(**************************************************************************) (* *) (* Copyright (c) 2014 - 2016. *) (* Dynamic Ledger Solutions, Inc. *) (* *) (* All rights reserved. No warranty, explicit or implicit, provided. *) (* *) (**************************************************************************) module Canceler = Lwt_utils.Canceler module type DISTRIBUTED_DB = sig type t type key type value type param val known: t -> key -> bool Lwt.t type error += Missing_data of key type error += Canceled of key type error += Timeout of key val read: t -> key -> value tzresult Lwt.t val read_opt: t -> key -> value option Lwt.t val read_exn: t -> key -> value Lwt.t val prefetch: t -> ?peer:P2p.Peer_id.t -> ?timeout:float -> key -> param -> unit val fetch: t -> ?peer:P2p.Peer_id.t -> ?timeout:float -> key -> param -> value tzresult Lwt.t val clear_or_cancel: t -> key -> unit val inject: t -> key -> value -> bool Lwt.t val watch: t -> (key * value) Lwt_stream.t * Watcher.stopper end module type DISK_TABLE = sig type store type key type value val known: store -> key -> bool Lwt.t val read: store -> key -> value tzresult Lwt.t val read_opt: store -> key -> value option Lwt.t val read_exn: store -> key -> value Lwt.t end module type MEMORY_TABLE = sig type 'a t type key val create: int -> 'a t val find: 'a t -> key -> 'a val add: 'a t -> key -> 'a -> unit val replace: 'a t -> key -> 'a -> unit val remove: 'a t -> key -> unit val fold: (key -> 'a -> 'b -> 'b) -> 'a t -> 'b -> 'b end module type SCHEDULER_EVENTS = sig type t type key val request: t -> P2p.Peer_id.t option -> key -> unit val notify: t -> P2p.Peer_id.t -> key -> unit val notify_cancelation: t -> key -> unit val notify_unrequested: t -> P2p.Peer_id.t -> key -> unit val notify_duplicate: t -> P2p.Peer_id.t -> key -> unit val notify_invalid: t -> P2p.Peer_id.t -> key -> unit end module type PRECHECK = sig type key type param type notified_value type value val precheck: key -> param -> notified_value -> value option end module Make_table (Hash : sig type t val name : string val encoding : t Data_encoding.t val pp : Format.formatter -> t -> unit end) (Disk_table : DISK_TABLE with type key := Hash.t) (Memory_table : MEMORY_TABLE with type key := Hash.t) (Scheduler : SCHEDULER_EVENTS with type key := Hash.t) (Precheck : PRECHECK with type key := Hash.t and type value := Disk_table.value) : sig include DISTRIBUTED_DB with type key = Hash.t and type value = Disk_table.value and type param = Precheck.param val create: ?global_input:(key * value) Watcher.input -> Scheduler.t -> Disk_table.store -> t val notify: t -> P2p.Peer_id.t -> key -> Precheck.notified_value -> unit Lwt.t end = struct type key = Hash.t type value = Disk_table.value type param = Precheck.param type t = { scheduler: Scheduler.t ; disk: Disk_table.store ; memory: status Memory_table.t ; global_input: (key * value) Watcher.input option ; input: (key * value) Watcher.input ; } and status = | Pending of { wakener : value tzresult Lwt.u ; mutable waiters : int ; param : param } | Found of value let known s k = match Memory_table.find s.memory k with | exception Not_found -> Disk_table.known s.disk k | Pending _ -> Lwt.return_false | Found _ -> Lwt.return_true let read_opt s k = match Memory_table.find s.memory k with | exception Not_found -> Disk_table.read_opt s.disk k | Found v -> Lwt.return (Some v) | Pending _ -> Lwt.return_none let read_exn s k = match Memory_table.find s.memory k with | exception Not_found -> Disk_table.read_exn s.disk k | Found v -> Lwt.return v | Pending _ -> Lwt.fail Not_found type error += Missing_data of key type error += Canceled of key type error += Timeout of key let () = Error_monad.register_error_kind `Permanent ~id: ("distributed_db." ^ Hash.name ^ ".missing") ~title: ("Missing " ^ Hash.name) ~description: ("Some " ^ Hash.name ^ " is missing from the distributed db") ~pp: (fun ppf key -> Format.fprintf ppf "Missing %s %a" Hash.name Hash.pp key) (Data_encoding.obj1 (Data_encoding.req "key" Hash.encoding)) (function Missing_data key -> Some key | _ -> None) (fun key -> Missing_data key) let read s k = match Memory_table.find s.memory k with | exception Not_found -> trace (Missing_data k) @@ Disk_table.read s.disk k | Found v -> return v | Pending _ -> fail (Missing_data k) let wrap s k ?timeout t = let t = Lwt.protected t in Lwt.on_cancel t begin fun () -> match Memory_table.find s.memory k with | exception Not_found -> () | Found _ -> () | Pending data -> data.waiters <- data.waiters - 1 ; if data.waiters = 0 then begin Memory_table.remove s.memory k ; Scheduler.notify_cancelation s.scheduler k ; end end ; match timeout with | None -> t | Some delay -> let timeout = Lwt_unix.sleep delay >>= fun () -> fail (Timeout k) in Lwt.pick [ t ; timeout ] let fetch s ?peer ?timeout k param = match Memory_table.find s.memory k with | exception Not_found -> begin Disk_table.read_opt s.disk k >>= function | Some v -> return v | None -> match Memory_table.find s.memory k with | exception Not_found -> begin let waiter, wakener = Lwt.wait () in Memory_table.add s.memory k (Pending { wakener ; waiters = 1 ; param }) ; Scheduler.request s.scheduler peer k ; wrap s k ?timeout waiter end | Pending data -> Scheduler.request s.scheduler peer k ; data.waiters <- data.waiters + 1 ; wrap s k ?timeout (Lwt.waiter_of_wakener data.wakener) | Found v -> return v end | Pending data -> Scheduler.request s.scheduler peer k ; data.waiters <- data.waiters + 1 ; wrap s k ?timeout (Lwt.waiter_of_wakener data.wakener) | Found v -> return v let prefetch s ?peer ?timeout k param = try ignore (fetch s ?peer ?timeout k param) with _ -> () let notify s p k v = match Memory_table.find s.memory k with | exception Not_found -> begin Disk_table.known s.disk k >>= function | true -> Scheduler.notify_duplicate s.scheduler p k ; Lwt.return_unit | false -> Scheduler.notify_unrequested s.scheduler p k ; Lwt.return_unit end | Pending { wakener = w ; param } -> begin match Precheck.precheck k param v with | None -> Scheduler.notify_invalid s.scheduler p k ; Lwt.return_unit | Some v -> Scheduler.notify s.scheduler p k ; Memory_table.replace s.memory k (Found v) ; Lwt.wakeup_later w (Ok v) ; iter_option s.global_input ~f:(fun input -> Watcher.notify input (k, v)) ; Watcher.notify s.input (k, v) ; Lwt.return_unit end | Found _ -> Scheduler.notify_duplicate s.scheduler p k ; Lwt.return_unit let inject s k v = match Memory_table.find s.memory k with | exception Not_found -> begin Disk_table.known s.disk k >>= function | true -> Lwt.return_false | false -> Memory_table.add s.memory k (Found v) ; Lwt.return_true end | Pending _ | Found _ -> Lwt.return_false let clear_or_cancel s k = match Memory_table.find s.memory k with | exception Not_found -> () | Pending { wakener = w ; _ } -> Scheduler.notify_cancelation s.scheduler k ; Memory_table.remove s.memory k ; Lwt.wakeup_later w (Error [Canceled k]) | Found _ -> Memory_table.remove s.memory k let watch s = Watcher.create_stream s.input let create ?global_input scheduler disk = let memory = Memory_table.create 17 in let input = Watcher.create_input () in { scheduler ; disk ; memory ; input ; global_input } end module type REQUEST = sig type key type param val active : param -> P2p.Peer_id.Set.t val send : param -> P2p.Peer_id.t -> key list -> unit end module Make_request_scheduler (Hash : sig type t val name : string val encoding : t Data_encoding.t val pp : Format.formatter -> t -> unit end) (Table : MEMORY_TABLE with type key := Hash.t) (Request : REQUEST with type key := Hash.t) : sig type t val create: Request.param -> t val shutdown: t -> unit Lwt.t include SCHEDULER_EVENTS with type t := t and type key := Hash.t end = struct include Logging.Make(struct let name = "node.distributed_db.scheduler." ^ Hash.name end) type key = Hash.t type param = Request.param type t = { param: Request.param ; pending: status Table.t ; queue: event Lwt_pipe.t ; mutable events: event list Lwt.t ; canceler: Canceler.t ; mutable worker: unit Lwt.t ; } and status = { peers: P2p.Peer_id.Set.t ; next_request: float ; delay: float ; } and event = | Request of P2p.Peer_id.t option * key | Notify of P2p.Peer_id.t * key | Notify_cancelation of key | Notify_invalid of P2p.Peer_id.t * key | Notify_duplicate of P2p.Peer_id.t * key | Notify_unrequested of P2p.Peer_id.t * key let request t p k = assert (Lwt_pipe.push_now t.queue (Request (p, k))) let notify t p k = debug "push received %a from %a" Hash.pp k P2p.Peer_id.pp_short p ; assert (Lwt_pipe.push_now t.queue (Notify (p, k))) let notify_cancelation t k = debug "push cancelation %a" Hash.pp k ; assert (Lwt_pipe.push_now t.queue (Notify_cancelation k)) let notify_invalid t p k = debug "push received invalid %a from %a" Hash.pp k P2p.Peer_id.pp_short p ; assert (Lwt_pipe.push_now t.queue (Notify_invalid (p, k))) let notify_duplicate t p k = debug "push received duplicate %a from %a" Hash.pp k P2p.Peer_id.pp_short p ; assert (Lwt_pipe.push_now t.queue (Notify_duplicate (p, k))) let notify_unrequested t p k = debug "push received unrequested %a from %a" Hash.pp k P2p.Peer_id.pp_short p ; assert (Lwt_pipe.push_now t.queue (Notify_unrequested (p, k))) let compute_timeout state = let next = Table.fold (fun _ { next_request } acc -> min next_request acc) state.pending infinity in let now = Unix.gettimeofday () in let delay = next -. now in if delay <= 0. then Lwt.return_unit else begin (* lwt_debug "waiting at least %.2fs" delay >>= fun () -> *) Lwt_unix.sleep delay end let may_pp_peer ppf = function | None -> () | Some peer -> P2p.Peer_id.pp_short ppf peer (* TODO should depend on the ressource kind... *) let initial_delay = 0.1 let process_event state now = function | Request (peer, key) -> begin lwt_debug "registering request %a from %a" Hash.pp key may_pp_peer peer >>= fun () -> try let data = Table.find state.pending key in let peers = match peer with | None -> data.peers | Some peer -> P2p.Peer_id.Set.add peer data.peers in Table.replace state.pending key { delay = initial_delay ; next_request = min data.next_request (now +. initial_delay) ; peers ; } ; lwt_debug "registering request %a from %a -> replaced" Hash.pp key may_pp_peer peer >>= fun () -> Lwt.return_unit with Not_found -> let peers = match peer with | None -> P2p.Peer_id.Set.empty | Some peer -> P2p.Peer_id.Set.singleton peer in Table.add state.pending key { peers ; next_request = now ; delay = initial_delay ; } ; lwt_debug "registering request %a from %a -> added" Hash.pp key may_pp_peer peer >>= fun () -> Lwt.return_unit end | Notify (peer, key) -> Table.remove state.pending key ; lwt_debug "received %a from %a" Hash.pp key P2p.Peer_id.pp_short peer >>= fun () -> Lwt.return_unit | Notify_cancelation key -> Table.remove state.pending key ; lwt_debug "canceled %a" Hash.pp key >>= fun () -> Lwt.return_unit | Notify_invalid (peer, key) -> lwt_debug "received invalid %a from %a" Hash.pp key P2p.Peer_id.pp_short peer >>= fun () -> (* TODO *) Lwt.return_unit | Notify_unrequested (peer, key) -> lwt_debug "received unrequested %a from %a" Hash.pp key P2p.Peer_id.pp_short peer >>= fun () -> (* TODO *) Lwt.return_unit | Notify_duplicate (peer, key) -> lwt_debug "received duplicate %a from %a" Hash.pp key P2p.Peer_id.pp_short peer >>= fun () -> (* TODO *) Lwt.return_unit let rec worker_loop state = let shutdown = Canceler.cancelation state.canceler and timeout = compute_timeout state in Lwt.choose [ (state.events >|= fun _ -> ()) ; timeout ; shutdown ] >>= fun () -> if Lwt.state shutdown <> Lwt.Sleep then lwt_debug "terminating" >>= fun () -> Lwt.return_unit else if Lwt.state state.events <> Lwt.Sleep then let now = Unix.gettimeofday () in state.events >>= fun events -> state.events <- Lwt_pipe.pop_all state.queue ; Lwt_list.iter_s (process_event state now) events >>= fun () -> worker_loop state else lwt_debug "timeout" >>= fun () -> let now = Unix.gettimeofday () in let active_peers = Request.active state.param in let requests = Table.fold (fun key { peers ; next_request ; delay } acc -> if next_request > now +. 0.2 then acc else let remaining_peers = P2p.Peer_id.Set.inter peers active_peers in if P2p.Peer_id.Set.is_empty remaining_peers && not (P2p.Peer_id.Set.is_empty peers) then ( Table.remove state.pending key ; acc ) else let requested_peer = P2p.Peer_id.random_set_elt (if P2p.Peer_id.Set.is_empty remaining_peers then active_peers else remaining_peers) in let next = { peers = remaining_peers ; next_request = now +. delay ; delay = delay *. 1.2 } in Table.replace state.pending key next ; let requests = try key :: P2p_types.Peer_id.Map.find requested_peer acc with Not_found -> [key] in P2p_types.Peer_id.Map.add requested_peer requests acc) state.pending P2p_types.Peer_id.Map.empty in P2p_types.Peer_id.Map.iter (Request.send state.param) requests ; P2p_types.Peer_id.Map.fold begin fun peer request acc -> acc >>= fun () -> Lwt_list.iter_s (fun key -> lwt_debug "requested %a from %a" Hash.pp key P2p.Peer_id.pp_short peer) request end requests Lwt.return_unit >>= fun () -> worker_loop state let create param = let state = { param ; queue = Lwt_pipe.create () ; pending = Table.create 17 ; events = Lwt.return [] ; canceler = Canceler.create () ; worker = Lwt.return_unit ; } in state.worker <- Lwt_utils.worker "db_request_scheduler" ~run:(fun () -> worker_loop state) ~cancel:(fun () -> Canceler.cancel state.canceler) ; state let shutdown s = Canceler.cancel s.canceler >>= fun () -> s.worker end