(**************************************************************************) (* *) (* Copyright (c) 2014 - 2016. *) (* Dynamic Ledger Solutions, Inc. *) (* *) (* All rights reserved. No warranty, explicit or implicit, provided. *) (* *) (**************************************************************************) module Message = Distributed_db_message module Metadata = Distributed_db_metadata type p2p = (Message.t, Metadata.t) P2p.net type connection = (Message.t, Metadata.t) P2p.connection type 'a request_param = { data: 'a ; active: unit -> P2p.Peer_id.Set.t ; send: P2p.Peer_id.t -> Message.t -> unit ; } module Make_raw (Hash : sig type t val name : string val encoding : t Data_encoding.t val pp : Format.formatter -> t -> unit end) (Disk_table : Distributed_db_functors.DISK_TABLE with type key := Hash.t) (Memory_table : Distributed_db_functors.MEMORY_TABLE with type key := Hash.t) (Request_message : sig type param val forge : param -> Hash.t list -> Message.t end) (Precheck : Distributed_db_functors.PRECHECK with type key := Hash.t and type value := Disk_table.value) = struct type key = Hash.t type value = Disk_table.value type param = Disk_table.store module Request = struct type param = Request_message.param request_param let active { active } = active () let send { data ; send } gid keys = send gid (Request_message.forge data keys) end module Scheduler = Distributed_db_functors.Make_request_scheduler (Hash) (Memory_table) (Request) module Table = Distributed_db_functors.Make_table (Hash) (Disk_table) (Memory_table) (Scheduler) (Precheck) type t = { scheduler: Scheduler.t ; table: Table.t ; } let create ?global_input request_param param = let scheduler = Scheduler.create request_param in let table = Table.create ?global_input scheduler param in { scheduler ; table } let shutdown { scheduler } = Scheduler.shutdown scheduler end module Fake_operation_storage = struct type store = State.Net.t type key = Operation_hash.t type value = Operation.t let known _ _ = Lwt.return_false let read _ _ = Lwt.return (Error_monad.error_exn Not_found) let read_opt _ _ = Lwt.return_none let read_exn _ _ = raise Not_found end module Raw_operation = Make_raw (Operation_hash) (Fake_operation_storage) (Operation_hash.Table) (struct type param = Net_id.t let forge net_id keys = Message.Get_operations (net_id, keys) end) (struct type param = unit type notified_value = Operation.t let precheck _ _ v = Some v end) module Block_header_storage = struct type store = State.Net.t type key = Block_hash.t type value = Block_header.t let known = State.Block.known_valid let read net_state h = State.Block.read net_state h >>=? fun b -> return (State.Block.header b) let read_opt net_state h = State.Block.read_opt net_state h >>= fun b -> Lwt.return (Utils.map_option State.Block.header b) let read_exn net_state h = State.Block.read_exn net_state h >>= fun b -> Lwt.return (State.Block.header b) end module Raw_block_header = Make_raw (Block_hash) (Block_header_storage) (Block_hash.Table) (struct type param = Net_id.t let forge net_id keys = Message.Get_block_headers (net_id, keys) end) (struct type param = unit type notified_value = Block_header.t let precheck _ _ v = Some v end) module Operation_hashes_storage = struct type store = State.Net.t type key = Block_hash.t * int type value = Operation_hash.t list let known net_state (h, _) = State.Block.known_valid net_state h let read net_state (h, i) = State.Block.read net_state h >>=? fun b -> State.Block.operation_hashes b i >>= fun (ops, _) -> return ops let read_opt net_state (h, i) = State.Block.read_opt net_state h >>= function | None -> Lwt.return_none | Some b -> State.Block.operation_hashes b i >>= fun (ops, _) -> Lwt.return (Some ops) let read_exn net_state (h, i) = State.Block.read_exn net_state h >>= fun b -> State.Block.operation_hashes b i >>= fun (ops, _) -> Lwt.return ops end module Operations_table = Hashtbl.Make(struct type t = Block_hash.t * int let hash = Hashtbl.hash let equal (b1, i1) (b2, i2) = Block_hash.equal b1 b2 && i1 = i2 end) module Raw_operation_hashes = struct include Make_raw (struct type t = Block_hash.t * int let name = "operation_hashes" let pp ppf (h, n) = Format.fprintf ppf "%a:%d" Block_hash.pp h n let encoding = let open Data_encoding in obj2 (req "block" Block_hash.encoding) (req "index" uint16) end) (Operation_hashes_storage) (Operations_table) (struct type param = Net_id.t let forge net_id keys = Message.Get_operation_hashes_for_blocks (net_id, keys) end) (struct type param = Operation_list_list_hash.t type notified_value = Operation_hash.t list * Operation_list_list_hash.path let precheck (_block, expected_ofs) expected_hash (ops, path) = let received_hash, received_ofs = Operation_list_list_hash.check_path path (Operation_list_hash.compute ops) in if received_ofs = expected_ofs && Operation_list_list_hash.compare expected_hash received_hash = 0 then Some ops else None end) let inject_all table hash operations = Lwt_list.mapi_p (fun i ops -> Table.inject table (hash, i) ops) operations >>= Lwt_list.for_all_s (fun x -> Lwt.return x) let read_all table hash n = map_p (fun i -> Table.read table (hash, i)) (0 -- (n-1)) let clear_all table hash n = List.iter (fun i -> Table.clear_or_cancel table (hash, i)) (0 -- (n-1)) end module Operations_storage = struct type store = State.Net.t type key = Block_hash.t * int type value = Operation.t list let known net_state (h, _) = State.Block.known_valid net_state h let read net_state (h, i) = State.Block.read net_state h >>=? fun b -> State.Block.operations b i >>= fun (ops, _) -> return ops let read_opt net_state (h, i) = State.Block.read_opt net_state h >>= function | None -> Lwt.return_none | Some b -> State.Block.operations b i >>= fun (ops, _) -> Lwt.return (Some ops) let read_exn net_state (h, i) = State.Block.read_exn net_state h >>= fun b -> State.Block.operations b i >>= fun (ops, _) -> Lwt.return ops end module Raw_operations = struct include Make_raw (struct type t = Block_hash.t * int let name = "operations" let pp ppf (h, n) = Format.fprintf ppf "%a:%d" Block_hash.pp h n let encoding = let open Data_encoding in obj2 (req "block" Block_hash.encoding) (req "index" uint16) end) (Operations_storage) (Operations_table) (struct type param = Net_id.t let forge net_id keys = Message.Get_operations_for_blocks (net_id, keys) end) (struct type param = Operation_list_list_hash.t type notified_value = Operation.t list * Operation_list_list_hash.path let precheck (_block, expected_ofs) expected_hash (ops, path) = let received_hash, received_ofs = Operation_list_list_hash.check_path path (Operation_list_hash.compute (List.map Operation.hash ops)) in if received_ofs = expected_ofs && Operation_list_list_hash.compare expected_hash received_hash = 0 then Some ops else None end) let inject_all table hash operations = Lwt_list.mapi_p (fun i ops -> Table.inject table (hash, i) ops) operations >>= Lwt_list.for_all_s (fun x -> Lwt.return x) let read_all table hash n = map_p (fun i -> Table.read table (hash, i)) (0 -- (n-1)) let clear_all table hash n = List.iter (fun i -> Table.clear_or_cancel table (hash, i)) (0 -- (n-1)) end module Protocol_storage = struct type store = State.t type key = Protocol_hash.t type value = Protocol.t let known = State.Protocol.known let read = State.Protocol.read let read_opt = State.Protocol.read_opt let read_exn = State.Protocol.read_exn end module Raw_protocol = Make_raw (Protocol_hash) (Protocol_storage) (Protocol_hash.Table) (struct type param = unit let forge () keys = Message.Get_protocols keys end) (struct type param = unit type notified_value = Protocol.t let precheck _ _ v = Some v end) type callback = { notify_branch: P2p.Peer_id.t -> Block_locator.t -> unit ; notify_head: P2p.Peer_id.t -> Block_hash.t -> Operation_hash.t list -> unit ; disconnection: P2p.Peer_id.t -> unit ; } type db = { p2p: p2p ; p2p_readers: p2p_reader P2p.Peer_id.Table.t ; disk: State.t ; active_nets: net_db Net_id.Table.t ; protocol_db: Raw_protocol.t ; block_input: (Block_hash.t * Block_header.t) Watcher.input ; operation_input: (Operation_hash.t * Operation.t) Watcher.input ; } and net_db = { net_state: State.Net.t ; global_db: db ; operation_db: Raw_operation.t ; block_header_db: Raw_block_header.t ; operation_hashes_db: Raw_operation_hashes.t ; operations_db: Raw_operations.t ; mutable callback: callback ; active_peers: P2p.Peer_id.Set.t ref ; active_connections: p2p_reader P2p.Peer_id.Table.t ; } and p2p_reader = { gid: P2p.Peer_id.t ; conn: connection ; peer_active_nets: net_db Net_id.Table.t ; canceler: Lwt_utils.Canceler.t ; mutable worker: unit Lwt.t ; } let noop_callback = { notify_branch = begin fun _gid _locator -> () end ; notify_head = begin fun _gid _block _ops -> () end ; disconnection = begin fun _gid -> () end ; } type t = db let state { net_state } = net_state module P2p_reader = struct type t = p2p_reader let may_activate global_db state net_id f = match Net_id.Table.find state.peer_active_nets net_id with | net_db -> f net_db | exception Not_found -> match Net_id.Table.find global_db.active_nets net_id with | net_db -> net_db.active_peers := P2p.Peer_id.Set.add state.gid !(net_db.active_peers) ; P2p.Peer_id.Table.add net_db.active_connections state.gid state ; Net_id.Table.add state.peer_active_nets net_id net_db ; f net_db | exception Not_found -> (* TODO decrease peer score. *) Lwt.return_unit let deactivate state net_db = net_db.callback.disconnection state.gid ; net_db.active_peers := P2p.Peer_id.Set.remove state.gid !(net_db.active_peers) ; P2p.Peer_id.Table.remove net_db.active_connections state.gid let may_handle state net_id f = match Net_id.Table.find state.peer_active_nets net_id with | exception Not_found -> (* TODO decrease peer score *) Lwt.return_unit | net_db -> f net_db let may_handle_global global_db net_id f = match Net_id.Table.find global_db.active_nets net_id with | exception Not_found -> Lwt.return_unit | net_db -> f net_db let handle_msg global_db state msg = let open Message in let module Logging = Logging.Make(struct let name = "node.distributed_db.p2p_reader" end) in let open Logging in lwt_debug "Read message from %a: %a" P2p.Peer_id.pp_short state.gid Message.pp_json msg >>= fun () -> match msg with | Get_current_branch net_id -> may_handle_global global_db net_id @@ fun net_db -> if not (Net_id.Table.mem state.peer_active_nets net_id) then ignore @@ P2p.try_send global_db.p2p state.conn @@ Get_current_branch net_id ; Chain.head net_db.net_state >>= fun head -> Block_locator.compute head 200 >>= fun locator -> ignore @@ P2p.try_send global_db.p2p state.conn @@ Current_branch (net_id, locator) ; Lwt.return_unit | Current_branch (net_id, locator) -> may_activate global_db state net_id @@ fun net_db -> Lwt_list.exists_p (State.Block.known_invalid net_db.net_state) (locator :> Block_hash.t list) >>= fun known_invalid -> if not known_invalid then net_db.callback.notify_branch state.gid locator ; (* TODO Kickban *) Lwt.return_unit | Deactivate net_id -> may_handle state net_id @@ fun net_db -> deactivate state net_db ; Net_id.Table.remove state.peer_active_nets net_id ; Lwt.return_unit | Get_current_head net_id -> may_handle state net_id @@ fun net_db -> Chain.head net_db.net_state >>= fun head -> Chain.mempool net_db.net_state >>= fun mempool -> ignore @@ P2p.try_send global_db.p2p state.conn @@ Current_head (net_id, State.Block.hash head, Utils.list_sub mempool 200) ; Lwt.return_unit | Current_head (net_id, head, mempool) -> may_handle state net_id @@ fun net_db -> State.Block.known_invalid net_db.net_state head >>= fun known_invalid -> if not known_invalid then net_db.callback.notify_head state.gid head mempool ; (* TODO Kickban *) Lwt.return_unit | Get_block_headers (net_id, hashes) -> may_handle state net_id @@ fun net_db -> (* TODO: Blame request of unadvertised blocks ? *) Lwt_list.iter_p (fun hash -> State.Block.read_opt net_db.net_state hash >|= function | None -> () | Some b -> let header = State.Block.header b in ignore @@ P2p.try_send global_db.p2p state.conn (Block_header header)) hashes | Block_header block -> may_handle state block.shell.net_id @@ fun net_db -> let hash = Block_header.hash block in Raw_block_header.Table.notify net_db.block_header_db.table state.gid hash block >>= fun () -> Lwt.return_unit | Get_operations (net_id, hashes) -> may_handle state net_id @@ fun net_db -> (* TODO: only answers for prevalidated operations *) Lwt_list.iter_p (fun hash -> Raw_operation.Table.read_opt net_db.operation_db.table hash >|= function | None -> () | Some p -> ignore @@ P2p.try_send global_db.p2p state.conn (Operation p)) hashes | Operation operation -> may_handle state operation.shell.net_id @@ fun net_db -> let hash = Operation.hash operation in Raw_operation.Table.notify net_db.operation_db.table state.gid hash operation >>= fun () -> Lwt.return_unit | Get_protocols hashes -> Lwt_list.iter_p (fun hash -> State.Protocol.read_opt global_db.disk hash >|= function | None -> () | Some p -> ignore @@ P2p.try_send global_db.p2p state.conn (Protocol p)) hashes | Protocol protocol -> let hash = Protocol.hash protocol in Raw_protocol.Table.notify global_db.protocol_db.table state.gid hash protocol >>= fun () -> Lwt.return_unit | Get_operation_hashes_for_blocks (net_id, blocks) -> may_handle state net_id @@ fun net_db -> (* TODO: Blame request of unadvertised blocks ? *) Lwt_list.iter_p (fun (hash, ofs) -> State.Block.read_opt net_db.net_state hash >>= function | None -> Lwt.return_unit | Some b -> State.Block.operation_hashes b ofs >>= fun (hashes, path) -> ignore @@ P2p.try_send global_db.p2p state.conn (Operation_hashes_for_block (net_id, hash, ofs, hashes, path)) ; Lwt.return_unit) blocks | Operation_hashes_for_block (net_id, block, ofs, ops, path) -> begin may_handle state net_id @@ fun net_db -> (* TODO early detection of non-requested list. *) let found_hash, found_ofs = Operation_list_list_hash.check_path path (Operation_list_hash.compute ops) in if found_ofs <> ofs then Lwt.return_unit else Raw_block_header.Table.read_opt net_db.block_header_db.table block >>= function | None -> Lwt.return_unit | Some bh -> if Operation_list_list_hash.compare found_hash bh.shell.operations_hash <> 0 then Lwt.return_unit else Raw_operation_hashes.Table.notify net_db.operation_hashes_db.table state.gid (block, ofs) (ops, path) >>= fun () -> Lwt.return_unit end | Get_operations_for_blocks (net_id, blocks) -> may_handle state net_id @@ fun net_db -> (* TODO: Blame request of unadvertised blocks ? *) Lwt_list.iter_p (fun (hash, ofs) -> State.Block.read_opt net_db.net_state hash >>= function | None -> Lwt.return_unit | Some b -> State.Block.operations b ofs >>= fun (hashes, path) -> ignore @@ P2p.try_send global_db.p2p state.conn (Operations_for_block (net_id, hash, ofs, hashes, path)) ; Lwt.return_unit) blocks | Operations_for_block (net_id, block, ofs, ops, path) -> may_handle state net_id @@ fun net_db -> (* TODO early detection of non-requested operations. *) let found_hash, found_ofs = Operation_list_list_hash.check_path path (Operation_list_hash.compute (List.map Operation.hash ops)) in if found_ofs <> ofs then Lwt.return_unit else Raw_block_header.Table.read_opt net_db.block_header_db.table block >>= function | None -> Lwt.return_unit | Some bh -> if Operation_list_list_hash.compare found_hash bh.shell.operations_hash <> 0 then Lwt.return_unit else Raw_operations.Table.notify net_db.operations_db.table state.gid (block, ofs) (ops, path) >>= fun () -> Lwt.return_unit let rec worker_loop global_db state = Lwt_utils.protect ~canceler:state.canceler begin fun () -> P2p.recv global_db.p2p state.conn end >>= function | Ok msg -> handle_msg global_db state msg >>= fun () -> worker_loop global_db state | Error _ -> Net_id.Table.iter (fun _ -> deactivate state) state.peer_active_nets ; P2p.Peer_id.Table.remove global_db.p2p_readers state.gid ; Lwt.return_unit let run db gid conn = let canceler = Lwt_utils.Canceler.create () in let state = { conn ; gid ; canceler ; peer_active_nets = Net_id.Table.create 17 ; worker = Lwt.return_unit ; } in Net_id.Table.iter (fun net_id _net_db -> Lwt.async begin fun () -> P2p.send db.p2p conn (Get_current_branch net_id) end) db.active_nets ; state.worker <- Lwt_utils.worker "db_network_reader" ~run:(fun () -> worker_loop db state) ~cancel:(fun () -> Lwt_utils.Canceler.cancel canceler) ; P2p.Peer_id.Table.add db.p2p_readers gid state let shutdown s = Lwt_utils.Canceler.cancel s.canceler >>= fun () -> s.worker end let active_peer_ids p2p () = List.fold_left (fun acc conn -> let { P2p.Connection_info.peer_id } = P2p.connection_info p2p conn in P2p.Peer_id.Set.add peer_id acc) P2p.Peer_id.Set.empty (P2p.connections p2p) let raw_try_send p2p peer_id msg = match P2p.find_connection p2p peer_id with | None -> () | Some conn -> ignore (P2p.try_send p2p conn msg : bool) let create disk p2p = let global_request = { data = () ; active = active_peer_ids p2p ; send = raw_try_send p2p ; } in let protocol_db = Raw_protocol.create global_request disk in let active_nets = Net_id.Table.create 17 in let p2p_readers = P2p.Peer_id.Table.create 17 in let block_input = Watcher.create_input () in let operation_input = Watcher.create_input () in let db = { p2p ; p2p_readers ; disk ; active_nets ; protocol_db ; block_input ; operation_input } in P2p.on_new_connection p2p (P2p_reader.run db) ; P2p.iter_connections p2p (P2p_reader.run db) ; db let activate ({ p2p ; active_nets } as global_db) net_state = let net_id = State.Net.id net_state in match Net_id.Table.find active_nets net_id with | exception Not_found -> let active_peers = ref P2p.Peer_id.Set.empty in let p2p_request = { data = net_id ; active = (fun () -> !active_peers) ; send = raw_try_send p2p ; } in let operation_db = Raw_operation.create ~global_input:global_db.operation_input p2p_request net_state in let block_header_db = Raw_block_header.create ~global_input:global_db.block_input p2p_request net_state in let operation_hashes_db = Raw_operation_hashes.create p2p_request net_state in let operations_db = Raw_operations.create p2p_request net_state in let net = { global_db ; operation_db ; block_header_db ; operation_hashes_db ; operations_db ; net_state ; callback = noop_callback ; active_peers ; active_connections = P2p.Peer_id.Table.create 53 ; } in P2p.iter_connections p2p (fun _peer_id conn -> Lwt.async begin fun () -> P2p.send p2p conn (Get_current_branch net_id) end) ; Net_id.Table.add active_nets net_id net ; net | net -> net let set_callback net_db callback = net_db.callback <- callback let deactivate net_db = let { active_nets ; p2p } = net_db.global_db in let net_id = State.Net.id net_db.net_state in Net_id.Table.remove active_nets net_id ; P2p.Peer_id.Table.iter (fun _peer_id reader -> P2p_reader.deactivate reader net_db ; Lwt.async begin fun () -> P2p.send p2p reader.conn (Deactivate net_id) end) net_db.active_connections ; Raw_operation.shutdown net_db.operation_db >>= fun () -> Raw_block_header.shutdown net_db.block_header_db >>= fun () -> Lwt.return_unit >>= fun () -> Lwt.return_unit let get_net { active_nets } net_id = try Some (Net_id.Table.find active_nets net_id) with Not_found -> None let disconnect { global_db = { p2p } } peer_id = match P2p.find_connection p2p peer_id with | None -> Lwt.return_unit | Some conn -> P2p.disconnect p2p conn let shutdown { p2p ; p2p_readers ; active_nets } = P2p.Peer_id.Table.fold (fun _peer_id reader acc -> P2p_reader.shutdown reader >>= fun () -> acc) p2p_readers Lwt.return_unit >>= fun () -> Net_id.Table.fold (fun _ net_db acc -> Raw_operation.shutdown net_db.operation_db >>= fun () -> Raw_block_header.shutdown net_db.block_header_db >>= fun () -> acc) active_nets Lwt.return_unit >>= fun () -> P2p.shutdown p2p >>= fun () -> Lwt.return_unit let read_all_operations net_db hash n = Lwt_list.map_p (fun i -> Raw_operations.Table.read_opt net_db.operations_db.table (hash, i)) (0 -- (n-1)) >>= fun operations -> mapi_p (fun i ops -> match ops with | Some ops -> return ops | None -> Raw_operation_hashes.Table.read net_db.operation_hashes_db.table (hash, i) >>=? fun hashes -> map_p (Raw_operation.Table.read net_db.operation_db.table) hashes) operations let commit_block net_db hash validation_result = Raw_block_header.Table.read net_db.block_header_db.table hash >>=? fun header -> read_all_operations net_db hash header.shell.validation_passes >>=? fun operations -> State.Block.store net_db.net_state header operations validation_result >>=? fun res -> Raw_block_header.Table.clear_or_cancel net_db.block_header_db.table hash ; Raw_operation_hashes.clear_all net_db.operation_hashes_db.table hash header.shell.validation_passes ; Raw_operations.clear_all net_db.operations_db.table hash header.shell.validation_passes ; (* TODO: proper handling of the operations table by the prevalidator. *) List.iter (List.iter (fun op -> Raw_operation.Table.clear_or_cancel net_db.operation_db.table (Operation.hash op))) operations ; return res let commit_invalid_block net_db hash = Raw_block_header.Table.read net_db.block_header_db.table hash >>=? fun header -> State.Block.store_invalid net_db.net_state header >>=? fun res -> Raw_block_header.Table.clear_or_cancel net_db.block_header_db.table hash ; Raw_operation_hashes.clear_all net_db.operation_hashes_db.table hash header.shell.validation_passes ; Raw_operations.clear_all net_db.operations_db.table hash header.shell.validation_passes ; return res let inject_operation net_db h op = fail_unless (Net_id.equal op.Operation.shell.net_id (State.Net.id net_db.net_state)) (failure "Inconsitent net_id in operation") >>=? fun () -> Raw_operation.Table.inject net_db.operation_db.table h op >>= fun res -> return res let inject_protocol db h p = Raw_protocol.Table.inject db.protocol_db.table h p let commit_protocol db h = Raw_protocol.Table.read db.protocol_db.table h >>=? fun p -> State.Protocol.store db.disk p >>= fun res -> Raw_protocol.Table.clear_or_cancel db.protocol_db.table h ; return (res <> None) type operation = | Blob of Operation.t | Hash of Operation_hash.t let resolve_operation net_db = function | Blob op -> fail_unless (Net_id.equal op.shell.net_id (State.Net.id net_db.net_state)) (failure "Inconsistent net_id in operation.") >>=? fun () -> return (Operation.hash op, op) | Hash oph -> Raw_operation.Table.read net_db.operation_db.table oph >>=? fun op -> return (oph, op) let inject_block db bytes operations = let hash = Block_hash.hash_bytes [bytes] in match Block_header.of_bytes bytes with | None -> failwith "Cannot parse block header." | Some block -> match get_net db block.shell.net_id with | None -> failwith "Unknown network." | Some net_db -> map_p (map_p (resolve_operation net_db)) operations >>=? fun operations -> let hashes = List.map (List.map fst) operations in let operations = List.map (List.map snd) operations in let computed_hash = Operation_list_list_hash.compute (List.map Operation_list_hash.compute hashes) in fail_when (Operation_list_list_hash.compare computed_hash block.shell.operations_hash <> 0) (Exn (Failure "Incoherent operation list")) >>=? fun () -> Raw_block_header.Table.inject net_db.block_header_db.table hash block >>= function | false -> failwith "Previously injected block." | true -> Raw_operation_hashes.inject_all net_db.operation_hashes_db.table hash hashes >>= fun _ -> Raw_operations.inject_all net_db.operations_db.table hash operations >>= fun _ -> return (hash, block) let clear_block net_db hash n = Raw_operations.clear_all net_db.operations_db.table hash n ; Raw_operation_hashes.clear_all net_db.operation_hashes_db.table hash n ; Raw_block_header.Table.clear_or_cancel net_db.block_header_db.table hash let broadcast_head net_db head mempool = let msg : Message.t = Current_head (State.Net.id net_db.net_state, head, mempool) in P2p.Peer_id.Table.iter (fun _peer_id state -> ignore (P2p.try_send net_db.global_db.p2p state.conn msg)) net_db.active_connections let watch_block_header { block_input } = Watcher.create_stream block_input let watch_operation { operation_input } = Watcher.create_stream operation_input let watch_protocol { protocol_db } = Raw_protocol.Table.watch protocol_db.table module Raw = struct type 'a t = | Bootstrap | Advertise of P2p_types.Point.t list | Message of 'a | Disconnect let encoding = P2p.Raw.encoding Message.cfg.encoding let supported_versions = Message.cfg.versions end 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 watch: t -> (key * value) Lwt_stream.t * Watcher.stopper val prefetch: t -> ?peer:P2p.Peer_id.t -> 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 end module Make (Table : Distributed_db_functors.DISTRIBUTED_DB) (Kind : sig type t val proj: t -> Table.t end) = struct type t = Kind.t type key = Table.key type value = Table.value type param = Table.param let known t k = Table.known (Kind.proj t) k type error += Missing_data = Table.Missing_data type error += Canceled = Table.Canceled type error += Timeout = Table.Timeout let read t k = Table.read (Kind.proj t) k let read_opt t k = Table.read_opt (Kind.proj t) k let read_exn t k = Table.read_exn (Kind.proj t) k let prefetch t ?peer k p = Table.prefetch (Kind.proj t) ?peer k p let fetch t ?peer ?timeout k p = Table.fetch (Kind.proj t) ?peer ?timeout k p let clear_or_cancel t k = Table.clear_or_cancel (Kind.proj t) k let inject t k v = Table.inject (Kind.proj t) k v let watch t = Table.watch (Kind.proj t) end module Block_header = Make (Raw_block_header.Table) (struct type t = net_db let proj net = net.block_header_db.table end) module Operation_hashes = Make (Raw_operation_hashes.Table) (struct type t = net_db let proj net = net.operation_hashes_db.table end) module Operations = Make (Raw_operations.Table) (struct type t = net_db let proj net = net.operations_db.table end) module Operation = Make (Raw_operation.Table) (struct type t = net_db let proj net = net.operation_db.table end) module Protocol = Make (Raw_protocol.Table) (struct type t = db let proj db = db.protocol_db.table end)