chore: Version 0.3 #136

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aniva wants to merge 487 commits from dev into main
13 changed files with 299 additions and 195 deletions
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@ -46,7 +46,7 @@ namespace Lean
def setOptionFromString' (opts : Options) (entry : String) : ExceptT String IO Options := do def setOptionFromString' (opts : Options) (entry : String) : ExceptT String IO Options := do
let ps := (entry.splitOn "=").map String.trim let ps := (entry.splitOn "=").map String.trim
let [key, val] ← pure ps | throw "invalid configuration option entry, it must be of the form '<key> = <value>'" let [key, val] ← pure ps | throw "invalid configuration option entry, it must be of the form '<key> = <value>'"
let key := Pantograph.str_to_name key let key := key.toName
let defValue ← getOptionDefaultValue key let defValue ← getOptionDefaultValue key
match defValue with match defValue with
| DataValue.ofString _ => pure $ opts.setString key val | DataValue.ofString _ => pure $ opts.setString key val
@ -88,7 +88,7 @@ unsafe def main (args: List String): IO Unit := do
let imports:= args.filter (λ s => ¬ (s.startsWith "--")) let imports:= args.filter (λ s => ¬ (s.startsWith "--"))
let env ← Lean.importModules let env ← Lean.importModules
(imports := imports.toArray.map (λ str => { module := str_to_name str, runtimeOnly := false })) (imports := imports.toArray.map (λ str => { module := str.toName, runtimeOnly := false }))
(opts := {}) (opts := {})
(trustLevel := 1) (trustLevel := 1)
let context: Context := { let context: Context := {

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@ -30,16 +30,17 @@ def execute (command: Protocol.Command): MainM Lean.Json := do
| .error ierror => return Lean.toJson ierror | .error ierror => return Lean.toJson ierror
| .error error => return Lean.toJson $ errorCommand s!"Unable to parse json: {error}" | .error error => return Lean.toJson $ errorCommand s!"Unable to parse json: {error}"
match command.cmd with match command.cmd with
| "reset" => run reset | "reset" => run reset
| "stat" => run stat | "stat" => run stat
| "expr.echo" => run expr_echo | "expr.echo" => run expr_echo
| "lib.catalog" => run lib_catalog | "lib.catalog" => run lib_catalog
| "lib.inspect" => run lib_inspect | "lib.inspect" => run lib_inspect
| "options.set" => run options_set | "options.set" => run options_set
| "options.print" => run options_print | "options.print" => run options_print
| "goal.start" => run goal_start | "goal.start" => run goal_start
| "goal.tactic" => run goal_tactic | "goal.tactic" => run goal_tactic
| "goal.delete" => run goal_delete | "goal.continue" => run goal_continue
| "goal.delete" => run goal_delete
| "goal.print" => run goal_print | "goal.print" => run goal_print
| cmd => | cmd =>
let error: Protocol.InteractionError := let error: Protocol.InteractionError :=
@ -53,7 +54,7 @@ def execute (command: Protocol.Command): MainM Lean.Json := do
reset (_: Protocol.Reset): MainM (CR Protocol.StatResult) := do reset (_: Protocol.Reset): MainM (CR Protocol.StatResult) := do
let state ← get let state ← get
let nGoals := state.goalStates.size let nGoals := state.goalStates.size
set { state with goalStates := Lean.HashMap.empty } set { state with nextId := 0, goalStates := Lean.HashMap.empty }
return .ok { nGoals } return .ok { nGoals }
stat (_: Protocol.Stat): MainM (CR Protocol.StatResult) := do stat (_: Protocol.Stat): MainM (CR Protocol.StatResult) := do
let state ← get let state ← get
@ -69,7 +70,7 @@ def execute (command: Protocol.Command): MainM Lean.Json := do
lib_inspect (args: Protocol.LibInspect): MainM (CR Protocol.LibInspectResult) := do lib_inspect (args: Protocol.LibInspect): MainM (CR Protocol.LibInspectResult) := do
let state ← get let state ← get
let env ← Lean.MonadEnv.getEnv let env ← Lean.MonadEnv.getEnv
let name := str_to_name args.name let name := args.name.toName
let info? := env.find? name let info? := env.find? name
match info? with match info? with
| none => return .error $ errorIndex s!"Symbol not found {args.name}" | none => return .error $ errorIndex s!"Symbol not found {args.name}"
@ -132,7 +133,7 @@ def execute (command: Protocol.Command): MainM Lean.Json := do
| .error str => return .error <| errorI "elab" str | .error str => return .error <| errorI "elab" str
| .ok expr => return .ok expr)) | .ok expr => return .ok expr))
| .none, .some copyFrom => | .none, .some copyFrom =>
(match env.find? <| str_to_name copyFrom with (match env.find? <| copyFrom.toName with
| .none => return .error <| errorIndex s!"Symbol not found: {copyFrom}" | .none => return .error <| errorIndex s!"Symbol not found: {copyFrom}"
| .some cInfo => return .ok cInfo.type) | .some cInfo => return .ok cInfo.type)
| _, _ => | _, _ =>
@ -142,9 +143,11 @@ def execute (command: Protocol.Command): MainM Lean.Json := do
| .ok expr => | .ok expr =>
let goalState ← GoalState.create expr let goalState ← GoalState.create expr
let stateId := state.nextId let stateId := state.nextId
let goalStates := state.goalStates.insert stateId goalState set { state with
set { state with goalStates, nextId := state.nextId + 1 } goalStates := state.goalStates.insert stateId goalState,
return .ok { stateId } nextId := state.nextId + 1
}
return .ok { stateId, root := goalState.root.name.toString }
goal_tactic (args: Protocol.GoalTactic): MainM (CR Protocol.GoalTacticResult) := do goal_tactic (args: Protocol.GoalTactic): MainM (CR Protocol.GoalTacticResult) := do
let state ← get let state ← get
match state.goalStates.find? args.stateId with match state.goalStates.find? args.stateId with
@ -160,8 +163,10 @@ def execute (command: Protocol.Command): MainM Lean.Json := do
| .error error => return .error error | .error error => return .error error
| .ok (.success nextGoalState) => | .ok (.success nextGoalState) =>
let nextStateId := state.nextId let nextStateId := state.nextId
let goalStates := state.goalStates.insert state.nextId goalState set { state with
set { state with goalStates, nextId := state.nextId + 1 } goalStates := state.goalStates.insert state.nextId nextGoalState,
nextId := state.nextId + 1,
}
let goals ← nextGoalState.serializeGoals (parent := .some goalState) (options := state.options) let goals ← nextGoalState.serializeGoals (parent := .some goalState) (options := state.options)
return .ok { return .ok {
nextStateId? := .some nextStateId, nextStateId? := .some nextStateId,
@ -173,6 +178,33 @@ def execute (command: Protocol.Command): MainM Lean.Json := do
return .error $ errorIndex s!"Invalid goal id index {goalId}" return .error $ errorIndex s!"Invalid goal id index {goalId}"
| .ok (.failure messages) => | .ok (.failure messages) =>
return .ok { tacticErrors? := .some messages } return .ok { tacticErrors? := .some messages }
goal_continue (args: Protocol.GoalContinue): MainM (CR Protocol.GoalContinueResult) := do
let state ← get
match state.goalStates.find? args.target with
| .none => return .error $ errorIndex s!"Invalid state index {args.target}"
| .some target => do
let nextState? ← match args.branch?, args.goals? with
| .some branchId, .none => do
match state.goalStates.find? branchId with
| .none => return .error $ errorIndex s!"Invalid state index {branchId}"
| .some branch => pure $ target.continue branch
| .none, .some goals =>
let goals := goals.map (λ name => { name := name.toName })
pure $ target.resume goals
| _, _ => return .error <| errorI "arguments" "Exactly one of {branch, goals} must be supplied"
match nextState? with
| .error error => return .ok { error? := .some error }
| .ok nextGoalState =>
let nextStateId := state.nextId
set { state with
goalStates := state.goalStates.insert nextStateId nextGoalState,
nextId := state.nextId + 1
}
let goals ← nextGoalState.serializeGoals (parent := .none) (options := state.options)
return .ok {
nextStateId? := .some nextStateId,
goals? := .some goals,
}
goal_delete (args: Protocol.GoalDelete): MainM (CR Protocol.GoalDeleteResult) := do goal_delete (args: Protocol.GoalDelete): MainM (CR Protocol.GoalDeleteResult) := do
let state ← get let state ← get
let goalStates := args.stateIds.foldl (λ map id => map.erase id) state.goalStates let goalStates := args.stateIds.foldl (λ map id => map.erase id) state.goalStates

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@ -169,27 +169,36 @@ protected def GoalState.tryAssign (state: GoalState) (goalId: Nat) (expr: String
return .failure #[← exception.toMessageData.toString] return .failure #[← exception.toMessageData.toString]
tacticM { elaborator := .anonymous } |>.run' state.savedState.tactic tacticM { elaborator := .anonymous } |>.run' state.savedState.tactic
/-- After finishing one branch of a proof (`graftee`), pick up from the point where the proof was left off (`target`) -/ /--
protected def GoalState.continue (target: GoalState) (graftee: GoalState): Except String GoalState := Brings into scope a list of goals
if target.root != graftee.root then -/
.error s!"Roots of two continued goal states do not match: {target.root.name} != {graftee.root.name}" protected def GoalState.resume (state: GoalState) (goals: List MVarId): Except String GoalState :=
-- Ensure goals are not dangling if ¬ (goals.all (λ goal => state.mvars.contains goal)) then
else if ¬ (target.goals.all (λ goal => graftee.mvars.contains goal)) then .error s!"Goals not in scope"
.error s!"Some goals in target are not present in the graftee"
else else
-- Set goals to the goals that have not been assigned yet, similar to the `focus` tactic. -- Set goals to the goals that have not been assigned yet, similar to the `focus` tactic.
let unassigned := target.goals.filter (λ goal => let unassigned := goals.filter (λ goal =>
let mctx := graftee.mctx let mctx := state.mctx
¬(mctx.eAssignment.contains goal || mctx.dAssignment.contains goal)) ¬(mctx.eAssignment.contains goal || mctx.dAssignment.contains goal))
.ok { .ok {
state with
savedState := { savedState := {
term := graftee.savedState.term, term := state.savedState.term,
tactic := { goals := unassigned }, tactic := { goals := unassigned },
}, },
root := target.root,
newMVars := graftee.newMVars,
} }
/--
Brings into scope all goals from `branch`
-/
protected def GoalState.continue (target: GoalState) (branch: GoalState): Except String GoalState :=
if !target.goals.isEmpty then
.error s!"Target state has unresolved goals"
else if target.root != branch.root then
.error s!"Roots of two continued goal states do not match: {target.root.name} != {branch.root.name}"
else
target.resume (goals := branch.goals)
protected def GoalState.rootExpr? (goalState: GoalState): Option Expr := protected def GoalState.rootExpr? (goalState: GoalState): Option Expr :=
let expr := goalState.mctx.eAssignment.find! goalState.root let expr := goalState.mctx.eAssignment.find! goalState.root
let (expr, _) := instantiateMVarsCore (mctx := goalState.mctx) (e := expr) let (expr, _) := instantiateMVarsCore (mctx := goalState.mctx) (e := expr)

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@ -142,6 +142,8 @@ structure GoalStart where
deriving Lean.FromJson deriving Lean.FromJson
structure GoalStartResult where structure GoalStartResult where
stateId: Nat := 0 stateId: Nat := 0
-- Name of the root metavariable
root: String
deriving Lean.ToJson deriving Lean.ToJson
structure GoalTactic where structure GoalTactic where
-- Identifiers for tree, state, and goal -- Identifiers for tree, state, and goal
@ -163,6 +165,21 @@ structure GoalTacticResult where
-- Existence of this field shows the tactic parsing has failed -- Existence of this field shows the tactic parsing has failed
parseError?: Option String := .none parseError?: Option String := .none
deriving Lean.ToJson deriving Lean.ToJson
structure GoalContinue where
-- State from which the continuation acquires the context
target: Nat
-- One of the following must be supplied
-- The state which is an ancestor of `target` where goals will be extracted from
branch?: Option Nat := .none
-- Or, the particular goals that should be brought back into scope
goals?: Option (List String) := .none
deriving Lean.FromJson
structure GoalContinueResult where
error?: Option String := .none
nextStateId?: Option Nat := .none
goals?: Option (Array Goal) := .none
deriving Lean.ToJson
-- Remove goal states -- Remove goal states
structure GoalDelete where structure GoalDelete where

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@ -2,10 +2,6 @@ import Lean.Declaration
namespace Pantograph namespace Pantograph
/-- Converts a symbol of the form `aa.bb.cc` to a name -/
def str_to_name (s: String): Lean.Name :=
(s.splitOn ".").foldl Lean.Name.str Lean.Name.anonymous
def is_symbol_unsafe_or_internal (n: Lean.Name) (info: Lean.ConstantInfo): Bool := def is_symbol_unsafe_or_internal (n: Lean.Name) (info: Lean.ConstantInfo): Bool :=
let nameDeduce: Bool := match n.getRoot with let nameDeduce: Bool := match n.getRoot with
| .str _ name => name.startsWith "_" name == "Lean" | .str _ name => name.startsWith "_" name == "Lean"

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@ -1,5 +1,5 @@
namespace Pantograph namespace Pantograph
def version := "0.2.7" def version := "0.2.8"
end Pantograph end Pantograph

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@ -33,7 +33,7 @@ result of a command execution. The command can be passed in one of two formats
command { ... } command { ... }
{ "cmd": command, "payload": ... } { "cmd": command, "payload": ... }
``` ```
The list of available commands can be found in `Pantograph/Commands.lean` and below. An The list of available commands can be found in `Pantograph/Protocol.lean` and below. An
empty command aborts the REPL. empty command aborts the REPL.
The `pantograph` executable must be run with a list of modules to import. It can The `pantograph` executable must be run with a list of modules to import. It can
@ -54,18 +54,18 @@ Example proving a theorem: (alternatively use `goal.start {"copyFrom": "Nat.add_
``` ```
$ pantograph Init $ pantograph Init
goal.start {"expr": "∀ (n m : Nat), n + m = m + n"} goal.start {"expr": "∀ (n m : Nat), n + m = m + n"}
goal.tactic {"goalId": 0, "tactic": "intro n m"} goal.tactic {"stateId": 0, "goalId": 0, "tactic": "intro n m"}
goal.tactic {"goalId": 1, "tactic": "assumption"} goal.tactic {"stateId": 1, "goalId": 0, "tactic": "assumption"}
goal.delete {"goalIds": [0]} goal.delete {"stateIds": [0]}
stat {} stat {}
goal.tactic {"goalId": 1, "tactic": "rw [Nat.add_comm]"} goal.tactic {"stateId": 1, "goalId": 0, "tactic": "rw [Nat.add_comm]"}
stat stat
``` ```
where the application of `assumption` should lead to a failure. where the application of `assumption` should lead to a failure.
## Commands ## Commands
See `Pantograph/Commands.lean` for a description of the parameters and return values in JSON. See `Pantograph/Protocol.lean` for a description of the parameters and return values in JSON.
- `reset`: Delete all cached expressions and proof trees - `reset`: Delete all cached expressions and proof trees
- `expr.echo {"expr": <expr>}`: Determine the type of an expression and round-trip it - `expr.echo {"expr": <expr>}`: Determine the type of an expression and round-trip it
- `lib.catalog`: Display a list of all safe Lean symbols in the current context - `lib.catalog`: Display a list of all safe Lean symbols in the current context
@ -73,10 +73,11 @@ See `Pantograph/Commands.lean` for a description of the parameters and return va
given symbol; If value flag is set, the value is printed or hidden. By default given symbol; If value flag is set, the value is printed or hidden. By default
only the values of definitions are printed. only the values of definitions are printed.
- `options.set { key: value, ... }`: Set one or more options (not Lean options; those - `options.set { key: value, ... }`: Set one or more options (not Lean options; those
have to be set via command line arguments.), for options, see `Pantograph/Commands.lean` have to be set via command line arguments.), for options, see `Pantograph/Protocol.lean`
- `options.print`: Display the current set of options - `options.print`: Display the current set of options
- `goal.start {["name": <name>], ["expr": <expr>], ["copyFrom": <symbol>]}`: Start a new goal from a given expression or symbol - `goal.start {["name": <name>], ["expr": <expr>], ["copyFrom": <symbol>]}`: Start a new goal from a given expression or symbol
- `goal.tactic {"stateId": <id>, "goalId": <id>, ["tactic": <tactic>], ["expr": <expr>]}`: Execute a tactic string on a given goal - `goal.tactic {"stateId": <id>, "goalId": <id>, ["tactic": <tactic>], ["expr": <expr>]}`: Execute a tactic string on a given goal
- `goal.continue {"stateId": <id>, ["branch": <id>], ["goals": <names>]}`: Continue from a proof state
- `goal.remove {"stateIds": [<id>]}"`: Remove a bunch of stored goals. - `goal.remove {"stateIds": [<id>]}"`: Remove a bunch of stored goals.
- `goal.print {"stateId": <id>}"`: Print a goal state - `goal.print {"stateId": <id>}"`: Print a goal state
- `stat`: Display resource usage - `stat`: Display resource usage

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@ -1,4 +1,6 @@
import Pantograph.Protocol import Pantograph.Protocol
import Pantograph.Goal
import LSpec
namespace Pantograph namespace Pantograph
@ -15,6 +17,19 @@ def Goal.devolatilize (goal: Goal): Goal :=
v with v with
name := "" name := ""
} }
deriving instance DecidableEq, Repr for Expression
deriving instance DecidableEq, Repr for Variable
deriving instance DecidableEq, Repr for Goal
end Protocol end Protocol
def TacticResult.toString : TacticResult → String
| .success state => s!".success ({state.goals.length} goals)"
| .failure messages =>
let messages := "\n".intercalate messages.toList
s!".failure {messages}"
| .parseError error => s!".parseError {error}"
| .indexError index => s!".indexError {index}"
def assertUnreachable (message: String): LSpec.TestSeq := LSpec.check message false
end Pantograph end Pantograph

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@ -1,31 +1,28 @@
import LSpec import LSpec
import Pantograph.Goal import Pantograph.Goal
import Pantograph.Serial import Pantograph.Serial
import Test.Common
namespace Pantograph.Test.Holes namespace Pantograph.Test.Holes
open Pantograph open Pantograph
open Lean open Lean
abbrev TestM := StateRefT LSpec.TestSeq (ReaderT Commands.Options M) abbrev TestM := StateRefT LSpec.TestSeq (ReaderT Protocol.Options M)
deriving instance DecidableEq, Repr for Commands.Expression def addTest (test: LSpec.TestSeq): TestM Unit := do
deriving instance DecidableEq, Repr for Commands.Variable
deriving instance DecidableEq, Repr for Commands.Goal
def add_test (test: LSpec.TestSeq): TestM Unit := do
set $ (← get) ++ test set $ (← get) ++ test
def start_goal (hole: String): TestM (Option GoalState) := do def startProof (expr: String): TestM (Option GoalState) := do
let env ← Lean.MonadEnv.getEnv let env ← Lean.MonadEnv.getEnv
let syn? := syntax_from_str env hole let syn? := syntax_from_str env expr
add_test $ LSpec.check s!"Parsing {hole}" (syn?.isOk) addTest $ LSpec.check s!"Parsing {expr}" (syn?.isOk)
match syn? with match syn? with
| .error error => | .error error =>
IO.println error IO.println error
return Option.none return Option.none
| .ok syn => | .ok syn =>
let expr? ← syntax_to_expr syn let expr? ← syntax_to_expr_type syn
add_test $ LSpec.check s!"Elaborating" expr?.isOk addTest $ LSpec.check s!"Elaborating" expr?.isOk
match expr? with match expr? with
| .error error => | .error error =>
IO.println error IO.println error
@ -34,40 +31,21 @@ def start_goal (hole: String): TestM (Option GoalState) := do
let goal ← GoalState.create (expr := expr) let goal ← GoalState.create (expr := expr)
return Option.some goal return Option.some goal
def assert_unreachable (message: String): LSpec.TestSeq := LSpec.check message false def buildGoal (nameType: List (String × String)) (target: String) (userName?: Option String := .none): Protocol.Goal :=
def build_goal (nameType: List (String × String)) (target: String): Commands.Goal :=
{ {
userName?,
target := { pp? := .some target}, target := { pp? := .some target},
vars := (nameType.map fun x => ({ vars := (nameType.map fun x => ({
name := x.fst, userName := x.fst,
type? := .some { pp? := .some x.snd }, type? := .some { pp? := .some x.snd },
isInaccessible? := .some false isInaccessible? := .some false
})).toArray })).toArray
} }
-- Like `build_goal` but allow certain variables to be elided. def proofRunner (env: Lean.Environment) (tests: TestM Unit): IO LSpec.TestSeq := do
def build_goal_selective (nameType: List (String × Option String)) (target: String): Commands.Goal :=
{
target := { pp? := .some target},
vars := (nameType.map fun x => ({
name := x.fst,
type? := x.snd.map (λ type => { pp? := type }),
isInaccessible? := x.snd.map (λ _ => false)
})).toArray
}
def construct_sigma: TestM Unit := do
let goal? ← start_goal "∀ (n m: Nat), n + m = m + n"
add_test $ LSpec.check "Start goal" goal?.isSome
if let .some goal := goal? then
return ()
def proof_runner (env: Lean.Environment) (tests: TestM Unit): IO LSpec.TestSeq := do
let termElabM := tests.run LSpec.TestSeq.done |>.run {} -- with default options let termElabM := tests.run LSpec.TestSeq.done |>.run {} -- with default options
let coreContext: Lean.Core.Context := { let coreContext: Lean.Core.Context := {
currNamespace := str_to_name "Aniva", currNamespace := Name.append .anonymous "Aniva",
openDecls := [], -- No 'open' directives needed openDecls := [], -- No 'open' directives needed
fileName := "<Pantograph>", fileName := "<Pantograph>",
fileMap := { source := "", positions := #[0], lines := #[1] } fileMap := { source := "", positions := #[0], lines := #[1] }
@ -83,17 +61,155 @@ def proof_runner (env: Lean.Environment) (tests: TestM Unit): IO LSpec.TestSeq :
| .ok (_, a) => | .ok (_, a) =>
return a return a
/-- M-coupled goals -/
def test_m_couple: TestM Unit := do
let state? ← startProof "(2: Nat) ≤ 5"
let state0 ← match state? with
| .some state => pure state
| .none => do
addTest $ assertUnreachable "Goal could not parse"
return ()
let state1 ← match ← state0.execute (goalId := 0) (tactic := "apply Nat.le_trans") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check "apply Nat.le_trans" ((← state1.serializeGoals (options := ← read)).map (·.target.pp?) =
#[.some "2 ≤ ?m", .some "?m ≤ 5", .some "Nat"])
addTest $ LSpec.test "(1 root)" state1.rootExpr?.isNone
-- Set m to 3
let state2 ← match ← state1.execute (goalId := 2) (tactic := "exact 3") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.test "(1b root)" state2.rootExpr?.isNone
let state1b ← match state2.continue state1 with
| .error msg => do
addTest $ assertUnreachable $ msg
return ()
| .ok state => pure state
addTest $ LSpec.check "exact 3" ((← state1b.serializeGoals (options := ← read)).map (·.target.pp?) =
#[.some "2 ≤ 3", .some "3 ≤ 5"])
addTest $ LSpec.test "(2 root)" state1b.rootExpr?.isNone
return ()
def test_proposition_generation: TestM Unit := do
let state? ← startProof "Σ' p:Prop, p"
let state0 ← match state? with
| .some state => pure state
| .none => do
addTest $ assertUnreachable "Goal could not parse"
return ()
let state1 ← match ← state0.execute (goalId := 0) (tactic := "apply PSigma.mk") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check "apply PSigma.mk" ((← state1.serializeGoals (options := ← read)).map (·.devolatilize) =
#[
buildGoal [] "?fst" (userName? := .some "snd"),
buildGoal [] "Prop" (userName? := .some "fst")
])
if let #[goal1, goal2] := ← state1.serializeGoals (options := { (← read) with printExprAST := true }) then
addTest $ LSpec.test "(1 reference)" (goal1.target.sexp? = .some s!"(:mv {goal2.name})")
addTest $ LSpec.test "(1 root)" state1.rootExpr?.isNone
let state2 ← match ← state1.tryAssign (goalId := 0) (expr := "λ (x: Nat) => _") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check ":= λ (x: Nat), _" ((← state2.serializeGoals (options := ← read)).map (·.target.pp?) =
#[.some "Nat → Prop", .some "∀ (x : Nat), ?m.29 x"])
addTest $ LSpec.test "(2 root)" state2.rootExpr?.isNone
let state3 ← match ← state2.tryAssign (goalId := 1) (expr := "fun x => Eq.refl x") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check ":= Eq.refl" ((← state3.serializeGoals (options := ← read)).map (·.target.pp?) =
#[])
addTest $ LSpec.test "(3 root)" state3.rootExpr?.isSome
return ()
def test_partial_continuation: TestM Unit := do
let state? ← startProof "(2: Nat) ≤ 5"
let state0 ← match state? with
| .some state => pure state
| .none => do
addTest $ assertUnreachable "Goal could not parse"
return ()
let state1 ← match ← state0.execute (goalId := 0) (tactic := "apply Nat.le_trans") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check "apply Nat.le_trans" ((← state1.serializeGoals (options := ← read)).map (·.target.pp?) =
#[.some "2 ≤ ?m", .some "?m ≤ 5", .some "Nat"])
let state2 ← match ← state1.execute (goalId := 2) (tactic := "apply Nat.succ") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check "apply Nat.succ" ((← state2.serializeGoals (options := ← read)).map (·.target.pp?) =
#[.some "Nat"])
-- Execute a partial continuation
let coupled_goals := state1.goals ++ state2.goals
let state1b ← match state2.resume (goals := coupled_goals) with
| .error msg => do
addTest $ assertUnreachable $ msg
return ()
| .ok state => pure state
addTest $ LSpec.check "(continue)" ((← state1b.serializeGoals (options := ← read)).map (·.target.pp?) =
#[.some "2 ≤ Nat.succ ?m", .some "Nat.succ ?m ≤ 5", .some "Nat"])
addTest $ LSpec.test "(2 root)" state1b.rootExpr?.isNone
-- Roundtrip
--let coupled_goals := coupled_goals.map (λ g =>
-- { name := str_to_name $ name_to_ast g.name (sanitize := false)})
let coupled_goals := coupled_goals.map (λ g => name_to_ast g.name (sanitize := false))
let coupled_goals := coupled_goals.map (λ g => { name := g.toName })
let state1b ← match state2.resume (goals := coupled_goals) with
| .error msg => do
addTest $ assertUnreachable $ msg
return ()
| .ok state => pure state
addTest $ LSpec.check "(continue)" ((← state1b.serializeGoals (options := ← read)).map (·.target.pp?) =
#[.some "2 ≤ Nat.succ ?m", .some "Nat.succ ?m ≤ 5", .some "Nat"])
addTest $ LSpec.test "(2 root)" state1b.rootExpr?.isNone
-- Continuation should fail if the state does not exist:
match state0.resume coupled_goals with
| .error error => addTest $ LSpec.check "(continuation failure message)" (error = "Goals not in scope")
| .ok _ => addTest $ assertUnreachable "(continuation failure)"
-- Continuation should fail if some goals have not been solved
match state2.continue state1 with
| .error error => addTest $ LSpec.check "(continuation failure message)" (error = "Target state has unresolved goals")
| .ok _ => addTest $ assertUnreachable "(continuation failure)"
return ()
def suite: IO LSpec.TestSeq := do def suite: IO LSpec.TestSeq := do
let env: Lean.Environment ← Lean.importModules let env: Lean.Environment ← Lean.importModules
(imports := #["Init"].map (λ str => { module := str_to_name str, runtimeOnly := false })) (imports := #["Init"].map (λ str => { module := str.toName, runtimeOnly := false }))
(opts := {}) (opts := {})
(trustLevel := 1) (trustLevel := 1)
let tests := [ let tests := [
("Σ'", construct_sigma) ("2 < 5", test_m_couple),
("Proposition Generation", test_proposition_generation),
("Partial Continuation", test_partial_continuation)
] ]
let tests ← tests.foldlM (fun acc tests => do let tests ← tests.foldlM (fun acc tests => do
let (name, tests) := tests let (name, tests) := tests
let tests ← proof_runner env tests let tests ← proofRunner env tests
return acc ++ (LSpec.group name tests)) LSpec.TestSeq.done return acc ++ (LSpec.group name tests)) LSpec.TestSeq.done
return LSpec.group "Holes" tests return LSpec.group "Holes" tests

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@ -83,21 +83,36 @@ def test_malformed_command : IO LSpec.TestSeq :=
Protocol.InteractionError)) Protocol.InteractionError))
] ]
def test_tactic : IO LSpec.TestSeq := def test_tactic : IO LSpec.TestSeq :=
let goal: Protocol.Goal := { let goal1: Protocol.Goal := {
name := "_uniq.10", name := "_uniq.10",
target := { pp? := .some "∀ (q : Prop), x q → q x" }, target := { pp? := .some "∀ (q : Prop), x q → q x" },
vars := #[{ name := "_uniq.9", userName := "x", isInaccessible? := .some false, type? := .some { pp? := .some "Prop" }}], vars := #[{ name := "_uniq.9", userName := "x", isInaccessible? := .some false, type? := .some { pp? := .some "Prop" }}],
} }
let goal2: Protocol.Goal := {
name := "_uniq.13",
target := { pp? := .some "x y → y x" },
vars := #[
{ name := "_uniq.9", userName := "x", isInaccessible? := .some false, type? := .some { pp? := .some "Prop" }},
{ name := "_uniq.12", userName := "y", isInaccessible? := .some false, type? := .some { pp? := .some "Prop" }}
],
}
subroutine_runner [ subroutine_runner [
subroutine_step "goal.start" subroutine_step "goal.start"
[("expr", .str "∀ (p q: Prop), p q → q p")] [("expr", .str "∀ (p q: Prop), p q → q p")]
(Lean.toJson ({stateId := 0}: (Lean.toJson ({stateId := 0, root := "_uniq.8"}:
Protocol.GoalStartResult)), Protocol.GoalStartResult)),
subroutine_step "goal.tactic" subroutine_step "goal.tactic"
[("stateId", .num 0), ("goalId", .num 0), ("tactic", .str "intro x")] [("stateId", .num 0), ("goalId", .num 0), ("tactic", .str "intro x")]
(Lean.toJson ({ (Lean.toJson ({
nextStateId? := .some 1, nextStateId? := .some 1,
goals? := #[goal], goals? := #[goal1],
}:
Protocol.GoalTacticResult)),
subroutine_step "goal.tactic"
[("stateId", .num 1), ("goalId", .num 0), ("tactic", .str "intro y")]
(Lean.toJson ({
nextStateId? := .some 2,
goals? := #[goal2],
}: }:
Protocol.GoalTacticResult)) Protocol.GoalTacticResult))
] ]

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@ -1,5 +1,5 @@
import LSpec import LSpec
--import Test.Holes import Test.Holes
import Test.Integration import Test.Integration
import Test.Proofs import Test.Proofs
import Test.Serial import Test.Serial
@ -10,7 +10,7 @@ def main := do
Lean.initSearchPath (← Lean.findSysroot) Lean.initSearchPath (← Lean.findSysroot)
let suites := [ let suites := [
--Holes.suite, Holes.suite,
Integration.suite, Integration.suite,
Proofs.suite, Proofs.suite,
Serial.suite Serial.suite

View File

@ -6,17 +6,6 @@ import Pantograph.Goal
import Pantograph.Serial import Pantograph.Serial
import Test.Common import Test.Common
namespace Pantograph
def TacticResult.toString : TacticResult → String
| .success state => s!".success ({state.goals.length} goals)"
| .failure messages =>
let messages := "\n".intercalate messages.toList
s!".failure {messages}"
| .parseError error => s!".parseError {error}"
| .indexError index => s!".indexError {index}"
end Pantograph
namespace Pantograph.Test.Proofs namespace Pantograph.Test.Proofs
open Pantograph open Pantograph
open Lean open Lean
@ -27,10 +16,6 @@ inductive Start where
abbrev TestM := StateRefT LSpec.TestSeq (ReaderT Protocol.Options M) abbrev TestM := StateRefT LSpec.TestSeq (ReaderT Protocol.Options M)
deriving instance DecidableEq, Repr for Protocol.Expression
deriving instance DecidableEq, Repr for Protocol.Variable
deriving instance DecidableEq, Repr for Protocol.Goal
def addTest (test: LSpec.TestSeq): TestM Unit := do def addTest (test: LSpec.TestSeq): TestM Unit := do
set $ (← get) ++ test set $ (← get) ++ test
@ -38,7 +23,7 @@ def startProof (start: Start): TestM (Option GoalState) := do
let env ← Lean.MonadEnv.getEnv let env ← Lean.MonadEnv.getEnv
match start with match start with
| .copy name => | .copy name =>
let cInfo? := str_to_name name |> env.find? let cInfo? := name.toName |> env.find?
addTest $ LSpec.check s!"Symbol exists {name}" cInfo?.isSome addTest $ LSpec.check s!"Symbol exists {name}" cInfo?.isSome
match cInfo? with match cInfo? with
| .some cInfo => | .some cInfo =>
@ -64,8 +49,6 @@ def startProof (start: Start): TestM (Option GoalState) := do
let goal ← GoalState.create (expr := expr) let goal ← GoalState.create (expr := expr)
return Option.some goal return Option.some goal
def assertUnreachable (message: String): LSpec.TestSeq := LSpec.check message false
def buildGoal (nameType: List (String × String)) (target: String) (userName?: Option String := .none): Protocol.Goal := def buildGoal (nameType: List (String × String)) (target: String) (userName?: Option String := .none): Protocol.Goal :=
{ {
userName?, userName?,
@ -270,7 +253,7 @@ def proof_or_comm: TestM Unit := do
addTest $ LSpec.check " assumption" state4_2.goals.isEmpty addTest $ LSpec.check " assumption" state4_2.goals.isEmpty
addTest $ LSpec.check "(4_2 root)" state4_2.rootExpr?.isNone addTest $ LSpec.check "(4_2 root)" state4_2.rootExpr?.isNone
-- Ensure the proof can continue from `state4_2`. -- Ensure the proof can continue from `state4_2`.
let state2b ← match state2.continue state4_2 with let state2b ← match state4_2.continue state2 with
| .error msg => do | .error msg => do
addTest $ assertUnreachable $ msg addTest $ assertUnreachable $ msg
return () return ()
@ -303,80 +286,6 @@ def proof_or_comm: TestM Unit := do
] ]
} }
/-- M-coupled goals -/
def proof_m_couple: TestM Unit := do
let state? ← startProof (.expr "(2: Nat) ≤ 5")
let state0 ← match state? with
| .some state => pure state
| .none => do
addTest $ assertUnreachable "Goal could not parse"
return ()
let state1 ← match ← state0.execute (goalId := 0) (tactic := "apply Nat.le_trans") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check "apply Nat.le_trans" ((← state1.serializeGoals (options := ← read)).map (·.target.pp?) =
#[.some "2 ≤ ?m", .some "?m ≤ 5", .some "Nat"])
addTest $ LSpec.test "(1 root)" state1.rootExpr?.isNone
-- Set m to 3
let state2 ← match ← state1.execute (goalId := 2) (tactic := "exact 3") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.test "(1b root)" state2.rootExpr?.isNone
let state1b ← match state1.continue state2 with
| .error msg => do
addTest $ assertUnreachable $ msg
return ()
| .ok state => pure state
addTest $ LSpec.check "exact 3" ((← state1b.serializeGoals (options := ← read)).map (·.target.pp?) =
#[.some "2 ≤ 3", .some "3 ≤ 5"])
addTest $ LSpec.test "(2 root)" state1b.rootExpr?.isNone
return ()
def proof_proposition_generation: TestM Unit := do
let state? ← startProof (.expr "Σ' p:Prop, p")
let state0 ← match state? with
| .some state => pure state
| .none => do
addTest $ assertUnreachable "Goal could not parse"
return ()
let state1 ← match ← state0.execute (goalId := 0) (tactic := "apply PSigma.mk") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check "apply PSigma.mk" ((← state1.serializeGoals (options := ← read)).map (·.devolatilize) =
#[
buildGoal [] "?fst" (userName? := .some "snd"),
buildGoal [] "Prop" (userName? := .some "fst")
])
if let #[goal1, goal2] := ← state1.serializeGoals (options := { (← read) with printExprAST := true }) then
addTest $ LSpec.test "(1 reference)" (goal1.target.sexp? = .some s!"(:mv {goal2.name})")
addTest $ LSpec.test "(1 root)" state1.rootExpr?.isNone
let state2 ← match ← state1.tryAssign (goalId := 0) (expr := "λ (x: Nat) => _") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check ":= λ (x: Nat), _" ((← state2.serializeGoals (options := ← read)).map (·.target.pp?) =
#[.some "Nat → Prop", .some "∀ (x : Nat), ?m.29 x"])
addTest $ LSpec.test "(2 root)" state2.rootExpr?.isNone
let state3 ← match ← state2.tryAssign (goalId := 1) (expr := "fun x => Eq.refl x") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check ":= Eq.refl" ((← state3.serializeGoals (options := ← read)).map (·.target.pp?) =
#[])
addTest $ LSpec.test "(3 root)" state3.rootExpr?.isSome
return ()
def suite: IO LSpec.TestSeq := do def suite: IO LSpec.TestSeq := do
let env: Lean.Environment ← Lean.importModules let env: Lean.Environment ← Lean.importModules
@ -388,9 +297,7 @@ def suite: IO LSpec.TestSeq := do
("Nat.add_comm manual", proof_nat_add_comm true), ("Nat.add_comm manual", proof_nat_add_comm true),
("Nat.add_comm delta", proof_delta_variable), ("Nat.add_comm delta", proof_delta_variable),
("arithmetic", proof_arith), ("arithmetic", proof_arith),
("Or.comm", proof_or_comm), ("Or.comm", proof_or_comm)
("2 < 5", proof_m_couple),
("Proposition Generation", proof_proposition_generation)
] ]
let tests ← tests.foldlM (fun acc tests => do let tests ← tests.foldlM (fun acc tests => do
let (name, tests) := tests let (name, tests) := tests

View File

@ -9,9 +9,6 @@ open Lean
deriving instance Repr, DecidableEq for Protocol.BoundExpression deriving instance Repr, DecidableEq for Protocol.BoundExpression
def test_str_to_name: LSpec.TestSeq :=
LSpec.test "Symbol parsing" (Name.str (.str (.str .anonymous "Lean") "Meta") "run" = Pantograph.str_to_name "Lean.Meta.run")
def test_name_to_ast: LSpec.TestSeq := def test_name_to_ast: LSpec.TestSeq :=
let quote := "\"" let quote := "\""
let escape := "\\" let escape := "\\"
@ -21,14 +18,14 @@ def test_name_to_ast: LSpec.TestSeq :=
LSpec.test s!"«̈{escape}{quote}»" (name_to_ast (Name.str .anonymous s!"{escape}{quote}") = s!"{quote}«{escape}{quote}»{quote}") LSpec.test s!"«̈{escape}{quote}»" (name_to_ast (Name.str .anonymous s!"{escape}{quote}") = s!"{quote}«{escape}{quote}»{quote}")
def test_expr_to_binder (env: Environment): IO LSpec.TestSeq := do def test_expr_to_binder (env: Environment): IO LSpec.TestSeq := do
let entries: List (String × Protocol.BoundExpression) := [ let entries: List (Name × Protocol.BoundExpression) := [
("Nat.add_comm", { binders := #[("n", "Nat"), ("m", "Nat")], target := "n + m = m + n" }), ("Nat.add_comm".toName, { binders := #[("n", "Nat"), ("m", "Nat")], target := "n + m = m + n" }),
("Nat.le_of_succ_le", { binders := #[("n", "Nat"), ("m", "Nat"), ("h", "Nat.succ n ≤ m")], target := "n ≤ m" }) ("Nat.le_of_succ_le".toName, { binders := #[("n", "Nat"), ("m", "Nat"), ("h", "Nat.succ n ≤ m")], target := "n ≤ m" })
] ]
let coreM := entries.foldlM (λ suites (symbol, target) => do let coreM: CoreM LSpec.TestSeq := entries.foldlM (λ suites (symbol, target) => do
let env ← MonadEnv.getEnv let env ← MonadEnv.getEnv
let expr := str_to_name symbol |> env.find? |>.get! |>.type let expr := env.find? symbol |>.get! |>.type
let test := LSpec.check symbol ((← type_expr_to_bound expr) = target) let test := LSpec.check symbol.toString ((← type_expr_to_bound expr) = target)
return LSpec.TestSeq.append suites test) LSpec.TestSeq.done |>.run' return LSpec.TestSeq.append suites test) LSpec.TestSeq.done |>.run'
let coreContext: Core.Context := { let coreContext: Core.Context := {
currNamespace := Lean.Name.str .anonymous "Aniva" currNamespace := Lean.Name.str .anonymous "Aniva"
@ -54,7 +51,7 @@ def test_sexp_of_symbol (env: Environment): IO LSpec.TestSeq := do
] ]
let metaM: MetaM LSpec.TestSeq := entries.foldlM (λ suites (symbol, target) => do let metaM: MetaM LSpec.TestSeq := entries.foldlM (λ suites (symbol, target) => do
let env ← MonadEnv.getEnv let env ← MonadEnv.getEnv
let expr := str_to_name symbol |> env.find? |>.get! |>.type let expr := env.find? symbol.toName |>.get! |>.type
let test := LSpec.check symbol ((serialize_expression_ast expr) = target) let test := LSpec.check symbol ((serialize_expression_ast expr) = target)
return LSpec.TestSeq.append suites test) LSpec.TestSeq.done return LSpec.TestSeq.append suites test) LSpec.TestSeq.done
let coreM := metaM.run' let coreM := metaM.run'
@ -72,12 +69,11 @@ def test_sexp_of_symbol (env: Environment): IO LSpec.TestSeq := do
def suite: IO LSpec.TestSeq := do def suite: IO LSpec.TestSeq := do
let env: Environment ← importModules let env: Environment ← importModules
(imports := #["Init"].map (λ str => { module := str_to_name str, runtimeOnly := false })) (imports := #["Init"].map (λ str => { module := str.toName, runtimeOnly := false }))
(opts := {}) (opts := {})
(trustLevel := 1) (trustLevel := 1)
return LSpec.group "Serialization" $ return LSpec.group "Serialization" $
(LSpec.group "str_to_name" test_str_to_name) ++
(LSpec.group "name_to_ast" test_name_to_ast) ++ (LSpec.group "name_to_ast" test_name_to_ast) ++
(LSpec.group "Expression binder" (← test_expr_to_binder env)) ++ (LSpec.group "Expression binder" (← test_expr_to_binder env)) ++
(LSpec.group "Sexp from symbol" (← test_sexp_of_symbol env)) (LSpec.group "Sexp from symbol" (← test_sexp_of_symbol env))