(************************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* feedback ~state_id Feedback.Processed) () let state_ready, state_ready_hook = Hook.make ~default:(fun state_id -> ()) () let forward_feedback, forward_feedback_hook = Hook.make ~default:(function | { Feedback.id = Feedback.Edit edit_id; route; contents } -> feedback ~edit_id ~route contents | { Feedback.id = Feedback.State state_id; route; contents } -> feedback ~state_id ~route contents) () let parse_error, parse_error_hook = Hook.make ~default:(function | Feedback.Edit edit_id -> fun loc msg -> feedback ~edit_id (Feedback.ErrorMsg (loc, string_of_ppcmds msg)) | Feedback.State state_id -> fun loc msg -> feedback ~state_id (Feedback.ErrorMsg (loc, string_of_ppcmds msg))) () let execution_error, execution_error_hook = Hook.make ~default:(fun state_id loc msg -> feedback ~state_id (Feedback.ErrorMsg (loc, string_of_ppcmds msg))) () let unreachable_state, unreachable_state_hook = Hook.make ~default:(fun _ -> ()) () include Hook (* enables: Hooks.(call foo args) *) let call = get let call_process_error_once = let processed : unit Exninfo.t = Exninfo.make () in fun (_, info as ei) -> match Exninfo.get info processed with | Some _ -> ei | None -> let e, info = call process_error ei in let info = Exninfo.add info processed () in e, info end (* During interactive use we cache more states so that Undoing is fast *) let interactive () = if !Flags.ide_slave || !Flags.print_emacs || not !Flags.batch_mode then `Yes else `No let async_proofs_workers_extra_env = ref [||] type ast = { verbose : bool; loc : Loc.t; mutable expr : vernac_expr } let pr_ast { expr } = pr_vernac expr (* Wrapper for Vernacentries.interp to set the feedback id *) let vernac_interp ?proof id ?route { verbose; loc; expr } = let rec internal_command = function | VernacResetName _ | VernacResetInitial | VernacBack _ | VernacBackTo _ | VernacRestart | VernacUndo _ | VernacUndoTo _ | VernacBacktrack _ | VernacAbortAll | VernacAbort _ -> true | VernacTime el -> List.for_all (fun (_,e) -> internal_command e) el | _ -> false in if internal_command expr then begin prerr_endline ("ignoring " ^ string_of_ppcmds(pr_vernac expr)) end else begin set_id_for_feedback ?route (Feedback.State id); Aux_file.record_in_aux_set_at loc; prerr_endline ("interpreting " ^ string_of_ppcmds(pr_vernac expr)); try Hooks.(call interp ?verbosely:(Some verbose) ?proof (loc, expr)) with e -> let e = Errors.push e in iraise Hooks.(call_process_error_once e) end (* Wrapper for Vernac.parse_sentence to set the feedback id *) let vernac_parse ?newtip ?route eid s = let feedback_id = if Option.is_empty newtip then Feedback.Edit eid else Feedback.State (Option.get newtip) in set_id_for_feedback ?route feedback_id; let pa = Pcoq.Gram.parsable (Stream.of_string s) in Flags.with_option Flags.we_are_parsing (fun () -> try match Pcoq.Gram.entry_parse Pcoq.main_entry pa with | None -> raise (Invalid_argument "vernac_parse") | Some ast -> ast with e when Errors.noncritical e -> let (e, info) = Errors.push e in let loc = Option.default Loc.ghost (Loc.get_loc info) in Hooks.(call parse_error feedback_id loc (iprint (e, info))); iraise (e, info)) () let pr_open_cur_subgoals () = try Printer.pr_open_subgoals () with Proof_global.NoCurrentProof -> str"" module Vcs_ = Vcs.Make(Stateid) type future_proof = Proof_global.closed_proof_output Future.computation type proof_mode = string type depth = int type cancel_switch = bool ref type branch_type = [ `Master | `Proof of proof_mode * depth | `Edit of proof_mode * Stateid.t * Stateid.t ] type cmd_t = { ctac : bool; (* is a tactic, needed by the 8.4 semantics of Undo *) cast : ast; cids : Id.t list; cqueue : [ `MainQueue | `TacQueue of cancel_switch | `QueryQueue of cancel_switch ] } type fork_t = ast * Vcs_.Branch.t * Vernacexpr.opacity_guarantee * Id.t list type qed_t = { qast : ast; keep : vernac_qed_type; mutable fproof : (future_proof * cancel_switch) option; brname : Vcs_.Branch.t; brinfo : branch_type Vcs_.branch_info } type seff_t = ast option type alias_t = Stateid.t * ast 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 [ `Ast of ast * Stateid.t | `Id of Stateid.t ] | `Alias of alias_t ] type visit = { step : step; next : Stateid.t } type state = { system : States.state; proof : Proof_global.state; shallow : bool } type branch = Vcs_.Branch.t * branch_type Vcs_.branch_info type backup = { mine : branch; others : branch list } type 'vcs state_info = { (* Make private *) mutable n_reached : int; mutable n_goals : int; mutable state : state option; mutable vcs_backup : 'vcs option * backup option; } let default_info () = { n_reached = 0; n_goals = 0; state = None; vcs_backup = None,None } (* Functions that work on a Vcs with a specific branch type *) module Vcs_aux : sig val proof_nesting : (branch_type, 't,'i) Vcs_.t -> int val find_proof_at_depth : (branch_type, 't, 'i) Vcs_.t -> int -> Vcs_.Branch.t * branch_type Vcs_.branch_info exception Expired val visit : (branch_type, transaction,'i) Vcs_.t -> Vcs_.Dag.node -> visit end = struct (* {{{ *) let proof_nesting vcs = List.fold_left max 0 (List.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(m, n) } -> Int.equal n pl | _, { Vcs_.kind = `Edit _ } -> anomaly(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(str"Visiting the initial state id") else if Stateid.equal id Stateid.dummy then anomaly(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 None; p, Noop] | [p, Noop; n, Sideff None]-> { step = `Sideff (`Id p); next = n } | [n, Sideff (Some x); p, Noop] | [p, Noop; n, Sideff (Some x)]-> { step = `Sideff(`Ast (x,p)); next = n } | [n, Sideff (Some x)]-> {step = `Sideff(`Ast (x,Stateid.dummy)); next=n} | _ -> anomaly (str ("Malformed VCS at node "^Stateid.to_string id)) with Not_found -> raise Expired end (* }}} *) (*************************** THE DOCUMENT *************************************) (******************************************************************************) (* 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) Vcs_.t val init : id -> unit 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 -> 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 : ast -> 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 -> Vcs_.NodeSet.t val cur_tip : unit -> id val get_info : id -> vcs state_info val reached : id -> bool -> unit val goals : id -> int -> unit val set_state : id -> state -> unit val get_state : id -> state option (* cuts from start -> stop, raising Expired if some nodes are not there *) val slice : start:id -> stop:id -> vcs val nodes_in_slice : start:id -> stop:id -> Stateid.t list val create_cluster : id list -> qed:id -> start:id -> unit val cluster_of : id -> (id * id) option val delete_cluster_of : id -> unit val proof_nesting : unit -> int val checkout_shallowest_proof_branch : unit -> unit val propagate_sideff : ast option -> 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 module StateidSet = Set.Make(Stateid) open Printf let print_dag vcs () = let fname = "stm_" ^ Str.global_replace (Str.regexp " ") "_" (System.process_id ()) in let string_of_transaction = function | Cmd { cast = t } | Fork (t, _,_,_) -> (try string_of_ppcmds (pr_ast t) with _ -> "ERR") | Sideff (Some t) -> sprintf "Sideff(%s)" (try string_of_ppcmds (pr_ast t) with _ -> "ERR") | Sideff None -> "EnvChange" | Noop -> " " | Alias (id,_) -> sprintf "Alias(%s)" (Stateid.to_string id) | Qed { qast } -> string_of_ppcmds (pr_ast qast) in let is_green id = match get_info vcs id with | Some { state = Some _ } -> true | _ -> false in let is_red id = match get_info vcs id with | Some s -> Int.equal s.n_reached ~-1 | _ -> 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") "
" (Str.global_replace (Str.regexp "<") "<" (Str.global_replace (Str.regexp ">") ">" (Str.global_replace (Str.regexp "\"") """ (Str.global_replace (Str.regexp "&") "&" (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 "<%s>" (quote (string_of_transaction tr)) in let ids = ref StateidSet.empty in let clus = Hashtbl.create 13 in let node_info id = match get_info vcs id with | None -> "" | Some info -> sprintf "<%s" (Stateid.to_string id) ^ sprintf " r:%d g:%d>" 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 add_to_clus_or_ids from cf = match cf with | None -> ids := StateidSet.add from !ids; false | Some c -> Hashtbl.replace clus c (try let n = Hashtbl.find clus c in from::n with Not_found -> [from]); true in let oc = open_out fname_dot in output_string oc "digraph states {\nsplines=ortho\n"; Dag.iter graph (fun from cf _ l -> let c1 = add_to_clus_or_ids from cf in List.iter (fun (dest, trans) -> let c2 = add_to_clus_or_ids dest (Dag.cluster_of graph dest) in fprintf oc "%s -> %s [xlabel=%s,labelfloat=%b];\n" (node from) (node dest) (edge trans) (c1 && c2)) l ); StateidSet.iter (nodefmt oc) !ids; Hashtbl.iter (fun c nodes -> fprintf oc "subgraph cluster_%s {\n" (Dag.Cluster.to_string c); List.iter (nodefmt oc) nodes; fprintf oc "color=blue; }\n" ) clus; 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) t let vcs : vcs ref = ref (empty Stateid.dummy) let init id = vcs := empty id; vcs := set_info !vcs id (default_info ()) 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 ()) () = assert(Vcs_.get_info !vcs id = None); vcs := set_info !vcs id (default_info ()); 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 with | VernacDefinition (_,(_,i),_) -> string_of_id i | VernacStartTheoremProof (_,[Some (_,i),_],_) -> string_of_id 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 = (get_info id).state <- Some s; if Flags.async_proofs_is_master () then Hooks.(call state_ready id) let get_state id = (get_info id).state let reached id b = let info = get_info id in if b then info.n_reached <- info.n_reached + 1 else 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; match get_branch edit_branch with | { kind = `Edit (mode, _, _) } -> Proof_global.activate_proof_mode mode | _ -> assert false end else let pl = proof_nesting () in try let branch, mode = match Vcs_aux.find_proof_at_depth !vcs pl with | h, { Vcs_.kind = `Proof (m, _) } -> h, m | _ -> assert false in checkout branch; prerr_endline ("mode:" ^ mode); Proof_global.activate_proof_mode mode with Failure _ -> checkout Branch.master; Proof_global.disactivate_proof_mode "Classic" (* copies the transaction on every open branch *) let propagate_sideff t = List.iter (fun b -> checkout b; let id = new_node () in merge id ~ours:(Sideff t) ~into:b Branch.master) (List.filter (fun b -> not (Branch.equal b Branch.master)) (branches ())) let visit id = Vcs_aux.visit !vcs id let nodes_in_slice ~start ~stop = let rec aux id = if Stateid.equal id 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 (`Ast (x,_)) } -> (id,Sideff (Some x)) :: aux n | _ -> anomaly(str("Cannot slice from "^ Stateid.to_string start ^ " to "^Stateid.to_string stop)) in aux stop let slice ~start ~stop = let l = nodes_in_slice ~start ~stop in let copy_info v id = Vcs_.set_info v id { (get_info id) with state = None; vcs_backup = None,None } in let copy_info_w_state v id = Vcs_.set_info v id { (get_info id) with vcs_backup = None,None } in let v = Vcs_.empty start in let v = copy_info v 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 (not (Option.is_empty (get_info start).state)); (* We put in the new dag the most recent state known to master *) let rec fill id = if (get_info id).state = None then fill (Vcs_aux.visit v id).next else copy_info_w_state v id in fill stop let nodes_in_slice ~start ~stop = List.rev (List.map fst (nodes_in_slice ~start ~stop)) let create_cluster l ~qed ~start = vcs := create_cluster !vcs l (qed,start) let cluster_of id = Option.map Dag.Cluster.data (cluster_of !vcs id) let delete_cluster_of id = Option.iter (fun x -> vcs := delete_cluster !vcs x) (Vcs_.cluster_of !vcs id) let gc () = let old_vcs = !vcs in let new_vcs, erased_nodes = gc old_vcs in Vcs_.NodeSet.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 (Thread.create run_command ()) end end let print ?(now=false) () = if not !Flags.debug && not now then () else NB.command ~now (print_dag !vcs) let backup () = !vcs let restore v = vcs := v end (* }}} *) let state_of_id id = try `Valid (VCS.get_info id).state with VCS.Expired -> `Expired (****** A cache: fills in the nodes of the VCS document with their value ******) module State : sig (** 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 : ?safe_id:Stateid.t -> ?redefine:bool -> ?cache:Summary.marshallable -> ?feedback_processed:bool -> (unit -> unit) -> Stateid.t -> unit val install_cached : Stateid.t -> unit val is_cached : ?cache:Summary.marshallable -> Stateid.t -> bool val exn_on : Stateid.t -> ?valid:Stateid.t -> iexn -> iexn (* to send states across worker/master *) type frozen_state val get_cached : Stateid.t -> frozen_state val same_env : frozen_state -> frozen_state -> bool type partial_state = [ `Full of frozen_state | `Proof of Stateid.t * Proof_global.state ] val proof_part_of_frozen : frozen_state -> Proof_global.state val assign : Stateid.t -> partial_state -> unit end = struct (* {{{ *) (* 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 (* helpers *) let freeze_global_state marshallable = { system = States.freeze ~marshallable; proof = Proof_global.freeze ~marshallable; shallow = (marshallable = `Shallow) } let unfreeze_global_state { system; proof } = States.unfreeze system; Proof_global.unfreeze proof (* hack to make futures functional *) let in_t, out_t = Dyn.create "state4future" let () = Future.set_freeze (fun () -> in_t (freeze_global_state `No, !cur_id)) (fun t -> let s,i = out_t t in unfreeze_global_state s; cur_id := i) type frozen_state = state type partial_state = [ `Full of frozen_state | `Proof of Stateid.t * Proof_global.state ] let proof_part_of_frozen { proof } = proof let freeze marhallable id = VCS.set_state id (freeze_global_state marhallable) let is_cached ?(cache=`No) id = if Stateid.equal id !cur_id then try match VCS.get_info id with | { state = None } when cache = `Yes -> freeze `No id; true | { state = None } when cache = `Shallow -> freeze `Shallow id; true | _ -> true with VCS.Expired -> false else try match VCS.get_info id with | { state = Some _ } -> true | _ -> false with VCS.Expired -> false let install_cached id = if Stateid.equal id !cur_id then () else (* optimization *) let s = match VCS.get_info id with | { state = Some s } -> s | _ -> anomaly (str "unfreezing a non existing state") in unfreeze_global_state s; cur_id := id let get_cached id = try match VCS.get_info id with | { state = Some s } -> s | _ -> anomaly (str "not a cached state") with VCS.Expired -> anomaly (str "not a cached state (expired)") let assign id what = if VCS.get_state id <> None then () else try match what with | `Full s -> VCS.set_state id s | `Proof(ontop,p) -> if is_cached ontop then ( VCS.set_state id { (get_cached ontop) with proof = p }) with VCS.Expired -> () let exn_on id ?valid (e, info) = match Stateid.get info with | Some _ -> (e, info) | None -> let loc = Option.default Loc.ghost (Loc.get_loc info) in let (e, info) = Hooks.(call_process_error_once (e, info)) in Hooks.(call execution_error id loc (iprint (e, info))); (e, Stateid.add info ?valid id) let same_env { system = s1 } { system = s2 } = let s1 = States.summary_of_state s1 in let e1 = Summary.project_summary s1 [Global.global_env_summary_name] in let s2 = States.summary_of_state s2 in let e2 = Summary.project_summary s2 [Global.global_env_summary_name] in Summary.pointer_equal e1 e2 let define ?safe_id ?(redefine=false) ?(cache=`No) ?(feedback_processed=true) f id = feedback ~state_id:id Feedback.(ProcessingIn !Flags.async_proofs_worker_id); let str_id = Stateid.to_string id in if is_cached id && not redefine then anomaly (str"defining state "++str str_id++str" twice"); try prerr_endline("defining "^str_id^" (cache="^ if cache = `Yes then "Y)" else if cache = `Shallow then "S)" else "N)"); f (); if cache = `Yes then freeze `No id else if cache = `Shallow then freeze `Shallow id; prerr_endline ("setting cur id to "^str_id); cur_id := id; if feedback_processed then Hooks.(call state_computed id ~in_cache:false); VCS.reached id true; if Proof_global.there_are_pending_proofs () then VCS.goals id (Proof_global.get_open_goals ()); with e -> let (e, info) = Errors.push e in let good_id = !cur_id in cur_id := Stateid.dummy; VCS.reached id false; Hooks.(call unreachable_state id); match Stateid.get info, safe_id with | None, None -> iraise (exn_on id ~valid:good_id (e, info)) | None, Some good_id -> iraise (exn_on id ~valid:good_id (e, info)) | Some _, None -> iraise (e, info) | Some (_,at), Some id -> iraise (e, Stateid.add info ~valid:id at) end (* }}} *) (****************************** CRUFT *****************************************) (******************************************************************************) (* The backtrack module simulates the classic behavior of a linear document *) module Backtrack : sig val record : unit -> unit val backto : Stateid.t -> unit val back_safe : unit -> unit (* we could navigate the dag, but this ways easy *) val branches_of : Stateid.t -> backup (* To be installed during initialization *) val undo_vernac_classifier : vernac_expr -> vernac_classification 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 backto oid = let info = VCS.get_info oid in match info.vcs_backup with | None, _ -> anomaly(str"Backtrack.backto "++str(Stateid.to_string oid)++ str": a state with no vcs_backup") | Some vcs, _ -> VCS.restore vcs let branches_of id = let info = VCS.get_info id in match info.vcs_backup with | _, None -> anomaly(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 = VernacUndo n}) } -> [], false, n | _ -> [],false,0 in match f acc (id, vcs, ids, tactic, undo) with | `Stop x -> x | `Cont acc -> next acc let back_safe () = let id = fold_until (fun n (id,_,_,_,_) -> if n >= 0 && State.is_cached id then `Stop id else `Cont (succ n)) 0 (VCS.get_branch_pos (VCS.current_branch ())) in backto id let undo_vernac_classifier v = try match v with | VernacResetInitial -> VtStm (VtBack Stateid.initial, true), VtNow | VernacResetName (_,name) -> msg_warning (str"Reset not implemented for automatically generated constants"); let id = VCS.get_branch_pos (VCS.current_branch ()) in (try let oid = fold_until (fun b (id,_,label,_,_) -> if b then `Stop id else `Cont (List.mem name label)) false id in VtStm (VtBack oid, true), VtNow with Not_found -> VtStm (VtBack id, true), VtNow) | VernacBack n -> let id = VCS.get_branch_pos (VCS.current_branch ()) in let oid = fold_until (fun n (id,_,_,_,_) -> if Int.equal n 0 then `Stop id else `Cont (n-1)) n id in VtStm (VtBack oid, true), VtNow | VernacUndo n -> let id = VCS.get_branch_pos (VCS.current_branch ()) in let oid = fold_until (fun 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)) n id in VtStm (VtBack oid, true), VtLater | VernacUndoTo _ | VernacRestart as e -> let m = match e with VernacUndoTo m -> m | _ -> 0 in let id = VCS.get_branch_pos (VCS.current_branch ()) in let vcs = match (VCS.get_info id).vcs_backup with | None, _ -> anomaly(str"Backtrack: tip with no vcs_backup") | Some vcs, _ -> vcs in let cb, _ = Vcs_aux.find_proof_at_depth vcs (Vcs_aux.proof_nesting vcs) 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 VtStm (VtBack oid, true), VtLater | VernacAbortAll -> let id = VCS.get_branch_pos (VCS.current_branch ()) in let oid = fold_until (fun () (id,vcs,_,_,_) -> match Vcs_.branches vcs with [_] -> `Stop id | _ -> `Cont ()) () id in VtStm (VtBack oid, true), VtLater | VernacBacktrack (id,_,_) | VernacBackTo id -> VtStm (VtBack (Stateid.of_int id), not !Flags.print_emacs), VtNow | _ -> VtUnknown, VtNow with | Not_found -> msg_warning(str"undo_vernac_classifier: going back to the initial state."); VtStm (VtBack Stateid.initial, true), VtNow end (* }}} *) 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 !hints loc "context_used" in let ids = List.map Names.Id.of_string (Str.split (Str.regexp " ") s) in let ids = List.map (fun id -> Loc.ghost, id) ids in SsExpr (SsSet ids) let get_hint_bp_time proof_name = try float_of_string (Aux_file.get !hints Loc.ghost proof_name) with Not_found -> 1.0 let record_pb_time proof_name loc 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 Loc.ghost proof_name proof_build_time; hints := Aux_file.set !hints Loc.ghost proof_name proof_build_time end exception RemoteException of std_ppcmds let _ = Errors.register_handler (function | RemoteException ppcmd -> ppcmd | _ -> raise Unhandled) (****************************** THE SCHEDULER *********************************) (******************************************************************************) 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_states : competence; t_assign : Proof_global.closed_proof_output Future.assignement -> unit; t_loc : Loc.t; 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 * 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 : Stateid.t * Stateid.t -> Loc.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_states : competence; t_assign : Proof_global.closed_proof_output Future.assignement -> unit; t_loc : Loc.t; 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 * competence | ReqStates of Stateid.t list type error = { e_error_at : Stateid.t; e_safe_id : Stateid.t; e_msg : std_ppcmds; 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 | RespDone let name = ref "proofworker" let extra_env () = !async_proofs_workers_extra_env let perspective = ref [] let set_perspective l = perspective := l let task_match age t = match age, t with | `Fresh, BuildProof { t_states } -> not !Flags.async_proofs_full || List.exists (fun x -> CList.mem_f Stateid.equal x !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 } -> assert(age = `Fresh); try Some (ReqBuildProof ({ Stateid.exn_info = t_exn_info; stop = t_stop; document = VCS.slice ~start:t_start ~stop:t_stop; loc = t_loc; uuid = t_uuid; name = t_name }, t_states)) with VCS.Expired -> None let use_response (s : competence AsyncTaskQueue.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 }, RespBuiltProof (pl, time) -> feedback (Feedback.InProgress ~-1); t_assign (`Val pl); record_pb_time t_name t_loc time; if not !Flags.async_proofs_full then `End else `Stay(t_states,[States t_states]) | `Fresh, BuildProof { t_assign; t_loc; t_name; t_states }, RespError { e_error_at; e_safe_id = valid; e_msg; e_safe_states } -> feedback (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 (strbrk s), info) in t_assign (`Exn e); Hooks.(call execution_error start Loc.ghost (strbrk s)); feedback (Feedback.InProgress ~-1) let build_proof_here (id,valid) loc eop = Future.create (State.exn_on id ~valid) (fun () -> let wall_clock1 = Unix.gettimeofday () in if !Flags.batch_mode then Reach.known_state ~cache:`No eop else Reach.known_state ~cache:`Shallow eop; let wall_clock2 = Unix.gettimeofday () in Aux_file.record_in_aux_at loc "proof_build_time" (Printf.sprintf "%.3f" (wall_clock2 -. wall_clock1)); Proof_global.return_proof ()) let perform_buildp { Stateid.exn_info; stop; document; loc } my_states = try VCS.restore document; VCS.print (); let proof, future_proof, time = let wall_clock = Unix.gettimeofday () in let fp = build_proof_here exn_info loc 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 let checked_proof = Future.chain ~pure:false future_proof (fun p -> let pobject, _ = Proof_global.close_future_proof stop (Future.from_val ~fix_exn p) in let terminator = (* The one sent by master is an InvalidKey *) Lemmas.(standard_proof_terminator [] (mk_hook (fun _ _ -> ()))) in vernac_interp stop ~proof:(pobject, terminator) { verbose = false; loc; expr = (VernacEndProof (Proved (Opaque None,None))) }) in ignore(Future.join checked_proof); RespBuiltProof(proof,time) with | e when Errors.noncritical e -> let (e, info) = Errors.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 prerr_endline "failed with the following exception:"; prerr_endline (string_of_ppcmds e_msg); let e_safe_states = List.filter State.is_cached my_states in RespError { e_error_at; e_safe_id; e_msg; e_safe_states } let perform_states query = if query = [] then [] else 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 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 id then Some (State.get_cached id) else None in match prev, this with | _, None -> None | Some (prev, o, `Cmd { cast = { expr = VernacSolve _ }}), Some n when State.same_env o n -> (* A pure tactic *) Some (id, `Proof (prev, State.proof_part_of_frozen n)) | Some _, Some s -> msg_warning (str "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,states) -> perform_buildp bp states | ReqStates sl -> RespStates (perform_states sl) let on_marshal_error s = function | States _ -> msg_error(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 } -> msg_error(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 t_exn_info t_loc t_stop)); feedback (Feedback.InProgress ~-1) end (* }}} *) (* Slave processes (if initialized, otherwise local lazy evaluation) *) and Slaves : sig (* (eventually) remote calls *) val build_proof : loc:Loc.t -> exn_info:(Stateid.t * Stateid.t) -> start:Stateid.t -> stop:Stateid.t -> name:string -> future_proof * 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 : unit -> unit type 'a tasks = ('a,VCS.vcs) Stateid.request 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_discharge -> 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 () = if Flags.async_proofs_is_master () then queue := Some (TaskQueue.create !Flags.async_proofs_n_workers) else queue := Some (TaskQueue.create 0) let check_task_aux extra name l i = let { Stateid.stop; document; loc; name = r_name } = List.nth l i in msg_info( 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 ~cache:`No stop; (* The original terminator, a hook, has not been saved in the .vio*) Proof_global.set_terminator (Lemmas.standard_proof_terminator [] (Lemmas.mk_hook (fun _ _ -> ()))); let proof = Proof_global.close_proof ~keep_body_ucst_sepatate:true (fun x -> x) 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 ~cache:`No start; vernac_interp stop ~proof { verbose = false; loc; expr = (VernacEndProof (Proved (Opaque None,None))) }; Some proof with e -> let (e, info) = Errors.push e in (try match Stateid.get info with | None -> pperrnl ( str"File " ++ str name ++ str ": proof of " ++ str r_name ++ spc () ++ iprint (e, info)) | Some (_, cur) -> match VCS.visit cur with | { step = `Cmd { cast = { loc } } } | { step = `Fork (( { loc }, _, _, _), _) } | { step = `Qed ( { qast = { loc } }, _) } | { step = `Sideff (`Ast ( { loc }, _)) } -> let start, stop = Loc.unloc loc in pperrnl ( str"File " ++ str name ++ str ": proof of " ++ str r_name ++ str ": chars " ++ int start ++ str "-" ++ int stop ++ spc () ++ iprint (e, info)) | _ -> pperrnl ( str"File " ++ str name ++ str ": proof of " ++ str r_name ++ spc () ++ iprint (e, info)) with e -> msg_error (str"unable to print error message: " ++ str (Printexc.to_string e))); None let finish_task name (u,cst,_) d p l i = let bucket = (List.nth l i).Stateid.uuid in match check_task_aux (Printf.sprintf ", bucket %d" bucket) name l i with | None -> exit 1 | Some (po,_) -> let discharge c = List.fold_right Cooking.cook_constr d.(bucket) c in let con = Nametab.locate_constant (Libnames.qualid_of_ident po.Proof_global.id) in let c = Global.lookup_constant con in let o = match c.Declarations.const_body with | Declarations.OpaqueDef o -> o | _ -> assert false in let uc = Option.get (Opaqueproof.get_constraints (Global.opaque_tables ()) o) in let pr = Future.from_val (Option.get (Global.body_of_constant_body c)) in let uc = Future.chain ~greedy:true ~pure:true uc Univ.hcons_universe_context_set in let pr = Future.chain ~greedy:true ~pure:true pr discharge in let pr = Future.chain ~greedy:true ~pure:true pr Constr.hcons in Future.sink pr; let extra = Future.join uc in u.(bucket) <- uc; p.(bucket) <- pr; u, Univ.ContextSet.union cst extra, false let check_task name l i = match check_task_aux "" name l i with | Some _ -> true | None -> false let info_tasks l = CList.map_i (fun i { Stateid.loc; name } -> let time1 = try float_of_string (Aux_file.get !hints loc "proof_build_time") with Not_found -> 0.0 in let time2 = try float_of_string (Aux_file.get !hints loc "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 Stateid in 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 ~loc ~exn_info ~start ~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 !Flags.compilation_mode = Flags.BuildVio then begin let f,assign = Future.create_delegate ~blocking:true (State.exn_on id ~valid) in let t_uuid = Future.uuid f in let task = ProofTask.(BuildProof { t_exn_info; t_start = start; t_stop = stop; t_assign = assign; t_loc = loc; t_uuid; t_name = pname; t_states = VCS.nodes_in_slice ~start ~stop }) in TaskQueue.enqueue_task (Option.get !queue) (task,cancel_switch); f, cancel_switch end else ProofTask.build_proof_here t_exn_info loc stop, cancel_switch else let f, t_assign = Future.create_delegate (State.exn_on id ~valid) in let t_uuid = Future.uuid f in feedback (Feedback.InProgress 1); let task = ProofTask.(BuildProof { t_exn_info; t_start = start; t_stop = stop; t_assign; t_loc = loc; t_uuid; t_name = pname; t_states = VCS.nodes_in_slice ~start ~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 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, _)) -> Some r | _ -> None) tasks in prerr_endline (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 * Evd.evar_universe_context type task = { t_state : Stateid.t; t_state_fb : Stateid.t; t_assign : output Future.assignement -> unit; t_ast : ast; t_goal : Goal.goal; t_kill : unit -> unit; t_name : string } include AsyncTaskQueue.Task with type task := task end = struct (* {{{ *) type output = Constr.constr * Evd.evar_universe_context let forward_feedback msg = Hooks.(call forward_feedback msg) type task = { t_state : Stateid.t; t_state_fb : Stateid.t; t_assign : output Future.assignement -> unit; t_ast : ast; 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 : ast; r_goal : Goal.goal; r_name : string } type response = | RespBuiltSubProof of output | RespError of std_ppcmds let name = ref "tacworker" let extra_env () = [||] type competence = unit 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 ~start:t_state ~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 o); `Stay ((),[]) | RespError msg -> let info = Stateid.add ~valid:t_state Exninfo.null t_state_fb in let e = (RemoteException msg, info) in t_assign (`Exn e); t_kill (); `Stay ((),[]) let on_marshal_error err { t_name } = 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 perform { r_state = id; r_state_fb; r_document = vcs; r_ast; r_goal } = Option.iter VCS.restore vcs; try Reach.known_state ~cache:`No id; let t, uc = Future.purify (fun () -> vernac_interp r_state_fb r_ast; let _,_,_,_,sigma = Proof.proof (Proof_global.give_me_the_proof ()) in match Evd.(evar_body (find sigma r_goal)) with | Evd.Evar_empty -> Errors.errorlabstrm "Stm" (str "no progress") | Evd.Evar_defined t -> let t = Evarutil.nf_evar sigma t in if Evarutil.is_ground_term sigma t then t, Evd.evar_universe_context sigma else Errors.errorlabstrm "Stm" (str"The solution is not ground")) () in RespBuiltSubProof (t,uc) with e when Errors.noncritical e -> RespError (Errors.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 : cancel_switch -> int -> Stateid.t -> Stateid.t -> ast -> unit end = struct (* {{{ *) module TaskQueue = AsyncTaskQueue.MakeQueue(TacTask) let vernac_interp cancel nworkers safe_id id { verbose; loc; expr = e } = let e, etac, time, fail = let rec find time fail = function | VernacSolve(_,_,re,b) -> re, b, time, fail | VernacTime [_,e] -> find true fail e | VernacFail e -> find time true e | _ -> errorlabstrm "Stm" (str"unsupported") in find false false e in Hooks.call Hooks.with_fail fail (fun () -> (if time then System.with_time false else (fun x -> x)) (fun () -> ignore(TaskQueue.with_n_workers nworkers (fun queue -> Proof_global.with_current_proof (fun _ p -> let goals, _, _, _, _ = Proof.proof p in let open TacTask in let res = CList.map_i (fun i g -> let f,assign= Future.create_delegate (State.exn_on id ~valid:safe_id) in let t_ast = { verbose;loc;expr = VernacSolve(SelectNth i,None,e,etac) } 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 () -> TaskQueue.cancel_all queue) }, cancel); Goal.uid g,f) 1 goals in TaskQueue.join queue; let assign_tac : unit Proofview.tactic = Proofview.V82.tactic (fun gl -> let open Tacmach in let sigma, g = project gl, sig_it gl in let gid = Goal.uid g in let f = try List.assoc gid res with Not_found -> Errors.anomaly(str"Partac: wrong focus") in if Future.is_over f then let pt, uc = Future.join f in prerr_endline (string_of_ppcmds(hov 0 ( str"g=" ++ str gid ++ spc () ++ str"t=" ++ (Printer.pr_constr pt) ++ spc () ++ str"uc=" ++ Evd.pr_evar_universe_context uc))); let sigma = Goal.V82.partial_solution sigma g pt in let sigma = Evd.merge_universe_context sigma uc in re_sig [] sigma else (* One has failed and cancelled the others, but not this one *) re_sig [g] sigma) in Proof.run_tactic (Global.env()) assign_tac p)))) ()) end (* }}} *) and QueryTask : sig type task = { t_where : Stateid.t; t_for : Stateid.t ; t_what : ast } include AsyncTaskQueue.Task with type task := task end = struct (* {{{ *) type task = { t_where : Stateid.t; t_for : Stateid.t ; t_what : ast } type request = { r_where : Stateid.t ; r_for : Stateid.t ; r_what : ast; r_doc : VCS.vcs } type response = unit let name = ref "queryworker" let extra_env _ = [||] type competence = unit 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 ~start:t_where ~stop:t_where; r_what = t_what } with VCS.Expired -> None let use_response _ _ _ = `End let on_marshal_error _ _ = 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 ~cache:`No r_where; try vernac_interp r_for { r_what with verbose = true }; feedback ~state_id:r_for Feedback.Processed with e when Errors.noncritical e -> let msg = string_of_ppcmds (print e) in feedback ~state_id:r_for (Feedback.ErrorMsg (Loc.ghost, 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 : unit -> unit val vernac_interp : cancel_switch -> Stateid.t -> Stateid.t -> ast -> unit end = struct (* {{{ *) module TaskQueue = AsyncTaskQueue.MakeQueue(QueryTask) let queue = ref None let vernac_interp switch prev id q = assert(TaskQueue.n_workers (Option.get !queue) > 0); TaskQueue.enqueue_task (Option.get !queue) QueryTask.({ QueryTask.t_where = prev; t_for = id; t_what = q }, switch) let init () = queue := Some (TaskQueue.create (if !Flags.async_proofs_full then 1 else 0)) end (* }}} *) (* Runs all transactions needed to reach a state *) and Reach : sig val known_state : ?redefine_qed:bool -> cache:Summary.marshallable -> Stateid.t -> unit end = struct (* {{{ *) let pstate = ["meta counter"; "evar counter"; "program-tcc-table"] let async_policy () = let open Flags in if interactive () = `Yes then (async_proofs_is_master () || !async_proofs_mode = Flags.APonLazy) else (!compilation_mode = Flags.BuildVio || !async_proofs_mode <> Flags.APoff) let delegate name = let time = get_hint_bp_time name in time >= 1.0 || !Flags.compilation_mode = Flags.BuildVio || !Flags.async_proofs_full let collect_proof keep cur hd brkind id = prerr_endline ("Collecting proof ending at "^Stateid.to_string id); let no_name = "" in let name = function | [] -> no_name | id :: _ -> Id.to_string id in let loc = (snd cur).loc in let is_defined = function | _, { expr = VernacEndProof (Proved ((Transparent|Opaque (Some _)),_)) } -> true | _ -> false in let proof_using_ast = function | Some (_, ({ expr = VernacProof(_,Some _) } as v)) -> Some v | _ -> None in let has_proof_using x = proof_using_ast x <> None in let proof_no_using = function | Some (_, ({ expr = VernacProof(t,None) } as v)) -> t,v | _ -> assert false in let has_proof_no_using = function | Some (_, { expr = VernacProof(_,None) }) -> true | _ -> false in let parent = function Some (p, _) -> p | None -> assert false in let rec collect last accn id = let view = VCS.visit id in match view.step with | `Cmd { cast = x } -> collect (Some (id,x)) (id::accn) view.next | `Sideff (`Ast (x,_)) -> collect (Some (id,x)) (id::accn) view.next (* An Alias could jump everywhere... we hope we can ignore it*) | `Alias _ -> `Sync (no_name,None,`Alias) | `Fork((_,_,_,_::_::_), _) -> `Sync (no_name,proof_using_ast last,`MutualProofs) | `Fork((_,_,Doesn'tGuaranteeOpacity,_), _) -> `Sync (no_name,proof_using_ast last,`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,proof_using_ast last,accn,name,delegate name) | `Fork((_, hd', GuaranteesOpacity, ids), _) when has_proof_no_using last && not (State.is_cached (parent last)) && !Flags.compilation_mode = Flags.BuildVio -> 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 <- VernacProof(t, Some hint); `ASync (parent last,proof_using_ast last,accn,name,delegate name) with Not_found -> `Sync (no_name,None,`NoHint)) | `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, None, accn, name, delegate name) | `Sideff _ -> `Sync (no_name,None,`NestedProof) | _ -> `Sync (no_name,None,`Unknown) in let make_sync why = function | `Sync(name,pua,_) -> `Sync (name,pua,why) | `MaybeASync(_,pua,_,name,_) -> `Sync (name,pua,why) | `ASync(_,pua,_,name,_) -> `Sync (name,pua,why) in let check_policy rc = if async_policy () then rc else make_sync `Policy rc in match cur, (VCS.visit id).step, brkind with | (parent, { expr = VernacExactProof _ }), `Fork _, _ -> `Sync (no_name,None,`Immediate) | _, _, { VCS.kind = `Edit _ } -> check_policy (collect (Some cur) [] id) | _ -> if is_defined cur then `Sync (no_name,None,`Transparent) else if keep == VtDrop then `Sync (no_name,None,`Aborted) else let rc = collect (Some cur) [] id in if keep == VtKeep && (not(State.is_cached id) || !Flags.async_proofs_full) then check_policy rc else make_sync `AlreadyEvaluated rc let string_of_reason = function | `Transparent -> "Transparent" | `AlreadyEvaluated -> "AlreadyEvaluated" | `Policy -> "Policy" | `NestedProof -> "NestedProof" | `Immediate -> "Immediate" | `Alias -> "Alias" | `NoHint -> "NoHint" | `Doesn'tGuaranteeOpacity -> "Doesn'tGuaranteeOpacity" | `Aborted -> "Aborted" | _ -> "Unknown Reason" let wall_clock_last_fork = ref 0.0 let known_state ?(redefine_qed=false) ~cache id = (* ugly functions to process nested lemmas, i.e. hard to reproduce * side effects *) let cherry_pick_non_pstate () = Summary.freeze_summary ~marshallable:`No ~complement:true pstate, Lib.freeze ~marshallable:`No in let inject_non_pstate (s,l) = Summary.unfreeze_summary s; Lib.unfreeze l in let rec pure_cherry_pick_non_pstate id = Future.purify (fun id -> prerr_endline ("cherry-pick non pstate " ^ Stateid.to_string id); reach id; cherry_pick_non_pstate ()) id (* traverses the dag backward from nodes being already calculated *) and reach ?(redefine_qed=false) ?(cache=cache) id = prerr_endline ("reaching: " ^ Stateid.to_string id); if not redefine_qed && State.is_cached ~cache id then begin State.install_cached id; Hooks.(call state_computed id ~in_cache:true); prerr_endline ("reached (cache)") 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 = `TacQueue cancel } -> (fun () -> reach ~cache:`Shallow view.next; Partac.vernac_interp cancel !Flags.async_proofs_n_tacworkers view.next id x ), cache, true | `Cmd { cast = x; cqueue = `QueryQueue cancel } when Flags.async_proofs_is_master () -> (fun () -> reach ~cache:`Shallow view.next; Query.vernac_interp cancel view.next id x ), cache, false | `Cmd { cast = x } -> (fun () -> reach view.next; vernac_interp id x ), cache, true | `Fork ((x,_,_,_), None) -> (fun () -> reach view.next; vernac_interp id x; wall_clock_last_fork := Unix.gettimeofday () ), `Yes, true | `Fork ((x,_,_,_), Some prev) -> (fun () -> reach ~cache:`Shallow prev; reach view.next; (try vernac_interp id x; with e when Errors.noncritical e -> let (e, info) = Errors.push e in let info = Stateid.add info ~valid:prev id in iraise (e, info)); wall_clock_last_fork := Unix.gettimeofday () ), `Yes, true | `Qed ({ qast = x; keep; brinfo; brname } as qed, eop) -> let rec aux = function | `ASync (start, pua, nodes, name, delegate) -> (fun () -> assert(keep == VtKeep); let stop, exn_info, loc = eop, (id, eop), x.loc in prerr_endline ("Asynchronous " ^ Stateid.to_string id); VCS.create_cluster nodes ~qed:id ~start; begin match brinfo, qed.fproof with | { VCS.kind = `Edit _ }, None -> assert false | { VCS.kind = `Edit _ }, Some (ofp, cancel) -> assert(redefine_qed = true); let fp, cancel = Slaves.build_proof ~loc ~exn_info ~start ~stop ~name in Future.replace ofp fp; qed.fproof <- Some (fp, cancel) | { VCS.kind = `Proof _ }, Some _ -> assert false | { VCS.kind = `Proof _ }, None -> reach ~cache:`Shallow start; let fp, cancel = if delegate then Slaves.build_proof ~loc ~exn_info ~start ~stop ~name else ProofTask.build_proof_here exn_info loc stop, ref false in qed.fproof <- Some (fp, cancel); let proof = Proof_global.close_future_proof ~feedback_id:id fp in if not delegate then ignore(Future.compute fp); reach view.next; vernac_interp id ~proof x; feedback ~state_id:id Feedback.Incomplete | { VCS.kind = `Master }, _ -> assert false end; Proof_global.discard_all () ), (if redefine_qed then `No else `Yes), true | `Sync (name, _, `Immediate) -> (fun () -> assert (Stateid.equal view.next eop); reach eop; vernac_interp id x; Proof_global.discard_all () ), `Yes, true | `Sync (name, pua, reason) -> (fun () -> prerr_endline ("Synchronous " ^ Stateid.to_string id ^ " " ^ string_of_reason reason); reach eop; let wall_clock = Unix.gettimeofday () in record_pb_time name x.loc (wall_clock -. !wall_clock_last_fork); let proof = if keep != VtKeep then None else Some(Proof_global.close_proof ~keep_body_ucst_sepatate:false (State.exn_on id ~valid:eop)) in if proof = None then prerr_endline "NONE!!!!!"; reach view.next; if keep == VtKeepAsAxiom then Option.iter (vernac_interp id) pua; let wall_clock2 = Unix.gettimeofday () in vernac_interp id ?proof x; let wall_clock3 = Unix.gettimeofday () in Aux_file.record_in_aux_at x.loc "proof_check_time" (Printf.sprintf "%.3f" (wall_clock3 -. wall_clock2)); Proof_global.discard_all () ), `Yes, true | `MaybeASync (start, pua, nodes, name, delegate) -> (fun () -> prerr_endline ("MaybeAsynchronous " ^ Stateid.to_string id); reach ~cache:`Shallow start; (* no sections *) if List.is_empty (Environ.named_context (Global.env ())) then pi1 (aux (`ASync (start, pua, nodes, name, delegate))) () else pi1 (aux (`Sync (name, pua, `Unknown))) () ), (if redefine_qed then `No else `Yes), true in aux (collect_proof keep (view.next, x) brname brinfo eop) | `Sideff (`Ast (x,_)) -> (fun () -> reach view.next; vernac_interp id x; ), cache, true | `Sideff (`Id origin) -> (fun () -> reach view.next; inject_non_pstate (pure_cherry_pick_non_pstate origin); ), cache, true in let cache_step = if !Flags.async_proofs_cache = Some Flags.Force then `Yes else cache_step in State.define ~cache:cache_step ~redefine:redefine_qed ~feedback_processed step id; prerr_endline ("reached: "^ Stateid.to_string id) in reach ~redefine_qed id end (* }}} *) (********************************* STM API ************************************) (******************************************************************************) let init () = VCS.init Stateid.initial; set_undo_classifier Backtrack.undo_vernac_classifier; State.define ~cache:`Yes (fun () -> ()) Stateid.initial; Backtrack.record (); Slaves.init (); if Flags.async_proofs_is_master () then begin prerr_endline "Initialising workers"; Query.init (); let opts = match !Flags.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 let observe id = let vcs = VCS.backup () in try Reach.known_state ~cache:(interactive ()) id; VCS.print () with e -> let e = Errors.push e in VCS.print (); VCS.restore vcs; iraise e let finish ?(print_goals=false) () = observe (VCS.get_branch_pos (VCS.current_branch ())); if print_goals then msg_notice (pr_open_cur_subgoals ()); VCS.print () let wait () = Slaves.wait_all_done (); VCS.print () let join () = finish (); wait (); prerr_endline "Joining the environment"; Global.join_safe_environment (); VCS.print (); VCS.print () let dump_snapshot () = Slaves.dump_snapshot (), RemoteCounter.snapshot () type document = VCS.vcs 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 = Future.purify (Slaves.check_task name tasks) i in pperr_flush (); VCS.restore vcs; rc with e when Errors.noncritical e -> VCS.restore vcs; false let info_tasks (tasks,_) = Slaves.info_tasks tasks let finish_tasks name u d p (t,rcbackup as tasks) = RemoteCounter.restore rcbackup; let finish_task u (_,_,i) = let vcs = VCS.backup () in let u = Future.purify (Slaves.finish_task name u d p t) i in pperr_flush (); VCS.restore vcs; u in try let u, a, _ = List.fold_left finish_task u (info_tasks tasks) in (u,a,true), p with e -> let e = Errors.push e in pperrnl (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 () in VCS.merge id ~ours:(Qed (qed None)) brname; VCS.delete_branch brname; if keep <> VtDrop then VCS.propagate_sideff None; `Ok | { VCS.kind = `Edit (mode, 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 (); Reach.known_state ~redefine_qed:true ~cache:`No qed_id; VCS.checkout VCS.Branch.master; `Unfocus qed_id | { VCS.kind = `Master } -> iraise (State.exn_on ?valid Stateid.dummy (Proof_global.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 tty = if e = Errors.Drop then iraise (e, info) else match Stateid.get info with | None -> VCS.restore vcs; VCS.print (); if tty && interactive () = `Yes then begin (* Hopefully the 1 to last state is valid *) Backtrack.back_safe (); VCS.checkout_shallowest_proof_branch (); end; VCS.print (); anomaly(str"error with no safe_id attached:" ++ spc() ++ Errors.print_no_report e) | Some (safe_id, id) -> prerr_endline ("Failed at state " ^ Stateid.to_string id); VCS.restore vcs; if tty && interactive () = `Yes then begin (* We stay on a valid state *) Backtrack.backto safe_id; VCS.checkout_shallowest_proof_branch (); Reach.known_state ~cache:(interactive ()) safe_id; end; VCS.print (); iraise (e, info) let snapshot_vio ldir long_f_dot_v = finish (); if List.length (VCS.branches ()) > 1 then Errors.errorlabstrm "stm" (str"Cannot dump a vio with open proofs"); Library.save_library_to ~todo:(dump_snapshot ()) ldir long_f_dot_v (Global.opaque_tables ()) let reset_task_queue = Slaves.reset_task_queue (* Document building *) let process_transaction ?(newtip=Stateid.fresh ()) ~tty verbose c (loc, expr) = let warn_if_pos a b = if b then msg_warning(pr_ast a ++ str" should not be part of a script") in let v, x = expr, { verbose = verbose; loc; expr } in prerr_endline ("{{{ processing: "^ string_of_ppcmds (pr_ast x)); let vcs = VCS.backup () in try let head = VCS.current_branch () in VCS.checkout head; let rc = begin prerr_endline (" classified as: " ^ string_of_vernac_classification c); match c with (* PG stuff *) | VtStm(VtPG,false), VtNow -> vernac_interp Stateid.dummy x; `Ok | VtStm(VtPG,_), _ -> anomaly(str "PG command in script or VtLater") (* Joining various parts of the document *) | VtStm (VtJoinDocument, b), VtNow -> warn_if_pos x b; join (); `Ok | VtStm (VtFinish, b), VtNow -> warn_if_pos x b; finish (); `Ok | VtStm (VtWait, b), VtNow -> warn_if_pos x b; finish (); wait (); `Ok | VtStm (VtPrintDag, b), VtNow -> warn_if_pos x b; VCS.print ~now:true (); `Ok | VtStm (VtObserve id, b), VtNow -> warn_if_pos x b; observe id; `Ok | VtStm ((VtObserve _ | VtFinish | VtJoinDocument |VtPrintDag |VtWait),_), VtLater -> anomaly(str"classifier: join actions cannot be classified as VtLater") (* Back *) | VtStm (VtBack oid, true), w -> let id = VCS.new_node ~id:newtip () in 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 x VtDrop branch)) (VCS.branches ()); VCS.checkout_shallowest_proof_branch (); let head = VCS.current_branch () in List.iter (fun b -> if not(VCS.Branch.equal b head) then begin VCS.checkout b; VCS.commit (VCS.new_node ()) (Alias (oid,x)); end) (VCS.branches ()); VCS.checkout_shallowest_proof_branch (); VCS.commit id (Alias (oid,x)); Backtrack.record (); if w == VtNow then finish (); `Ok | VtStm (VtBack id, false), VtNow -> prerr_endline ("undo to state " ^ Stateid.to_string id); Backtrack.backto id; VCS.checkout_shallowest_proof_branch (); Reach.known_state ~cache:(interactive ()) id; `Ok | VtStm (VtBack id, false), VtLater -> anomaly(str"classifier: VtBack + VtLater must imply part_of_script") (* Query *) | VtQuery (false,(report_id,route)), VtNow when tty = true -> finish (); (try Future.purify (vernac_interp report_id ~route) { verbose = true; loc; expr } with e when Errors.noncritical e -> let e = Errors.push e in iraise (State.exn_on report_id e)); `Ok | VtQuery (false,(report_id,route)), VtNow -> (try vernac_interp report_id ~route x with e when Errors.noncritical e -> let e = Errors.push e in iraise (State.exn_on report_id e)); `Ok | VtQuery (true,(report_id,_)), w -> assert(Stateid.equal report_id Stateid.dummy); let id = VCS.new_node ~id:newtip () in let queue = if !Flags.async_proofs_full then `QueryQueue (ref false) else `MainQueue in VCS.commit id (Cmd {ctac=false;cast = x; cids = []; cqueue = queue }); Backtrack.record (); if w == VtNow then finish (); `Ok | VtQuery (false,_), VtLater -> anomaly(str"classifier: VtQuery + VtLater must imply part_of_script") (* Proof *) | VtStartProof (mode, guarantee, names), w -> let id = VCS.new_node ~id:newtip () 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 (mode, VCS.proof_nesting () + 1)) end else begin VCS.branch bname (`Proof (mode, VCS.proof_nesting () + 1)); VCS.merge id ~ours:(Fork (x, bname, guarantee, names)) head end; Proof_global.activate_proof_mode mode; Backtrack.record (); if w == VtNow then finish (); `Ok | VtProofMode _, VtLater -> anomaly(str"VtProofMode must be executed VtNow") | VtProofMode mode, VtNow -> let id = VCS.new_node ~id:newtip () in VCS.checkout VCS.Branch.master; VCS.commit id (Cmd {ctac=false;cast = x;cids=[];cqueue = `MainQueue}); VCS.propagate_sideff (Some x); List.iter (fun bn -> match VCS.get_branch bn with | { VCS.root; kind = `Master; pos } -> () | { VCS.root; kind = `Proof(_,d); pos } -> VCS.delete_branch bn; VCS.branch ~root ~pos bn (`Proof(mode,d)) | { VCS.root; kind = `Edit(_,f,q); pos } -> VCS.delete_branch bn; VCS.branch ~root ~pos bn (`Edit(mode,f,q))) (VCS.branches ()); VCS.checkout_shallowest_proof_branch (); Backtrack.record (); finish (); `Ok | VtProofStep paral, w -> let id = VCS.new_node ~id:newtip () in let queue = if paral then `TacQueue (ref false) else `MainQueue in VCS.commit id (Cmd {ctac = true;cast = x;cids = [];cqueue = queue }); Backtrack.record (); if w == VtNow then finish (); `Ok | VtQed keep, w -> let valid = if tty then Some(VCS.get_branch_pos head) else None in let rc = merge_proof_branch ?valid ~id:newtip x keep head in VCS.checkout_shallowest_proof_branch (); Backtrack.record (); if w == VtNow then finish (); rc (* Side effect on all branches *) | VtUnknown, _ when expr = VernacToplevelControl Drop -> vernac_interp (VCS.get_branch_pos head) x; `Ok | VtSideff l, w -> let id = VCS.new_node ~id:newtip () in VCS.checkout VCS.Branch.master; VCS.commit id (Cmd {ctac=false;cast=x;cids=l;cqueue=`MainQueue}); VCS.propagate_sideff (Some x); VCS.checkout_shallowest_proof_branch (); Backtrack.record (); if w == VtNow then finish (); `Ok (* Unknown: we execute it, check for open goals and propagate sideeff *) | VtUnknown, VtNow -> let id = VCS.new_node ~id:newtip () in let head_id = VCS.get_branch_pos head in Reach.known_state ~cache:`Yes head_id; (* ensure it is ok *) let step () = VCS.checkout VCS.Branch.master; let mid = VCS.get_branch_pos VCS.Branch.master in Reach.known_state ~cache:(interactive ()) mid; vernac_interp id x; (* Vernac x may or may not start a proof *) if VCS.Branch.equal head VCS.Branch.master && Proof_global.there_are_pending_proofs () then begin let bname = VCS.mk_branch_name x in VCS.commit id (Fork (x,bname,Doesn'tGuaranteeOpacity,[])); VCS.branch bname (`Proof ("Classic", VCS.proof_nesting () + 1)); Proof_global.activate_proof_mode "Classic"; end else begin VCS.commit id (Cmd {ctac=false; cast = x; cids = []; cqueue = `MainQueue}); VCS.propagate_sideff (Some x); VCS.checkout_shallowest_proof_branch (); end in State.define ~safe_id:head_id ~cache:`Yes step id; Backtrack.record (); `Ok | VtUnknown, VtLater -> anomaly(str"classifier: VtUnknown must imply VtNow") end in (* Proof General *) begin match v with | VernacStm (PGLast _) -> if not (VCS.Branch.equal head VCS.Branch.master) then vernac_interp Stateid.dummy { verbose = true; loc = Loc.ghost; expr = VernacShow (ShowGoal OpenSubgoals) } | _ -> () end; prerr_endline "processed }}}"; VCS.print (); rc with e -> let e = Errors.push e in handle_failure e vcs tty let print_ast id = try match VCS.visit id with | { step = `Cmd { cast = { loc; expr } } } | { step = `Fork (({ loc; expr }, _, _, _), _) } | { step = `Qed ({ qast = { loc; expr } }, _) } -> let xml = try Texmacspp.tmpp expr loc with e -> Xml_datatype.PCData ("ERROR " ^ Printexc.to_string e) in xml; | _ -> Xml_datatype.PCData "ERROR" with _ -> Xml_datatype.PCData "ERROR" let stop_worker n = Slaves.cancel_worker n let add ~ontop ?newtip ?(check=ignore) verb eid s = let cur_tip = VCS.cur_tip () in if Stateid.equal ontop cur_tip then begin let _, ast as loc_ast = vernac_parse ?newtip eid s in check(loc_ast); let clas = classify_vernac ast in match process_transaction ?newtip ~tty:false verb clas loc_ast with | `Ok -> VCS.cur_tip (), `NewTip | `Unfocus qed_id -> qed_id, `Unfocus (VCS.cur_tip ()) end else begin (* For now, arbitrary edits should be announced with edit_at *) anomaly(str"Not yet implemented, the GUI should not try this") end let set_perspective id_list = Slaves.set_perspective id_list type focus = { start : Stateid.t; stop : Stateid.t; tip : Stateid.t } let query ~at ?(report_with=(Stateid.dummy,Feedback.default_route)) s = Future.purify (fun s -> if Stateid.equal at Stateid.dummy then finish () else Reach.known_state ~cache:`Yes at; let newtip, route = report_with in let _, ast as loc_ast = vernac_parse ~newtip ~route 0 s in let clas = classify_vernac ast in match clas with | VtStm (w,_), _ -> ignore(process_transaction ~tty:false true (VtStm (w,false), VtNow) loc_ast) | _ -> ignore(process_transaction ~tty:false true (VtQuery (false,report_with), VtNow) loc_ast)) s let edit_at 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 = if id = cur then true else match VCS.visit cur with | { step = `Fork _ } -> false | { next } -> aux next in aux (VCS.get_branch_pos (VCS.current_branch ())) in let is_ancestor_of_cur_branch id = Vcs_.NodeSet.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 | { next } when next = root -> root | { step = `Fork _ } -> tip | { step = `Sideff (`Ast(_,id)|`Id id) } -> id | { next } -> master_for_br root next in let reopen_branch start at_id mode qed_id tip = let master_id, cancel_switch = (* Hum, this should be the real start_id in the clusted and not next *) match VCS.visit qed_id with | { step = `Qed ({ fproof = Some (_,cs)},_) } -> start, cs | _ -> anomaly (str "Cluster not ending with Qed") in VCS.branch ~root:master_id ~pos:id VCS.edit_branch (`Edit (mode, qed_id, master_id)); VCS.delete_cluster_of id; cancel_switch := true; Reach.known_state ~cache:(interactive ()) id; VCS.checkout_shallowest_proof_branch (); `Focus { stop = qed_id; start = master_id; tip } in let backto id = 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) && Vcs_.NodeSet.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 brname brinfo.VCS.kind; VCS.delete_cluster_of id; VCS.gc (); Reach.known_state ~cache:(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 = _, { VCS.kind = (`Proof(m,_)|`Edit(m,_,_)) }} -> Some m | _ -> None in match focused, VCS.cluster_of id, branch_info with | _, Some _, None -> assert false | false, Some (qed_id,start), Some mode -> let tip = VCS.cur_tip () in if has_failed qed_id && not !Flags.async_proofs_never_reopen_branch then reopen_branch start id mode qed_id tip else backto id | true, Some (qed_id,_), Some mode -> if on_cur_branch id then begin assert false end else if is_ancestor_of_cur_branch id then begin backto id 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 ~cache:(interactive ()) id; VCS.checkout_shallowest_proof_branch (); `NewTip end else if is_ancestor_of_cur_branch id then begin backto id end else begin anomaly(str"Cannot leave an `Edit branch open") end | false, None, _ -> backto id in VCS.print (); rc with e -> let (e, info) = Errors.push e in match Stateid.get info with | None -> VCS.print (); anomaly (str ("edit_at "^Stateid.to_string id^": ") ++ Errors.print_no_report e) | Some (_, id) -> prerr_endline ("Failed at state " ^ Stateid.to_string id); VCS.restore vcs; VCS.print (); iraise (e, info) (*********************** TTY API (PG, coqtop, coqc) ***************************) (******************************************************************************) let interp verb (_,e as lexpr) = let clas = classify_vernac e in let rc = process_transaction ~tty:true verb clas lexpr in if rc <> `Ok then anomaly(str"tty loop can't be mixed with the STM protocol"); if interactive () = `Yes || (!Flags.async_proofs_mode = Flags.APoff && !Flags.compilation_mode = Flags.BuildVo) then let vcs = VCS.backup () in let print_goals = verb && match clas with | VtQuery _, _ -> false | (VtProofStep _ | VtStm (VtBack _, _) | VtStartProof _), _ -> true | _ -> not !Flags.coqtop_ui || !Flags.print_emacs in try finish ~print_goals () with e -> let e = Errors.push e in handle_failure e vcs true let finish () = finish () let get_current_state () = VCS.cur_tip () let current_proof_depth () = 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 () = List.map unmangle (List.map_filter proofname (VCS.branches ())) let get_current_proof_name () = Option.map unmangle (proofname (VCS.current_branch ())) let get_script prf = let branch, test = match prf with | None -> VCS.Branch.master, fun _ -> true | Some name -> VCS.current_branch (), List.mem name in let rec find acc id = if Stateid.equal id Stateid.initial || Stateid.equal id Stateid.dummy then acc else let view = VCS.visit id in match view.step with | `Fork((_,_,_,ns), _) when test ns -> acc | `Qed (qed, proof) -> find [qed.qast.expr, (VCS.get_info id).n_goals] proof | `Sideff (`Ast (x,_)) -> find ((x.expr, (VCS.get_info id).n_goals)::acc) view.next | `Sideff (`Id id) -> find acc id | `Cmd {cast = x} -> find ((x.expr, (VCS.get_info id).n_goals)::acc) view.next | `Alias (id,_) -> find acc id | `Fork _ -> find acc view.next in find [] (VCS.get_branch_pos branch) (* indentation code for Show Script, initially contributed by D. de Rauglaudre *) let indent_script_item ((ng1,ngl1),nl,beginend,ppl) (cmd,ng) = (* ng1 : number of goals remaining at the current level (before cmd) ngl1 : stack of previous levels with their remaining goals ng : number of goals after the execution of cmd beginend : special indentation stack for { } *) let ngprev = List.fold_left (+) ng1 ngl1 in let new_ngl = if ng > ngprev then (* We've branched *) (ng - ngprev + 1, ng1 - 1 :: ngl1) else if ng < ngprev then (* A subgoal have been solved. Let's compute the new current level by discarding all levels with 0 remaining goals. *) let rec loop = function | (0, ng2::ngl2) -> loop (ng2,ngl2) | p -> p in loop (ng1-1, ngl1) else (* Standard case, same goal number as before *) (ng1, ngl1) in (* When a subgoal have been solved, separate this block by an empty line *) let new_nl = (ng < ngprev) in (* Indentation depth *) let ind = List.length ngl1 in (* Some special handling of bullets and { }, to get a nicer display *) let pred n = max 0 (n-1) in let ind, nl, new_beginend = match cmd with | VernacSubproof _ -> pred ind, nl, (pred ind)::beginend | VernacEndSubproof -> List.hd beginend, false, List.tl beginend | VernacBullet _ -> pred ind, nl, beginend | _ -> ind, nl, beginend in let pp = (if nl then fnl () else mt ()) ++ (hov (ind+1) (str (String.make ind ' ') ++ Ppvernac.pr_vernac cmd)) in (new_ngl, new_nl, new_beginend, pp :: ppl) let show_script ?proof () = try let prf = try match proof with | None -> Some (Pfedit.get_current_proof_name ()) | Some (p,_) -> Some (p.Proof_global.id) with Proof_global.NoCurrentProof -> None in let cmds = get_script prf in let _,_,_,indented_cmds = List.fold_left indent_script_item ((1,[]),false,[],[]) cmds in let indented_cmds = List.rev (indented_cmds) in msg_notice (v 0 (prlist_with_sep fnl (fun x -> x) indented_cmds)) with Vcs_aux.Expired -> () (* Export hooks *) let state_computed_hook = Hooks.state_computed_hook let state_ready_hook = Hooks.state_ready_hook let parse_error_hook = Hooks.parse_error_hook let execution_error_hook = Hooks.execution_error_hook let forward_feedback_hook = Hooks.forward_feedback_hook let process_error_hook = Hooks.process_error_hook let interp_hook = Hooks.interp_hook let with_fail_hook = Hooks.with_fail_hook let unreachable_state_hook = Hooks.unreachable_state_hook (* vim:set foldmethod=marker: *)