(**************************************************************************) (* *) (* Copyright (c) 2014 - 2016. *) (* Dynamic Ledger Solutions, Inc. *) (* *) (* All rights reserved. No warranty, explicit or implicit, provided. *) (* *) (**************************************************************************) open Logging.Node.State type error += | Unknown_network of Net_id.t type error += Bad_data_dir let () = Error_monad.register_error_kind `Temporary ~id:"state.unknown_network" ~title:"Unknown network" ~description:"TODO" ~pp:(fun ppf id -> Format.fprintf ppf "Unknown network %a" Net_id.pp id) Data_encoding.(obj1 (req "net" Net_id.encoding)) (function Unknown_network x -> Some x | _ -> None) (fun x -> Unknown_network x) ; Error_monad.register_error_kind `Permanent ~id:"badDataDir" ~title:"Bad data directory" ~description:"The data directory could not be read. \ This could be because it was generated with an \ old version of the tezos-node program. \ Deleting and regenerating this directory \ may fix the problem." Data_encoding.empty (function Bad_data_dir -> Some () | _ -> None) (fun () -> Bad_data_dir) ; (** *) module Shared = struct type 'a t = { data: 'a ; lock: Lwt_mutex.t ; } let create data = { data ; lock = Lwt_mutex.create () } let use { data ; lock } f = Lwt_mutex.with_lock lock (fun () -> f data) end type global_state = { global_data: global_data Shared.t ; protocol_store: Store.Protocol.store Shared.t ; } and global_data = { nets: net_state Net_id.Table.t ; global_store: Store.t ; context_index: Context.index ; } and net_state = { global_state: global_state ; net_id: Net_id.t ; genesis: genesis ; expiration: Time.t option ; allow_forked_network: bool ; block_store: Store.Block.store Shared.t ; context_index: Context.index Shared.t ; block_watcher: block Watcher.input ; chain_state: chain_state Shared.t ; } and genesis = { time: Time.t ; block: Block_hash.t ; protocol: Protocol_hash.t ; } and chain_state = { mutable data: chain_data ; chain_store: Store.Chain.store ; } and chain_data = { current_head: block ; current_reversed_mempool: Operation_hash.t list ; } and block = { net_state: net_state ; hash: Block_hash.t ; contents: Store.Block.contents ; } let read_chain_store { chain_state } f = Shared.use chain_state begin fun state -> f state.chain_store state.data end let update_chain_store { net_id ; context_index ; chain_state } f = Shared.use chain_state begin fun state -> f state.chain_store state.data >>= fun (data, res) -> Lwt_utils.may data ~f:begin fun data -> state.data <- data ; Shared.use context_index begin fun context_index -> Context.set_head context_index net_id data.current_head.contents.context end >>= fun () -> Lwt.return_unit end >>= fun () -> Lwt.return res end type t = global_state module Locked_block = struct let store_genesis store genesis commit = let net_id = Net_id.of_block_hash genesis.block in let shell : Block_header.shell_header = { net_id ; level = 0l ; proto_level = 0 ; predecessor = genesis.block ; timestamp = genesis.time ; fitness = [] ; validation_passes = 0 ; operations_hash = Operation_list_list_hash.empty ; } in let header : Block_header.t = { shell ; proto = MBytes.create 0 } in Store.Block.Contents.store (store, genesis.block) { Store.Block.header ; message = "Genesis" ; max_operations_ttl = 0 ; context = commit } >>= fun () -> Lwt.return header end module Net = struct type nonrec genesis = genesis = { time: Time.t ; block: Block_hash.t ; protocol: Protocol_hash.t ; } let genesis_encoding = let open Data_encoding in conv (fun { time ; block ; protocol } -> (time, block, protocol)) (fun (time, block, protocol) -> { time ; block ; protocol }) (obj3 (req "timestamp" Time.encoding) (req "block" Block_hash.encoding) (req "protocol" Protocol_hash.encoding)) type t = net_state type net_state = t let allocate ~genesis ~expiration ~allow_forked_network ~current_head global_state context_index chain_store block_store = Store.Block.Contents.read_exn (block_store, current_head) >>= fun current_block -> let rec chain_state = { data = { current_head = { net_state ; hash = current_head ; contents = current_block ; } ; current_reversed_mempool = [] ; } ; chain_store ; } and net_state = { global_state ; net_id = Net_id.of_block_hash genesis.block ; chain_state = { Shared.data = chain_state ; lock = Lwt_mutex.create () } ; genesis ; expiration ; allow_forked_network ; block_store = Shared.create block_store ; context_index = Shared.create context_index ; block_watcher = Watcher.create_input () ; } in Lwt.return net_state let locked_create global_state data ?expiration ?(allow_forked_network = false) net_id genesis commit = let net_store = Store.Net.get data.global_store net_id in let block_store = Store.Block.get net_store and chain_store = Store.Chain.get net_store in Store.Net.Genesis_hash.store net_store genesis.block >>= fun () -> Store.Net.Genesis_time.store net_store genesis.time >>= fun () -> Store.Net.Genesis_protocol.store net_store genesis.protocol >>= fun () -> Store.Chain.Current_head.store chain_store genesis.block >>= fun () -> Store.Chain.Known_heads.store chain_store genesis.block >>= fun () -> begin match expiration with | None -> Lwt.return_unit | Some time -> Store.Net.Expiration.store net_store time end >>= fun () -> begin if allow_forked_network then Store.Net.Allow_forked_network.store data.global_store net_id else Lwt.return_unit end >>= fun () -> Locked_block.store_genesis block_store genesis commit >>= fun _genesis_header -> allocate ~genesis ~current_head:genesis.block ~expiration ~allow_forked_network global_state data.context_index chain_store block_store let create state ?allow_forked_network genesis = let net_id = Net_id.of_block_hash genesis.block in Shared.use state.global_data begin fun data -> if Net_id.Table.mem data.nets net_id then Pervasives.failwith "State.Net.create" else Context.commit_genesis data.context_index ~net_id ~time:genesis.time ~protocol:genesis.protocol >>= fun commit -> locked_create state data ?allow_forked_network net_id genesis commit >>= fun net -> Net_id.Table.add data.nets net_id net ; Lwt.return net end let locked_read global_state data id = let net_store = Store.Net.get data.global_store id in let block_store = Store.Block.get net_store and chain_store = Store.Chain.get net_store in Store.Net.Genesis_hash.read net_store >>=? fun genesis_hash -> Store.Net.Genesis_time.read net_store >>=? fun time -> Store.Net.Genesis_protocol.read net_store >>=? fun protocol -> Store.Net.Expiration.read_opt net_store >>= fun expiration -> Store.Net.Allow_forked_network.known data.global_store id >>= fun allow_forked_network -> let genesis = { time ; protocol ; block = genesis_hash } in Store.Chain.Current_head.read chain_store >>=? fun current_head -> try allocate ~genesis ~current_head ~expiration ~allow_forked_network global_state data.context_index chain_store block_store >>= return with Not_found -> fail Bad_data_dir let locked_read_all global_state data = Store.Net.list data.global_store >>= fun ids -> iter_p (fun id -> locked_read global_state data id >>=? fun net -> Net_id.Table.add data.nets id net ; return ()) ids let read_all state = Shared.use state.global_data begin fun data -> locked_read_all state data end let get state id = Shared.use state.global_data begin fun data -> try return (Net_id.Table.find data.nets id) with Not_found -> fail (Unknown_network id) end let all state = Shared.use state.global_data begin fun { nets } -> Lwt.return @@ Net_id.Table.fold (fun _ net acc -> net :: acc) nets [] end let id { net_id } = net_id let genesis { genesis } = genesis let expiration { expiration } = expiration let allow_forked_network { allow_forked_network } = allow_forked_network let global_state { global_state } = global_state let destroy state net = lwt_debug "destroy %a" Net_id.pp (id net) >>= fun () -> Shared.use state.global_data begin fun { global_store ; nets } -> Net_id.Table.remove nets (id net) ; Store.Net.destroy global_store (id net) >>= fun () -> Lwt.return_unit end end module Block = struct type t = block = { net_state: Net.t ; hash: Block_hash.t ; contents: Store.Block.contents ; } type block = t let compare b1 b2 = Block_hash.compare b1.hash b2.hash let equal b1 b2 = Block_hash.equal b1.hash b2.hash let hash { hash } = hash let header { contents = { header } } = header let net_state { net_state } = net_state let shell_header { contents = { header = { shell } } } = shell let net_id b = (shell_header b).net_id let timestamp b = (shell_header b).timestamp let fitness b = (shell_header b).fitness let level b = (shell_header b).level let proto_level b = (shell_header b).proto_level let validation_passes b = (shell_header b).validation_passes let message { contents = { message } } = message let max_operations_ttl { contents = { max_operations_ttl } } = max_operations_ttl let known_valid net_state hash = Shared.use net_state.block_store begin fun store -> Store.Block.Contents.known (store, hash) end let known_invalid net_state hash = Shared.use net_state.block_store begin fun store -> Store.Block.Invalid_block.known store hash end let known net_state hash = Shared.use net_state.block_store begin fun store -> Store.Block.Contents.known (store, hash) >>= fun known -> if known then Lwt.return_true else Store.Block.Invalid_block.known store hash end let read net_state hash = Shared.use net_state.block_store begin fun store -> Store.Block.Contents.read (store, hash) >>=? fun contents -> return { net_state ; hash ; contents } end let read_opt net_state hash = read net_state hash >>= function | Error _ -> Lwt.return None | Ok v -> Lwt.return (Some v) let read_exn net_state hash = Shared.use net_state.block_store begin fun store -> Store.Block.Contents.read_exn (store, hash) >>= fun contents -> Lwt.return { net_state ; hash ; contents } end (* Quick accessor to be optimized ?? *) let read_predecessor net_state hash = read net_state hash >>=? fun { contents = { header } } -> return header.shell.predecessor let read_predecessor_opt net_state hash = read_predecessor net_state hash >>= function | Error _ -> Lwt.return None | Ok v -> Lwt.return (Some v) let read_predecessor_exn net_state hash = read_exn net_state hash >>= fun { contents = { header } } -> Lwt.return header.shell.predecessor let predecessor { net_state ; contents = { header } ; hash } = if Block_hash.equal hash header.shell.predecessor then Lwt.return_none else read_exn net_state header.shell.predecessor >>= fun block -> Lwt.return (Some block) let store net_state block_header operations { Updater.context ; fitness ; message ; max_operations_ttl } = let bytes = Block_header.to_bytes block_header in let hash = Block_header.hash_raw bytes in (* let's the validator check the consistency... of fitness, level, ... *) let message = match message with | Some message -> message | None -> Format.asprintf "%a(%ld): %a" Block_hash.pp_short hash block_header.shell.level Fitness.pp fitness in Shared.use net_state.block_store begin fun store -> Store.Block.Invalid_block.known store hash >>= fun known_invalid -> fail_when known_invalid (failure "Known invalid") >>=? fun () -> Store.Block.Contents.known (store, hash) >>= fun known -> if known then return None else begin Context.commit ~time:block_header.shell.timestamp ~message context >>= fun commit -> let contents = { Store.Block.header = block_header ; message ; max_operations_ttl ; context = commit ; } in Store.Block.Contents.store (store, hash) contents >>= fun () -> let hashes = List.map (List.map Operation.hash) operations in let list_hashes = List.map Operation_list_hash.compute hashes in Lwt_list.iteri_p (fun i hashes -> let path = Operation_list_list_hash.compute_path list_hashes i in Store.Block.Operation_hashes.store (store, hash) i hashes >>= fun () -> Store.Block.Operation_path.store (store, hash) i path) hashes >>= fun () -> Lwt_list.iteri_p (fun i ops -> Store.Block.Operations.store (store, hash) i ops) operations >>= fun () -> (* Update the chain state. *) Shared.use net_state.chain_state begin fun chain_state -> let store = chain_state.chain_store in let predecessor = block_header.shell.predecessor in Store.Chain.Known_heads.remove store predecessor >>= fun () -> Store.Chain.Known_heads.store store hash end >>= fun () -> let block = { net_state ; hash ; contents } in Watcher.notify net_state.block_watcher block ; return (Some block) end end let store_invalid net_state block_header = let bytes = Block_header.to_bytes block_header in let hash = Block_header.hash_raw bytes in Shared.use net_state.block_store begin fun store -> Store.Block.Contents.known (store, hash) >>= fun known_valid -> fail_when known_valid (failure "Known valid") >>=? fun () -> Store.Block.Invalid_block.known store hash >>= fun known_invalid -> if known_invalid then return false else Store.Block.Invalid_block.store store hash { level = block_header.shell.level } >>= fun () -> return true end let watcher net_state = Watcher.create_stream net_state.block_watcher let operation_hashes { net_state ; hash ; contents } i = if i < 0 || contents.header.shell.validation_passes <= i then invalid_arg "State.Block.operations" ; Shared.use net_state.block_store begin fun store -> Store.Block.Operation_hashes.read_exn (store, hash) i >>= fun hashes -> Store.Block.Operation_path.read_exn (store, hash) i >>= fun path -> Lwt.return (hashes, path) end let all_operation_hashes { net_state ; hash ; contents } = Shared.use net_state.block_store begin fun store -> Lwt_list.map_p (Store.Block.Operation_hashes.read_exn (store, hash)) (0 -- (contents.header.shell.validation_passes - 1)) end let operations { net_state ; hash ; contents } i = if i < 0 || contents.header.shell.validation_passes <= i then invalid_arg "State.Block.operations" ; Shared.use net_state.block_store begin fun store -> Store.Block.Operation_path.read_exn (store, hash) i >>= fun path -> Store.Block.Operations.read_exn (store, hash) i >>= fun ops -> Lwt.return (ops, path) end let all_operations { net_state ; hash ; contents } = Shared.use net_state.block_store begin fun store -> Lwt_list.map_p (fun i -> Store.Block.Operations.read_exn (store, hash) i) (0 -- (contents.header.shell.validation_passes - 1)) end let context { net_state ; hash } = Shared.use net_state.block_store begin fun block_store -> Store.Block.Contents.read_exn (block_store, hash) end >>= fun { context = commit } -> Shared.use net_state.context_index begin fun context_index -> Context.checkout_exn context_index commit end let protocol_hash block = context block >>= fun context -> Context.get_protocol context let test_network block = context block >>= fun context -> Context.get_test_network context end let read_block { global_data } hash = Shared.use global_data begin fun { nets } -> Net_id.Table.fold (fun _net_id net_state acc -> acc >>= function | Some _ -> acc | None -> Block.read_opt net_state hash >>= function | None -> acc | Some block -> Lwt.return (Some block)) nets Lwt.return_none end let read_block_exn t hash = read_block t hash >>= function | None -> Lwt.fail Not_found | Some b -> Lwt.return b let fork_testnet block protocol expiration = Shared.use block.net_state.global_state.global_data begin fun data -> Block.context block >>= fun context -> Context.set_test_network context Not_running >>= fun context -> Context.set_protocol context protocol >>= fun context -> Context.commit_test_network_genesis data.context_index block.hash block.contents.header.shell.timestamp context >>=? fun (net_id, genesis, commit) -> let genesis = { block = genesis ; time = Time.add block.contents.header.shell.timestamp 1L ; protocol ; } in Net.locked_create block.net_state.global_state data net_id ~expiration genesis commit >>= fun net -> return net end module Protocol = struct let known global_state hash = Shared.use global_state.protocol_store begin fun store -> Store.Protocol.Contents.known store hash end let read global_state hash = Shared.use global_state.protocol_store begin fun store -> Store.Protocol.Contents.read store hash end let read_opt global_state hash = Shared.use global_state.protocol_store begin fun store -> Store.Protocol.Contents.read_opt store hash end let read_exn global_state hash = Shared.use global_state.protocol_store begin fun store -> Store.Protocol.Contents.read_exn store hash end let read_raw global_state hash = Shared.use global_state.protocol_store begin fun store -> Store.Protocol.RawContents.read (store, hash) end let read_raw_opt global_state hash = Shared.use global_state.protocol_store begin fun store -> Store.Protocol.RawContents.read_opt (store, hash) end let read_raw_exn global_state hash = Shared.use global_state.protocol_store begin fun store -> Store.Protocol.RawContents.read_exn (store, hash) end let store global_state p = let bytes = Protocol.to_bytes p in let hash = Protocol.hash_raw bytes in Shared.use global_state.protocol_store begin fun store -> Store.Protocol.Contents.known store hash >>= fun known -> if known then Lwt.return None else Store.Protocol.RawContents.store (store, hash) bytes >>= fun () -> Lwt.return (Some hash) end let remove global_state hash = Shared.use global_state.protocol_store begin fun store -> Store.Protocol.Contents.known store hash >>= fun known -> if known then Lwt.return_false else Store.Protocol.Contents.remove store hash >>= fun () -> Lwt.return_true end let list global_state = Shared.use global_state.protocol_store begin fun store -> Store.Protocol.Contents.fold_keys store ~init:Protocol_hash.Set.empty ~f:(fun x acc -> Lwt.return (Protocol_hash.Set.add x acc)) end end module Registred_protocol = struct module type T = sig val hash: Protocol_hash.t include Updater.NODE_PROTOCOL val complete_b58prefix : Context.t -> string -> string list Lwt.t end type t = (module T) let build_v1 hash = let (module F) = Tezos_protocol_compiler.Registerer.get_exn hash in let module Name = struct let name = Protocol_hash.to_b58check hash end in let module Env = Tezos_protocol_environment.Make(Name)() in (module struct let hash = hash module P = F(Env) include P include Updater.LiftProtocol(Name)(Env)(P) let complete_b58prefix = Env.Context.complete end : T) module VersionTable = Protocol_hash.Table let versions : (module T) VersionTable.t = VersionTable.create 20 let mem hash = VersionTable.mem versions hash || Tezos_protocol_compiler.Registerer.mem hash let get_exn hash = try VersionTable.find versions hash with Not_found -> let proto = build_v1 hash in VersionTable.add versions hash proto ; proto let get hash = try Some (get_exn hash) with Not_found -> None end module Register_embedded_protocol (Env : Updater.Node_protocol_environment_sigs.V1) (Proto : Env.Updater.PROTOCOL) (Source : sig val hash: Protocol_hash.t option val sources: Tezos_data.Protocol.t end) = struct let () = let hash = match Source.hash with | None -> Tezos_data.Protocol.hash Source.sources | Some hash -> hash in let module Name = struct let name = Protocol_hash.to_b58check hash end in (* TODO add a memory table for "embedded" sources... *) Registred_protocol.VersionTable.add Registred_protocol.versions hash (module struct let hash = hash include Proto include Updater.LiftProtocol(Name)(Env)(Proto) let complete_b58prefix = Env.Context.complete end : Registred_protocol.T) end let read ?patch_context ~store_root ~context_root () = Store.init store_root >>=? fun global_store -> Context.init ?patch_context ~root:context_root >>= fun context_index -> let global_data = { nets = Net_id.Table.create 17 ; global_store ; context_index ; } in let state = { global_data = Shared.create global_data ; protocol_store = Shared.create @@ Store.Protocol.get global_store ; } in Net.read_all state >>=? fun () -> return state let close { global_data } = Shared.use global_data begin fun { global_store } -> Store.close global_store ; Lwt.return_unit end