(**************************************************************************) (* *) (* Copyright (c) 2014 - 2017. *) (* Dynamic Ledger Solutions, Inc. *) (* *) (* All rights reserved. No warranty, explicit or implicit, provided. *) (* *) (**************************************************************************) open State let path (b1: Block.t) (b2: Block.t) = if not (Net_id.equal (Block.net_id b1) (Block.net_id b2)) then invalid_arg "Chain_traversal.path" ; let rec loop acc current = if Block.equal b1 current then Lwt.return (Some acc) else Block.predecessor current >>= function | Some pred -> loop (current :: acc) pred | None -> Lwt.return_none in loop [] b2 let common_ancestor (b1: Block.t) (b2: Block.t) = if not ( Net_id.equal (Block.net_id b1) (Block.net_id b2)) then invalid_arg "Chain_traversal.path" ; let rec loop (b1: Block.t) (b2: Block.t) = if Block.equal b1 b2 then Lwt.return b1 else if Time.(Block.timestamp b1 <= Block.timestamp b2) then Block.predecessor b2 >>= function | None -> assert false | Some b2 -> loop b1 b2 else Block.predecessor b1 >>= function | None -> assert false | Some b1 -> loop b1 b2 in loop b1 b2 let iter_predecessors ?max ?min_fitness ?min_date heads ~f = let module Local = struct exception Exit end in let compare b1 b2 = match Fitness.compare (Block.fitness b1) (Block.fitness b2) with | 0 -> begin match Time.compare (Block.timestamp b1) (Block.timestamp b2) with | 0 -> Block.compare b1 b2 | res -> res end | res -> res in let pop, push = (* Poor-man priority queue *) let queue : Block.t list ref = ref [] in let pop () = match !queue with | [] -> None | b :: bs -> queue := bs ; Some b in let push b = let rec loop = function | [] -> [b] | b' :: bs' as bs -> let cmp = compare b b' in if cmp = 0 then bs else if cmp < 0 then b' :: loop bs' else b :: bs in queue := loop !queue in pop, push in let check_count = match max with | None -> (fun () -> ()) | Some max -> let cpt = ref 0 in fun () -> if !cpt >= max then raise Local.Exit ; incr cpt in let check_fitness = match min_fitness with | None -> (fun _ -> true) | Some min_fitness -> (fun b -> Fitness.compare min_fitness (Block.fitness b) <= 0) in let check_date = match min_date with | None -> (fun _ -> true) | Some min_date -> (fun b -> Time.(min_date <= Block.timestamp b)) in let rec loop () = match pop () with | None -> Lwt.return () | Some b -> check_count () ; f b >>= fun () -> Block.predecessor b >>= function | None -> loop () | Some p -> if check_fitness p && check_date p then push p ; loop () in List.iter push heads ; try loop () with Local.Exit -> Lwt.return () let iter_predecessors ?max ?min_fitness ?min_date heads ~f = match heads with | [] -> Lwt.return_unit | b :: _ -> let net_id = Block.net_id b in if not (List.for_all (fun b -> Net_id.equal net_id (Block.net_id b)) heads) then invalid_arg "State.Helpers.iter_predecessors" ; iter_predecessors ?max ?min_fitness ?min_date heads ~f let new_blocks ~from_block ~to_block = common_ancestor from_block to_block >>= fun ancestor -> path ancestor to_block >>= function | None -> assert false | Some path -> Lwt.return (ancestor, path) let live_blocks block n = let rec loop bacc oacc block n = Block.all_operation_hashes block >>= fun hashes -> let oacc = List.fold_left (List.fold_left (fun oacc op -> Operation_hash.Set.add op oacc)) oacc hashes in let bacc = Block_hash.Set.add (Block.hash block) bacc in if n = 0 then Lwt.return (bacc, oacc) else Block.predecessor block >>= function | None -> Lwt.return (bacc, oacc) | Some predecessor -> loop bacc oacc predecessor (pred n) in loop Block_hash.Set.empty Operation_hash.Set.empty block n