Coverage report

(************************************************************************)
(*         *   The Coq Proof Assistant / The Coq Development Team       *)
(*  v      *   INRIA, CNRS and contributors - Copyright 1999-2019       *)
(* <O___,, *       (see CREDITS file for the list of authors)           *)
(*   \VV/  **************************************************************)
(*    //   *    This file is distributed under the terms of the         *)
(*         *     GNU Lesser General Public License Version 2.1          *)
(*         *     (see LICENSE file for the text of the license)         *)
(************************************************************************)

(* enable in case of stm problems  *)
(* let stm_debug () = !Flags.debug *)
let stm_debug = ref false

let stm_pr_err s  = Format.eprintf "%s] %s\n%!"     (Spawned.process_id ()) s
let stm_pp_err pp = Format.eprintf "%s] @[%a@]\n%!" (Spawned.process_id ()) Pp.pp_with pp

let stm_prerr_endline s = if !stm_debug then begin stm_pr_err (s ()) end else ()
let stm_pperr_endline s = if !stm_debug then begin stm_pp_err (s ()) end else ()

let stm_prerr_debug   s = if !Flags.debug then begin stm_pr_err (s ()) end else ()

open Pp
open CErrors
open Names
open Feedback
open Vernacexpr
open Vernacextend

module PG_compat = Vernacstate.Proof_global [@@ocaml.warning "-3"]

let is_vtkeep = function VtKeep _ -> true | _ -> false
let get_vtkeep = function VtKeep x -> x | _ -> assert false

module AsyncOpts = struct

  type cache = Force
  type async_proofs = APoff | APonLazy | APon
  type tac_error_filter = [ `None | `Only of string list | `All ]

  type stm_opt = {
    async_proofs_n_workers : int;
    async_proofs_n_tacworkers : int;

    async_proofs_cache : cache option;
    async_proofs_mode : async_proofs;

    async_proofs_private_flags : string option;
    async_proofs_never_reopen_branch : bool;

    async_proofs_tac_error_resilience : tac_error_filter;
    async_proofs_cmd_error_resilience : bool;
    async_proofs_delegation_threshold : float;

    async_proofs_worker_priority : CoqworkmgrApi.priority;
  }

  let default_opts = {
    async_proofs_n_workers = 1;
    async_proofs_n_tacworkers = 2;

    async_proofs_cache = None;

    async_proofs_mode = APoff;

    async_proofs_private_flags = None;
    async_proofs_never_reopen_branch = false;

    async_proofs_tac_error_resilience = `Only [ "curly" ];
    async_proofs_cmd_error_resilience = true;
    async_proofs_delegation_threshold = 0.03;

    async_proofs_worker_priority = CoqworkmgrApi.Low;
  }

  let cur_opt = ref default_opts
end

open AsyncOpts

let async_proofs_is_master opt =
  opt.async_proofs_mode = APon &&
  !Flags.async_proofs_worker_id = "master"

let execution_error ?loc state_id msg =
    feedback ~id:state_id (Message (Error, loc, msg))

module Hooks = struct

let state_computed, state_computed_hook = Hook.make
 ~default:(fun ~doc:_ state_id ~in_cache ->
    feedback ~id:state_id Processed) ()

let state_ready, state_ready_hook = Hook.make
 ~default:(fun ~doc:_ state_id -> ()) ()

let forward_feedback, forward_feedback_hook =
  let m = Mutex.create () in
  Hook.make ~default:(function
    | { doc_id = did; span_id = id; route; contents } ->
        try Mutex.lock m; feedback ~did ~id ~route contents; Mutex.unlock m
        with e -> Mutex.unlock m; raise e) ()

let unreachable_state, unreachable_state_hook = Hook.make
 ~default:(fun ~doc:_ _ _ -> ()) ()

let document_add, document_add_hook = Hook.make
 ~default:(fun _ _ -> ()) ()

let document_edit, document_edit_hook = Hook.make
 ~default:(fun _ -> ()) ()

let sentence_exec, sentence_exec_hook = Hook.make
 ~default:(fun _ -> ()) ()

include Hook

(* enables:  Hooks.(call foo args) *)
let call = get

end

let async_proofs_workers_extra_env = ref [||]

type aast = {
  verbose : bool;
  indentation : int;
  strlen : int;
  mutable expr : vernac_control; (* mutable: Proof using hinted by aux file *)
}
let pr_ast { expr; indentation } = Pp.(int indentation ++ str " " ++ Ppvernac.pr_vernac expr)

(* Commands piercing opaque *)
let may_pierce_opaque = function
  | VernacPrint _
  | VernacExtend (("Extraction",_), _)
  | VernacExtend (("SeparateExtraction",_), _)
  | VernacExtend (("ExtractionLibrary",_), _)
  | VernacExtend (("RecursiveExtractionLibrary",_), _)
  | VernacExtend (("ExtractionConstant",_), _)
  | VernacExtend (("ExtractionInlinedConstant",_), _)
  | VernacExtend (("ExtractionInductive",_), _) -> true
  | _ -> false

let update_global_env () =
  if PG_compat.there_are_pending_proofs () then
    PG_compat.update_global_env ()

module Vcs_ = Vcs.Make(Stateid.Self)
type future_proof = Proof_global.closed_proof_output Future.computation

type depth = int
type branch_type =
  [ `Master
  | `Proof of depth
  | `Edit of
      Stateid.t * Stateid.t  * Vernacextend.vernac_qed_type * Vcs_.Branch.t ]
(* TODO 8.7 : split commands and tactics, since this type is too messy now *)
type cmd_t = {
  ctac : bool; (* is a tactic *)
  ceff : bool; (* is a side-effecting command in the middle of a proof *)
  cast : aast;
  cids : Names.Id.t list;
  cblock : proof_block_name option;
  cqueue : [ `MainQueue
           | `TacQueue of solving_tac * anon_abstracting_tac * AsyncTaskQueue.cancel_switch
           | `QueryQueue of AsyncTaskQueue.cancel_switch
           | `SkipQueue ] }
type fork_t = aast * Vcs_.Branch.t * opacity_guarantee * Names.Id.t list
type qed_t = {
  qast : aast;
  keep : vernac_qed_type;
  mutable fproof : (future_proof * AsyncTaskQueue.cancel_switch) option;
  brname : Vcs_.Branch.t;
  brinfo : branch_type Vcs_.branch_info
}
type seff_t = ReplayCommand of aast | CherryPickEnv
type alias_t = Stateid.t * aast

type transaction =
  | Cmd    of cmd_t
  | Fork   of fork_t
  | Qed    of qed_t
  | Sideff of seff_t
  | Alias  of alias_t
  | Noop
type step =
  [ `Cmd    of cmd_t
  | `Fork   of fork_t * Stateid.t option
  | `Qed    of qed_t * Stateid.t
  | `Sideff of seff_t * Stateid.t
  | `Alias  of alias_t ]

type visit = { step : step; next : Stateid.t }

let mkTransTac cast cblock cqueue =
  Cmd { ctac = true; cast; cblock; cqueue; cids = []; ceff = false }

let mkTransCmd cast cids ceff cqueue =
  Cmd { ctac = false; cast; cblock = None; cqueue; cids; ceff }

(* Parts of the system state that are morally part of the proof state *)
let summary_pstate = Evarutil.meta_counter_summary_tag,
                     Evd.evar_counter_summary_tag,
                     DeclareObl.program_tcc_summary_tag

type cached_state =
  | EmptyState
  | ParsingState of Vernacstate.Parser.state
  | FullState of Vernacstate.t
  | ErrorState of Vernacstate.Parser.state option * Exninfo.iexn
type branch = Vcs_.Branch.t * branch_type Vcs_.branch_info
type backup = { mine : branch; others : branch list }

type 'vcs state_info = { (* TODO: Make this record private to VCS *)
  mutable n_reached : int;      (* debug cache: how many times was computed *)
  mutable n_goals : int;        (* open goals: indentation *)
  mutable state : cached_state; (* state value *)
  mutable proof_mode : Pvernac.proof_mode option;
  mutable vcs_backup : 'vcs option * backup option;
}
let default_info proof_mode =
  {
    n_reached = 0; n_goals = 0;
    state = EmptyState;
    proof_mode;
    vcs_backup = (None,None);
  }

module DynBlockData : Dyn.S = Dyn.Make ()

(* Clusters of nodes implemented as Dag properties.  While Dag and Vcs impose
 * no constraint on properties, here we impose boxes to be non overlapping.
 * Such invariant makes sense for the current kinds of boxes (proof blocks and
 * entire proofs) but may make no sense and dropped/refined in the future.
 * Such invariant is useful to detect broken proof block detection code *)
type box =
  | ProofTask of pt
  | ProofBlock of static_block_declaration * proof_block_name
and pt = { (* TODO: inline records in OCaml 4.03 *)
  lemma : Stateid.t;
  qed   : Stateid.t;
}
and static_block_declaration = {
  block_start : Stateid.t;
  block_stop  : Stateid.t;
  dynamic_switch : Stateid.t;
  carry_on_data : DynBlockData.t;
}

(* Functions that work on a Vcs with a specific branch type *)
module Vcs_aux : sig

  val proof_nesting : (branch_type, 't,'i,'c) Vcs_.t -> int
  val find_proof_at_depth :
          (branch_type, 't, 'i,'c) Vcs_.t -> int ->
      Vcs_.Branch.t * branch_type Vcs_.branch_info
  exception Expired
  val visit : (branch_type, transaction,'i,'c) Vcs_.t -> Vcs_.Dag.node -> visit

end = struct (* {{{ *)

  let proof_nesting vcs =
    List.fold_left max 0
      (CList.map_filter
        (function
         | { Vcs_.kind = `Proof n } -> Some n
         | { Vcs_.kind = `Edit _ } -> Some 1
         | _ -> None)
        (List.map (Vcs_.get_branch vcs) (Vcs_.branches vcs)))

  let find_proof_at_depth vcs pl =
    try List.find (function
          | _, { Vcs_.kind = `Proof n } -> Int.equal n pl
          | _, { Vcs_.kind = `Edit _ } -> anomaly(Pp.str "find_proof_at_depth")
          | _ -> false)
        (List.map (fun h -> h, Vcs_.get_branch vcs h) (Vcs_.branches vcs))
    with Not_found -> failwith "find_proof_at_depth"

  exception Expired
  let visit vcs id =
    if Stateid.equal id Stateid.initial then
      anomaly(Pp.str "Visiting the initial state id.")
    else if Stateid.equal id Stateid.dummy then
      anomaly(Pp.str "Visiting the dummy state id.")
    else
    try
      match Vcs_.Dag.from_node (Vcs_.dag vcs) id with
      | [n, Cmd x] -> { step = `Cmd x; next = n }
      | [n, Alias x] -> { step = `Alias x; next = n }
      | [n, Fork x] -> { step = `Fork (x,None); next = n }
      | [n, Fork x; p, Noop] -> { step = `Fork (x,Some p); next = n }
      | [p, Noop; n, Fork x] -> { step = `Fork (x,Some p); next = n }
      | [n, Qed x; p, Noop]
      | [p, Noop; n, Qed x] -> { step = `Qed (x,p); next = n }
      | [n, Sideff CherryPickEnv; p, Noop]
      | [p, Noop; n, Sideff CherryPickEnv]-> { step = `Sideff (CherryPickEnv, p); next = n }
      | [n, Sideff (ReplayCommand x); p, Noop]
      | [p, Noop; n, Sideff (ReplayCommand x)]-> { step = `Sideff(ReplayCommand x,p); next = n }
      | [n, Sideff (ReplayCommand x)]-> {step = `Sideff(ReplayCommand x, Stateid.dummy); next=n}
      | _ -> anomaly (Pp.str ("Malformed VCS at node "^Stateid.to_string id^"."))
    with Not_found -> raise Expired

end (* }}} *)

(*************************** THE DOCUMENT *************************************)
(******************************************************************************)

type interactive_top = TopLogical of DirPath.t | TopPhysical of string

(* The main document type associated to a VCS *)
type stm_doc_type =
  | VoDoc       of string
  | VioDoc      of string
  | Interactive of interactive_top

(* Dummy until we land the functional interp patch + fixed start_library *)
type doc = int
let dummy_doc : doc = 0

(* Imperative wrap around VCS to obtain _the_ VCS that is the
 * representation of the document Coq is currently processing *)
module VCS : sig

  exception Expired

  module Branch : (module type of Vcs_.Branch with type t = Vcs_.Branch.t)
  type id = Stateid.t
  type 'branch_type branch_info = 'branch_type Vcs_.branch_info = {
    kind : [> `Master] as 'branch_type;
    root : id;
    pos  : id;
  }

  type vcs = (branch_type, transaction, vcs state_info, box) Vcs_.t

  val init : stm_doc_type -> id -> Vernacstate.Parser.state -> doc
  (* val get_type : unit -> stm_doc_type *)
  val set_ldir : Names.DirPath.t -> unit
  val get_ldir : unit -> Names.DirPath.t

  val is_interactive : unit -> bool
  val is_vio_doc : unit -> bool

  val current_branch : unit -> Branch.t
  val checkout : Branch.t -> unit
  val branches : unit -> Branch.t list
  val get_branch : Branch.t -> branch_type branch_info
  val get_branch_pos : Branch.t -> id
  val new_node : ?id:Stateid.t -> Pvernac.proof_mode option -> unit -> id
  val merge : id -> ours:transaction -> ?into:Branch.t -> Branch.t -> unit
  val rewrite_merge : id -> ours:transaction -> at:id -> Branch.t -> unit
  val delete_branch : Branch.t -> unit
  val commit : id -> transaction -> unit
  val mk_branch_name : aast -> Branch.t
  val edit_branch : Branch.t
  val branch : ?root:id -> ?pos:id -> Branch.t -> branch_type -> unit
  val reset_branch : Branch.t -> id -> unit
  val reachable : id -> Stateid.Set.t
  val cur_tip : unit -> id

  val get_info : id -> vcs state_info
  val reached : id -> unit
  val goals : id -> int -> unit
  val set_state : id -> cached_state -> unit
  val get_state : id -> cached_state
  val set_parsing_state : id -> Vernacstate.Parser.state -> unit
  val get_parsing_state : id -> Vernacstate.Parser.state option
  val get_proof_mode : id -> Pvernac.proof_mode option

  (* cuts from start -> stop, raising Expired if some nodes are not there *)
  val slice : block_start:id -> block_stop:id -> vcs
  val nodes_in_slice : block_start:id -> block_stop:id -> Stateid.t list

  val create_proof_task_box : id list -> qed:id -> block_start:id -> unit
  val create_proof_block : static_block_declaration -> string -> unit
  val box_of : id -> box list
  val delete_boxes_of : id -> unit
  val proof_task_box_of : id -> pt option

  val proof_nesting : unit -> int
  val checkout_shallowest_proof_branch : unit -> unit
  val propagate_sideff : action:seff_t -> Stateid.t list
  val propagate_qed : unit -> unit

  val gc : unit -> unit

  val visit : id -> visit

  val print : ?now:bool -> unit -> unit

  val backup : unit -> vcs
  val restore : vcs -> unit

end = struct (* {{{ *)

  include Vcs_
  exception Expired = Vcs_aux.Expired

  open Printf

  let print_dag vcs () =

    (* Due to threading, be wary that this will be called from the
       toplevel with we_are_parsing set to true, as indeed, the
       toplevel is waiting for input . What a race! XD

       In case you are hitting the race enable stm_debug.
    *)
    if !stm_debug then Flags.we_are_parsing := false;

    let fname =
      "stm_" ^ Str.global_replace (Str.regexp " ") "_" (Spawned.process_id ()) in
    let string_of_transaction = function
      | Cmd { cast = t } | Fork (t, _,_,_) ->
          (try Pp.string_of_ppcmds (pr_ast t) with _ -> "ERR")
      | Sideff (ReplayCommand t) ->
          sprintf "Sideff(%s)"
            (try Pp.string_of_ppcmds (pr_ast t) with _ -> "ERR")
      | Sideff CherryPickEnv -> "EnvChange"
      | Noop -> " "
      | Alias (id,_) -> sprintf "Alias(%s)" (Stateid.to_string id)
      | Qed { qast } -> Pp.string_of_ppcmds (pr_ast qast) in
    let is_green id =
      match get_info vcs id with
      | Some { state = FullState _ } -> true
      | _ -> false in
    let is_red id =
      match get_info vcs id with
      | Some { state = ErrorState _ } -> true
      | _ -> false in
    let head = current_branch vcs in
    let heads =
      List.map (fun x -> x, (get_branch vcs x).pos) (branches vcs) in
    let graph = dag vcs in
    let quote s =
      Str.global_replace (Str.regexp "\n") "<BR/>"
       (Str.global_replace (Str.regexp "<") "&lt;"
        (Str.global_replace (Str.regexp ">") "&gt;"
         (Str.global_replace (Str.regexp "\"") "&quot;"
          (Str.global_replace (Str.regexp "&") "&amp;"
           (String.sub s 0 (min (String.length s) 20)))))) in
    let fname_dot, fname_ps =
      let f = "/tmp/" ^ Filename.basename fname in
      f ^ ".dot", f ^ ".pdf" in
    let node id = "s" ^ Stateid.to_string id in
    let edge tr =
      sprintf "<<FONT POINT-SIZE=\"12\" FACE=\"sans\">%s</FONT>>"
        (quote (string_of_transaction tr)) in
    let node_info id =
      match get_info vcs id with
      | None -> ""
      | Some info ->
          sprintf "<<FONT POINT-SIZE=\"12\">%s</FONT>" (Stateid.to_string id) ^
          sprintf " <FONT POINT-SIZE=\"11\">r:%d g:%d</FONT>>"
            info.n_reached info.n_goals in
    let color id =
      if is_red id then "red" else if is_green id then "green" else "white" in
    let nodefmt oc id =
      fprintf oc "%s [label=%s,style=filled,fillcolor=%s];\n"
        (node id) (node_info id) (color id) in

    let ids = ref Stateid.Set.empty in
    let boxes = ref [] in
    (* Fill in *)
    Dag.iter graph (fun from _ _ l ->
      ids := Stateid.Set.add from !ids;
      List.iter (fun box -> boxes := box :: !boxes)
        (Dag.property_of graph from);
      List.iter (fun (dest, _) ->
        ids := Stateid.Set.add dest !ids;
        List.iter (fun box -> boxes := box :: !boxes)
          (Dag.property_of graph dest))
      l);
    boxes := CList.sort_uniquize Dag.Property.compare !boxes;

    let oc = open_out fname_dot in
    output_string oc "digraph states {\n";
    Dag.iter graph (fun from cf _ l ->
      List.iter (fun (dest, trans) ->
       fprintf oc "%s -> %s [xlabel=%s,labelfloat=true];\n"
           (node from) (node dest) (edge trans)) l
    );

    let contains b1 b2 =
      Stateid.Set.subset
        (Dag.Property.having_it b2) (Dag.Property.having_it b1) in
    let same_box = Dag.Property.equal in
    let outerboxes boxes =
       List.filter (fun b ->
         not (List.exists (fun b1 ->
           not (same_box b1 b) && contains b1 b) boxes)
         ) boxes in
    let rec rec_print b =
      boxes := CList.remove same_box b !boxes;
      let sub_boxes = List.filter (contains b) (outerboxes !boxes) in
      fprintf oc "subgraph cluster_%s {\n" (Dag.Property.to_string b);
      List.iter rec_print sub_boxes;
      Stateid.Set.iter (fun id ->
        if Stateid.Set.mem id !ids then begin
          ids := Stateid.Set.remove id !ids;
          nodefmt oc id
        end)
        (Dag.Property.having_it b);
      match Dag.Property.data b with
      | ProofBlock ({ dynamic_switch = id }, lbl) ->
          fprintf oc "label=\"%s (test:%s)\";\n" lbl (Stateid.to_string id);
          fprintf oc "color=red; }\n"
      | ProofTask _ -> fprintf oc "color=blue; }\n"
      in
    List.iter rec_print (outerboxes !boxes);
    Stateid.Set.iter (nodefmt oc) !ids;

    List.iteri (fun i (b,id) ->
      let shape = if Branch.equal head b then "box3d" else "box" in
      fprintf oc "b%d -> %s;\n" i (node id);
      fprintf oc "b%d [shape=%s,label=\"%s\"];\n" i shape
        (Branch.to_string b);
    ) heads;

    output_string oc "}\n";
    close_out oc;
    ignore(Sys.command
      ("dot -Tpdf -Gcharset=latin1 " ^ fname_dot ^ " -o" ^ fname_ps))

  type vcs = (branch_type, transaction, vcs state_info, box) t
  let vcs : vcs ref = ref (empty Stateid.dummy)

  let doc_type = ref (Interactive (TopLogical (Names.DirPath.make [])))
  let ldir = ref Names.DirPath.empty

  let init dt id ps =
    doc_type := dt;
    vcs := empty id;
    let info = { (default_info None) with state = ParsingState ps } in
    vcs := set_info !vcs id info;
    dummy_doc

  let set_ldir ld =
    ldir := ld

  let get_ldir () = !ldir
  (* let get_type () = !doc_type *)

  let is_interactive () =
    match !doc_type with
    | Interactive _ -> true
    | _ -> false

  let is_vio_doc () =
    match !doc_type with
    | VioDoc _ -> true
    | _ -> false

  let current_branch () = current_branch !vcs

  let checkout head = vcs := checkout !vcs head
  let branches () = branches !vcs
  let get_branch head = get_branch !vcs head
  let get_branch_pos head = (get_branch head).pos
  let new_node ?(id=Stateid.fresh ()) proof_mode () =
    assert(Vcs_.get_info !vcs id = None);
    vcs := set_info !vcs id (default_info proof_mode);
    id
  let merge id ~ours ?into branch =
    vcs := merge !vcs id ~ours ~theirs:Noop ?into branch
  let delete_branch branch = vcs := delete_branch !vcs branch
  let reset_branch branch id = vcs := reset_branch !vcs branch id
  let commit id t = vcs := commit !vcs id t
  let rewrite_merge id ~ours ~at branch =
    vcs := rewrite_merge !vcs id ~ours ~theirs:Noop ~at branch
  let reachable id = reachable !vcs id
  let mk_branch_name { expr = x } = Branch.make
    (match x.CAst.v.Vernacexpr.expr with
    | VernacDefinition (_,({CAst.v=Name i},_),_) -> Id.to_string i
    | VernacStartTheoremProof (_,[({CAst.v=i},_),_]) -> Id.to_string i
    | VernacInstance (({CAst.v=Name i},_),_,_,_,_) -> Id.to_string i
    | _ -> "branch")
  let edit_branch = Branch.make "edit"
  let branch ?root ?pos name kind = vcs := branch !vcs ?root ?pos name kind
  let get_info id =
    match get_info !vcs id with
    | Some x -> x
    | None -> raise Vcs_aux.Expired
  let set_state id s =
    let info = get_info id in
    info.state <- s;
    let is_full_state_valid = match s with
      | FullState _ -> true
      | EmptyState | ErrorState _ | ParsingState _ -> false
    in
    if async_proofs_is_master !cur_opt && is_full_state_valid then
      Hooks.(call state_ready ~doc:dummy_doc (* XXX should be taken in input *) id)

  let get_state id = (get_info id).state

  let get_parsing_state id =
    stm_pperr_endline (fun () -> str "retrieve parsing state state " ++ str (Stateid.to_string id) ++ str " }}}");
    match (get_info id).state with
    | FullState s -> Some s.Vernacstate.parsing
    | ParsingState s -> Some s
    | ErrorState (s,_) -> s
    | EmptyState -> None

  let set_parsing_state id ps =
    let info = get_info id in
    let new_state =
      match info.state with
      | FullState s -> assert false
      | ParsingState s -> assert false
      | ErrorState _ -> assert false
      | EmptyState -> ParsingState ps
    in
    info.state <- new_state

  let get_proof_mode id = (get_info id).proof_mode

  let reached id =
    let info = get_info id in
    info.n_reached <- info.n_reached + 1
  let goals id n = (get_info id).n_goals <- n
  let cur_tip () = get_branch_pos (current_branch ())

  let proof_nesting () = Vcs_aux.proof_nesting !vcs

  let checkout_shallowest_proof_branch () =
    if List.mem edit_branch (Vcs_.branches !vcs) then begin
      checkout edit_branch
    end else
      let pl = proof_nesting () in
      try
        let branch = fst @@ Vcs_aux.find_proof_at_depth !vcs pl in
        checkout branch
      with Failure _ ->
        checkout Branch.master

  (* copies the transaction on every open branch *)
  let propagate_sideff ~action =
    List.map (fun b ->
      checkout b;
      let proof_mode = get_proof_mode @@ get_branch_pos b in
      let id = new_node proof_mode () in
      merge id ~ours:(Sideff action) ~into:b Branch.master;
      id)
    (List.filter (fun b -> not (Branch.equal b Branch.master)) (branches ()))

  let propagate_qed () =
    List.iter (fun b ->
      checkout b;
      let proof_mode = get_proof_mode @@ get_branch_pos b in
      let id = new_node proof_mode () in
      let parsing = Option.get @@ get_parsing_state (get_branch_pos b) in
      merge id ~ours:(Sideff CherryPickEnv) ~into:b Branch.master;
      set_parsing_state id parsing)
    (List.filter (fun b -> not (Branch.equal b Branch.master)) (branches ()))

  let visit id = Vcs_aux.visit !vcs id

  let nodes_in_slice ~block_start ~block_stop =
    let rec aux id =
      if Stateid.equal id block_start then [] else
      match visit id with
      | { next = n; step = `Cmd x } -> (id,Cmd x) :: aux n
      | { next = n; step = `Alias x } -> (id,Alias x) :: aux n
      | { next = n; step = `Sideff (ReplayCommand x,_) } ->
           (id,Sideff (ReplayCommand x)) :: aux n
      | _ -> anomaly Pp.(str("Cannot slice from "^ Stateid.to_string block_start ^
                         " to "^Stateid.to_string block_stop^"."))
    in aux block_stop

  (* [slice] copies a slice of the DAG, keeping only the last known valid state.
     When it copies a state, it drops the libobjects and keeps only the structure. *)
  let slice ~block_start ~block_stop =
    let l = nodes_in_slice ~block_start ~block_stop in
    let copy_info v id =
      let info = get_info id in
      Vcs_.set_info v id
        { info with state = EmptyState;
                    vcs_backup = None,None } in
    let make_shallow = function
      | FullState st -> FullState (Vernacstate.make_shallow st)
      | x -> x
    in
    let copy_info_w_state v id =
      let info = get_info id in
      Vcs_.set_info v id { info with state = make_shallow info.state; vcs_backup = None,None } in
    let copy_proof_blockes v =
      let nodes = Vcs_.Dag.all_nodes (Vcs_.dag v) in
      let props =
        Stateid.Set.fold (fun n pl -> Vcs_.property_of !vcs n @ pl) nodes [] in
      let props = CList.sort_uniquize Vcs_.Dag.Property.compare props in
      List.fold_left (fun v p ->
        Vcs_.create_property v
          (Stateid.Set.elements (Vcs_.Dag.Property.having_it p))
          (Vcs_.Dag.Property.data p)) v props
    in
    let v = Vcs_.empty block_start in
    let v = copy_info v block_start in
    let v = List.fold_right (fun (id,tr) v ->
      let v = Vcs_.commit v id tr in
      let v = copy_info v id in
      v) l v in
    (* Stm should have reached the beginning of proof *)
    assert (match get_state block_start
            with FullState _ -> true | _  -> false);
    (* We put in the new dag the most recent state known to master *)
    let rec fill id =
      match get_state id with
      | EmptyState | ErrorState _ | ParsingState _ -> fill (Vcs_aux.visit v id).next
      | FullState _ -> copy_info_w_state v id
    in
    let v = fill block_stop in
    (* We put in the new dag the first state (since Qed shall run on it,
     * see check_task_aux) *)
    let v = copy_info_w_state v block_start in
    copy_proof_blockes v

  let nodes_in_slice ~block_start ~block_stop =
    List.rev (List.map fst (nodes_in_slice ~block_start ~block_stop))

  let topo_invariant l =
    let all = List.fold_right Stateid.Set.add l Stateid.Set.empty in
    List.for_all
      (fun x ->
         let props = property_of !vcs x in
         let sets = List.map Dag.Property.having_it props in
         List.for_all (fun s -> Stateid.Set.(subset s all || subset all s)) sets)
      l

  let create_proof_task_box l ~qed ~block_start:lemma =
    if not (topo_invariant l) then anomaly Pp.(str "overlapping boxes.");
    vcs := create_property !vcs l (ProofTask { qed; lemma })
  let create_proof_block ({ block_start; block_stop} as decl) name =
    let l = nodes_in_slice ~block_start ~block_stop in
    if not (topo_invariant l) then anomaly Pp.(str "overlapping boxes.");
    vcs := create_property !vcs l (ProofBlock (decl, name))
  let box_of id = List.map Dag.Property.data (property_of !vcs id)
  let delete_boxes_of id =
    List.iter (fun x -> vcs := delete_property !vcs x) (property_of !vcs id)
  let proof_task_box_of id =
    match
      CList.map_filter (function ProofTask x -> Some x | _ -> None) (box_of id)
    with
    | [] -> None
    | [x] -> Some x
    | _ -> anomaly Pp.(str "node with more than 1 proof task box.")

  let gc () =
    let old_vcs = !vcs in
    let new_vcs, erased_nodes = gc old_vcs in
    Stateid.Set.iter (fun id ->
        match (Vcs_aux.visit old_vcs id).step with
        | `Qed ({ fproof = Some (_, cancel_switch) }, _)
        | `Cmd { cqueue = `TacQueue (_,_,cancel_switch) }
        | `Cmd { cqueue = `QueryQueue cancel_switch } ->
             cancel_switch := true
        | _ -> ())
      erased_nodes;
    vcs := new_vcs

  module NB : sig (* Non blocking Sys.command *)

    val command : now:bool -> (unit -> unit) -> unit

  end = struct

    let m = Mutex.create ()
    let c = Condition.create ()
    let job = ref None
    let worker = ref None

    let set_last_job j =
      Mutex.lock m;
      job := Some j;
      Condition.signal c;
      Mutex.unlock m

    let get_last_job () =
      Mutex.lock m;
      while Option.is_empty !job do Condition.wait c m; done;
      match !job with
      | None -> assert false
      | Some x -> job := None; Mutex.unlock m; x

    let run_command () =
      try while true do get_last_job () () done
      with e -> () (* No failure *)

    let command ~now job =
      if now then job ()
      else begin
        set_last_job job;
        if Option.is_empty !worker then
          worker := Some (CThread.create run_command ())
      end

  end

  let print ?(now=false) () =
    if !Flags.debug then NB.command ~now (print_dag !vcs)

  let backup () = !vcs
  let restore v = vcs := v

end (* }}} *)

let state_of_id ~doc id =
  try match VCS.get_state id with
    | FullState s -> `Valid (Some s)
    | ErrorState (_,(e,_)) -> `Error e
    | EmptyState | ParsingState _ -> `Valid None
  with VCS.Expired -> `Expired

(****** A cache: fills in the nodes of the VCS document with their value ******)
module State : sig

  type t

  val freeze : unit -> t
  val unfreeze : t -> unit

  (** The function is from unit, so it uses the current state to define
      a new one.  I.e. one may been to install the right state before
      defining a new one.
      Warning: an optimization in installed_cached requires that state
      modifying functions are always executed using this wrapper. *)
  val define :
    doc:doc ->
    ?safe_id:Stateid.t ->
    ?redefine:bool -> ?cache:bool ->
    ?feedback_processed:bool -> (unit -> unit) -> Stateid.t -> unit

  val fix_exn_ref : (Exninfo.iexn -> Exninfo.iexn) ref

  val install_cached : Stateid.t -> unit
  (* val install_parsing_state : Stateid.t -> unit *)
  val is_cached : ?cache:bool -> Stateid.t -> bool
  val is_cached_and_valid : ?cache:bool -> Stateid.t -> bool

  val exn_on : Stateid.t -> valid:Stateid.t -> Exninfo.iexn -> Exninfo.iexn

  (* to send states across worker/master *)
  val get_cached : Stateid.t -> Vernacstate.t
  val same_env : Vernacstate.t -> Vernacstate.t -> bool

  type proof_part

  type partial_state =
    [ `Full of Vernacstate.t
    | `ProofOnly of Stateid.t * proof_part ]

  val proof_part_of_frozen : Vernacstate.t -> proof_part
  val assign : Stateid.t -> partial_state -> unit

  (* Handlers for initial state, prior to document creation. *)
  val register_root_state : unit -> unit
  val restore_root_state : unit -> unit

  val purify : ('a -> 'b) -> 'a -> 'b

end = struct (* {{{ *)

  type t = { id : Stateid.t; vernac_state : Vernacstate.t }

  (* cur_id holds Stateid.dummy in case the last attempt to define a state
   * failed, so the global state may contain garbage *)
  let cur_id = ref Stateid.dummy
  let fix_exn_ref = ref (fun x -> x)

  let freeze () = { id = !cur_id; vernac_state = Vernacstate.freeze_interp_state ~marshallable:false }
  let unfreeze st =
    Vernacstate.unfreeze_interp_state st.vernac_state;
    cur_id := st.id

  let invalidate_cur_state () = cur_id := Stateid.dummy

  type proof_part =
    Vernacstate.LemmaStack.t option *
    int *                                   (* Evarutil.meta_counter_summary_tag *)
    int *                                   (* Evd.evar_counter_summary_tag *)
    DeclareObl.program_info CEphemeron.key Names.Id.Map.t (* Obligations.program_tcc_summary_tag *)

  type partial_state =
    [ `Full of Vernacstate.t
    | `ProofOnly of Stateid.t * proof_part ]

  let proof_part_of_frozen { Vernacstate.lemmas; system } =
    let st = States.summary_of_state system in
    lemmas,
    Summary.project_from_summary st Util.(pi1 summary_pstate),
    Summary.project_from_summary st Util.(pi2 summary_pstate),
    Summary.project_from_summary st Util.(pi3 summary_pstate)

  let cache_state ~marshallable id =
    VCS.set_state id (FullState (Vernacstate.freeze_interp_state ~marshallable))

  let freeze_invalid id iexn =
    let ps = VCS.get_parsing_state id in
    VCS.set_state id (ErrorState (ps,iexn))

  let is_cached ?(cache=false) id only_valid =
    if Stateid.equal id !cur_id then
      try match VCS.get_info id with
        | ({ state = EmptyState } | { state = ParsingState _ }) when cache -> cache_state ~marshallable:false id; true
        | _ -> true
      with VCS.Expired -> false
    else
      try match VCS.get_state id with
        | EmptyState | ParsingState _ -> false
        | FullState _ -> true
        | ErrorState _ -> not only_valid
      with VCS.Expired -> false

  let is_cached_and_valid ?cache id = is_cached ?cache id true
  let is_cached ?cache id = is_cached ?cache id false

  let install_cached id =
    match VCS.get_state id with
    | FullState s ->
       Vernacstate.unfreeze_interp_state s;
       cur_id := id

    | ErrorState (_,ie) ->
       Exninfo.iraise ie

    | EmptyState | ParsingState _ ->
      (* coqc has a 1 slot cache and only for valid states *)
      if (VCS.is_interactive ()) || not (Stateid.equal id !cur_id) then
        anomaly Pp.(str "installing a non cached state.")

  (*
  let install_parsing_state id =
    if not (Stateid.equal id !cur_id) then begin
      Vernacstate.Parser.install @@ VCS.get_parsing_state id
    end
     *)

  let get_cached id =
    try match VCS.get_state id with
    | FullState s -> s
    | _ -> anomaly Pp.(str "not a cached state.")
    with VCS.Expired -> anomaly Pp.(str "not a cached state (expired).")

  let assign id what =
    let open Vernacstate in
    if VCS.get_state id <> EmptyState then () else
    try match what with
    | `Full s ->
         let s =
           try
            let prev = (VCS.visit id).next in
            if is_cached_and_valid prev
            then { s with lemmas =
                PG_compat.copy_terminators
                  ~src:((get_cached prev).lemmas) ~tgt:s.lemmas }
            else s
           with VCS.Expired -> s in
         VCS.set_state id (FullState s)
    | `ProofOnly(ontop,(pstate,c1,c2,c3)) ->
         if is_cached_and_valid ontop then
           let s = get_cached ontop in
           let s = { s with lemmas =
             PG_compat.copy_terminators ~src:s.lemmas ~tgt:pstate } in
           let s = { s with system =
             States.replace_summary s.system
               begin
                 let st = States.summary_of_state s.system in
                 let st = Summary.modify_summary st Util.(pi1 summary_pstate) c1 in
                 let st = Summary.modify_summary st Util.(pi2 summary_pstate) c2 in
                 let st = Summary.modify_summary st Util.(pi3 summary_pstate) c3 in
                 st
               end
                } in
           VCS.set_state id (FullState s)
    with VCS.Expired -> ()

  let exn_on id ~valid (e, info) =
    match Stateid.get info with
    | Some _ -> (e, info)
    | None ->
        let loc = Loc.get_loc info in
        execution_error ?loc id (iprint (e, info));
        (e, Stateid.add info ~valid id)

  let same_env { Vernacstate.system = s1 } { Vernacstate.system = s2 } =
    let s1 = States.summary_of_state s1 in
    let e1 = Summary.project_from_summary s1 Global.global_env_summary_tag in
    let s2 = States.summary_of_state s2 in
    let e2 = Summary.project_from_summary s2 Global.global_env_summary_tag in
    e1 == e2

  (* [define] puts the system in state [id] calling [f ()] *)
  (* [safe_id] is the last known valid state before execution *)
  let define ~doc ?safe_id ?(redefine=false) ?(cache=false) ?(feedback_processed=true)
        f id
  =
    feedback ~id:id (ProcessingIn !Flags.async_proofs_worker_id);
    let str_id = Stateid.to_string id in
    if is_cached id && not redefine then
      anomaly Pp.(str"defining state "++str str_id++str" twice.");
    try
      stm_prerr_endline (fun () -> "defining "^str_id^" (cache="^
        if cache then "Y)" else "N)");
      let good_id = match safe_id with None -> !cur_id | Some id -> id in
      fix_exn_ref := exn_on id ~valid:good_id;
      f ();
      fix_exn_ref := (fun x -> x);
      if cache then cache_state ~marshallable:false id;
      stm_prerr_endline (fun () -> "setting cur id to "^str_id);
      cur_id := id;
      if feedback_processed then
        Hooks.(call state_computed ~doc id ~in_cache:false);
      VCS.reached id;
      if PG_compat.there_are_pending_proofs () then
        VCS.goals id (PG_compat.get_open_goals ())
    with e ->
      let (e, info) = CErrors.push e in
      let good_id = !cur_id in
      invalidate_cur_state ();
      VCS.reached id;
      let ie =
        match Stateid.get info, safe_id with
        | None, None -> (exn_on id ~valid:good_id (e, info))
        | None, Some good_id -> (exn_on id ~valid:good_id (e, info))
        | Some _, None -> (e, info)
        | Some (_,at), Some id -> (e, Stateid.add info ~valid:id at) in
      if cache then freeze_invalid id ie;
      Hooks.(call unreachable_state ~doc id ie);
      Exninfo.iraise ie

  let init_state = ref None

  let register_root_state () =
    init_state := Some (Vernacstate.freeze_interp_state ~marshallable:false)

  let restore_root_state () =
    cur_id := Stateid.dummy;
    Vernacstate.unfreeze_interp_state (Option.get !init_state)

  (* Protect against state changes *)
  let purify f x =
    let st = freeze () in
    try
      let res = f x in
      Vernacstate.invalidate_cache ();
      unfreeze st;
      res
    with e ->
      let e = CErrors.push e in
      Vernacstate.invalidate_cache ();
      unfreeze st;
      Exninfo.iraise e

end (* }}} *)

(* Wrapper for the proof-closing special path for Qed *)
let stm_qed_delay_proof ?route ~proof ~info ~id ~st ~loc ~control pending : Vernacstate.t =
  set_id_for_feedback ?route dummy_doc id;
  Vernacinterp.interp_qed_delayed_proof ~proof ~info ~st ~control (CAst.make ?loc pending)

(* Wrapper for Vernacentries.interp to set the feedback id *)
(* It is currently called 19 times, this number should be certainly
   reduced... *)
let stm_vernac_interp ?route id st { verbose; expr } : Vernacstate.t =
  (* The Stm will gain the capability to interpret commmads affecting
     the whole document state, such as backtrack, etc... so we start
     to design the stm command interpreter now *)
  set_id_for_feedback ?route dummy_doc id;
  Aux_file.record_in_aux_set_at ?loc:expr.CAst.loc ();
  (* We need to check if a command should be filtered from
   * vernac_entries, as it cannot handle it. This should go away in
   * future refactorings.
  *)
  let is_filtered_command = function
    | VernacResetName _ | VernacResetInitial | VernacBack _
    | VernacRestart | VernacUndo _ | VernacUndoTo _
    | VernacAbortAll | VernacAbort _ -> true
    | _ -> false
  in
  (* XXX unsupported attributes *)
  let cmd = expr.CAst.v.expr in
  if is_filtered_command cmd then
    (stm_pperr_endline Pp.(fun () -> str "ignoring " ++ Ppvernac.pr_vernac expr); st)
  else begin
    stm_pperr_endline Pp.(fun () -> str "interpreting " ++ Ppvernac.pr_vernac expr);
    Vernacinterp.interp ?verbosely:(Some verbose) ~st expr
  end

(****************************** CRUFT *****************************************)
(******************************************************************************)

(* The backtrack module simulates the classic behavior of a linear document *)
module Backtrack : sig

  val record : unit -> unit

  (* we could navigate the dag, but this ways easy *)
  val branches_of : Stateid.t -> backup

  (* Returns the state that the command should backtract to *)
  val undo_vernac_classifier : vernac_control -> doc:doc -> Stateid.t
  val get_prev_proof : doc:doc -> Stateid.t -> Proof.t option
  val get_proof : doc:doc -> Stateid.t -> Proof.t option

end = struct (* {{{ *)

  let record () =
    List.iter (fun current_branch ->
      let mine = current_branch, VCS.get_branch current_branch in
      let info = VCS.get_info (VCS.get_branch_pos current_branch) in
      let others =
        CList.map_filter (fun b ->
          if Vcs_.Branch.equal b current_branch then None
          else Some(b, VCS.get_branch b)) (VCS.branches ()) in
      let backup = if fst info.vcs_backup <> None then fst info.vcs_backup
        else Some (VCS.backup ()) in
      let branches = if snd info.vcs_backup <> None then snd info.vcs_backup
        else Some { mine; others } in
      info.vcs_backup <- backup, branches)
    [VCS.current_branch (); VCS.Branch.master]

  let branches_of id =
    let info = VCS.get_info id in
    match info.vcs_backup with
    | _, None ->
       anomaly Pp.(str"Backtrack.branches_of "++str(Stateid.to_string id)++
                   str": a state with no vcs_backup.")
    | _, Some x -> x

  let rec fold_until f acc id =
    let next acc =
      if id = Stateid.initial then raise Not_found
      else fold_until f acc (VCS.visit id).next in
    let info = VCS.get_info id in
    match info.vcs_backup with
    | None, _ -> next acc
    | Some vcs, _ ->
        let ids, tactic, undo =
          if id = Stateid.initial || id = Stateid.dummy then [],false,0 else
          match VCS.visit id with
          | { step = `Fork ((_,_,_,l),_) } -> l, false,0
          | { step = `Cmd { cids = l; ctac } } -> l, ctac,0
          | { step = `Alias (_,{ expr }) } when not (Vernacprop.has_Fail expr) ->
          begin match expr.CAst.v.expr with
                | VernacUndo n -> [], false, n
                | _ -> [],false,0
          end
          | _ -> [],false,0 in
        match f acc (id, vcs, ids, tactic, undo) with
        | `Stop x -> x
        | `Cont acc -> next acc

  let undo_costly_in_batch_mode =
    CWarnings.create ~name:"undo-batch-mode" ~category:"non-interactive" Pp.(fun v ->
        str "Command " ++ Ppvernac.pr_vernac v ++
        str (" is not recommended in batch mode. In particular, going back in the document" ^
             " is not efficient in batch mode due to Coq not caching previous states for memory optimization reasons." ^
             " If your use is intentional, you may want to disable this warning and pass" ^
             " the \"-async-proofs-cache force\" option to Coq."))

  let back_tactic n (id,_,_,tactic,undo) =
    let value = (if tactic then 1 else 0) - undo in
    if Int.equal n 0 then `Stop id else `Cont (n-value)

  let get_proof ~doc id =
    match state_of_id ~doc id with
    | `Valid (Some vstate) -> Option.map (Vernacstate.LemmaStack.with_top_pstate ~f:Proof_global.get_proof) vstate.Vernacstate.lemmas
    | _ -> None

  let undo_vernac_classifier v ~doc =
    if not (VCS.is_interactive ()) && !cur_opt.async_proofs_cache <> Some Force
    then undo_costly_in_batch_mode v;
    try
      match v.CAst.v.expr with
      | VernacResetInitial ->
          Stateid.initial
      | VernacResetName {CAst.v=name} ->
          let id = VCS.cur_tip () in
          (try
            let oid =
              fold_until (fun b (id,_,label,_,_) ->
                if b then `Stop id else `Cont (List.mem name label))
              false id in
            oid
          with Not_found ->
            id)
      | VernacBack n ->
          let id = VCS.cur_tip () in
          let oid = fold_until (fun n (id,_,_,_,_) ->
            if Int.equal n 0 then `Stop id else `Cont (n-1)) n id in
          oid
      | VernacUndo n ->
          let id = VCS.cur_tip () in
          let oid = fold_until back_tactic n id in
          oid
      | VernacUndoTo _
      | VernacRestart as e ->
          let m = match e with VernacUndoTo m -> m | _ -> 0 in
          let id = VCS.cur_tip () in
          let vcs =
            match (VCS.get_info id).vcs_backup with
            | None, _ -> anomaly Pp.(str"Backtrack: tip with no vcs_backup.")
            | Some vcs, _ -> vcs in
          let cb, _ =
            try Vcs_aux.find_proof_at_depth vcs (Vcs_aux.proof_nesting vcs)
            with Failure _ -> raise PG_compat.NoCurrentProof in
          let n = fold_until (fun n (_,vcs,_,_,_) ->
            if List.mem cb (Vcs_.branches vcs) then `Cont (n+1) else `Stop n)
            0 id in
          let oid = fold_until (fun n (id,_,_,_,_) ->
            if Int.equal n 0 then `Stop id else `Cont (n-1)) (n-m-1) id in
          oid
      | VernacAbortAll ->
          let id = VCS.cur_tip () in
          let oid = fold_until (fun () (id,vcs,_,_,_) ->
            match Vcs_.branches vcs with [_] -> `Stop id | _ -> `Cont ())
            () id in
          oid
      | _ -> anomaly Pp.(str "incorrect VtMeta classification")
    with
    | Not_found ->
       CErrors.user_err ~hdr:"undo_vernac_classifier"
        Pp.(str "Cannot undo")

  let get_prev_proof ~doc id =
    try
      let np = get_proof ~doc id in
      match np with
      | None -> None
      | Some cp ->
        let did = ref id in
        let rv = ref np in
        let done_ = ref false in
        while not !done_ do
          did := fold_until back_tactic 1 !did;
          rv := get_proof ~doc !did;
          done_ := match !rv with
            | Some rv -> not (Goal.Set.equal (Proof.all_goals rv) (Proof.all_goals cp))
            | None -> true
        done;
        !rv
    with Not_found | PG_compat.NoCurrentProof -> None

end (* }}} *)

let get_prev_proof = Backtrack.get_prev_proof
let get_proof = Backtrack.get_proof

let hints = ref Aux_file.empty_aux_file
let set_compilation_hints file =
  hints := Aux_file.load_aux_file_for file

let get_hint_ctx loc =
  let s = Aux_file.get ?loc !hints "context_used" in
  let ids = List.map Names.Id.of_string (Str.split (Str.regexp " ") s) in
  let ids = List.map (fun id -> CAst.make id) ids in
  match ids with
  | [] -> SsEmpty
  | x :: xs ->
    List.fold_left (fun a x -> SsUnion (SsSingl x,a)) (SsSingl x) xs

let get_hint_bp_time proof_name =
  try float_of_string (Aux_file.get !hints proof_name)
  with Not_found -> 1.0

let record_pb_time ?loc proof_name time =
  let proof_build_time = Printf.sprintf "%.3f" time in
  Aux_file.record_in_aux_at ?loc "proof_build_time" proof_build_time;
  if proof_name <> "" then begin
    Aux_file.record_in_aux_at proof_name proof_build_time;
    hints := Aux_file.set !hints proof_name proof_build_time
  end

exception RemoteException of Pp.t
let _ = CErrors.register_handler (function
  | RemoteException ppcmd -> ppcmd
  | _ -> raise Unhandled)

(****************** proof structure for error recovery ************************)
(******************************************************************************)

type document_node = {
  indentation : int;
  ast : Vernacexpr.vernac_control;
  id : Stateid.t;
}

type document_view = {
  entry_point : document_node;
  prev_node : document_node -> document_node option;
}

type static_block_detection =
  document_view -> static_block_declaration option

type recovery_action = {
  base_state : Stateid.t;
  goals_to_admit : Goal.goal list;
  recovery_command : Vernacexpr.vernac_control option;
}

type dynamic_block_error_recovery =
  doc -> static_block_declaration -> [ `ValidBlock of recovery_action | `Leaks ]

let proof_block_delimiters = ref []

let register_proof_block_delimiter name static dynamic =
  if List.mem_assoc name !proof_block_delimiters then
    CErrors.user_err ~hdr:"STM" Pp.(str "Duplicate block delimiter " ++ str name);
  proof_block_delimiters := (name, (static,dynamic)) :: !proof_block_delimiters

let mk_doc_node id = function
  | { step = `Cmd { ctac; cast = { indentation; expr }}; next } when ctac ->
       Some { indentation; ast = expr; id }
  | { step = `Sideff (ReplayCommand { indentation; expr }, _); next } ->
       Some { indentation; ast = expr; id }
  | _ -> None
let prev_node { id } =
  let id = (VCS.visit id).next in
  mk_doc_node id (VCS.visit id)
let cur_node id = mk_doc_node id (VCS.visit id)

let is_block_name_enabled name =
  match !cur_opt.async_proofs_tac_error_resilience with
  | `None -> false
  | `All -> true
  | `Only l -> List.mem name l

let detect_proof_block id name =
  let name = match name with None -> "indent" | Some x -> x in
  if is_block_name_enabled name &&
     (async_proofs_is_master !cur_opt || Flags.async_proofs_is_worker ())
  then (
  match cur_node id with
  | None -> ()
  | Some entry_point -> try
      let static, _ = List.assoc name !proof_block_delimiters in
      begin match static { prev_node; entry_point } with
      | None -> ()
      | Some ({ block_start; block_stop } as decl) ->
          VCS.create_proof_block decl name
      end
    with Not_found ->
      CErrors.user_err ~hdr:"STM"
        Pp.(str "Unknown proof block delimiter " ++ str name)
  )
(****************************** THE SCHEDULER *********************************)
(******************************************************************************)

(* Unused module warning doesn't understand [module rec] *)
[@@@ocaml.warning "-60"]
module rec ProofTask : sig

  type competence = Stateid.t list
  type task_build_proof = {
    t_exn_info : Stateid.t * Stateid.t;
    t_start    : Stateid.t;
    t_stop     : Stateid.t;
    t_drop     : bool;
    t_states   : competence;
    t_assign   : Proof_global.closed_proof_output Future.assignment -> unit;
    t_loc      : Loc.t option;
    t_uuid     : Future.UUID.t;
    t_name     : string }

  type task =
    | BuildProof of task_build_proof
    | States of Stateid.t list

  type request =
  | ReqBuildProof of (Future.UUID.t,VCS.vcs) Stateid.request * bool * competence
  | ReqStates of Stateid.t list

  include AsyncTaskQueue.Task
  with type task := task
   and type competence := competence
   and type request := request

  val build_proof_here :
    doc:doc ->
    ?loc:Loc.t ->
    drop_pt:bool ->
    Stateid.t * Stateid.t -> Stateid.t ->
      Proof_global.closed_proof_output Future.computation

  (* If set, only tasks overlapping with this list are processed *)
  val set_perspective : Stateid.t list -> unit

end = struct (* {{{ *)

  let forward_feedback msg = Hooks.(call forward_feedback msg)

  type competence = Stateid.t list
  type task_build_proof = {
    t_exn_info : Stateid.t * Stateid.t;
    t_start    : Stateid.t;
    t_stop     : Stateid.t;
    t_drop     : bool;
    t_states   : competence;
    t_assign   : Proof_global.closed_proof_output Future.assignment -> unit;
    t_loc      : Loc.t option;
    t_uuid     : Future.UUID.t;
    t_name     : string }

  type task =
    | BuildProof of task_build_proof
    | States of Stateid.t list

  type worker_status = Fresh | Old of competence

  type request =
  | ReqBuildProof of (Future.UUID.t,VCS.vcs) Stateid.request * bool * competence
  | ReqStates of Stateid.t list

  type error = {
    e_error_at    : Stateid.t;
    e_safe_id     : Stateid.t;
    e_msg         : Pp.t;
    e_safe_states : Stateid.t list }

  type response =
    | RespBuiltProof of Proof_global.closed_proof_output * float
    | RespError of error
    | RespStates of (Stateid.t * State.partial_state) list

  let name = ref "proofworker"
  let extra_env () = !async_proofs_workers_extra_env

  let perspective = ref []
  let set_perspective l = perspective := l

  let is_inside_perspective st = true
    (* This code is now disabled. If an IDE needs this feature, make it accessible again.
    List.exists (fun x -> CList.mem_f Stateid.equal x !perspective) st
    *)

  let task_match age t =
    match age, t with
    | Fresh, BuildProof { t_states } -> is_inside_perspective t_states
    | Old my_states, States l ->
        List.for_all (fun x -> CList.mem_f Stateid.equal x my_states) l
    | _ -> false

  let name_of_task = function
    | BuildProof t -> "proof: " ^ t.t_name
    | States l -> "states: " ^ String.concat "," (List.map Stateid.to_string l)
  let name_of_request = function
    | ReqBuildProof(r,_,_) -> "proof: " ^ r.Stateid.name
    | ReqStates l -> "states: "^String.concat "," (List.map Stateid.to_string l)

  let request_of_task age = function
    | States l -> Some (ReqStates l)
    | BuildProof {
        t_exn_info;t_start;t_stop;t_loc;t_uuid;t_name;t_states;t_drop
      } ->
        assert(age = Fresh);
        try Some (ReqBuildProof ({
          Stateid.exn_info = t_exn_info;
          stop = t_stop;
          document = VCS.slice ~block_start:t_start ~block_stop:t_stop;
          loc = t_loc;
          uuid = t_uuid;
          name = t_name }, t_drop, t_states))
        with VCS.Expired -> None

  let use_response (s : worker_status) t r =
    match s, t, r with
    | Old c, States _, RespStates l ->
        List.iter (fun (id,s) -> State.assign id s) l; `End
    | Fresh, BuildProof { t_assign; t_loc; t_name; t_states; t_drop },
              RespBuiltProof (pl, time) ->
        feedback (InProgress ~-1);
        t_assign (`Val pl);
        record_pb_time ?loc:t_loc t_name time;
        if t_drop then `Stay(t_states,[States t_states])
        else `End
    | Fresh, BuildProof { t_assign; t_loc; t_name; t_states },
            RespError { e_error_at; e_safe_id = valid; e_msg; e_safe_states } ->
        feedback (InProgress ~-1);
        let info = Stateid.add ~valid Exninfo.null e_error_at in
        let e = (RemoteException e_msg, info) in
        t_assign (`Exn e);
        `Stay(t_states,[States e_safe_states])
    | _ -> assert false

  let on_task_cancellation_or_expiration_or_slave_death = function
    | None -> ()
    | Some (States _) -> ()
    | Some (BuildProof { t_start = start; t_assign }) ->
        let s = "Worker dies or task expired" in
        let info = Stateid.add ~valid:start Exninfo.null start in
        let e = (RemoteException (Pp.strbrk s), info) in
        t_assign (`Exn e);
        execution_error start (Pp.strbrk s);
        feedback (InProgress ~-1)

  let build_proof_here ~doc ?loc ~drop_pt (id,valid) eop =
    Future.create (State.exn_on id ~valid) (fun () ->
      let wall_clock1 = Unix.gettimeofday () in
      Reach.known_state ~doc ~cache:(VCS.is_interactive ()) eop;
      let wall_clock2 = Unix.gettimeofday () in
      Aux_file.record_in_aux_at ?loc "proof_build_time"
        (Printf.sprintf "%.3f" (wall_clock2 -. wall_clock1));
      let p = PG_compat.return_proof ~allow_partial:drop_pt () in
      if drop_pt then feedback ~id Complete;
      p)

  let perform_buildp { Stateid.exn_info; stop; document; loc } drop my_states =
    try
      VCS.restore document;
      VCS.print ();
      let proof, future_proof, time =
        let wall_clock = Unix.gettimeofday () in
        let fp = build_proof_here ~doc:dummy_doc (* XXX should be document *) ?loc ~drop_pt:drop exn_info stop in
        let proof = Future.force fp in
        proof, fp, Unix.gettimeofday () -. wall_clock in
      (* We typecheck the proof with the kernel (in the worker) to spot
       * the few errors tactics don't catch, like the "fix" tactic building
       * a bad fixpoint *)
      let fix_exn = Future.fix_exn_of future_proof in
      (* STATE: We use the current installed imperative state *)
      let st = State.freeze () in
      if not drop then begin
        let checked_proof = Future.chain future_proof (fun p ->
          let opaque = Proof_global.Opaque in

          (* Unfortunately close_future_proof and friends are not pure so we need
             to set the state manually here *)
          State.unfreeze st;
          let pobject, _info =
            PG_compat.close_future_proof ~opaque ~feedback_id:stop (Future.from_val ~fix_exn p) in

          let st = Vernacstate.freeze_interp_state ~marshallable:false in
          stm_qed_delay_proof ~st ~id:stop
            ~proof:pobject ~info:(Lemmas.Info.make ()) ~loc ~control:[] (Proved (opaque,None))) in
        ignore(Future.join checked_proof);
      end;
      (* STATE: Restore the state XXX: handle exn *)
      State.unfreeze st;
      RespBuiltProof(proof,time)
    with
    | e when CErrors.noncritical e || e = Stack_overflow ->
        let (e, info) = CErrors.push e in
        (* This can happen if the proof is broken.  The error has also been
         * signalled as a feedback, hence we can silently recover *)
        let e_error_at, e_safe_id = match Stateid.get info with
          | Some (safe, err) -> err, safe
          | None -> Stateid.dummy, Stateid.dummy in
        let e_msg = iprint (e, info) in
        stm_pperr_endline Pp.(fun () -> str "failed with the following exception: " ++ fnl () ++ e_msg);
        let e_safe_states = List.filter State.is_cached_and_valid my_states in
        RespError { e_error_at; e_safe_id; e_msg; e_safe_states }

  let perform_states query =
    if query = [] then [] else
    let is_tac e = match Vernac_classifier.classify_vernac e with
    | VtProofStep _ -> true
    | _ -> false
    in
    let initial =
      let rec aux id =
        try match VCS.visit id with { next } -> aux next
        with VCS.Expired -> id in
      aux (List.hd query) in
    let get_state seen id =
      let prev =
        try
          let { next = prev; step } = VCS.visit id in
          if State.is_cached_and_valid prev && List.mem prev seen
          then Some (prev, State.get_cached prev, step)
          else None
        with VCS.Expired -> None in
      let this =
        if State.is_cached_and_valid id then Some (State.get_cached id) else None in
      match prev, this with
      | _, None -> None
      | Some (prev, o, `Cmd { cast = { expr }}), Some n
        when is_tac expr && State.same_env o n -> (* A pure tactic *)
          Some (id, `ProofOnly (prev, State.proof_part_of_frozen n))
      | Some _, Some s ->
        if !Flags.debug then msg_debug (Pp.str "STM: sending back a fat state");
          Some (id, `Full s)
      | _, Some s -> Some (id, `Full s) in
    let rec aux seen = function
      | [] -> []
      | id :: rest ->
          match get_state seen id with
          | None -> aux seen rest
          | Some stuff -> stuff :: aux (id :: seen) rest in
    aux [initial] query

  let perform = function
    | ReqBuildProof (bp,drop,states) -> perform_buildp bp drop states
    | ReqStates sl -> RespStates (perform_states sl)

  let on_marshal_error s = function
    | States _ ->
      msg_warning Pp.(strbrk("Marshalling error: "^s^". "^
                             "The system state could not be sent to the master process."))
    | BuildProof { t_exn_info; t_stop; t_assign; t_loc; t_drop = drop_pt } ->
      msg_warning Pp.(strbrk("Marshalling error: "^s^". "^
                             "The system state could not be sent to the worker process. "^
                             "Falling back to local, lazy, evaluation."));
      t_assign(`Comp(build_proof_here ~doc:dummy_doc (* XXX should be stored in a closure, it is the same doc that was used to generate the task *) ?loc:t_loc ~drop_pt t_exn_info t_stop));
      feedback (InProgress ~-1)

end (* }}} *)

(* Slave processes (if initialized, otherwise local lazy evaluation) *)
and Slaves : sig

  (* (eventually) remote calls *)
  val build_proof :
    doc:doc ->
    ?loc:Loc.t -> drop_pt:bool ->
    exn_info:(Stateid.t * Stateid.t) -> block_start:Stateid.t -> block_stop:Stateid.t ->
      name:string -> future_proof * AsyncTaskQueue.cancel_switch

  (* blocking function that waits for the task queue to be empty *)
  val wait_all_done : unit -> unit

  (* initialize the whole machinery (optional) *)
  val init : CoqworkmgrApi.priority -> unit

  type 'a tasks = (('a,VCS.vcs) Stateid.request * bool) list
  val dump_snapshot : unit -> Future.UUID.t tasks
  val check_task : string -> int tasks -> int -> bool
  val info_tasks : 'a tasks -> (string * float * int) list
  val finish_task :
    string ->
    Library.seg_univ -> Library.seg_proofs ->
    int tasks -> int -> Library.seg_univ

  val cancel_worker : WorkerPool.worker_id -> unit

  val reset_task_queue : unit -> unit

  val set_perspective : Stateid.t list -> unit

end = struct (* {{{ *)

  module TaskQueue = AsyncTaskQueue.MakeQueue(ProofTask) ()

  let queue = ref None
  let init priority =
    if async_proofs_is_master !cur_opt then
      queue := Some (TaskQueue.create !cur_opt.async_proofs_n_workers priority)
    else
      queue := Some (TaskQueue.create 0 priority)

  let check_task_aux extra name l i =
    let { Stateid.stop; document; loc; name = r_name }, drop = List.nth l i in
    Flags.if_verbose msg_info
      Pp.(str(Printf.sprintf "Checking task %d (%s%s) of %s" i r_name extra name));
    VCS.restore document;
    let start =
      let rec aux cur =
        try aux (VCS.visit cur).next
        with VCS.Expired -> cur in
      aux stop in
    try
      Reach.known_state ~doc:dummy_doc (* XXX should be document *) ~cache:false stop;
      if drop then
        let _proof = PG_compat.return_proof ~allow_partial:true () in
        `OK_ADMITTED
      else begin
      let opaque = Proof_global.Opaque in

      (* The original terminator, a hook, has not been saved in the .vio*)
      let proof, _info =
        PG_compat.close_proof ~opaque ~keep_body_ucst_separate:true (fun x -> x) in

      let info = Lemmas.Info.make () in

      (* We jump at the beginning since the kernel handles side effects by also
       * looking at the ones that happen to be present in the current env *)

      Reach.known_state ~doc:dummy_doc (* XXX should be document *) ~cache:false start;
      (* STATE SPEC:
       * - start: First non-expired state! [This looks very fishy]
       * - end  : start + qed
       * => takes nothing from the itermediate states.
       *)
      (* STATE We use the state resulting from reaching start. *)
      let st = Vernacstate.freeze_interp_state ~marshallable:false in
      ignore(stm_qed_delay_proof ~id:stop ~st ~proof ~info ~loc ~control:[] (Proved (opaque,None)));
      `OK proof
      end
    with e ->
      let (e, info) = CErrors.push e in
      (try match Stateid.get info with
      | None ->
        msg_warning Pp.(
            str"File " ++ str name ++ str ": proof of " ++ str r_name ++
            spc () ++ iprint (e, info))
      | Some (_, cur) ->
          match VCS.visit cur with
          | { step = `Cmd { cast } }
          | { step = `Fork (( cast, _, _, _), _) }
          | { step = `Qed ( { qast = cast }, _) }
          | { step = `Sideff (ReplayCommand cast, _) } ->
              let loc = cast.expr.CAst.loc in
              let start, stop = Option.cata Loc.unloc (0,0) loc in
              msg_warning Pp.(
                str"File " ++ str name ++ str ": proof of " ++ str r_name ++
                str ": chars " ++ int start ++ str "-" ++ int stop ++
                spc () ++ iprint (e, info))
          | _ ->
              msg_warning Pp.(
                str"File " ++ str name ++ str ": proof of " ++ str r_name ++
                spc () ++ iprint (e, info))
    with e ->
      msg_warning Pp.(str"unable to print error message: " ++
                      str (Printexc.to_string e)));
      if drop then `ERROR_ADMITTED else `ERROR

  let finish_task name (cst,_) p l i =
    let { Stateid.uuid = bucket }, drop = List.nth l i in
    let bucket_name =
      if bucket < 0 then (assert drop; ", no bucket")
      else Printf.sprintf ", bucket %d" bucket in
    match check_task_aux bucket_name name l i with
    | `ERROR -> exit 1
    | `ERROR_ADMITTED -> cst, false
    | `OK_ADMITTED -> cst, false
    | `OK { Proof_global.name } ->
        let con = Nametab.locate_constant (Libnames.qualid_of_ident name) in
        let c = Global.lookup_constant con in
        let o = match c.Declarations.const_body with
          | Declarations.OpaqueDef o -> o
          | _ -> assert false in
        (* No need to delay the computation, the future has been forced by
           the call to [check_task_aux] above. *)
        let uc = Opaqueproof.force_constraints Library.indirect_accessor (Global.opaque_tables ()) o in
        let uc = Univ.hcons_universe_context_set uc in
        let (pr, priv, ctx) = Option.get (Global.body_of_constant_body Library.indirect_accessor c) in
        (* We only manipulate monomorphic terms here. *)
        let () = assert (Univ.AUContext.is_empty ctx) in
        let () = match priv with
        | Opaqueproof.PrivateMonomorphic () -> ()
        | Opaqueproof.PrivatePolymorphic (univs, uctx) ->
          let () = assert (Int.equal (Univ.AUContext.size ctx) univs) in
          assert (Univ.ContextSet.is_empty uctx)
        in
        let pr = Constr.hcons pr in
        let dummy = p.(bucket) in
        let () = assert (Option.is_empty dummy) in
        p.(bucket) <- Some (pr, priv);
        Univ.ContextSet.union cst uc, false

  let check_task name l i =
    match check_task_aux "" name l i with
    | `OK _ | `OK_ADMITTED -> true
    | `ERROR | `ERROR_ADMITTED -> false

  let info_tasks l =
    CList.map_i (fun i ({ Stateid.loc; name }, _) ->
      let time1 =
        try float_of_string (Aux_file.get ?loc !hints "proof_build_time")
        with Not_found -> 0.0 in
      let time2 =
        try float_of_string (Aux_file.get ?loc !hints "proof_check_time")
        with Not_found -> 0.0 in
      name, max (time1 +. time2) 0.0001,i) 0 l

  let set_perspective idl =
    ProofTask.set_perspective idl;
    TaskQueue.broadcast (Option.get !queue);
    let open ProofTask in
    let overlap s1 s2 =
      List.exists (fun x -> CList.mem_f Stateid.equal x s2) s1 in
    let overlap_rel s1 s2 =
      match overlap s1 idl, overlap s2 idl with
      | true, true | false, false -> 0
      | true, false -> -1
      | false, true -> 1 in
    TaskQueue.set_order (Option.get !queue) (fun task1 task2 ->
     match task1, task2 with
     | BuildProof { t_states = s1 },
       BuildProof { t_states = s2 } -> overlap_rel s1 s2
     | _ -> 0)

  let build_proof ~doc ?loc ~drop_pt ~exn_info ~block_start ~block_stop ~name:pname =
    let id, valid as t_exn_info = exn_info in
    let cancel_switch = ref false in
    if TaskQueue.n_workers (Option.get !queue) = 0 then
      if VCS.is_vio_doc () then begin
        let f,assign =
         Future.create_delegate ~blocking:true ~name:pname (State.exn_on id ~valid) in
        let t_uuid = Future.uuid f in
        let task = ProofTask.(BuildProof {
          t_exn_info; t_start = block_start; t_stop = block_stop; t_drop = drop_pt;
          t_assign = assign; t_loc = loc; t_uuid; t_name = pname;
          t_states = VCS.nodes_in_slice ~block_start ~block_stop }) in
        TaskQueue.enqueue_task (Option.get !queue) task ~cancel_switch;
        f, cancel_switch
      end else
        ProofTask.build_proof_here ~doc ?loc ~drop_pt t_exn_info block_stop, cancel_switch
    else
      let f, t_assign = Future.create_delegate ~name:pname (State.exn_on id ~valid) in
      let t_uuid = Future.uuid f in
      feedback (InProgress 1);
      let task = ProofTask.(BuildProof {
        t_exn_info; t_start = block_start; t_stop = block_stop; t_assign; t_drop = drop_pt;
        t_loc = loc; t_uuid; t_name = pname;
        t_states = VCS.nodes_in_slice ~block_start ~block_stop }) in
      TaskQueue.enqueue_task (Option.get !queue) task ~cancel_switch;
      f, cancel_switch

  let wait_all_done () = TaskQueue.join (Option.get !queue)

  let cancel_worker n = TaskQueue.cancel_worker (Option.get !queue) n

  (* For external users this name is nicer than request *)
  type 'a tasks = (('a,VCS.vcs) Stateid.request * bool) list
  let dump_snapshot () =
    let tasks = TaskQueue.snapshot (Option.get !queue) in
    let reqs =
      CList.map_filter
        ProofTask.(fun x ->
             match request_of_task Fresh x with
             | Some (ReqBuildProof (r, b, _)) -> Some(r, b)
             | _ -> None)
        tasks in
    stm_prerr_endline (fun () -> Printf.sprintf "dumping %d tasks\n" (List.length reqs));
    reqs

  let reset_task_queue () = TaskQueue.clear (Option.get !queue)

end (* }}} *)

and TacTask : sig

  type output = (Constr.constr * UState.t) option
  type task = {
    t_state    : Stateid.t;
    t_state_fb : Stateid.t;
    t_assign   : output Future.assignment -> unit;
    t_ast      : int * aast;
    t_goal     : Goal.goal;
    t_kill     : unit -> unit;
    t_name     : string }

  include AsyncTaskQueue.Task with type task := task

end = struct (* {{{ *)

  type output = (Constr.constr * UState.t) option

  let forward_feedback msg = Hooks.(call forward_feedback msg)

  type task = {
    t_state    : Stateid.t;
    t_state_fb : Stateid.t;
    t_assign   : output Future.assignment -> unit;
    t_ast      : int * aast;
    t_goal     : Goal.goal;
    t_kill     : unit -> unit;
    t_name     : string }

  type request = {
    r_state    : Stateid.t;
    r_state_fb : Stateid.t;
    r_document : VCS.vcs option;
    r_ast      : int * aast;
    r_goal     : Goal.goal;
    r_name     : string }

  type response =
    | RespBuiltSubProof of (Constr.constr * UState.t)
    | RespError of Pp.t
    | RespNoProgress

  let name = ref "tacticworker"
  let extra_env () = [||]
  type competence = unit
  type worker_status = Fresh | Old of competence

  let task_match _ _ = true

  (* run by the master, on a thread *)
  let request_of_task age { t_state; t_state_fb; t_ast; t_goal; t_name } =
    try Some {
      r_state    = t_state;
      r_state_fb = t_state_fb;
      r_document =
        if age <> Fresh then None
        else Some (VCS.slice ~block_start:t_state ~block_stop:t_state);
      r_ast      = t_ast;
      r_goal     = t_goal;
      r_name     = t_name }
    with VCS.Expired -> None

  let use_response _ { t_assign; t_state; t_state_fb; t_kill } resp =
    match resp with
    | RespBuiltSubProof o -> t_assign (`Val (Some o)); `Stay ((),[])
    | RespNoProgress ->
        t_assign (`Val None);
        t_kill ();
        `Stay ((),[])
    | RespError msg ->
        let e = (RemoteException msg, Exninfo.null) in
        t_assign (`Exn e);
        t_kill ();
        `Stay ((),[])

  let on_marshal_error err { t_name } =
    stm_pr_err ("Fatal marshal error: " ^ t_name );
    flush_all (); exit 1

  let on_task_cancellation_or_expiration_or_slave_death = function
    | Some { t_kill } -> t_kill ()
    | _ -> ()

  let command_focus = Proof.new_focus_kind ()
  let focus_cond = Proof.no_cond command_focus

  let perform { r_state = id; r_state_fb; r_document = vcs; r_ast; r_goal } =
    Option.iter VCS.restore vcs;
    try
      Reach.known_state ~doc:dummy_doc (* XXX should be vcs *) ~cache:false id;
      State.purify (fun () ->
       let Proof.{sigma=sigma0} = Proof.data (PG_compat.give_me_the_proof ()) in
       let g = Evd.find sigma0 r_goal in
       let is_ground c = Evarutil.is_ground_term sigma0 c in
       if not (
         is_ground Evd.(evar_concl g) &&
         List.for_all (Context.Named.Declaration.for_all is_ground)
                      Evd.(evar_context g))
       then
         CErrors.user_err ~hdr:"STM" Pp.(strbrk("the par: goal selector supports ground "^
           "goals only"))
       else begin
        let (i, ast) = r_ast in
        PG_compat.map_proof (fun p -> Proof.focus focus_cond () i p);
        (* STATE SPEC:
         * - start : id
         * - return: id
         * => captures state id in a future closure, which will
           discard execution state but for the proof + univs.
        *)
        let st = Vernacstate.freeze_interp_state ~marshallable:false in
        ignore(stm_vernac_interp r_state_fb st ast);
        let Proof.{sigma} = Proof.data (PG_compat.give_me_the_proof ()) in
        match Evd.(evar_body (find sigma r_goal)) with
        | Evd.Evar_empty -> RespNoProgress
        | Evd.Evar_defined t ->
            let t = Evarutil.nf_evar sigma t in
            if Evarutil.is_ground_term sigma t then
              let t = EConstr.Unsafe.to_constr t in
              RespBuiltSubProof (t, Evd.evar_universe_context sigma)
            else CErrors.user_err ~hdr:"STM" Pp.(str"The solution is not ground")
       end) ()
    with e when CErrors.noncritical e -> RespError (CErrors.print e)

  let name_of_task { t_name } = t_name
  let name_of_request { r_name } = r_name

end (* }}} *)

and Partac : sig

  val vernac_interp :
    solve:bool -> abstract:bool -> cancel_switch:AsyncTaskQueue.cancel_switch ->
    int -> CoqworkmgrApi.priority -> Stateid.t -> Stateid.t -> aast -> unit

end = struct (* {{{ *)

  module TaskQueue = AsyncTaskQueue.MakeQueue(TacTask) ()

  let stm_fail ~st fail f =
    if fail then
      Vernacinterp.with_fail ~st f
    else
      f ()

  let vernac_interp ~solve ~abstract ~cancel_switch nworkers priority safe_id id
    { indentation; verbose; expr = e; strlen } : unit
  =
    let cl, time, batch, fail =
      let rec find ~time ~batch ~fail cl = match cl with
        | ControlTime batch :: cl -> find ~time:true ~batch ~fail cl
        | ControlRedirect _ :: cl -> find ~time ~batch ~fail cl
        | ControlFail :: cl -> find ~time ~batch ~fail:true cl
        | cl -> cl, time, batch, fail in
      find ~time:false ~batch:false ~fail:false e.CAst.v.control in
    let e = CAst.map (fun cmd -> { cmd with control = cl }) e in
    let st = Vernacstate.freeze_interp_state ~marshallable:false in
    stm_fail ~st fail (fun () ->
    (if time then System.with_time ~batch ~header:(Pp.mt ()) else (fun x -> x)) (fun () ->
    TaskQueue.with_n_workers nworkers priority (fun queue ->
    PG_compat.map_proof (fun p ->
      let Proof.{goals} = Proof.data p in
      let open TacTask in
      let res = CList.map_i (fun i g ->
        let f, assign =
          Future.create_delegate
            ~name:(Printf.sprintf "subgoal %d" i)
            (State.exn_on id ~valid:safe_id) in
        let t_ast = (i, { indentation; verbose; expr = e; strlen }) in
        let t_name = Goal.uid g in
        TaskQueue.enqueue_task queue
          { t_state = safe_id; t_state_fb = id;
            t_assign = assign; t_ast; t_goal = g; t_name;
            t_kill = (fun () -> if solve then TaskQueue.cancel_all queue) }
           ~cancel_switch;
        g,f)
        1 goals in
      TaskQueue.join queue;
      let assign_tac : unit Proofview.tactic =
        Proofview.(Goal.enter begin fun g ->
        let gid = Goal.goal g in
        let f =
          try List.assoc gid res
          with Not_found -> CErrors.anomaly(str"Partac: wrong focus.") in
        if not (Future.is_over f) then
          (* One has failed and cancelled the others, but not this one *)
          if solve then Tacticals.New.tclZEROMSG
            (str"Interrupted by the failure of another goal")
          else tclUNIT ()
        else
          let open Notations in
          match Future.join f with
          | Some (pt, uc) ->
            let sigma, env = PG_compat.get_current_context () in
            stm_pperr_endline (fun () -> hov 0 (
              str"g=" ++ int (Evar.repr gid) ++ spc () ++
              str"t=" ++ (Printer.pr_constr_env env sigma pt) ++ spc () ++
              str"uc=" ++ Termops.pr_evar_universe_context uc));
            (if abstract then Abstract.tclABSTRACT None else (fun x -> x))
              (V82.tactic (Refiner.tclPUSHEVARUNIVCONTEXT uc) <*>
              Tactics.exact_no_check (EConstr.of_constr pt))
          | None ->
            if solve then Tacticals.New.tclSOLVE [] else tclUNIT ()
        end)
      in
      let p,_,() = Proof.run_tactic (Global.env()) assign_tac p in
      p))) ())

end (* }}} *)

and QueryTask : sig

  type task = { t_where : Stateid.t; t_for : Stateid.t ; t_what : aast }
  include AsyncTaskQueue.Task with type task := task

end = struct (* {{{ *)

  type task =
    { t_where : Stateid.t; t_for : Stateid.t ; t_what : aast }

  type request =
    { r_where : Stateid.t ; r_for : Stateid.t ; r_what : aast; r_doc : VCS.vcs }
  type response = unit

  let name = ref "queryworker"
  let extra_env _ = [||]
  type competence = unit
  type worker_status = Fresh | Old of competence

  let task_match _ _ = true

  let request_of_task _ { t_where; t_what; t_for } =
    try Some {
      r_where = t_where;
      r_for   = t_for;
      r_doc   = VCS.slice ~block_start:t_where ~block_stop:t_where;
      r_what  = t_what }
    with VCS.Expired -> None

  let use_response _ _ _ = `End

  let on_marshal_error _ _ =
    stm_pr_err ("Fatal marshal error in query");
    flush_all (); exit 1

  let on_task_cancellation_or_expiration_or_slave_death _ = ()

  let forward_feedback msg = Hooks.(call forward_feedback msg)

  let perform { r_where; r_doc; r_what; r_for } =
    VCS.restore r_doc;
    VCS.print ();
    Reach.known_state ~doc:dummy_doc (* XXX should be r_doc *) ~cache:false r_where;
    (* STATE *)
    let st = Vernacstate.freeze_interp_state ~marshallable:false in
    try
      (* STATE SPEC:
       * - start: r_where
       * - end  : after execution of r_what
       *)
      ignore(stm_vernac_interp r_for st { r_what with verbose = true });
      feedback ~id:r_for Processed
    with e when CErrors.noncritical e ->
      let e = CErrors.push e in
      let msg = iprint e     in
      feedback ~id:r_for (Message (Error, None, msg))

  let name_of_task { t_what } = string_of_ppcmds (pr_ast t_what)
  let name_of_request { r_what } = string_of_ppcmds (pr_ast r_what)

end (* }}} *)

and Query : sig

  val init : CoqworkmgrApi.priority -> unit
  val vernac_interp : cancel_switch:AsyncTaskQueue.cancel_switch -> Stateid.t ->  Stateid.t -> aast -> unit

end = struct (* {{{ *)

  module TaskQueue = AsyncTaskQueue.MakeQueue(QueryTask) ()

  let queue = ref None

  let vernac_interp ~cancel_switch prev id q =
    assert(TaskQueue.n_workers (Option.get !queue) > 0);
    TaskQueue.enqueue_task (Option.get !queue)
      QueryTask.({ t_where = prev; t_for = id; t_what = q }) ~cancel_switch

  let init priority = queue := Some (TaskQueue.create 0 priority)

end (* }}} *)

(* Runs all transactions needed to reach a state *)
and Reach : sig

  val known_state :
    doc:doc -> ?redefine_qed:bool -> cache:bool ->
      Stateid.t -> unit

end = struct (* {{{ *)

let async_policy () =
  if Attributes.is_universe_polymorphism () then false (* FIXME this makes no sense, it is the default value of the attribute *)
  else if VCS.is_interactive () then
    (async_proofs_is_master !cur_opt || !cur_opt.async_proofs_mode = APonLazy)
  else
    (VCS.is_vio_doc () || !cur_opt.async_proofs_mode <> APoff)

let delegate name =
     get_hint_bp_time name >= !cur_opt.async_proofs_delegation_threshold
  || VCS.is_vio_doc ()

let collect_proof keep cur hd brkind id =
 stm_prerr_endline (fun () -> "Collecting proof ending at "^Stateid.to_string id);
 let no_name = "" in
 let name = function
   | [] -> no_name
   | id :: _ -> Names.Id.to_string id in
 let loc = (snd cur).expr.CAst.loc in
 let is_defined_expr = function
   | VernacEndProof (Proved (Proof_global.Transparent,_)) -> true
   | _ -> false in
 let is_defined = function
   | _, { expr = e } -> is_defined_expr e.CAst.v.expr
                        && (not (Vernacprop.has_Fail e)) in
 let proof_using_ast = function
   | VernacProof(_,Some _) -> true
   | _ -> false
 in
 let proof_using_ast = function
   | Some (_, v) when proof_using_ast v.expr.CAst.v.expr
                      && (not (Vernacprop.has_Fail v.expr)) -> Some v
   | _ -> None in
 let has_proof_using x = proof_using_ast x <> None in
 let proof_no_using = function
   | VernacProof(t,None) -> t
   | _ -> assert false
 in
 let proof_no_using = function
   | Some (_, v) -> proof_no_using v.expr.CAst.v.expr, v
   | _ -> assert false in
 let has_proof_no_using = function
   | VernacProof(_,None) -> true
   | _ -> false
 in
 let has_proof_no_using = function
   | Some (_, v) -> has_proof_no_using v.expr.CAst.v.expr
                    && (not (Vernacprop.has_Fail v.expr))
   | _ -> false in
 let too_complex_to_delegate = function
   | VernacDeclareModule _
   | VernacDefineModule _
   | VernacDeclareModuleType _
   | VernacInclude _
   | VernacRequire _
   | VernacImport _ -> true
   | ast -> may_pierce_opaque ast in
 let parent = function Some (p, _) -> p | None -> assert false in
 let is_empty = function `Async(_,[],_,_) | `MaybeASync(_,[],_,_) -> true | _ -> false in
 let rec collect last accn id =
    let view = VCS.visit id in
    match view.step with
    | (`Sideff (ReplayCommand x,_) | `Cmd { cast = x })
      when too_complex_to_delegate x.expr.CAst.v.expr ->
       `Sync(no_name,`Print)
    | `Cmd { cast = x } -> collect (Some (id,x)) (id::accn) view.next
    | `Sideff (ReplayCommand x,_) -> collect (Some (id,x)) (id::accn) view.next
    (* An Alias could jump everywhere... we hope we can ignore it*)
    | `Alias _ -> `Sync (no_name,`Alias)
    | `Fork((_,_,_,_::_::_), _) ->
        `Sync (no_name,`MutualProofs)
    | `Fork((_,_,Doesn'tGuaranteeOpacity,_), _) ->
        `Sync (no_name,`Doesn'tGuaranteeOpacity)
    | `Fork((_,hd',GuaranteesOpacity,ids), _) when has_proof_using last ->
        assert (VCS.Branch.equal hd hd' || VCS.Branch.equal hd VCS.edit_branch);
        let name = name ids in
        `ASync (parent last,accn,name,delegate name)
    | `Fork((_, hd', GuaranteesOpacity, ids), _) when
       has_proof_no_using last && not (State.is_cached_and_valid (parent last)) &&
       VCS.is_vio_doc () ->
        assert (VCS.Branch.equal hd hd'||VCS.Branch.equal hd VCS.edit_branch);
        (try
          let name, hint = name ids, get_hint_ctx loc  in
          let t, v = proof_no_using last in
          v.expr <- CAst.map (fun _ -> { control = []; attrs = []; expr = VernacProof(t, Some hint)}) v.expr;
          `ASync (parent last,accn,name,delegate name)
        with Not_found ->
          let name = name ids in
          `MaybeASync (parent last, accn, name, delegate name))
    | `Fork((_, hd', GuaranteesOpacity, ids), _) ->
        assert (VCS.Branch.equal hd hd' || VCS.Branch.equal hd VCS.edit_branch);
        let name = name ids in
        `MaybeASync (parent last, accn, name, delegate name)
    | `Sideff (CherryPickEnv,_) ->
        `Sync (no_name,`NestedProof)
    | _ -> `Sync (no_name,`Unknown) in
 let make_sync why = function
   | `Sync(name,_) -> `Sync (name,why)
   | `MaybeASync(_,_,name,_) -> `Sync (name,why)
   | `ASync(_,_,name,_) -> `Sync (name,why) in

 let check_policy rc = if async_policy () then rc else make_sync `Policy rc in
 let is_vernac_exact = function
   | VernacExactProof _ -> true
   | _ -> false
 in
 match cur, (VCS.visit id).step, brkind with
 | (parent, x), `Fork _, _ when is_vernac_exact x.expr.CAst.v.expr
                                && (not (Vernacprop.has_Fail x.expr)) ->
     `Sync (no_name,`Immediate)
 | _, _, { VCS.kind = `Edit _ }  -> check_policy (collect (Some cur) [] id)
 | _ ->
     if is_defined cur then `Sync (no_name,`Transparent)
     else if keep == VtDrop then `Sync (no_name,`Aborted)
     else
       let rc = collect (Some cur) [] id in
       if is_empty rc then make_sync `AlreadyEvaluated rc
       else if (is_vtkeep keep) && (not(State.is_cached_and_valid id))
       then check_policy rc
       else make_sync `AlreadyEvaluated rc

let string_of_reason = function
  | `Transparent -> "non opaque"
  | `AlreadyEvaluated -> "proof already evaluated"
  | `Policy -> "policy"
  | `NestedProof -> "contains nested proof"
  | `Immediate -> "proof term given explicitly"
  | `Aborted -> "aborted proof"
  | `Doesn'tGuaranteeOpacity -> "not a simple opaque lemma"
  | `MutualProofs -> "block of mutually recursive proofs"
  | `Alias -> "contains Undo-like command"
  | `Print -> "contains Print-like command"
  | `NoPU_NoHint_NoES -> "no 'Proof using..', no .aux file, inside a section"
  | `Unknown -> "unsupported case"

let log_string s = stm_prerr_debug (fun () -> "STM: " ^ s)
let log_processing_async id name = log_string Printf.(sprintf
  "%s: proof %s: asynch" (Stateid.to_string id) name
)
let log_processing_sync id name reason = log_string Printf.(sprintf
  "%s: proof %s: synch (cause: %s)"
  (Stateid.to_string id) name (string_of_reason reason)
)

let wall_clock_last_fork = ref 0.0

let known_state ~doc ?(redefine_qed=false) ~cache id =

  let error_absorbing_tactic id blockname exn =
    (* We keep the static/dynamic part of block detection separate, since
       the static part could be performed earlier.  As of today there is
       no advantage in doing so since no UI can exploit such piece of info *)
    detect_proof_block id blockname;

    let boxes = VCS.box_of id in
    let valid_boxes = CList.map_filter (function
      | ProofBlock ({ block_stop } as decl, name) when Stateid.equal block_stop id ->
          Some (decl, name)
      | _ -> None) boxes in
    assert(List.length valid_boxes < 2);
    if valid_boxes = [] then Exninfo.iraise exn
    else
      let decl, name = List.hd valid_boxes in
      try
        let _, dynamic_check = List.assoc name !proof_block_delimiters in
        match dynamic_check dummy_doc decl with
        | `Leaks -> Exninfo.iraise exn
        | `ValidBlock { base_state; goals_to_admit; recovery_command } -> begin
           let tac =
             Proofview.Goal.enter begin fun gl ->
               if CList.mem_f Evar.equal
                 (Proofview.Goal.goal gl) goals_to_admit then
             Proofview.give_up else Proofview.tclUNIT ()
              end in
           match (VCS.get_info base_state).state with
           | FullState { Vernacstate.lemmas } ->
               Option.iter PG_compat.unfreeze lemmas;
               PG_compat.with_current_proof (fun _ p ->
                 feedback ~id:id Feedback.AddedAxiom;
                 fst (Pfedit.solve Goal_select.SelectAll None tac p), ());
               (* STATE SPEC:
                * - start: Modifies the input state adding a proof.
                * - end  : maybe after recovery command.
               *)
               (* STATE: We use an updated state with proof *)
               let st = Vernacstate.freeze_interp_state ~marshallable:false in
               Option.iter (fun expr -> ignore(stm_vernac_interp id st {
                  verbose = true; expr; indentation = 0;
                  strlen = 0 } ))
               recovery_command
           | _ -> assert false
        end
      with Not_found ->
          CErrors.user_err ~hdr:"STM"
            (str "Unknown proof block delimiter " ++ str name)
  in

  (* Absorb tactic errors from f () *)
  let resilient_tactic id blockname f =
    if !cur_opt.async_proofs_tac_error_resilience = `None ||
       (async_proofs_is_master !cur_opt &&
        !cur_opt.async_proofs_mode = APoff)
    then f ()
    else
      try f ()
      with e when CErrors.noncritical e ->
        let ie = CErrors.push e in
        error_absorbing_tactic id blockname ie in
  (* Absorb errors from f x *)
  let resilient_command f x =
    if not !cur_opt.async_proofs_cmd_error_resilience ||
       (async_proofs_is_master !cur_opt &&
        !cur_opt.async_proofs_mode = APoff)
    then f x
    else
      try f x
      with e when CErrors.noncritical e -> () in

  (* extract proof_ending in qed case, note that `Abort` and `Proof
     term.` could also fail in this case, however that'd be a bug I do
     believe as proof injection shouldn't happen here. *)
  let extract_pe (x : aast) =
    match x.expr.CAst.v.expr with
    | VernacEndProof pe -> x.expr.CAst.v.control, pe
    | _ -> CErrors.anomaly Pp.(str "Non-qed command classified incorrectly") in

  (* ugly functions to process nested lemmas, i.e. hard to reproduce
   * side effects *)
  let cherry_pick_non_pstate () =
    let st = Summary.freeze_summaries ~marshallable:false in
    let st = Summary.remove_from_summary st Util.(pi1 summary_pstate) in
    let st = Summary.remove_from_summary st Util.(pi2 summary_pstate) in
    let st = Summary.remove_from_summary st Util.(pi3 summary_pstate) in
    st, Lib.freeze ~marshallable:false in

  let inject_non_pstate (s,l) =
    Summary.unfreeze_summaries ~partial:true s; Lib.unfreeze l; update_global_env ()
  in
  let rec pure_cherry_pick_non_pstate safe_id id =
    State.purify (fun id ->
        stm_prerr_endline (fun () -> "cherry-pick non pstate " ^ Stateid.to_string id);
        reach ~safe_id id;
        cherry_pick_non_pstate ())
      id

  (* traverses the dag backward from nodes being already calculated *)
  and reach ?safe_id ?(redefine_qed=false) ?(cache=cache) id =
    stm_prerr_endline (fun () -> "reaching: " ^ Stateid.to_string id);
    if not redefine_qed && State.is_cached ~cache id then begin
      Hooks.(call state_computed ~doc id ~in_cache:true);
      stm_prerr_endline (fun () -> "reached (cache)");
      State.install_cached id
    end else
    let step, cache_step, feedback_processed =
      let view = VCS.visit id in
      match view.step with
      | `Alias (id,_) -> (fun () ->
            reach view.next; reach id
          ), cache, true
      | `Cmd { cast = x; cqueue = `SkipQueue } -> (fun () ->
            reach view.next), cache, true
      | `Cmd { cast = x; cqueue = `TacQueue (solve,abstract,cancel_switch); cblock } ->
          (fun () ->
            resilient_tactic id cblock (fun () ->
              reach ~cache:true view.next;
              Partac.vernac_interp ~solve ~abstract ~cancel_switch
                !cur_opt.async_proofs_n_tacworkers
                !cur_opt.async_proofs_worker_priority view.next id x)
          ), cache, true
      | `Cmd { cast = x; cqueue = `QueryQueue cancel_switch }
        when async_proofs_is_master !cur_opt -> (fun () ->
            reach view.next;
            Query.vernac_interp ~cancel_switch view.next id x
          ), cache, false
      | `Cmd { cast = x; ceff = eff; ctac = true; cblock } -> (fun () ->
            resilient_tactic id cblock (fun () ->
              reach view.next;
              (* State resulting from reach *)
              let st = Vernacstate.freeze_interp_state ~marshallable:false in
              ignore(stm_vernac_interp id st x)
            )
          ), eff || cache, true
      | `Cmd { cast = x; ceff = eff } -> (fun () ->
          (match !cur_opt.async_proofs_mode with
           | APon | APonLazy ->
             resilient_command reach view.next
           | APoff -> reach view.next);
          let st = Vernacstate.freeze_interp_state ~marshallable:false in
          ignore(stm_vernac_interp id st x)
        ), eff || cache, true
      | `Fork ((x,_,_,_), None) -> (fun () ->
            resilient_command reach view.next;
            let st = Vernacstate.freeze_interp_state ~marshallable:false in
            ignore(stm_vernac_interp id st x);
            wall_clock_last_fork := Unix.gettimeofday ()
          ), true, true
      | `Fork ((x,_,_,_), Some prev) -> (fun () -> (* nested proof *)
            reach ~cache:true prev;
            reach view.next;

            (try
               let st = Vernacstate.freeze_interp_state ~marshallable:false in
               ignore(stm_vernac_interp id st x);
            with e when CErrors.noncritical e ->
              let (e, info) = CErrors.push e in
              let info = Stateid.add info ~valid:prev id in
              Exninfo.iraise (e, info));
            wall_clock_last_fork := Unix.gettimeofday ()
          ), true, true
      | `Qed ({ qast = x; keep; brinfo; brname } as qed, eop) ->
          let rec aux = function
            | `ASync (block_start, nodes, name, delegate) -> (fun () ->
                let keep' = get_vtkeep keep in
                let drop_pt = keep' == VtKeepAxiom in
                let block_stop, exn_info, loc = eop, (id, eop), x.expr.CAst.loc in
                log_processing_async id name;
                VCS.create_proof_task_box nodes ~qed:id ~block_start;
                begin match brinfo, qed.fproof with
                | { VCS.kind = `Edit _ }, None -> assert false
                | { VCS.kind = `Edit (_,_, okeep, _) }, Some (ofp, cancel) ->
                    assert(redefine_qed = true);
                    if okeep <> keep then
                      msg_warning(strbrk("The command closing the proof changed. "
                        ^"The kernel cannot take this into account and will "
                        ^(if not drop_pt then "not check " else "reject ")
                        ^"the "^(if not drop_pt then "new" else "incomplete")
                        ^" proof. Reprocess the command declaring "
                        ^"the proof's statement to avoid that."));
                    let fp, cancel =
                      Slaves.build_proof ~doc
                        ?loc ~drop_pt ~exn_info ~block_start ~block_stop ~name in
                    Future.replace ofp fp;
                    qed.fproof <- Some (fp, cancel);
                    (* We don't generate a new state, but we still need
                     * to install the right one *)
                    State.install_cached id
                | { VCS.kind = `Proof _ }, Some _ -> assert false
                | { VCS.kind = `Proof _ }, None ->
                    reach ~cache:true block_start;
                    let fp, cancel =
                      if delegate then
                        Slaves.build_proof ~doc
                          ?loc ~drop_pt ~exn_info ~block_start ~block_stop ~name
                      else
                        ProofTask.build_proof_here ~doc ?loc
                          ~drop_pt exn_info block_stop, ref false
                    in
                    qed.fproof <- Some (fp, cancel);
                    let opaque = match keep' with
                      | VtKeepAxiom | VtKeepOpaque ->
                        Proof_global.Opaque (* Admitted -> Opaque should be OK. *)
                      | VtKeepDefined -> Proof_global.Transparent
                    in
                    let proof, info =
                      PG_compat.close_future_proof ~opaque ~feedback_id:id fp in
                    if not delegate then ignore(Future.compute fp);
                    reach view.next;
                    let st = Vernacstate.freeze_interp_state ~marshallable:false in
                    let control, pe = extract_pe x in
                    ignore(stm_qed_delay_proof ~id ~st ~proof ~info ~loc ~control pe);
                    feedback ~id:id Incomplete
                | { VCS.kind = `Master }, _ -> assert false
                end;
                PG_compat.discard_all ()
              ), not redefine_qed, true
          | `Sync (name, `Immediate) -> (fun () ->
                reach eop;
                let st = Vernacstate.freeze_interp_state ~marshallable:false in
                ignore(stm_vernac_interp id st x);
                PG_compat.discard_all ()
              ), true, true
          | `Sync (name, reason) -> (fun () ->
                log_processing_sync id name reason;
                reach eop;
                let wall_clock = Unix.gettimeofday () in
                let loc = x.expr.CAst.loc in
                record_pb_time name ?loc (wall_clock -. !wall_clock_last_fork);
                let proof =
                  match keep with
                  | VtDrop -> None
                  | VtKeep VtKeepAxiom ->
                      let ctx = UState.empty in
                      let fp = Future.from_val ([],ctx) in
                      qed.fproof <- Some (fp, ref false); None
                  | VtKeep opaque ->
                    let opaque = let open Proof_global in  match opaque with
                      | VtKeepOpaque -> Opaque | VtKeepDefined -> Transparent
                      | VtKeepAxiom -> assert false
                    in
                      Some(PG_compat.close_proof ~opaque
                                ~keep_body_ucst_separate:false
                                (State.exn_on id ~valid:eop)) in
                if keep <> VtKeep VtKeepAxiom then
                  reach view.next;
                let wall_clock2 = Unix.gettimeofday () in
                let st = Vernacstate.freeze_interp_state ~marshallable:false in
                let _st = match proof with
                  | None ->  stm_vernac_interp id st x
                  | Some (proof, info) ->
                    let control, pe = extract_pe x in
                    stm_qed_delay_proof ~id ~st ~proof ~info ~loc ~control pe
                in
                let wall_clock3 = Unix.gettimeofday () in
                Aux_file.record_in_aux_at ?loc:x.expr.CAst.loc "proof_check_time"
                  (Printf.sprintf "%.3f" (wall_clock3 -. wall_clock2));
                PG_compat.discard_all ()
              ), true, true
          | `MaybeASync (start, nodes, name, delegate) -> (fun () ->
                reach ~cache:true start;
                (* no sections *)
                if CList.is_empty (Environ.named_context (Global.env ()))
                then Util.pi1 (aux (`ASync (start, nodes, name, delegate))) ()
                else Util.pi1 (aux (`Sync (name, `NoPU_NoHint_NoES))) ()
              ), not redefine_qed, true
          in
          aux (collect_proof keep (view.next, x) brname brinfo eop)
      | `Sideff (ReplayCommand x,_) -> (fun () ->
            reach view.next;
            let st = Vernacstate.freeze_interp_state ~marshallable:false in
            ignore(stm_vernac_interp id st x)
          ), cache, true
      | `Sideff (CherryPickEnv, origin) -> (fun () ->
            reach view.next;
            inject_non_pstate (pure_cherry_pick_non_pstate view.next origin);
          ), cache, true
    in
    let cache_step =
      !cur_opt.async_proofs_cache = Some Force || cache_step
    in
    State.define ~doc ?safe_id
      ~cache:cache_step ~redefine:redefine_qed ~feedback_processed step id;
    stm_prerr_endline (fun () -> "reached: "^ Stateid.to_string id) in
  reach ~redefine_qed id

end (* }}} *)
[@@@ocaml.warning "+60"]

(********************************* STM API ************************************)
(******************************************************************************)

(* Main initialization routine *)
type stm_init_options = {
  (* The STM will set some internal flags differently depending on the
     specified [doc_type]. This distinction should disappear at some
     some point. *)
  doc_type     : stm_doc_type;

  (* Initial load path in scope for the document. Usually extracted
     from -R options / _CoqProject *)
  iload_path   : Loadpath.coq_path list;

  (* Require [require_libs] before the initial state is
     ready. Parameters follow [Library], that is to say,
     [lib,prefix,import_export] means require library [lib] from
     optional [prefix] and [import_export] if [Some false/Some true]
     is used.  *)
  require_libs : (string * string option * bool option) list;

  (* STM options that apply to the current document. *)
  stm_options  : AsyncOpts.stm_opt;
}
(* fb_handler   : Feedback.feedback -> unit; *)

(*
let doc_type_module_name (std : stm_doc_type) =
  match std with
  | VoDoc mn | VioDoc mn | Vio2Vo mn -> mn
  | Interactive mn -> Names.DirPath.to_string mn
*)

let init_core () =
  if !cur_opt.async_proofs_mode = APon then Control.enable_thread_delay := true;
  State.register_root_state ()

let dirpath_of_file f =
  let ldir0 =
    try
      let lp = Loadpath.find_load_path (Filename.dirname f) in
      Loadpath.logical lp
    with Not_found -> Libnames.default_root_prefix
  in
  let f = try Filename.chop_extension (Filename.basename f) with Invalid_argument _ -> f in
  let id = Id.of_string f in
  let ldir = Libnames.add_dirpath_suffix ldir0 id in
  ldir

let new_doc { doc_type ; iload_path; require_libs; stm_options } =

  let require_file (dir, from, exp) =
    let mp = Libnames.qualid_of_string dir in
    let mfrom = Option.map Libnames.qualid_of_string from in
    Flags.silently (Vernacentries.vernac_require mfrom exp) [mp] in

  (* Set the options from the new documents *)
  AsyncOpts.cur_opt := stm_options;

  (* We must reset the whole state before creating a document! *)
  State.restore_root_state ();

  let doc = VCS.init doc_type Stateid.initial (Vernacstate.Parser.init ()) in

  (* Set load path; important, this has to happen before we declare
     the library below as [Declaremods/Library] will infer the module
     name by looking at the load path! *)
  List.iter Loadpath.add_coq_path iload_path;

  Safe_typing.allow_delayed_constants := !cur_opt.async_proofs_mode <> APoff;

  begin match doc_type with
    | Interactive ln ->
      let dp = match ln with
        | TopLogical dp -> dp
        | TopPhysical f -> dirpath_of_file f
      in
      Declaremods.start_library dp

    | VoDoc f ->
      let ldir = dirpath_of_file f in
      let () = Flags.verbosely Declaremods.start_library ldir in
      VCS.set_ldir ldir;
      set_compilation_hints f

    | VioDoc f ->
      let ldir = dirpath_of_file f in
      let () = Flags.verbosely Declaremods.start_library ldir in
      VCS.set_ldir ldir;
      set_compilation_hints f
  end;

  (* Import initial libraries. *)
  List.iter require_file require_libs;

  (* We record the state at this point! *)
  State.define ~doc ~cache:true ~redefine:true (fun () -> ()) Stateid.initial;
  Backtrack.record ();
  Slaves.init stm_options.async_proofs_worker_priority;
  if async_proofs_is_master !cur_opt then begin
    stm_prerr_endline (fun () -> "Initializing workers");
    Query.init stm_options.async_proofs_worker_priority;
    let opts = match !cur_opt.async_proofs_private_flags with
      | None -> []
      | Some s -> Str.split_delim (Str.regexp ",") s in
    begin try
      let env_opt = Str.regexp "^extra-env=" in
      let env = List.find (fun s -> Str.string_match env_opt s 0) opts in
      async_proofs_workers_extra_env := Array.of_list
        (Str.split_delim (Str.regexp ";") (Str.replace_first env_opt "" env))
    with Not_found -> () end;
  end;
  doc, VCS.cur_tip ()

let observe ~doc id =
  Hooks.(call sentence_exec id);
  let vcs = VCS.backup () in
  try
    Reach.known_state ~doc ~cache:(VCS.is_interactive ()) id;
    VCS.print ();
    doc
  with e ->
    let e = CErrors.push e in
    VCS.print ();
    VCS.restore vcs;
    Exninfo.iraise e

let finish ~doc =
  let head = VCS.current_branch () in
  let doc = observe ~doc (VCS.get_branch_pos head) in
  VCS.print (); doc

let wait ~doc =
  let doc = observe ~doc (VCS.get_branch_pos VCS.Branch.master) in
  Slaves.wait_all_done ();
  VCS.print ();
  doc

let rec join_admitted_proofs id =
  if Stateid.equal id Stateid.initial then () else
  let view = VCS.visit id in
  match view.step with
  | `Qed ({ keep = VtKeep VtKeepAxiom; fproof = Some (fp,_) },_) ->
       ignore(Future.force fp);
       join_admitted_proofs view.next
  | _ -> join_admitted_proofs view.next

(* Error resiliency may have tolerated some broken commands *)
let rec check_no_err_states ~doc visited id =
  let open Stateid in
  if Set.mem id visited then visited else
  match state_of_id ~doc id with
  | `Error e -> raise e
  | _ ->
     let view = VCS.visit id in
     match view.step with
     | `Qed(_,id) ->
         let visited = check_no_err_states ~doc (Set.add id visited) id in
         check_no_err_states ~doc visited view.next
     | _ -> check_no_err_states ~doc (Set.add id visited) view.next

let join ~doc =
  let doc = wait ~doc in
  stm_prerr_endline (fun () -> "Joining the environment");
  Global.join_safe_environment ();
  stm_prerr_endline (fun () -> "Joining Admitted proofs");
  join_admitted_proofs (VCS.get_branch_pos VCS.Branch.master);
  stm_prerr_endline (fun () -> "Checking no error states");
  ignore(check_no_err_states ~doc (Stateid.Set.singleton Stateid.initial)
    (VCS.get_branch_pos VCS.Branch.master));
  VCS.print ();
  doc

let dump_snapshot () = Slaves.dump_snapshot (), RemoteCounter.snapshot ()

type tasks = int Slaves.tasks * RemoteCounter.remote_counters_status
let check_task name (tasks,rcbackup) i =
  RemoteCounter.restore rcbackup;
  let vcs = VCS.backup () in
  try
    let rc = State.purify (Slaves.check_task name tasks) i in
    VCS.restore vcs;
    rc
  with e when CErrors.noncritical e -> VCS.restore vcs; false
let info_tasks (tasks,_) = Slaves.info_tasks tasks

let finish_tasks name u p (t,rcbackup as tasks) =
  RemoteCounter.restore rcbackup;
  let finish_task u (_,_,i) =
    let vcs = VCS.backup () in
    let u = State.purify (Slaves.finish_task name u p t) i in
    VCS.restore vcs;
    u in
  try
    let a, _ = List.fold_left finish_task u (info_tasks tasks) in
    (a,true), p
  with e ->
    let e = CErrors.push e in
    msg_warning (str"File " ++ str name ++ str ":" ++ spc () ++ iprint e);
    exit 1

let merge_proof_branch ~valid ?id qast keep brname =
  let brinfo = VCS.get_branch brname in
  let qed fproof = { qast; keep; brname; brinfo; fproof } in
  match brinfo with
  | { VCS.kind = `Proof _ } ->
      VCS.checkout VCS.Branch.master;
      let id = VCS.new_node ?id None () in
      let parsing = Option.get @@ VCS.get_parsing_state (VCS.cur_tip ()) in
      VCS.merge id ~ours:(Qed (qed None)) brname;
      VCS.set_parsing_state id parsing;
      VCS.delete_branch brname;
      VCS.propagate_qed ();
      `Ok
  | { VCS.kind = `Edit (qed_id, master_id, _,_) } ->
      let ofp =
        match VCS.visit qed_id with
        | { step = `Qed ({ fproof }, _) } -> fproof
        | _ -> assert false in
      VCS.rewrite_merge qed_id ~ours:(Qed (qed ofp)) ~at:master_id brname;
      VCS.delete_branch brname;
      VCS.gc ();
      let _st : unit = Reach.known_state ~doc:dummy_doc (* XXX should be taken in input *) ~redefine_qed:true ~cache:false qed_id in
      VCS.checkout VCS.Branch.master;
      `Unfocus qed_id
  | { VCS.kind = `Master } ->
       Exninfo.iraise (State.exn_on ~valid Stateid.dummy (PG_compat.NoCurrentProof, Exninfo.null))

(* When tty is true, this code also does some of the job of the user interface:
   jump back to a state that is valid *)
let handle_failure (e, info) vcs =
  VCS.restore vcs;
  VCS.print ();
  Exninfo.iraise (e, info)

let snapshot_vio ~doc ~output_native_objects ldir long_f_dot_vo =
  let doc = finish ~doc in
  if List.length (VCS.branches ()) > 1 then
    CErrors.user_err ~hdr:"stm" (str"Cannot dump a vio with open proofs");
  Library.save_library_to ~todo:(dump_snapshot ()) ~output_native_objects
    ldir long_f_dot_vo
    (Global.opaque_tables ());
  doc

let reset_task_queue = Slaves.reset_task_queue

(* Document building *)

(* We process a meta command found in the document *)
let process_back_meta_command ~newtip ~head oid aast =
    let valid = VCS.get_branch_pos head in
    let old_parsing = Option.get @@ VCS.get_parsing_state oid in

    (* Merge in and discard all the branches currently open that were not open in `oid` *)
    let { mine; others } = Backtrack.branches_of oid in
    List.iter (fun branch ->
        if not (List.mem_assoc branch (mine::others)) then
          ignore(merge_proof_branch ~valid aast VtDrop branch))
      (VCS.branches ());

    (* We add a node on top of every branch, to represent state aliasing *)
    VCS.checkout_shallowest_proof_branch ();
    let head = VCS.current_branch () in
    List.iter (fun b ->
        VCS.checkout b;
        let id = if (VCS.Branch.equal b head) then Some newtip else None in
        let proof_mode = VCS.get_proof_mode @@ VCS.cur_tip () in
        let id = VCS.new_node ?id proof_mode () in
        VCS.commit id (Alias (oid,aast));
        VCS.set_parsing_state id old_parsing)
      (VCS.branches ());
    VCS.checkout_shallowest_proof_branch ();
    Backtrack.record (); `Ok

let get_allow_nested_proofs =
  Goptions.declare_bool_option_and_ref
    ~depr:false
    ~name:"Nested Proofs Allowed"
    ~key:Vernac_classifier.stm_allow_nested_proofs_option_name
    ~value:false

(** [process_transaction] adds a node in the document *)
let process_transaction ~doc ?(newtip=Stateid.fresh ())
  ({ verbose; expr } as x) c =
  stm_pperr_endline (fun () -> str "{{{ processing: " ++ pr_ast x);
  let vcs = VCS.backup () in
  try
    let head = VCS.current_branch () in
    VCS.checkout head;
    let head_parsing =
      Option.get @@ VCS.(get_parsing_state (get_branch_pos head)) in
    let proof_mode = VCS.(get_proof_mode (get_branch_pos head)) in
    let rc = begin
      stm_prerr_endline (fun () ->
        "  classified as: " ^ Vernac_classifier.string_of_vernac_classification c);
      match c with
      (* Meta *)
      | VtMeta ->
        let id = Backtrack.undo_vernac_classifier expr ~doc in
        process_back_meta_command ~newtip ~head id x

      (* Query *)
      | VtQuery ->
          let id = VCS.new_node ~id:newtip proof_mode () in
          let queue =
            if VCS.is_vio_doc () &&
               VCS.((get_branch head).kind = `Master) &&
               may_pierce_opaque x.expr.CAst.v.expr
            then `SkipQueue
            else `MainQueue in
          VCS.commit id (mkTransCmd x [] false queue);
          VCS.set_parsing_state id head_parsing;
          Backtrack.record (); `Ok

      (* Proof *)
      | VtStartProof (guarantee, names) ->

         if not (get_allow_nested_proofs ()) && VCS.proof_nesting () > 0 then
           "Nested proofs are not allowed unless you turn option Nested Proofs Allowed on."
           |> Pp.str
           |> (fun s -> (UserError (None, s), Exninfo.null))
           |> State.exn_on ~valid:Stateid.dummy newtip
           |> Exninfo.iraise
         else

          let proof_mode = Some (Vernacinterp.get_default_proof_mode ()) in
          let id = VCS.new_node ~id:newtip proof_mode () in
          let bname = VCS.mk_branch_name x in
          VCS.checkout VCS.Branch.master;
          if VCS.Branch.equal head VCS.Branch.master then begin
            VCS.commit id (Fork (x, bname, guarantee, names));
            VCS.branch bname (`Proof (VCS.proof_nesting () + 1))
          end else begin
            VCS.branch bname (`Proof (VCS.proof_nesting () + 1));
            VCS.merge id ~ours:(Fork (x, bname, guarantee, names)) head
          end;
          VCS.set_parsing_state id head_parsing;
          Backtrack.record (); `Ok

      | VtProofStep { parallel; proof_block_detection = cblock } ->
          let id = VCS.new_node ~id:newtip proof_mode () in
          let queue =
            match parallel with
            | `Yes(solve,abstract) -> `TacQueue (solve, abstract, ref false)
            | `No -> `MainQueue in
          VCS.commit id (mkTransTac x cblock queue);
          (* Static proof block detection delayed until an error really occurs.
             If/when and UI will make something useful with this piece of info,
             detection should occur here.
          detect_proof_block id cblock; *)
          VCS.set_parsing_state id head_parsing;
          Backtrack.record (); `Ok

      | VtQed keep ->
          let valid = VCS.get_branch_pos head in
          let rc =
            merge_proof_branch ~valid ~id:newtip x keep head in
          VCS.checkout_shallowest_proof_branch ();
          Backtrack.record ();
          rc

      (* Side effect in a (still open) proof is replayed on all branches*)
      | VtSideff (l, w) ->
          let id = VCS.new_node ~id:newtip proof_mode () in
          let new_ids =
            match (VCS.get_branch head).VCS.kind with
            | `Edit _ -> VCS.commit id (mkTransCmd x l true `MainQueue); []
            | `Master -> VCS.commit id (mkTransCmd x l false `MainQueue); []
            | `Proof _ ->
              VCS.checkout VCS.Branch.master;
              VCS.commit id (mkTransCmd x l true `MainQueue);
              (* We can't replay a Definition since universes may be differently
               * inferred.  This holds in Coq >= 8.5 *)
              let action = match x.expr.CAst.v.expr with
                | VernacDefinition(_, _, DefineBody _) -> CherryPickEnv
                | _ -> ReplayCommand x in
              VCS.propagate_sideff ~action
          in
          VCS.checkout_shallowest_proof_branch ();
          Backtrack.record ();
          let parsing_state =
            begin match w with
              | VtNow ->
                (* We need to execute to get the new parsing state *)
                ignore(finish ~doc:dummy_doc);
                let parsing = Vernacstate.Parser.cur_state () in
                (* If execution has not been put in cache, we need to save the parsing state *)
                if (VCS.get_info id).state == EmptyState then VCS.set_parsing_state id parsing;
                parsing
              | VtLater -> VCS.set_parsing_state id head_parsing; head_parsing
            end
          in
          (* We save the parsing state on non-master branches *)
          List.iter (fun id ->
              if (VCS.get_info id).state == EmptyState then
              VCS.set_parsing_state id parsing_state) new_ids;
          `Ok

      | VtProofMode pm ->
        let proof_mode = Pvernac.lookup_proof_mode pm in
        let id = VCS.new_node ~id:newtip proof_mode () in
        VCS.commit id (mkTransCmd x [] false `MainQueue);
        VCS.set_parsing_state id head_parsing;
        Backtrack.record (); `Ok

    end in
    let pr_rc rc = match rc with
      | `Ok -> Pp.(seq [str "newtip ("; str (Stateid.to_string (VCS.cur_tip ())); str ")"])
      | _   -> Pp.(str "unfocus")
    in
    stm_pperr_endline (fun () -> str "processed with " ++ pr_rc rc ++ str " }}}");
    VCS.print ();
    rc
  with e ->
    let e = CErrors.push e in
    handle_failure e vcs

let get_ast ~doc id =
  match VCS.visit id with
  | { step = `Cmd { cast = { expr } } }
  | { step = `Fork (({ expr }, _, _, _), _) }
  | { step = `Sideff ((ReplayCommand { expr }) , _) }
  | { step = `Qed ({ qast = { expr } }, _) } ->
    Some expr
  | _ -> None

let stop_worker n = Slaves.cancel_worker n

let parse_sentence ~doc sid ~entry pa =
  let ps = Option.get @@ VCS.get_parsing_state sid in
  let proof_mode = VCS.get_proof_mode sid in
  Vernacstate.Parser.parse ps (entry proof_mode) pa

(* You may need to know the len + indentation of previous command to compute
 * the indentation of the current one.
 *  Eg.   foo. bar.
 * Here bar is indented of the indentation of foo + its strlen (4) *)
let ind_len_loc_of_id sid =
  if Stateid.equal sid Stateid.initial then None
  else match (VCS.visit sid).step with
  | `Cmd { ctac = true; cast = { indentation; strlen; expr } } ->
    Some (indentation, strlen, expr.CAst.loc)
  | _ -> None

(* the indentation logic works like this: if the beginning of the
   command is different than the start we are in a new line, thus
   indentation follows from the starting position. Otherwise, we use
   the previous one plus the offset.

   Note, this could maybe improved by handling more cases in
   compute_indentation. *)

let compute_indentation ?loc sid = Option.cata (fun loc ->
  let open Loc              in
  (* The effective length is the length on the last line *)
  let len = loc.ep - loc.bp in
  let prev_indent = match ind_len_loc_of_id sid with
    | None         -> 0
    | Some (i,l,p) -> i + l
  in
  (* Now if the line has not changed, the need to add the previous indent *)
  let eff_indent = loc.bp - loc.bol_pos in
  if loc.bol_pos = 0 then
    eff_indent + prev_indent, len
  else
    eff_indent, len
  ) (0, 0) loc

let add ~doc ~ontop ?newtip verb ast =
  Hooks.(call document_add ast ontop);
  let loc = ast.CAst.loc in
  let cur_tip = VCS.cur_tip () in
  if not (Stateid.equal ontop cur_tip) then
    user_err ?loc ~hdr:"Stm.add"
      (str "Stm.add called for a different state (" ++ str (Stateid.to_string ontop) ++
       str ") than the tip: " ++ str (Stateid.to_string cur_tip) ++ str "." ++ fnl () ++
       str "This is not supported yet, sorry.");
  let indentation, strlen = compute_indentation ?loc ontop in
  (* XXX: Classifiy vernac should be moved inside process transaction *)
  let clas = Vernac_classifier.classify_vernac ast in
  let aast = { verbose = verb; indentation; strlen; expr = ast } in
  match process_transaction ~doc ?newtip aast clas with
  | `Ok -> doc, VCS.cur_tip (), `NewTip
  | `Unfocus qed_id -> doc, qed_id, `Unfocus (VCS.cur_tip ())

let set_perspective ~doc id_list = Slaves.set_perspective id_list

type focus = {
  start : Stateid.t;
  stop : Stateid.t;
  tip : Stateid.t
}

let query ~doc ~at ~route s =
  State.purify (fun s ->
    if Stateid.equal at Stateid.dummy then ignore(finish ~doc:dummy_doc)
    else Reach.known_state ~doc ~cache:true at;
      let rec loop () =
        match parse_sentence ~doc at ~entry:Pvernac.main_entry s with
        | None -> ()
        | Some ast ->
          let loc = ast.CAst.loc in
          let indentation, strlen = compute_indentation ?loc at in
          let st = State.get_cached at in
          let aast = {
            verbose = true; indentation; strlen;
            expr = ast } in
          ignore(stm_vernac_interp ~route at st aast);
          loop ()
      in
      loop ()
  )
  s

let edit_at ~doc id =
  Hooks.(call document_edit id);
  if Stateid.equal id Stateid.dummy then anomaly(str"edit_at dummy.") else
  let vcs = VCS.backup () in
  let on_cur_branch id =
    let rec aux cur =
      match VCS.visit cur with
      | { step = `Fork _ } -> false
      | { next } -> if id = cur then true else aux next in
    aux (VCS.get_branch_pos (VCS.current_branch ())) in
  let rec is_pure_aux id =
    let view = VCS.visit id in
    match view.step with
    | `Cmd _ -> is_pure_aux view.next
    | `Fork _ -> true
    | _ -> false in
  let is_pure id =
    match (VCS.visit id).step with
    | `Qed (_,last_step) -> is_pure_aux last_step
    | _ -> assert false
  in
  let is_ancestor_of_cur_branch id =
    Stateid.Set.mem id
      (VCS.reachable (VCS.get_branch_pos (VCS.current_branch ()))) in
  let has_failed qed_id =
    match VCS.visit qed_id with
    | { step = `Qed ({ fproof = Some (fp,_) }, _) } -> Future.is_exn fp
    | _ -> false in
  let rec master_for_br root tip =
      if Stateid.equal tip Stateid.initial then tip else
      match VCS.visit tip with
      | { step = (`Fork _ | `Qed _) } -> tip
      | { step = `Sideff (ReplayCommand _,id) } -> id
      | { step = `Sideff _ } -> tip
      | { next } -> master_for_br root next in
  let reopen_branch start at_id qed_id tip old_branch =
    let master_id, cancel_switch, keep =
      (* Hum, this should be the real start_id in the cluster and not next *)
      match VCS.visit qed_id with
      | { step = `Qed ({ fproof = Some (_,cs); keep },_) } -> start, cs, keep
      | _ -> anomaly (str "ProofTask not ending with Qed.") in
    VCS.branch ~root:master_id ~pos:id
      VCS.edit_branch (`Edit (qed_id, master_id, keep, old_branch));
    VCS.delete_boxes_of id;
    cancel_switch := true;
    Reach.known_state ~doc ~cache:(VCS.is_interactive ()) id;
    VCS.checkout_shallowest_proof_branch ();
    `Focus { stop = qed_id; start = master_id; tip } in
  let no_edit = function
   | `Edit (_,_,_,_) -> `Proof 1
   | x -> x in
  let backto id bn =
    List.iter VCS.delete_branch (VCS.branches ());
    let ancestors = VCS.reachable id in
    let { mine = brname, brinfo; others } = Backtrack.branches_of id in
    List.iter (fun (name,{ VCS.kind = k; root; pos }) ->
      if not(VCS.Branch.equal name VCS.Branch.master) &&
         Stateid.Set.mem root ancestors then
        VCS.branch ~root ~pos name k)
      others;
    VCS.reset_branch VCS.Branch.master (master_for_br brinfo.VCS.root id);
    VCS.branch ~root:brinfo.VCS.root ~pos:brinfo.VCS.pos
      (Option.default brname bn)
      (no_edit brinfo.VCS.kind);
    VCS.delete_boxes_of id;
    VCS.gc ();
    VCS.print ();
    Reach.known_state ~doc ~cache:(VCS.is_interactive ()) id;
    VCS.checkout_shallowest_proof_branch ();
    `NewTip in
  try
    let rc =
      let focused = List.exists ((=) VCS.edit_branch) (VCS.branches ()) in
      let branch_info =
        match snd (VCS.get_info id).vcs_backup with
        | Some{ mine = bn, { VCS.kind = `Proof _ }} -> Some bn
        | Some{ mine = _, { VCS.kind = `Edit(_,_,_,bn) }} -> Some bn
        | _ -> None in
      match focused, VCS.proof_task_box_of id, branch_info with
      | _, Some _, None -> assert false
      | false, Some { qed = qed_id ; lemma = start }, Some bn ->
          let tip = VCS.cur_tip () in
          if has_failed qed_id && is_pure qed_id && not !cur_opt.async_proofs_never_reopen_branch
          then reopen_branch start id qed_id tip bn
          else backto id (Some bn)
      | true, Some { qed = qed_id }, Some bn ->
          if on_cur_branch id then begin
            assert false
          end else if is_ancestor_of_cur_branch id then begin
            backto id (Some bn)
          end else begin
            anomaly(str"Cannot leave an `Edit branch open.")
          end
      | true, None, _ ->
          if on_cur_branch id then begin
            VCS.reset_branch (VCS.current_branch ()) id;
            Reach.known_state ~doc ~cache:(VCS.is_interactive ()) id;
            VCS.checkout_shallowest_proof_branch ();
            `NewTip
          end else if is_ancestor_of_cur_branch id then begin
            backto id None
          end else begin
            anomaly(str"Cannot leave an `Edit branch open.")
          end
      | false, None, Some bn -> backto id (Some bn)
      | false, None, None -> backto id None
    in
    VCS.print ();
    doc, rc
  with e ->
    let (e, info) = CErrors.push e in
    match Stateid.get info with
    | None ->
        VCS.print ();
        anomaly (str ("edit_at "^Stateid.to_string id^": ") ++
          CErrors.print_no_report e ++ str ".")
    | Some (_, id) ->
        stm_prerr_endline (fun () -> "Failed at state " ^ Stateid.to_string id);
        VCS.restore vcs;
        VCS.print ();
        Exninfo.iraise (e, info)

let get_current_state ~doc = VCS.cur_tip ()
let get_ldir ~doc = VCS.get_ldir ()

let get_doc did = dummy_doc

(*********************** TTY API (PG, coqtop, coqc) ***************************)
(******************************************************************************)

let current_proof_depth ~doc =
  let head = VCS.current_branch () in
  match VCS.get_branch head with
  | { VCS.kind = `Master } -> 0
  | { VCS.pos = cur; VCS.kind = (`Proof _ | `Edit _); VCS.root = root } ->
      let rec distance root =
        if Stateid.equal cur root then 0
        else 1 + distance (VCS.visit cur).next in
      distance cur

let unmangle n =
  let n = VCS.Branch.to_string n in
  let idx = String.index n '_' + 1 in
  Names.Id.of_string (String.sub n idx (String.length n - idx))

let proofname b = match VCS.get_branch b with
  | { VCS.kind = (`Proof _| `Edit _) } -> Some b
  | _ -> None

let get_all_proof_names ~doc =
  List.map unmangle (CList.map_filter proofname (VCS.branches ()))

(* Export hooks *)
let state_computed_hook = Hooks.state_computed_hook
let state_ready_hook = Hooks.state_ready_hook
let forward_feedback_hook = Hooks.forward_feedback_hook
let unreachable_state_hook = Hooks.unreachable_state_hook
let document_add_hook = Hooks.document_add_hook
let document_edit_hook = Hooks.document_edit_hook
let sentence_exec_hook = Hooks.sentence_exec_hook
let () = Hook.set DeclareObl.stm_get_fix_exn (fun () -> !State.fix_exn_ref)

type document = VCS.vcs
let backup () = VCS.backup ()
let restore d = VCS.restore d


(* vim:set foldmethod=marker: *)
stm/stm.ml

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