (incr ++ " ") arg
| .lam _bName bTy body _binfo => do
logInfo m!"{incr}lam: {e}"
explore_term (incr ++ " ") bTy
explore_term (incr ++ " ") body
| .forallE _bName bTy body _bInfo => do
logInfo m!"{incr}forallE: {e}"
explore_term (incr ++ " ") bTy
explore_term (incr ++ " ") body
| .letE _dName ty val body _nonDep => do
logInfo m!"{incr}letE: {e}"
explore_term (incr ++ " ") ty
explore_term (incr ++ " ") val
explore_term (incr ++ " ") body
| .lit _ => do logInfo m!"{incr}lit: {e}"; return ()
| .mdata _ e => do
logInfo m!"{incr}mdata: {e}"
explore_term (incr ++ " ") e
| .proj _ _ struct => do
logInfo m!"{incr}proj: {e}"
explore_term (incr ++ " ") struct
def explore_decl (n : Name) : TermElabM Unit := do
logInfo m!"Name: {n}"
let env ← getEnv
let decl := env.constants.find! n
match decl with
| .defnInfo val =>
logInfo m!"About to explore defn: {decl.name}"
logInfo m!"# Type:"
explore_term "" val.type
logInfo m!"# Value:"
explore_term "" val.value
| .axiomInfo _ => throwError m!"axiom: {n}"
| .thmInfo _ => throwError m!"thm: {n}"
| .opaqueInfo _ => throwError m!"opaque: {n}"
| .quotInfo _ => throwError m!"quot: {n}"
| .inductInfo _ => throwError m!"induct: {n}"
| .ctorInfo _ => throwError m!"ctor: {n}"
| .recInfo _ => throwError m!"rec: {n}"
syntax (name := printDecl) "print_decl " ident : command
open Lean.Elab.Command
@[command_elab printDecl] def elabPrintDecl : CommandElab := fun stx => do
liftTermElabM do
let id := stx[1]
addCompletionInfo <| CompletionInfo.id id id.getId (danglingDot := false) {} none
let cs ← resolveGlobalConstWithInfos id
explore_decl cs[0]!
private def test1 : Nat := 0
private def test2 (x : Nat) : Nat := x
print_decl test1
print_decl test2
def printDecls (decls : List LocalDecl) : MetaM Unit := do
let decls ← decls.foldrM (λ decl msg => do
pure (m!"\n{decl.toExpr} : {← inferType decl.toExpr}" ++ msg)) m!""
logInfo m!"# Ctx decls:{decls}"
-- Small utility: print all the declarations in the context (including the "implementation details")
elab "print_all_ctx_decls" : tactic => do
let ctx ← Lean.MonadLCtx.getLCtx
let decls ← ctx.getAllDecls
printDecls decls
-- Small utility: print all declarations in the context
elab "print_ctx_decls" : tactic => do
let ctx ← Lean.MonadLCtx.getLCtx
let decls ← ctx.getDecls
printDecls decls
-- A map visitor function for expressions (adapted from `AbstractNestedProofs.visit`)
-- The continuation takes as parameters:
-- - the current depth of the expression (useful for printing/debugging)
-- - the expression to explore
partial def mapVisit (k : Nat → Expr → MetaM Expr) (e : Expr) : MetaM Expr := do
let mapVisitBinders (xs : Array Expr) (k2 : MetaM Expr) : MetaM Expr := do
let localInstances ← getLocalInstances
let mut lctx ← getLCtx
for x in xs do
let xFVarId := x.fvarId!
let localDecl ← xFVarId.getDecl
let type ← mapVisit k localDecl.type
let localDecl := localDecl.setType type
let localDecl ← match localDecl.value? with
| some value => let value ← mapVisit k value; pure <| localDecl.setValue value
| none => pure localDecl
lctx :=lctx.modifyLocalDecl xFVarId fun _ => localDecl
withLCtx lctx localInstances k2
-- TODO: use a cache? (Lean.checkCache)
let rec visit (i : Nat) (e : Expr) : MetaM Expr := do
-- Explore
let e ← k i e
match e with
| .bvar _
| .fvar _
| .mvar _
| .sort _
| .lit _
| .const _ _ => pure e
| .app .. => do e.withApp fun f args => return mkAppN f (← args.mapM (visit (i + 1)))
| .lam .. =>
lambdaLetTelescope e fun xs b =>
mapVisitBinders xs do mkLambdaFVars xs (← visit (i + 1) b) (usedLetOnly := false)
| .forallE .. => do
forallTelescope e fun xs b => mapVisitBinders xs do mkForallFVars xs (← visit (i + 1) b)
| .letE .. => do
lambdaLetTelescope e fun xs b => mapVisitBinders xs do
mkLambdaFVars xs (← visit (i + 1) b) (usedLetOnly := false)
| .mdata _ b => return e.updateMData! (← visit (i + 1) b)
| .proj _ _ b => return e.updateProj! (← visit (i + 1) b)
visit 0 e
-- Generate a fresh user name for an anonymous proposition to introduce in the
-- assumptions
def mkFreshAnonPropUserName := mkFreshUserName `_
section Methods
variable [MonadLiftT MetaM m] [MonadControlT MetaM m] [Monad m] [MonadError m]
variable {a : Type}
/- Like `lambdaTelescopeN` but only destructs a fixed number of lambdas -/
def lambdaTelescopeN (e : Expr) (n : Nat) (k : Array Expr → Expr → m a) : m a :=
lambdaTelescope e fun xs body => do
if xs.size < n then throwError "lambdaTelescopeN: not enough lambdas"
let xs := xs.extract 0 n
let ys := xs.extract n xs.size
let body ← liftMetaM (mkLambdaFVars ys body)
k xs body
/- Like `lambdaTelescope`, but only destructs one lambda
TODO: is there an equivalent of this function somewhere in the
standard library? -/
def lambdaOne (e : Expr) (k : Expr → Expr → m a) : m a :=
lambdaTelescopeN e 1 λ xs b => k (xs.get! 0) b
def isExists (e : Expr) : Bool := e.getAppFn.isConstOf ``Exists ∧ e.getAppNumArgs = 2
-- Remark: Lean doesn't find the inhabited and nonempty instances if we don'
-- put them explicitely in the signature
partial def existsTelescopeProcess [Inhabited (m a)] [Nonempty (m a)]
(fvars : Array Expr) (e : Expr) (k : Array Expr → Expr → m a) : m a := do
-- Attempt to deconstruct an existential
if isExists e then do
let p := e.appArg!
lambdaOne p fun x ne =>
existsTelescopeProcess (fvars.push x) ne k
else
-- No existential: call the continuation
k fvars e
def existsTelescope [Inhabited (m a)] [Nonempty (m a)] (e : Expr) (k : Array Expr → Expr → m a) : m a := do
existsTelescopeProcess #[] e k
end Methods
-- TODO: this should take a continuation
def addDeclTac (name : Name) (val : Expr) (type : Expr) (asLet : Bool) : TacticM Expr :=
-- I don't think we need that
withMainContext do
-- Insert the new declaration
let withDecl := if asLet then withLetDecl name type val else withLocalDeclD name type
withDecl fun nval => do
-- For debugging
let lctx ← Lean.MonadLCtx.getLCtx
let fid := nval.fvarId!
let decl := lctx.get! fid
trace[Arith] " new decl: \"{decl.userName}\" ({nval}) : {decl.type} := {decl.value}"
--
-- Tranform the main goal `?m0` to `let x = nval in ?m1`
let mvarId ← getMainGoal
let newMVar ← mkFreshExprSyntheticOpaqueMVar (← mvarId.getType)
let newVal ← mkLetFVars #[nval] newMVar
-- There are two cases:
-- - asLet is true: newVal is `let $name := $val in $newMVar`
-- - asLet is false: ewVal is `λ $name => $newMVar`
-- We need to apply it to `val`
let newVal := if asLet then newVal else mkAppN newVal #[val]
-- Assign the main goal and update the current goal
mvarId.assign newVal
let goals ← getUnsolvedGoals
setGoals (newMVar.mvarId! :: goals)
-- Return the new value - note: we are in the *new* context, created
-- after the declaration was added, so it will persist
pure nval
def addDeclTacSyntax (name : Name) (val : Syntax) (asLet : Bool) : TacticM Unit :=
-- I don't think we need that
withMainContext do
--
let val ← Term.elabTerm val .none
let type ← inferType val
-- In some situations, the type will be left as a metavariable (for instance,
-- if the term is `3`, Lean has the choice between `Nat` and `Int` and will
-- not choose): we force the instantiation of the meta-variable
synthesizeSyntheticMVarsUsingDefault
--
let _ ← addDeclTac name val type asLet
elab "custom_let " n:ident " := " v:term : tactic => do
addDeclTacSyntax n.getId v (asLet := true)
elab "custom_have " n:ident " := " v:term : tactic =>
addDeclTacSyntax n.getId v (asLet := false)
example : Nat := by
custom_let x := 4
custom_have y := 4
apply y
example (x : Bool) : Nat := by
cases x <;> custom_let x := 3 <;> apply x
-- Repeatedly apply a tactic
partial def repeatTac (tac : TacticM Unit) : TacticM Unit := do
try
tac
allGoals (focus (repeatTac tac))
-- TODO: does this restore the state?
catch _ => pure ()
def firstTac (tacl : List (TacticM Unit)) : TacticM Unit := do
match tacl with
| [] => pure ()
| tac :: tacl =>
-- Should use try ... catch or Lean.observing?
-- Generally speaking we should use Lean.observing? to restore the state,
-- but with tactics the try ... catch variant seems to work
try do
tac
-- Check that there are no remaining goals
let gl ← Tactic.getUnsolvedGoals
if ¬ gl.isEmpty then throwError "tactic failed"
catch _ => firstTac tacl
/- let res ← Lean.observing? do
tac
-- Check that there are no remaining goals
let gl ← Tactic.getUnsolvedGoals
if ¬ gl.isEmpty then throwError "tactic failed"
match res with
| some _ => pure ()
| none => firstTac tacl -/
-- Taken from Lean.Elab.evalAssumption
def assumptionTac : TacticM Unit :=
liftMetaTactic fun mvarId => do mvarId.assumption; pure []
def isConj (e : Expr) : MetaM Bool :=
e.consumeMData.withApp fun f args => pure (f.isConstOf ``And ∧ args.size = 2)
-- Return the first conjunct if the expression is a conjunction, or the
-- expression itself otherwise. Also return the second conjunct if it is a
-- conjunction.
def optSplitConj (e : Expr) : MetaM (Expr × Option Expr) := do
e.consumeMData.withApp fun f args =>
if f.isConstOf ``And ∧ args.size = 2 then pure (args.get! 0, some (args.get! 1))
else pure (e, none)
-- Split the goal if it is a conjunction
def splitConjTarget : TacticM Unit := do
withMainContext do
let g ← getMainTarget
trace[Utils] "splitConjTarget: goal: {g}"
-- The tactic was initially implemened with `_root_.Lean.MVarId.apply`
-- but it tended to mess the goal by unfolding terms, even when it failed
let (l, r) ← optSplitConj g
match r with
| none => do throwError "The goal is not a conjunction"
| some r => do
let lmvar ← mkFreshExprSyntheticOpaqueMVar l
let rmvar ← mkFreshExprSyntheticOpaqueMVar r
let and_intro ← mkAppM ``And.intro #[lmvar, rmvar]
let g ← getMainGoal
g.assign and_intro
let goals ← getUnsolvedGoals
setGoals (lmvar.mvarId! :: rmvar.mvarId! :: goals)
-- Destruct an equaliy and return the two sides
def destEq (e : Expr) : MetaM (Expr × Expr) := do
e.withApp fun f args =>
if f.isConstOf ``Eq ∧ args.size = 3 then pure (args.get! 1, args.get! 2)
else throwError "Not an equality: {e}"
-- Return the set of FVarIds in the expression
partial def getFVarIds (e : Expr) (hs : HashSet FVarId := HashSet.empty) : MetaM (HashSet FVarId) := do
e.withApp fun body args => do
let hs := if body.isFVar then hs.insert body.fvarId! else hs
args.foldlM (fun hs arg => getFVarIds arg hs) hs
-- Tactic to split on a disjunction.
-- The expression `h` should be an fvar.
-- TODO: there must be simpler. Use use _root_.Lean.MVarId.cases for instance
def splitDisjTac (h : Expr) (kleft kright : TacticM Unit) : TacticM Unit := do
trace[Arith] "assumption on which to split: {h}"
-- Retrieve the main goal
withMainContext do
let goalType ← getMainTarget
let hDecl := (← getLCtx).get! h.fvarId!
let hName := hDecl.userName
-- Case disjunction
let hTy ← inferType h
hTy.withApp fun f xs => do
trace[Arith] "as app: {f} {xs}"
-- Sanity check
if ¬ (f.isConstOf ``Or ∧ xs.size = 2) then throwError "Invalid argument to splitDisjTac"
let a := xs.get! 0
let b := xs.get! 1
-- Introduce the new goals
-- Returns:
-- - the match branch
-- - a fresh new mvar id
let mkGoal (hTy : Expr) (nGoalName : String) : MetaM (Expr × MVarId) := do
-- Introduce a variable for the assumption (`a` or `b`). Note that we reuse
-- the name of the assumption we split.
withLocalDeclD hName hTy fun var => do
-- The new goal
let mgoal ← mkFreshExprSyntheticOpaqueMVar goalType (tag := Name.mkSimple nGoalName)
-- Clear the assumption that we split
let mgoal ← mgoal.mvarId!.tryClearMany #[h.fvarId!]
-- The branch expression
let branch ← mkLambdaFVars #[var] (mkMVar mgoal)
pure (branch, mgoal)
let (inl, mleft) ← mkGoal a "left"
let (inr, mright) ← mkGoal b "right"
trace[Arith] "left: {inl}: {mleft}"
trace[Arith] "right: {inr}: {mright}"
-- Create the match expression
withLocalDeclD (← mkFreshAnonPropUserName) hTy fun hVar => do
let motive ← mkLambdaFVars #[hVar] goalType
let casesExpr ← mkAppOptM ``Or.casesOn #[a, b, motive, h, inl, inr]
let mgoal ← getMainGoal
trace[Arith] "goals: {← getUnsolvedGoals}"
trace[Arith] "main goal: {mgoal}"
mgoal.assign casesExpr
let goals ← getUnsolvedGoals
-- Focus on the left
setGoals [mleft]
withMainContext kleft
let leftGoals ← getUnsolvedGoals
-- Focus on the right
setGoals [mright]
withMainContext kright
let rightGoals ← getUnsolvedGoals
-- Put all the goals back
setGoals (leftGoals ++ rightGoals ++ goals)
trace[Arith] "new goals: {← getUnsolvedGoals}"
elab "split_disj " n:ident : tactic => do
withMainContext do
let decl ← Lean.Meta.getLocalDeclFromUserName n.getId
let fvar := mkFVar decl.fvarId
splitDisjTac fvar (fun _ => pure ()) (fun _ => pure ())
example (x y : Int) (h0 : x ≤ y ∨ x ≥ y) : x ≤ y ∨ x ≥ y := by
split_disj h0
. left; assumption
. right; assumption
-- Tactic to split on an exists.
-- `h` must be an FVar
def splitExistsTac (h : Expr) (optId : Option Name) (k : Expr → Expr → TacticM α) : TacticM α := do
withMainContext do
let goal ← getMainGoal
let hTy ← inferType h
if isExists hTy then do
-- Try to use the user-provided names
let altVarNames ← do
let hDecl ← h.fvarId!.getDecl
let id ← do
match optId with
| none => mkFreshUserName `x
| some id => pure id
pure #[{ varNames := [id, hDecl.userName] }]
let newGoals ← goal.cases h.fvarId! altVarNames
-- There should be exactly one goal
match newGoals.toList with
| [ newGoal ] =>
-- Set the new goal
let goals ← getUnsolvedGoals
setGoals (newGoal.mvarId :: goals)
-- There should be exactly two fields
let fields := newGoal.fields
withMainContext do
k (fields.get! 0) (fields.get! 1)
| _ =>
throwError "Unreachable"
else
throwError "Not a conjunction"
-- TODO: move
def listTryPopHead (ls : List α) : Option α × List α :=
match ls with
| [] => (none, ls)
| hd :: tl => (some hd, tl)
/- Destruct all the existentials appearing in `h`, and introduce them as variables
in the context.
If `ids` is not empty, we use it to name the introduced variables. We
transmit the stripped expression and the remaining ids to the continuation.
-/
partial def splitAllExistsTac [Inhabited α] (h : Expr) (ids : List (Option Name)) (k : Expr → List (Option Name) → TacticM α) : TacticM α := do
try
let (optId, ids) :=
match ids with
| [] => (none, [])
| x :: ids => (x, ids)
splitExistsTac h optId (fun _ body => splitAllExistsTac body ids k)
catch _ => k h ids
-- Tactic to split on a conjunction.
def splitConjTac (h : Expr) (optIds : Option (Name × Name)) (k : Expr → Expr → TacticM α) : TacticM α := do
withMainContext do
let goal ← getMainGoal
let hTy ← inferType h
if ← isConj hTy then do
-- Try to use the user-provided names
let altVarNames ←
match optIds with
| none => do
let id0 ← mkFreshAnonPropUserName
let id1 ← mkFreshAnonPropUserName
pure #[{ varNames := [id0, id1] }]
| some (id0, id1) => do
pure #[{ varNames := [id0, id1] }]
let newGoals ← goal.cases h.fvarId! altVarNames
-- There should be exactly one goal
match newGoals.toList with
| [ newGoal ] =>
-- Set the new goal
let goals ← getUnsolvedGoals
setGoals (newGoal.mvarId :: goals)
-- There should be exactly two fields
let fields := newGoal.fields
withMainContext do
k (fields.get! 0) (fields.get! 1)
| _ =>
throwError "Unreachable"
else
throwError "Not a conjunction"
-- Tactic to fully split a conjunction
partial def splitFullConjTacAux [Inhabited α] [Nonempty α] (keepCurrentName : Bool) (l : List Expr) (h : Expr) (k : List Expr → TacticM α) : TacticM α := do
try
let ids ← do
if keepCurrentName then do
let cur := (← h.fvarId!.getDecl).userName
let nid ← mkFreshAnonPropUserName
pure (some (cur, nid))
else
pure none
splitConjTac h ids (λ h1 h2 =>
splitFullConjTacAux keepCurrentName l h1 (λ l1 =>
splitFullConjTacAux keepCurrentName l1 h2 (λ l2 =>
k l2)))
catch _ =>
k (h :: l)
-- Tactic to fully split a conjunction
-- `keepCurrentName`: if `true`, then the first conjunct has the name of the original assumption
def splitFullConjTac [Inhabited α] [Nonempty α] (keepCurrentName : Bool) (h : Expr) (k : List Expr → TacticM α) : TacticM α := do
splitFullConjTacAux keepCurrentName [] h (λ l => k l.reverse)
syntax optAtArgs := ("at" ident)?
def elabOptAtArgs (args : TSyntax `Utils.optAtArgs) : TacticM (Option Expr) := do
withMainContext do
let args := (args.raw.getArgs.get! 0).getArgs
if args.size > 0 then do
let n := (args.get! 1).getId
let decl ← Lean.Meta.getLocalDeclFromUserName n
let fvar := mkFVar decl.fvarId
pure (some fvar)
else
pure none
elab "split_conj" args:optAtArgs : tactic => do
withMainContext do
match ← elabOptAtArgs args with
| some fvar => do
trace[Utils] "split at {fvar}"
splitConjTac fvar none (fun _ _ => pure ())
| none => do
trace[Utils] "split goal"
splitConjTarget
elab "split_conjs" args:optAtArgs : tactic => do
withMainContext do
match ← elabOptAtArgs args with
| some fvar =>
trace[Utils] "split at {fvar}"
splitFullConjTac false fvar (fun _ => pure ())
| none =>
trace[Utils] "split goal"
repeatTac splitConjTarget
elab "split_existsl" " at " n:ident : tactic => do
withMainContext do
let decl ← Lean.Meta.getLocalDeclFromUserName n.getId
let fvar := mkFVar decl.fvarId
splitAllExistsTac fvar [] (fun _ _ => pure ())
example (h : a ∧ b) : a := by
split_existsl at h
split_conj at h
assumption
example (h : ∃ x y z, x + y + z ≥ 0) : ∃ x, x ≥ 0 := by
split_existsl at h
rename_i x y z
exists x + y + z
/- Call the simp tactic.
The initialization of the context is adapted from Tactic.elabSimpArgs.
Something very annoying is that there is no function which allows to
initialize a simp context without doing an elaboration - as a consequence
we write our own here. -/
def simpAt (declsToUnfold : List Name) (thms : List Name) (hypsToUse : List FVarId)
(loc : Tactic.Location) :
Tactic.TacticM Unit := do
-- Initialize with the builtin simp theorems
let simpThms ← Tactic.simpOnlyBuiltins.foldlM (·.addConst ·) ({} : SimpTheorems)
-- Add the equational theorem for the declarations to unfold
let simpThms ←
declsToUnfold.foldlM (fun thms decl => thms.addDeclToUnfold decl) simpThms
-- Add the hypotheses and the rewriting theorems
let simpThms ←
hypsToUse.foldlM (fun thms fvarId =>
-- post: TODO: don't know what that is
-- inv: invert the equality
thms.add (.fvar fvarId) #[] (mkFVar fvarId) (post := false) (inv := false)
-- thms.eraseCore (.fvar fvar)
) simpThms
-- Add the rewriting theorems to use
let simpThms ←
thms.foldlM (fun thms thmName => do
let info ← getConstInfo thmName
if (← isProp info.type) then
-- post: TODO: don't know what that is
-- inv: invert the equality
thms.addConst thmName (post := false) (inv := false)
else
throwError "Not a proposition: {thmName}"
) simpThms
let congrTheorems ← getSimpCongrTheorems
let ctx : Simp.Context := { simpTheorems := #[simpThms], congrTheorems }
-- Apply the simplifier
let _ ← Tactic.simpLocation ctx (discharge? := .none) loc
end Utils
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