Pantograph/Test/Proofs.lean

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/-
Tests pertaining to goals with no interdependencies
-/
import LSpec
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import Pantograph.Goal
import Pantograph.Serial
import Test.Common
namespace Pantograph.Test.Proofs
open Pantograph
open Lean
inductive Start where
| copy (name: String) -- Start from some name in the environment
| expr (expr: String) -- Start from some expression
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abbrev TestM := StateRefT LSpec.TestSeq (ReaderT Protocol.Options Elab.TermElabM)
def addTest (test: LSpec.TestSeq): TestM Unit := do
set $ (← get) ++ test
def startProof (start: Start): TestM (Option GoalState) := do
let env ← Lean.MonadEnv.getEnv
match start with
| .copy name =>
let cInfo? := name.toName |> env.find?
addTest $ LSpec.check s!"Symbol exists {name}" cInfo?.isSome
match cInfo? with
| .some cInfo =>
let goal ← GoalState.create (expr := cInfo.type)
return Option.some goal
| .none =>
return Option.none
| .expr expr =>
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let syn? := parseTerm env expr
addTest $ LSpec.check s!"Parsing {expr}" (syn?.isOk)
match syn? with
| .error error =>
IO.println error
return Option.none
| .ok syn =>
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let expr? ← elabType syn
addTest $ LSpec.check s!"Elaborating" expr?.isOk
match expr? with
| .error error =>
IO.println error
return Option.none
| .ok expr =>
let goal ← GoalState.create (expr := expr)
return Option.some goal
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def buildNamedGoal (name: String) (nameType: List (String × String)) (target: String)
(userName?: Option String := .none): Protocol.Goal :=
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{
name,
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userName?,
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target := { pp? := .some target},
vars := (nameType.map fun x => ({
userName := x.fst,
type? := .some { pp? := .some x.snd },
})).toArray
}
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def buildGoal (nameType: List (String × String)) (target: String) (userName?: Option String := .none):
Protocol.Goal :=
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{
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userName?,
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target := { pp? := .some target},
vars := (nameType.map fun x => ({
userName := x.fst,
type? := .some { pp? := .some x.snd },
})).toArray
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}
def proofRunner (env: Lean.Environment) (tests: TestM Unit): IO LSpec.TestSeq := do
let termElabM := tests.run LSpec.TestSeq.done |>.run {} -- with default options
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let coreContext: Lean.Core.Context ← createCoreContext #[]
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let metaM := termElabM.run' (ctx := Condensed.elabContext)
let coreM := metaM.run'
match ← (coreM.run' coreContext { env := env }).toBaseIO with
| .error exception =>
return LSpec.test "Exception" (s!"internal exception #{← exception.toMessageData.toString}" = "")
| .ok (_, a) =>
return a
def test_identity: TestM Unit := do
let state? ← startProof (.expr "∀ (p: Prop), p → p")
let state0 ← match state? with
| .some state => pure state
| .none => do
addTest $ assertUnreachable "Goal could not parse"
return ()
let tactic := "intro p h"
let state1 ← match ← state0.tacticOn 0 tactic with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
let inner := "_uniq.12"
addTest $ LSpec.check tactic ((← state1.serializeGoals (options := ← read)).map (·.name) =
#[inner])
let state1parent ← state1.withParentContext do
serializeExpressionSexp (← instantiateAll state1.parentExpr?.get!) (sanitize := false)
addTest $ LSpec.test "(1 parent)" (state1parent == s!"(:lambda p (:sort 0) (:lambda h 0 (:subst (:mv {inner}) 1 0)))")
-- Individual test cases
example: ∀ (a b: Nat), a + b = b + a := by
intro n m
rw [Nat.add_comm]
def test_nat_add_comm (manual: Bool): TestM Unit := do
let state? ← startProof <| match manual with
| false => .copy "Nat.add_comm"
| true => .expr "∀ (a b: Nat), a + b = b + a"
addTest $ LSpec.check "Start goal" state?.isSome
let state0 ← match state? with
| .some state => pure state
| .none => do
addTest $ assertUnreachable "Goal could not parse"
return ()
let state1 ← match ← state0.tacticOn 0 "intro n m" with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check "intro n m" ((← state1.serializeGoals (options := ← read)).map (·.devolatilize) =
#[buildGoal [("n", "Nat"), ("m", "Nat")] "n + m = m + n"])
match ← state1.tacticOn 0 "assumption" with
| .failure #[message] =>
addTest $ LSpec.check "assumption" (message = "tactic 'assumption' failed\nn m : Nat\n⊢ n + m = m + n")
| other => do
addTest $ assertUnreachable $ other.toString
let state2 ← match ← state1.tacticOn 0 "rw [Nat.add_comm]" with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.test "rw [Nat.add_comm]" state2.goals.isEmpty
return ()
def test_delta_variable: TestM Unit := do
let options: Protocol.Options := { noRepeat := true }
let state? ← startProof <| .expr "∀ (a b: Nat), a + b = b + a"
addTest $ LSpec.check "Start goal" state?.isSome
let state0 ← match state? with
| .some state => pure state
| .none => do
addTest $ assertUnreachable "Goal could not parse"
return ()
let state1 ← match ← state0.tacticOn (goalId := 0) (tactic := "intro n") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check "intro n" ((← state1.serializeGoals (parent := state0) options).map (·.devolatilize) =
#[buildGoalSelective [("n", .some "Nat")] "∀ (b : Nat), n + b = b + n"])
let state2 ← match ← state1.tacticOn (goalId := 0) (tactic := "intro m") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check "intro m" ((← state2.serializeGoals (parent := state1) options).map (·.devolatilize) =
#[buildGoalSelective [("n", .none), ("m", .some "Nat")] "n + m = m + n"])
return ()
where
-- Like `buildGoal` but allow certain variables to be elided.
buildGoalSelective (nameType: List (String × Option String)) (target: String): Protocol.Goal :=
{
target := { pp? := .some target},
vars := (nameType.map fun x => ({
userName := x.fst,
type? := x.snd.map (λ type => { pp? := type }),
})).toArray
}
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example (w x y z : Nat) (p : Nat → Prop)
(h : p (x * y + z * w * x)) : p (x * w * z + y * x) := by
simp [Nat.add_assoc, Nat.add_comm, Nat.add_left_comm, Nat.mul_comm, Nat.mul_assoc, Nat.mul_left_comm] at *
assumption
def test_arith: TestM Unit := do
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let state? ← startProof (.expr "∀ (w x y z : Nat) (p : Nat → Prop) (h : p (x * y + z * w * x)), p (x * w * z + y * x)")
let state0 ← match state? with
| .some state => pure state
| .none => do
addTest $ assertUnreachable "Goal could not parse"
return ()
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let tactic := "intros"
let state1 ← match ← state0.tacticOn (goalId := 0) (tactic := tactic) with
| .success state => pure state
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| other => do
addTest $ assertUnreachable $ other.toString
return ()
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addTest $ LSpec.check tactic (state1.goals.length = 1)
addTest $ LSpec.test "(1 root)" state1.rootExpr?.isNone
let state2 ← match ← state1.tacticOn (goalId := 0) (tactic := "simp [Nat.add_assoc, Nat.add_comm, Nat.add_left_comm, Nat.mul_comm, Nat.mul_assoc, Nat.mul_left_comm] at *") with
| .success state => pure state
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| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check "simp ..." (state2.goals.length = 1)
addTest $ LSpec.check "(2 root)" state2.rootExpr?.isNone
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let tactic := "assumption"
let state3 ← match ← state2.tacticOn (goalId := 0) (tactic := tactic) with
| .success state => pure state
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| other => do
addTest $ assertUnreachable $ other.toString
return ()
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addTest $ LSpec.test tactic state3.goals.isEmpty
addTest $ LSpec.check "(3 root)" state3.rootExpr?.isSome
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return ()
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-- Two ways to write the same theorem
example: ∀ (p q: Prop), p q → q p := by
intro p q h
cases h
apply Or.inr
assumption
apply Or.inl
assumption
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example: ∀ (p q: Prop), p q → q p := by
intro p q h
cases h
. apply Or.inr
assumption
. apply Or.inl
assumption
def test_or_comm: TestM Unit := do
let state? ← startProof (.expr "∀ (p q: Prop), p q → q p")
let state0 ← match state? with
| .some state => pure state
| .none => do
addTest $ assertUnreachable "Goal could not parse"
return ()
addTest $ LSpec.check "(0 parent)" state0.parentExpr?.isNone
addTest $ LSpec.check "(0 root)" state0.rootExpr?.isNone
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let tactic := "intro p q h"
let state1 ← match ← state0.tacticOn (goalId := 0) (tactic := tactic) with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
let fvP := "_uniq.10"
let fvQ := "_uniq.13"
let fvH := "_uniq.16"
let state1g0 := "_uniq.17"
addTest $ LSpec.check tactic ((← state1.serializeGoals (options := ← read)) =
#[{
name := state1g0,
target := { pp? := .some "q p" },
vars := #[
{ name := fvP, userName := "p", type? := .some { pp? := .some "Prop" } },
{ name := fvQ, userName := "q", type? := .some { pp? := .some "Prop" } },
{ name := fvH, userName := "h", type? := .some { pp? := .some "p q" } }
]
}])
addTest $ LSpec.check "(1 parent)" state1.parentExpr?.isSome
addTest $ LSpec.check "(1 root)" state1.rootExpr?.isNone
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let state1parent ← state1.withParentContext do
serializeExpressionSexp (← instantiateAll state1.parentExpr?.get!) (sanitize := false)
addTest $ LSpec.test "(1 parent)" (state1parent == s!"(:lambda p (:sort 0) (:lambda q (:sort 0) (:lambda h ((:c Or) 1 0) (:subst (:mv {state1g0}) 2 1 0))))")
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let tactic := "cases h"
let state2 ← match ← state1.tacticOn (goalId := 0) (tactic := tactic) with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
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addTest $ LSpec.check tactic ((← state2.serializeGoals (options := ← read)).map (·.devolatilize) =
#[branchGoal "inl" "p", branchGoal "inr" "q"])
let (caseL, caseR) := ("_uniq.64", "_uniq.77")
addTest $ LSpec.check tactic ((← state2.serializeGoals (options := ← read)).map (·.name) =
#[caseL, caseR])
addTest $ LSpec.check "(2 parent exists)" state2.parentExpr?.isSome
addTest $ LSpec.check "(2 root)" state2.rootExpr?.isNone
let state2parent ← state2.withParentContext do
serializeExpressionSexp (← instantiateAll state2.parentExpr?.get!) (sanitize := false)
let orPQ := s!"((:c Or) (:fv {fvP}) (:fv {fvQ}))"
let orQP := s!"((:c Or) (:fv {fvQ}) (:fv {fvP}))"
let motive := s!"(:lambda t._@._hyg.26 {orPQ} (:forall h ((:c Eq) ((:c Or) (:fv {fvP}) (:fv {fvQ})) (:fv {fvH}) 0) {orQP}))"
let caseL := s!"(:lambda h._@._hyg.27 (:fv {fvP}) (:lambda h._@._hyg.28 ((:c Eq) {orPQ} (:fv {fvH}) ((:c Or.inl) (:fv {fvP}) (:fv {fvQ}) 0)) (:subst (:mv {caseL}) (:fv {fvP}) (:fv {fvQ}) 1)))"
let caseR := s!"(:lambda h._@._hyg.29 (:fv {fvQ}) (:lambda h._@._hyg.30 ((:c Eq) {orPQ} (:fv {fvH}) ((:c Or.inr) (:fv {fvP}) (:fv {fvQ}) 0)) (:subst (:mv {caseR}) (:fv {fvP}) (:fv {fvQ}) 1)))"
let conduit := s!"((:c Eq.refl) {orPQ} (:fv {fvH}))"
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addTest $ LSpec.test "(2 parent)" (state2parent ==
s!"((:c Or.casesOn) (:fv {fvP}) (:fv {fvQ}) {motive} (:fv {fvH}) {caseL} {caseR} {conduit})")
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let state3_1 ← match ← state2.tacticOn (goalId := 0) (tactic := "apply Or.inr") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
let state3_1parent ← state3_1.withParentContext do
serializeExpressionSexp (← instantiateAll state3_1.parentExpr?.get!) (sanitize := false)
addTest $ LSpec.test "(3_1 parent)" (state3_1parent == s!"((:c Or.inr) (:fv {fvQ}) (:fv {fvP}) (:mv _uniq.91))")
addTest $ LSpec.check "· apply Or.inr" (state3_1.goals.length = 1)
let state4_1 ← match ← state3_1.tacticOn (goalId := 0) (tactic := "assumption") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check " assumption" state4_1.goals.isEmpty
let state4_1parent ← instantiateAll state4_1.parentExpr?.get!
addTest $ LSpec.test "(4_1 parent)" state4_1parent.isFVar
addTest $ LSpec.check "(4_1 root)" state4_1.rootExpr?.isNone
let state3_2 ← match ← state2.tacticOn (goalId := 1) (tactic := "apply Or.inl") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check "· apply Or.inl" (state3_2.goals.length = 1)
let state4_2 ← match ← state3_2.tacticOn (goalId := 0) (tactic := "assumption") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check " assumption" state4_2.goals.isEmpty
addTest $ LSpec.check "(4_2 root)" state4_2.rootExpr?.isNone
-- Ensure the proof can continue from `state4_2`.
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let state2b ← match state4_2.continue state2 with
| .error msg => do
addTest $ assertUnreachable $ msg
return ()
| .ok state => pure state
addTest $ LSpec.test "(resume)" (state2b.goals == [state2.goals.get! 0])
let state3_1 ← match ← state2b.tacticOn (goalId := 0) (tactic := "apply Or.inr") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check "· apply Or.inr" (state3_1.goals.length = 1)
let state4_1 ← match ← state3_1.tacticOn (goalId := 0) (tactic := "assumption") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check " assumption" state4_1.goals.isEmpty
addTest $ LSpec.check "(4_1 root)" state4_1.rootExpr?.isSome
return ()
where
typeProp: Protocol.Expression := { pp? := .some "Prop" }
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branchGoal (caseName varName: String): Protocol.Goal := {
userName? := .some caseName,
target := { pp? := .some "q p" },
vars := #[
{ userName := "p", type? := .some typeProp },
{ userName := "q", type? := .some typeProp },
{ userName := "h✝", type? := .some { pp? := .some varName }, isInaccessible := true }
]
}
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example : ∀ (a b c1 c2: Nat), (b + a) + c1 = (b + a) + c2 → (a + b) + c1 = (b + a) + c2 := by
intro a b c1 c2 h
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conv =>
lhs
congr
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. rw [Nat.add_comm]
. rfl
exact h
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def test_conv: TestM Unit := do
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let state? ← startProof (.expr "∀ (a b c1 c2: Nat), (b + a) + c1 = (b + a) + c2 → (a + b) + c1 = (b + a) + c2")
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let state0 ← match state? with
| .some state => pure state
| .none => do
addTest $ assertUnreachable "Goal could not parse"
return ()
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let tactic := "intro a b c1 c2 h"
let state1 ← match ← state0.tacticOn (goalId := 0) (tactic := tactic) with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check tactic ((← state1.serializeGoals (options := ← read)).map (·.devolatilize) =
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#[interiorGoal [] "a + b + c1 = b + a + c2"])
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let state2 ← match ← state1.conv (state1.get! 0) with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
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addTest $ LSpec.check "conv => ..." ((← state2.serializeGoals (options := ← read)).map (·.devolatilize) =
#[{ interiorGoal [] "a + b + c1 = b + a + c2" with isConversion := true }])
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let convTactic := "rhs"
let state3R ← match ← state2.tacticOn (goalId := 0) convTactic with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
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addTest $ LSpec.check s!" {convTactic} (discard)" ((← state3R.serializeGoals (options := ← read)).map (·.devolatilize) =
#[{ interiorGoal [] "b + a + c2" with isConversion := true }])
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let convTactic := "lhs"
let state3L ← match ← state2.tacticOn (goalId := 0) convTactic with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check s!" {convTactic}" ((← state3L.serializeGoals (options := ← read)).map (·.devolatilize) =
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#[{ interiorGoal [] "a + b + c1" with isConversion := true }])
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let convTactic := "congr"
let state4 ← match ← state3L.tacticOn (goalId := 0) convTactic with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check s!" {convTactic}" ((← state4.serializeGoals (options := ← read)).map (·.devolatilize) =
#[
{ interiorGoal [] "a + b" with isConversion := true, userName? := .some "a" },
{ interiorGoal [] "c1" with isConversion := true, userName? := .some "a" }
])
let convTactic := "rw [Nat.add_comm]"
let state5_1 ← match ← state4.tacticOn (goalId := 0) convTactic with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check s!" · {convTactic}" ((← state5_1.serializeGoals (options := ← read)).map (·.devolatilize) =
#[{ interiorGoal [] "b + a" with isConversion := true, userName? := .some "a" }])
let convTactic := "rfl"
let state6_1 ← match ← state5_1.tacticOn (goalId := 0) convTactic with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check s!" {convTactic}" ((← state6_1.serializeGoals (options := ← read)).map (·.devolatilize) =
#[])
let state4_1 ← match state6_1.continue state4 with
| .ok state => pure state
| .error e => do
addTest $ expectationFailure "continue" e
return ()
let convTactic := "rfl"
let state6 ← match ← state4_1.tacticOn (goalId := 0) convTactic with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check s!" · {convTactic}" ((← state6.serializeGoals (options := ← read)).map (·.devolatilize) =
#[])
let state1_1 ← match ← state6.convExit with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
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let tactic := "exact h"
let stateF ← match ← state1_1.tacticOn (goalId := 0) (tactic := tactic) with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check tactic ((← stateF.serializeGoals (options := ← read)).map (·.devolatilize) =
#[])
where
h := "b + a + c1 = b + a + c2"
interiorGoal (free: List (String × String)) (target: String) :=
let free := [("a", "Nat"), ("b", "Nat"), ("c1", "Nat"), ("c2", "Nat"), ("h", h)] ++ free
buildGoal free target
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example : ∀ (a b c d: Nat), a + b = b + c → b + c = c + d → a + b = c + d := by
intro a b c d h1 h2
calc a + b = b + c := by apply h1
_ = c + d := by apply h2
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def test_calc: TestM Unit := do
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let state? ← startProof (.expr "∀ (a b c d: Nat), a + b = b + c → b + c = c + d → a + b = c + d")
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let state0 ← match state? with
| .some state => pure state
| .none => do
addTest $ assertUnreachable "Goal could not parse"
return ()
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let tactic := "intro a b c d h1 h2"
let state1 ← match ← state0.tacticOn (goalId := 0) (tactic := tactic) with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check tactic ((← state1.serializeGoals (options := ← read)).map (·.devolatilize) =
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#[interiorGoal [] "a + b = c + d"])
let pred := "a + b = b + c"
let state2 ← match ← state1.tryCalc (state1.get! 0) (pred := pred) with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
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addTest $ LSpec.check s!"calc {pred} := _" ((← state2.serializeGoals (options := ← read)).map (·.devolatilize) =
#[
interiorGoal [] "a + b = b + c" (.some "calc"),
interiorGoal [] "b + c = c + d"
])
addTest $ LSpec.test "(2.0 prev rhs)" (state2.calcPrevRhsOf? (state2.get! 0) |>.isNone)
addTest $ LSpec.test "(2.1 prev rhs)" (state2.calcPrevRhsOf? (state2.get! 1) |>.isSome)
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let tactic := "apply h1"
let state2m ← match ← state2.tacticOn (goalId := 0) (tactic := tactic) with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
let state3 ← match state2m.continue state2 with
| .ok state => pure state
| .error e => do
addTest $ expectationFailure "continue" e
return ()
let pred := "_ = c + d"
let state4 ← match ← state3.tryCalc (state3.get! 0) (pred := pred) with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check s!"calc {pred} := _" ((← state4.serializeGoals (options := ← read)).map (·.devolatilize) =
#[
interiorGoal [] "b + c = c + d" (.some "calc")
])
addTest $ LSpec.test "(4.0 prev rhs)" (state4.calcPrevRhsOf? (state4.get! 0) |>.isNone)
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let tactic := "apply h2"
let state4m ← match ← state4.tacticOn (goalId := 0) (tactic := tactic) with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.test "(4m root)" state4m.rootExpr?.isSome
where
interiorGoal (free: List (String × String)) (target: String) (userName?: Option String := .none) :=
let free := [("a", "Nat"), ("b", "Nat"), ("c", "Nat"), ("d", "Nat"),
("h1", "a + b = b + c"), ("h2", "b + c = c + d")] ++ free
buildGoal free target userName?
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def test_nat_zero_add: TestM Unit := do
let state? ← startProof (.expr "∀ (n: Nat), n + 0 = n")
let state0 ← match state? with
| .some state => pure state
| .none => do
addTest $ assertUnreachable "Goal could not parse"
return ()
let tactic := "intro n"
let state1 ← match ← state0.tacticOn (goalId := 0) (tactic := tactic) with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check tactic ((← state1.serializeGoals (options := ← read)).map (·.devolatilize) =
#[buildGoal [("n", "Nat")] "n + 0 = n"])
let recursor := "@Nat.brecOn"
let state2 ← match ← state1.tryMotivatedApply (state1.get! 0) (recursor := recursor) with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check s!"mapply {recursor}" ((← state2.serializeGoals (options := ← read)).map (·.devolatilizeVars) =
#[
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buildNamedGoal "_uniq.67" [("n", "Nat")] "Nat → Prop" (.some "motive"),
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buildNamedGoal "_uniq.68" [("n", "Nat")] "Nat",
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buildNamedGoal "_uniq.69" [("n", "Nat")] "∀ (t : Nat), Nat.below t → ?motive t",
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buildNamedGoal "_uniq.70" [("n", "Nat")] "?motive ?m.68 = (n + 0 = n)" (.some "conduit")
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])
let tactic := "exact n"
let state3b ← match ← state2.tacticOn (goalId := 1) (tactic := tactic) with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check tactic ((← state3b.serializeGoals (options := ← read)).map (·.devolatilize) =
#[])
let state2b ← match state3b.continue state2 with
| .ok state => pure state
| .error e => do
addTest $ assertUnreachable e
return ()
let tactic := "exact (λ x => x + 0 = x)"
let state3c ← match ← state2b.tacticOn (goalId := 0) (tactic := tactic) with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check tactic ((← state3c.serializeGoals (options := ← read)).map (·.devolatilize) =
#[])
let state2c ← match state3c.continue state2b with
| .ok state => pure state
| .error e => do
addTest $ assertUnreachable e
return ()
let tactic := "intro t h"
let state3 ← match ← state2c.tacticOn (goalId := 0) (tactic := tactic) with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check tactic ((← state3.serializeGoals (options := ← read)).map (·.devolatilize) =
#[buildGoal [("n", "Nat"), ("t", "Nat"), ("h", "Nat.below t")] "t + 0 = t"])
let tactic := "simp"
let state3d ← match ← state3.tacticOn (goalId := 0) (tactic := tactic) with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
let state2d ← match state3d.continue state2c with
| .ok state => pure state
| .error e => do
addTest $ assertUnreachable e
return ()
let tactic := "rfl"
let stateF ← match ← state2d.tacticOn (goalId := 0) (tactic := tactic) with
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| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check tactic ((← stateF.serializeGoals (options := ← read)) =
#[])
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let expr := stateF.mctx.eAssignment.find! stateF.root
let (expr, _) := instantiateMVarsCore (mctx := stateF.mctx) (e := expr)
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addTest $ LSpec.check "(F root)" stateF.rootExpr?.isSome
def test_nat_zero_add_alt: TestM Unit := do
let state? ← startProof (.expr "∀ (n: Nat), n + 0 = n")
let state0 ← match state? with
| .some state => pure state
| .none => do
addTest $ assertUnreachable "Goal could not parse"
return ()
let tactic := "intro n"
let state1 ← match ← state0.tacticOn (goalId := 0) (tactic := tactic) with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check tactic ((← state1.serializeGoals (options := ← read)).map (·.devolatilize) =
#[buildGoal [("n", "Nat")] "n + 0 = n"])
let recursor := "@Nat.brecOn"
let state2 ← match ← state1.tryMotivatedApply (state1.get! 0) (recursor := recursor) with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
let major := "_uniq.68"
addTest $ LSpec.check s!"mapply {recursor}" ((← state2.serializeGoals (options := ← read)).map (·.devolatilizeVars) =
#[
buildNamedGoal "_uniq.67" [("n", "Nat")] "Nat → Prop" (.some "motive"),
buildNamedGoal major [("n", "Nat")] "Nat",
buildNamedGoal "_uniq.69" [("n", "Nat")] "∀ (t : Nat), Nat.below t → ?motive t",
buildNamedGoal "_uniq.70" [("n", "Nat")] "?motive ?m.68 = (n + 0 = n)" (.some "conduit")
])
let tactic := "intro x"
let state3m ← match ← state2.tacticOn (goalId := 0) (tactic := tactic) with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check tactic ((← state3m.serializeGoals (options := ← read)).map (·.devolatilize) =
#[buildGoal [("n", "Nat"), ("x", "Nat")] "Prop" (.some "motive")])
let tactic := "apply Eq"
let state3m2 ← match ← state3m.tacticOn (goalId := 0) (tactic := tactic) with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
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let (eqL, eqR, eqT) := ("_uniq.88", "_uniq.89", "_uniq.87")
addTest $ LSpec.check tactic $ state3m2.goals.map (·.name.toString) = [eqL, eqR, eqT]
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let [_motive, _major, _step, conduit] := state2.goals | panic! "Goals conflict"
let state2b ← match state3m2.resume [conduit] with
| .ok state => pure state
| .error e => do
addTest $ assertUnreachable e
return ()
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let cNatAdd := "(:c HAdd.hAdd) (:c Nat) (:c Nat) (:c Nat) ((:c instHAdd) (:c Nat) (:c instAddNat))"
let cNat0 := "((:c OfNat.ofNat) (:c Nat) (:lit 0) ((:c instOfNatNat) (:lit 0)))"
let fvN := "_uniq.63"
let conduitRight := s!"((:c Eq) (:c Nat) ({cNatAdd} (:fv {fvN}) {cNat0}) (:fv {fvN}))"
let substOf (mv: String) := s!"(:subst (:mv {mv}) (:fv {fvN}) (:mv {major}))"
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addTest $ LSpec.check "resume" ((← state2b.serializeGoals (options := { ← read with printExprAST := true })) =
#[
{
name := "_uniq.70",
userName? := .some "conduit",
target := {
pp? := .some "(?m.92 ?m.68 = ?m.94 ?m.68) = (n + 0 = n)",
sexp? := .some s!"((:c Eq) (:sort 0) ((:c Eq) {substOf eqT} {substOf eqL} {substOf eqR}) {conduitRight})",
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},
vars := #[{
name := fvN,
userName := "n",
type? := .some { pp? := .some "Nat", sexp? := .some "(:c Nat)" },
}],
}
])
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def suite (env: Environment): List (String × IO LSpec.TestSeq) :=
let tests := [
("identity", test_identity),
("Nat.add_comm", test_nat_add_comm false),
("Nat.add_comm manual", test_nat_add_comm true),
("Nat.add_comm delta", test_delta_variable),
("arithmetic", test_arith),
("Or.comm", test_or_comm),
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("conv", test_conv),
("calc", test_calc),
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("Nat.zero_add", test_nat_zero_add),
("Nat.zero_add alt", test_nat_zero_add_alt),
]
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tests.map (fun (name, test) => (name, proofRunner env test))
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end Pantograph.Test.Proofs