src/Pure/PIDE/headless.scala
author wenzelm
Mon, 07 Oct 2019 21:51:31 +0200
changeset 70801 5352449209b1
parent 70800 44eeca528557
child 70872 7c77fb7a6fc9
permissions -rw-r--r--
clarified option type;

/*  Title:      Pure/PIDE/headless.scala
    Author:     Makarius

Headless PIDE session and resources from file-system.
*/

package isabelle


import java.io.{File => JFile}

import scala.annotation.tailrec
import scala.collection.mutable


object Headless
{
  /** session **/

  private def stable_snapshot(
    state: Document.State, version: Document.Version, name: Document.Node.Name): Document.Snapshot =
  {
    val snapshot = state.snapshot(name)
    assert(version.id == snapshot.version.id)
    snapshot
  }

  class Use_Theories_Result private[Headless](
    val state: Document.State,
    val version: Document.Version,
    val nodes: List[(Document.Node.Name, Document_Status.Node_Status)],
    val nodes_committed: List[(Document.Node.Name, Document_Status.Node_Status)])
  {
    def nodes_pending: List[(Document.Node.Name, Document_Status.Node_Status)] =
    {
      val committed = nodes_committed.iterator.map(_._1).toSet
      nodes.filter(p => !committed(p._1))
    }

    def snapshot(name: Document.Node.Name): Document.Snapshot =
      stable_snapshot(state, version, name)

    def ok: Boolean =
      (nodes.iterator ++ nodes_committed.iterator).forall({ case (_, st) => st.ok })
  }

  private object Load_State
  {
    def finished: Load_State = Load_State(Nil, Nil, 0)

    def count_file(name: Document.Node.Name): Long =
      name.path.file.length
  }

  private case class Load_State(
    pending: List[Document.Node.Name], rest: List[Document.Node.Name], load_limit: Long)
  {
    def next(
      dep_graph: Document.Node.Name.Graph[Unit],
      finished: Document.Node.Name => Boolean): (List[Document.Node.Name], Load_State) =
    {
      def load_requirements(pending1: List[Document.Node.Name], rest1: List[Document.Node.Name])
        : (List[Document.Node.Name], Load_State) =
      {
        val load_theories = dep_graph.all_preds(pending1).reverse.filterNot(finished)
        (load_theories, Load_State(pending1, rest1, load_limit))
      }

      if (!pending.forall(finished)) (Nil, this)
      else if (rest.isEmpty) (Nil, Load_State.finished)
      else if (load_limit == 0) load_requirements(rest, Nil)
      else {
        val reachable =
          dep_graph.reachable_limit(load_limit, Load_State.count_file, dep_graph.imm_preds, rest)
        val (pending1, rest1) = rest.partition(reachable)
        load_requirements(pending1, rest1)
      }
    }
  }

  class Session private[Headless](
    session_name: String,
    _session_options: => Options,
    override val resources: Resources) extends isabelle.Session(_session_options, resources)
  {
    session =>


    private def loaded_theory(name: Document.Node.Name): Boolean =
      resources.session_base.loaded_theory(name.theory)


    /* options */

    override def consolidate_delay: Time = session_options.seconds("headless_consolidate_delay")
    override def prune_delay: Time = session_options.seconds("headless_prune_delay")

    def default_check_delay: Time = session_options.seconds("headless_check_delay")
    def default_check_limit: Int = session_options.int("headless_check_limit")
    def default_nodes_status_delay: Time = session_options.seconds("headless_nodes_status_delay")
    def default_watchdog_timeout: Time = session_options.seconds("headless_watchdog_timeout")
    def default_commit_cleanup_delay: Time = session_options.seconds("headless_commit_cleanup_delay")


    /* temporary directory */

    val tmp_dir: JFile = Isabelle_System.tmp_dir("server_session")
    val tmp_dir_name: String = File.path(tmp_dir).implode

    def master_directory(master_dir: String): String =
      proper_string(master_dir) getOrElse tmp_dir_name

    override def toString: String = session_name

    override def stop(): Process_Result =
    {
      try { super.stop() }
      finally { Isabelle_System.rm_tree(tmp_dir) }
    }


    /* theories */

    private sealed case class Use_Theories_State(
      dep_graph: Document.Node.Name.Graph[Unit],
      load_state: Load_State,
      watchdog_timeout: Time,
      commit: Option[(Document.Snapshot, Document_Status.Node_Status) => Unit],
      last_update: Time = Time.now(),
      nodes_status: Document_Status.Nodes_Status = Document_Status.Nodes_Status.empty,
      already_committed: Map[Document.Node.Name, Document_Status.Node_Status] = Map.empty,
      result: Option[Exn.Result[Use_Theories_Result]] = None)
    {
      def update(new_nodes_status: Document_Status.Nodes_Status): Use_Theories_State =
        copy(last_update = Time.now(), nodes_status = new_nodes_status)

      def watchdog: Boolean =
        watchdog_timeout > Time.zero && Time.now() - last_update > watchdog_timeout

      def finished_result: Boolean = result.isDefined

      def join_result: Option[(Exn.Result[Use_Theories_Result], Use_Theories_State)] =
        if (finished_result) Some((result.get, this)) else None

      def cancel_result: Use_Theories_State =
        if (finished_result) this else copy(result = Some(Exn.Exn(Exn.Interrupt())))

      def clean_theories: (List[Document.Node.Name], Use_Theories_State) =
      {
        @tailrec def frontier(base: List[Document.Node.Name], front: Set[Document.Node.Name])
          : Set[Document.Node.Name] =
        {
          val add = base.filter(name => dep_graph.imm_succs(name).forall(front))
          if (add.isEmpty) front
          else {
            val preds = add.map(dep_graph.imm_preds)
            val base1 = (preds.head /: preds.tail)(_ ++ _).toList.filter(already_committed.keySet)
            frontier(base1, front ++ add)
          }
        }

        if (already_committed.isEmpty) (Nil, this)
        else {
          val base =
            (for {
              (name, (_, (_, succs))) <- dep_graph.iterator
              if succs.isEmpty && already_committed.isDefinedAt(name)
            } yield name).toList
          val clean = frontier(base, Set.empty)
          if (clean.isEmpty) (Nil, this)
          else {
            (dep_graph.topological_order.filter(clean),
              copy(dep_graph = dep_graph.exclude(clean)))
          }
        }
      }

      def check(state: Document.State, version: Document.Version, beyond_limit: Boolean)
        : (List[Document.Node.Name], Use_Theories_State) =
      {
        val already_committed1 =
          commit match {
            case None => already_committed
            case Some(commit_fn) =>
              (already_committed /: dep_graph.topological_order)(
                { case (committed, name) =>
                    def parents_committed: Boolean =
                      version.nodes(name).header.imports.forall(parent =>
                        loaded_theory(parent) || committed.isDefinedAt(parent))
                    if (!committed.isDefinedAt(name) && parents_committed &&
                        state.node_consolidated(version, name))
                    {
                      val snapshot = stable_snapshot(state, version, name)
                      val status = Document_Status.Node_Status.make(state, version, name)
                      commit_fn(snapshot, status)
                      committed + (name -> status)
                    }
                    else committed
                })
          }

        def finished_theory(name: Document.Node.Name): Boolean =
          loaded_theory(name) ||
          (if (commit.isDefined) already_committed1.isDefinedAt(name)
           else state.node_consolidated(version, name))

        val result1 =
          if (!finished_result &&
            (beyond_limit || watchdog ||
              dep_graph.keys_iterator.forall(name =>
                finished_theory(name) || nodes_status.quasi_consolidated(name))))
          {
            val nodes =
              (for {
                name <- dep_graph.keys_iterator
                if !loaded_theory(name)
              } yield { (name -> Document_Status.Node_Status.make(state, version, name)) }).toList
            val nodes_committed =
              (for {
                name <- dep_graph.keys_iterator
                status <- already_committed1.get(name)
              } yield (name -> status)).toList
            Some(Exn.Res(new Use_Theories_Result(state, version, nodes, nodes_committed)))
          }
          else result

        val (load_theories, load_state1) = load_state.next(dep_graph, finished_theory(_))

        (load_theories,
          copy(already_committed = already_committed1, result = result1, load_state = load_state1))
      }
    }

    def use_theories(
      theories: List[String],
      qualifier: String = Sessions.DRAFT,
      master_dir: String = "",
      unicode_symbols: Boolean = false,
      check_delay: Time = default_check_delay,
      check_limit: Int = default_check_limit,
      watchdog_timeout: Time = default_watchdog_timeout,
      nodes_status_delay: Time = default_nodes_status_delay,
      id: UUID.T = UUID.random(),
      // commit: must not block, must not fail
      commit: Option[(Document.Snapshot, Document_Status.Node_Status) => Unit] = None,
      commit_cleanup_delay: Time = default_commit_cleanup_delay,
      progress: Progress = No_Progress): Use_Theories_Result =
    {
      val dependencies =
      {
        val import_names =
          theories.map(thy =>
            resources.import_name(qualifier, master_directory(master_dir), thy) -> Position.none)
        resources.dependencies(import_names, progress = progress).check_errors
      }
      val dep_theories = dependencies.theories
      val dep_theories_set = dep_theories.toSet
      val dep_files =
        dependencies.loaded_files(false).flatMap(_._2).
          map(path => Document.Node.Name(resources.append("", path)))

      val use_theories_state =
      {
        val dep_graph = dependencies.theory_graph

        val maximals = dep_graph.maximals
        val rest =
          if (maximals.isEmpty || maximals.tail.isEmpty) maximals
          else {
            val depth = dep_graph.node_depth(Load_State.count_file)
            maximals.sortBy(node => - depth(node))
          }
        val load_limit =
          if (commit.isDefined) (session_options.real("headless_load_limit") * 1024 * 1024).round
          else 0
        val load_state = Load_State(Nil, rest, load_limit)

        Synchronized(Use_Theories_State(dep_graph, load_state, watchdog_timeout, commit))
      }

      def check_state(beyond_limit: Boolean = false)
      {
        val state = session.get_state()
        for {
          version <- state.stable_tip_version
          load_theories = use_theories_state.change_result(_.check(state, version, beyond_limit))
          if load_theories.nonEmpty
        } resources.load_theories(session, id, load_theories, dep_files, unicode_symbols, progress)
      }

      val check_progress =
      {
        var check_count = 0
        Event_Timer.request(Time.now(), repeat = Some(check_delay))
          {
            if (progress.stopped) use_theories_state.change(_.cancel_result)
            else {
              check_count += 1
              check_state(check_limit > 0 && check_count > check_limit)
            }
          }
      }

      val consumer =
      {
        val delay_nodes_status =
          Standard_Thread.delay_first(nodes_status_delay max Time.zero) {
            progress.nodes_status(use_theories_state.value.nodes_status)
          }

        val delay_commit_clean =
          Standard_Thread.delay_first(commit_cleanup_delay max Time.zero) {
            val clean_theories = use_theories_state.change_result(_.clean_theories)
            if (clean_theories.nonEmpty) {
              progress.echo("Removing " + clean_theories.length + " theories ...")
              resources.clean_theories(session, id, clean_theories)
            }
          }

        Session.Consumer[Session.Commands_Changed](getClass.getName) {
          case changed =>
            if (changed.nodes.exists(dep_theories_set)) {
              val snapshot = session.snapshot()
              val state = snapshot.state
              val version = snapshot.version

              val theory_progress =
                use_theories_state.change_result(st =>
                  {
                    val domain =
                      if (st.nodes_status.is_empty) dep_theories_set
                      else changed.nodes.iterator.filter(dep_theories_set).toSet

                    val (nodes_status_changed, nodes_status1) =
                      st.nodes_status.update(resources, state, version,
                        domain = Some(domain), trim = changed.assignment)

                    if (nodes_status_delay >= Time.zero && nodes_status_changed) {
                      delay_nodes_status.invoke
                    }

                    val theory_progress =
                      (for {
                        (name, node_status) <- nodes_status1.present.iterator
                        if changed.nodes.contains(name) && !st.already_committed.isDefinedAt(name)
                        p1 = node_status.percentage
                        if p1 > 0 && Some(p1) != st.nodes_status.get(name).map(_.percentage)
                      } yield Progress.Theory(name.theory, percentage = Some(p1))).toList

                    (theory_progress, st.update(nodes_status1))
                  })

              theory_progress.foreach(progress.theory(_))

              check_state()

              if (commit.isDefined && commit_cleanup_delay > Time.zero) {
                if (use_theories_state.value.finished_result)
                  delay_commit_clean.revoke
                else delay_commit_clean.invoke
              }
            }
        }
      }

      try {
        session.commands_changed += consumer
        check_state()
        use_theories_state.guarded_access(_.join_result)
        check_progress.cancel
      }
      finally {
        session.commands_changed -= consumer
        resources.unload_theories(session, id, dep_theories)
      }

      Exn.release(use_theories_state.guarded_access(_.join_result))
    }

    def purge_theories(
      theories: List[String],
      qualifier: String = Sessions.DRAFT,
      master_dir: String = "",
      all: Boolean = false): (List[Document.Node.Name], List[Document.Node.Name]) =
    {
      val nodes =
        if (all) None
        else Some(theories.map(resources.import_name(qualifier, master_directory(master_dir), _)))
      resources.purge_theories(session, nodes)
    }
  }



  /** resources **/

  object Resources
  {
    def apply(base_info: Sessions.Base_Info, log: Logger = No_Logger): Resources =
      new Resources(base_info, log = log)

    def make(
      options: Options,
      session_name: String,
      session_dirs: List[Path] = Nil,
      include_sessions: List[String] = Nil,
      progress: Progress = No_Progress,
      log: Logger = No_Logger): Resources =
    {
      val base_info =
        Sessions.base_info(options, session_name, dirs = session_dirs,
          include_sessions = include_sessions, progress = progress)
      apply(base_info, log = log)
    }

    final class Theory private[Headless](
      val node_name: Document.Node.Name,
      val node_header: Document.Node.Header,
      val text: String,
      val node_required: Boolean)
    {
      override def toString: String = node_name.toString

      def node_perspective: Document.Node.Perspective_Text =
        Document.Node.Perspective(node_required, Text.Perspective.empty, Document.Node.Overlays.empty)

      def make_edits(text_edits: List[Text.Edit]): List[Document.Edit_Text] =
        List(node_name -> Document.Node.Deps(node_header),
          node_name -> Document.Node.Edits(text_edits),
          node_name -> node_perspective)

      def node_edits(old: Option[Theory]): List[Document.Edit_Text] =
      {
        val (text_edits, old_required) =
          if (old.isEmpty) (Text.Edit.inserts(0, text), false)
          else (Text.Edit.replace(0, old.get.text, text), old.get.node_required)

        if (text_edits.isEmpty && node_required == old_required) Nil
        else make_edits(text_edits)
      }

      def purge_edits: List[Document.Edit_Text] =
        make_edits(Text.Edit.removes(0, text))

      def required(required: Boolean): Theory =
        if (required == node_required) this
        else new Theory(node_name, node_header, text, required)
    }

    sealed case class State(
      blobs: Map[Document.Node.Name, Document.Blob] = Map.empty,
      theories: Map[Document.Node.Name, Theory] = Map.empty,
      required: Multi_Map[Document.Node.Name, UUID.T] = Multi_Map.empty)
    {
      /* blobs */

      def doc_blobs: Document.Blobs = Document.Blobs(blobs)

      def update_blobs(names: List[Document.Node.Name]): (Document.Blobs, State) =
      {
        val new_blobs =
          names.flatMap(name =>
          {
            val bytes = Bytes.read(name.path)
            def new_blob: Document.Blob =
            {
              val text = bytes.text
              Document.Blob(bytes, text, Symbol.Text_Chunk(text), changed = true)
            }
            blobs.get(name) match {
              case Some(blob) => if (blob.bytes == bytes) None else Some(name -> new_blob)
              case None => Some(name -> new_blob)
            }
          })
        val blobs1 = (blobs /: new_blobs)(_ + _)
        val blobs2 = (blobs /: new_blobs)({ case (map, (a, b)) => map + (a -> b.unchanged) })
        (Document.Blobs(blobs1), copy(blobs = blobs2))
      }

      def blob_edits(name: Document.Node.Name, old_blob: Option[Document.Blob])
        : List[Document.Edit_Text] =
      {
        val blob = blobs.getOrElse(name, error("Missing blob " + quote(name.toString)))
        val text_edits =
          old_blob match {
            case None => List(Text.Edit.insert(0, blob.source))
            case Some(blob0) => Text.Edit.replace(0, blob0.source, blob.source)
          }
        if (text_edits.isEmpty) Nil
        else List(name -> Document.Node.Blob(blob), name -> Document.Node.Edits(text_edits))
      }


      /* theories */

      lazy val theory_graph: Document.Node.Name.Graph[Unit] =
        Document.Node.Name.make_graph(
          for ((name, theory) <- theories.toList)
          yield ((name, ()), theory.node_header.imports.filter(theories.isDefinedAt(_))))

      def is_required(name: Document.Node.Name): Boolean = required.isDefinedAt(name)

      def insert_required(id: UUID.T, names: List[Document.Node.Name]): State =
        copy(required = (required /: names)(_.insert(_, id)))

      def remove_required(id: UUID.T, names: List[Document.Node.Name]): State =
        copy(required = (required /: names)(_.remove(_, id)))

      def update_theories(update: List[(Document.Node.Name, Theory)]): State =
        copy(theories =
          (theories /: update)({ case (thys, (name, thy)) =>
            thys.get(name) match {
              case Some(thy1) if thy1 == thy => thys
              case _ => thys + (name -> thy)
            }
          }))

      def remove_theories(remove: List[Document.Node.Name]): State =
      {
        require(remove.forall(name => !is_required(name)))
        copy(theories = theories -- remove)
      }

      def unload_theories(session: Session, id: UUID.T, theories: List[Document.Node.Name])
        : (List[Document.Edit_Text], State) =
      {
        val st1 = remove_required(id, theories)
        val theory_edits =
          for {
            node_name <- theories
            theory <- st1.theories.get(node_name)
          }
          yield {
            val theory1 = theory.required(st1.is_required(node_name))
            val edits = theory1.node_edits(Some(theory))
            (edits, (node_name, theory1))
          }
        (theory_edits.flatMap(_._1), st1.update_theories(theory_edits.map(_._2)))
      }

      def purge_theories(session: Session, nodes: Option[List[Document.Node.Name]])
        : ((List[Document.Node.Name], List[Document.Node.Name], List[Document.Edit_Text]), State) =
      {
        val all_nodes = theory_graph.topological_order
        val purge = nodes.getOrElse(all_nodes).filterNot(is_required(_)).toSet

        val retain = theory_graph.all_preds(all_nodes.filterNot(purge)).toSet
        val (retained, purged) = all_nodes.partition(retain)
        val purge_edits = purged.flatMap(name => theories(name).purge_edits)

        ((purged, retained, purge_edits), remove_theories(purged))
      }
    }
  }

  class Resources private[Headless](
      val session_base_info: Sessions.Base_Info,
      log: Logger = No_Logger)
    extends isabelle.Resources(
      session_base_info.sessions_structure, session_base_info.check_base, log = log)
  {
    resources =>

    def options: Options = session_base_info.options


    /* session */

    def start_session(print_mode: List[String] = Nil, progress: Progress = No_Progress): Session =
    {
      val session = new Session(session_base_info.session, options, resources)

      val session_error = Future.promise[String]
      var session_phase: Session.Consumer[Session.Phase] = null
      session_phase =
        Session.Consumer(getClass.getName) {
          case Session.Ready =>
            session.phase_changed -= session_phase
            session_error.fulfill("")
          case Session.Terminated(result) if !result.ok =>
            session.phase_changed -= session_phase
            session_error.fulfill("Session start failed: return code " + result.rc)
          case _ =>
        }
      session.phase_changed += session_phase

      progress.echo("Starting session " + session_base_info.session + " ...")
      Isabelle_Process.start(session, options,
        logic = session_base_info.session, dirs = session_base_info.dirs, modes = print_mode)

      session_error.join match {
        case "" => session
        case msg => session.stop(); error(msg)
      }
    }


    /* theories */

    private val state = Synchronized(Resources.State())

    def load_theories(
      session: Session,
      id: UUID.T,
      theories: List[Document.Node.Name],
      files: List[Document.Node.Name],
      unicode_symbols: Boolean,
      progress: Progress)
    {
      val loaded_theories =
        for (node_name <- theories)
        yield {
          val path = node_name.path
          if (!node_name.is_theory) error("Not a theory file: " + path)

          progress.expose_interrupt()
          val text0 = File.read(path)
          val text = if (unicode_symbols) Symbol.decode(text0) else text0
          val node_header = resources.check_thy_reader(node_name, Scan.char_reader(text))
          new Resources.Theory(node_name, node_header, text, true)
        }

      val loaded = loaded_theories.length
      if (loaded > 1) progress.echo("Loading " + loaded + " theories ...")

      state.change(st =>
        {
          val (doc_blobs1, st1) = st.insert_required(id, theories).update_blobs(files)
          val theory_edits =
            for (theory <- loaded_theories)
            yield {
              val node_name = theory.node_name
              val theory1 = theory.required(st1.is_required(node_name))
              val edits = theory1.node_edits(st1.theories.get(node_name))
              (edits, (node_name, theory1))
            }
          val file_edits =
            for { node_name <- files if doc_blobs1.changed(node_name) }
            yield st1.blob_edits(node_name, st.blobs.get(node_name))

          session.update(doc_blobs1, theory_edits.flatMap(_._1) ::: file_edits.flatten)
          st1.update_theories(theory_edits.map(_._2))
        })
    }

    def unload_theories(session: Session, id: UUID.T, theories: List[Document.Node.Name])
    {
      state.change(st =>
      {
        val (edits, st1) = st.unload_theories(session, id, theories)
        session.update(st.doc_blobs, edits)
        st1
      })
    }

    def clean_theories(session: Session, id: UUID.T, theories: List[Document.Node.Name])
    {
      state.change(st =>
      {
        val (edits1, st1) = st.unload_theories(session, id, theories)
        val ((_, _, edits2), st2) = st1.purge_theories(session, None)
        session.update(st.doc_blobs, edits1 ::: edits2)
        st2
      })
    }

    def purge_theories(session: Session, nodes: Option[List[Document.Node.Name]])
      : (List[Document.Node.Name], List[Document.Node.Name]) =
    {
      state.change_result(st =>
      {
        val ((purged, retained, _), st1) = st.purge_theories(session, nodes)
        ((purged, retained), st1)
      })
    }
  }
}