(**************************************************************************) (* *) (* Copyright (c) 2014 - 2016. *) (* Dynamic Ledger Solutions, Inc. *) (* *) (* All rights reserved. No warranty, explicit or implicit, provided. *) (* *) (**************************************************************************) open Error_monad open Hash open Store let (>>=) = Lwt.bind let (>|=) = Lwt.(>|=) let (//) = Filename.concat (** Basic blocks *) let genesis_block = Block_hash.of_b58check "BLockGenesisGenesisGenesisGenesisGenesisGeneskvg68z" let genesis_protocol = Protocol_hash.of_b58check "ProtoDemoDemoDemoDemoDemoDemoDemoDemoDemoDemoD3c8k9" let genesis_time = Time.of_seconds 0L let genesis = { State.Net.time = genesis_time ; block = genesis_block ; protocol = genesis_protocol ; } (** *) let wrap_store_init f base_dir = let root = base_dir // "store" in Store.init root >>= function | Ok store -> f store >>= fun () -> return () | Error err -> Format.kasprintf Pervasives.failwith "@[Cannot initialize store:@ %a@]" pp_print_error err let wrap_raw_store_init f base_dir = let root = base_dir // "store" in Raw_store.init root >>= function | Ok store -> f store >>= fun () -> return () | Error err -> Format.kasprintf Pervasives.failwith "@[Cannot initialize store:@ %a@]" pp_print_error err let test_init _ = Lwt.return_unit let net_id = State.Net_id.Id genesis_block (** Operation store *) let make proto : Store.Operation.t = { shell = { net_id } ; proto } let op1 = make (MBytes.of_string "Capadoce") let oph1 = Operation.hash op1 let op2 = make (MBytes.of_string "Kivu") let oph2 = Operation.hash op2 let check_operation s h b = Operation.Contents.read (s, h) >>= function | Ok b' when Operation.equal b b' -> Lwt.return_unit | _ -> Printf.eprintf "Error while reading operation %s\n%!" (Operation_hash.to_hex h); exit 1 let test_operation s = let s = Store.Net.get s net_id in let s = Store.Operation.get s in Operation.Contents.store (s, oph1) op1 >>= fun () -> Operation.Contents.store (s, oph2) op2 >>= fun () -> check_operation s oph1 op1 >>= fun () -> check_operation s oph2 op2 (** Block store *) let lolblock ?(operations = []) header = let operations = Operation_list_list_hash.compute [Operation_list_hash.compute operations] in { Store.Block_header.shell = { timestamp = Time.of_seconds (Random.int64 1500L) ; net_id ; predecessor = genesis_block ; operations ; fitness = [MBytes.of_string @@ string_of_int @@ String.length header; MBytes.of_string @@ string_of_int @@ 12] } ; proto = MBytes.of_string header ; } let b1 = lolblock "Blop !" let bh1 = Store.Block_header.hash b1 let b2 = lolblock "Tacatlopo" let bh2 = Store.Block_header.hash b2 let b3 = lolblock ~operations:[oph1;oph2] "Persil" let bh3 = Store.Block_header.hash b3 let bh3' = let raw = Bytes.of_string @@ Block_hash.to_string bh3 in Bytes.set raw 31 '\000' ; Bytes.set raw 30 '\000' ; Block_hash.of_string_exn @@ Bytes.to_string raw let check_block s h b = Block_header.Contents.read_opt (s, h) >>= function | Some b' when Store.Block_header.equal b b' -> Lwt.return_unit | Some b' -> Printf.eprintf "Error while reading block %s\n%!" (Block_hash.to_hex h); exit 1 | None -> Printf.eprintf "Error while reading block %s (not found)\n%!" (Block_hash.to_hex h); exit 1 let test_block s = let s = Store.Net.get s net_id in let s = Store.Block_header.get s in Block_header.Contents.store (s, bh1) b1 >>= fun () -> Block_header.Contents.store (s, bh2) b2 >>= fun () -> Block_header.Contents.store (s, bh3) b3 >>= fun () -> check_block s bh1 b1 >>= fun () -> check_block s bh2 b2 >>= fun () -> check_block s bh3 b3 let test_expand s = let s = Store.Net.get s net_id in let s = Store.Block_header.get s in Block_header.Contents.store (s, bh1) b1 >>= fun () -> Block_header.Contents.store (s, bh2) b2 >>= fun () -> Block_header.Contents.store (s, bh3) b3 >>= fun () -> Block_header.Contents.store (s, bh3') b3 >>= fun () -> Base58.complete (Block_hash.to_short_b58check bh1) >>= fun res -> Assert.equal_string_list ~msg:__LOC__ res [Block_hash.to_b58check bh1] ; Base58.complete (Block_hash.to_short_b58check bh2) >>= fun res -> Assert.equal_string_list ~msg:__LOC__ res [Block_hash.to_b58check bh2] ; Base58.complete (Block_hash.to_short_b58check bh3) >>= fun res -> Assert.equal_string_list ~msg:__LOC__ res [Block_hash.to_b58check bh3] ; Lwt.return_unit (** Generic store *) let check (type t) (module Store: Store_sigs.STORE with type t = t) (s: Store.t) k d = Store.read_opt s k >|= fun d' -> if d' <> Some d then begin Assert.fail_msg "Error while reading key %S\n%!" (String.concat Filename.dir_sep k) ; end let check_none (type t) (module Store: Store_sigs.STORE with type t = t) (s: Store.t) k = Store.read_opt s k >|= function | None -> () | Some _ -> Assert.fail_msg "Error while reading non-existent key %S\n%!" (String.concat Filename.dir_sep k) let test_generic (type t) (module Store: Store_sigs.STORE with type t = t) (s: Store.t) = Store.store s ["day";"current"] (MBytes.of_string "Mercredi") >>= fun () -> Store.store s ["day";"next"] (MBytes.of_string "Jeudi") >>= fun () -> Store.store s ["day";"truc";"chose"] (MBytes.of_string "Vendredi") >>= fun () -> check (module Store) s ["day";"current"] (MBytes.of_string "Mercredi") >>= fun () -> check (module Store) s ["day";"next"] (MBytes.of_string "Jeudi") >>= fun () -> check_none (module Store) s ["day"] let list (type t) (module Store: Store_sigs.STORE with type t = t) (s: Store.t) k = Store.fold_keys s k ~init:[] ~f:(fun k acc -> Lwt.return (k :: acc)) let test_generic_list (type t) (module Store: Store_sigs.STORE with type t = t) (s: Store.t) = Store.store s ["a"; "b"] (MBytes.of_string "Novembre") >>= fun () -> Store.store s ["a"; "c"] (MBytes.of_string "Juin") >>= fun () -> Store.store s ["a"; "d"; "e"] (MBytes.of_string "Septembre") >>= fun () -> Store.store s ["f";] (MBytes.of_string "Avril") >>= fun () -> Store.store s ["g"; "h"] (MBytes.of_string "Avril") >>= fun () -> list (module Store) s [] >>= fun l -> Assert.equal_persist_list ~msg:__LOC__ [["a";"b"];["a";"c"];["a";"d";"e"];["f"];["g";"h"]] (List.sort compare l) ; list (module Store) s ["a"] >>= fun l -> Assert.equal_persist_list ~msg:__LOC__ [["a";"b"]; ["a";"c"]; ["a";"d";"e"]] (List.sort compare l) ; list (module Store) s ["f"] >>= fun l -> Assert.equal_persist_list ~msg:__LOC__ [] l ; list (module Store) s ["g"] >>= fun l -> Assert.equal_persist_list ~msg:__LOC__ [["g";"h"]] (List.sort compare l) ; list (module Store) s ["i"] >>= fun l -> Assert.equal_persist_list ~msg:__LOC__ [] l ; Lwt.return_unit (** HashSet *) open Store_helpers let test_hashset (type t) (module Store: Store_sigs.STORE with type t = t) (s: Store.t) = let module BlockSet = Block_hash.Set in let module StoreSet = Make_buffered_set (Make_substore(Store)(struct let name = ["test_set"] end)) (Block_hash) (BlockSet) in let open BlockSet in let bhset : BlockSet.t = BlockSet.add bh2 (BlockSet.add bh1 BlockSet.empty) in StoreSet.store_all s bhset >>= fun () -> StoreSet.read_all s >>= fun bhset' -> Assert.equal_block_set ~msg:__LOC__ bhset bhset' ; let bhset2 = Pervasives.(bhset |> BlockSet.add bh3 |> BlockSet.remove bh1) in StoreSet.store_all s bhset2 >>= fun () -> StoreSet.read_all s >>= fun bhset2' -> Assert.equal_block_set ~msg:__LOC__ bhset2 bhset2' ; StoreSet.fold s BlockSet.empty (fun bh acc -> Lwt.return (BlockSet.add bh acc)) >>= fun bhset2'' -> Assert.equal_block_set ~msg:__LOC__ bhset2 bhset2'' ; Store.store s ["day";"current"] (MBytes.of_string "Mercredi") >>= fun () -> StoreSet.remove_all s >>= fun () -> StoreSet.read_all s >>= fun empty -> Assert.equal_block_set ~msg:__LOC__ BlockSet.empty empty ; check (module Store) s ["day";"current"] (MBytes.of_string "Mercredi") >>= fun () -> Lwt.return_unit (** HashMap *) let test_hashmap (type t) (module Store: Store_sigs.STORE with type t = t) (s: Store.t) = let module BlockMap = Block_hash.Map in let module StoreMap = Make_buffered_map (Make_substore(Store)(struct let name = ["test_map"] end)) (Block_hash) (Make_value(struct type t = int * char let encoding = Data_encoding.(tup2 int31 (conv int_of_char char_of_int int8)) end)) (BlockMap) in let eq = (=) in let map = Pervasives.(BlockMap.empty |> BlockMap.add bh1 (1, 'a') |> BlockMap.add bh2 (2, 'b')) in StoreMap.store_all s map >>= fun () -> StoreMap.read_all s >>= fun map' -> Assert.equal_block_map ~msg:__LOC__ ~eq map map' ; let map2 = Pervasives.(map |> BlockMap.add bh3 (3, 'c') |> BlockMap.remove bh1) in StoreMap.store_all s map2 >>= fun () -> StoreMap.read_all s >>= fun map2' -> Assert.equal_block_map ~msg:__LOC__ ~eq map2 map2' ; Lwt.return_unit (** Functors *) let test_single (type t) (module Store: Store_sigs.STORE with type t = t) (s: Store.t) = let module Single = Make_single_store (Store) (struct let name = ["plop"] end) (Make_value(struct type t = int * string let encoding = Data_encoding.(tup2 int31 string) end)) in Single.known s >>= fun known -> Assert.is_false ~msg:__LOC__ known ; Single.read_opt s >>= fun v' -> Assert.equal ~msg:__LOC__ None v' ; let v = (3, "Non!") in Single.store s v >>= fun () -> Single.known s >>= fun known -> Assert.is_true ~msg:__LOC__ known ; Single.read_opt s >>= fun v' -> Assert.equal ~msg:__LOC__ (Some v) v' ; Single.remove s >>= fun v' -> Single.known s >>= fun known -> Assert.is_false ~msg:__LOC__ known ; Single.read_opt s >>= fun v' -> Assert.equal ~msg:__LOC__ None v' ; Lwt.return_unit module Sub = Make_substore(Raw_store)(struct let name = ["plop";"plip"] end) module SubBlocks = Make_indexed_substore (Make_substore(Raw_store)(struct let name = ["blocks"] end)) (Block_hash) module SubBlocksSet = SubBlocks.Make_buffered_set (struct let name = ["test_set"] end) (Block_hash.Set) module SubBlocksMap = SubBlocks.Make_buffered_map (struct let name = ["test_map"] end) (Make_value(struct type t = int * string let encoding = Data_encoding.(tup2 int31 string) end)) (Block_hash.Map) let test_subblock s = SubBlocksSet.known s bh1 >>= fun known -> Assert.is_false ~msg:__LOC__ known ; SubBlocksSet.store s bh1 >>= fun () -> SubBlocksSet.store s bh2 >>= fun () -> SubBlocksSet.known s bh2 >>= fun known -> Assert.is_true ~msg:__LOC__ known ; SubBlocksSet.read_all s >>= fun set -> let set' = Block_hash.Set.empty |> Block_hash.Set.add bh1 |> Block_hash.Set.add bh2 in Assert.equal_block_set ~msg:__LOC__ set set' ; SubBlocksSet.remove s bh2 >>= fun () -> let set = Block_hash.Set.empty |> Block_hash.Set.add bh3' |> Block_hash.Set.add bh3 in SubBlocksSet.store_all s set >>= fun () -> SubBlocksSet.elements s >>= fun elts -> Assert.equal_block_hash_list ~msg:__LOC__ (List.sort Block_hash.compare elts) (List.sort Block_hash.compare [bh3 ; bh3']) ; SubBlocksSet.store s bh2 >>= fun () -> SubBlocksSet.remove s bh3 >>= fun () -> SubBlocksSet.elements s >>= fun elts -> Assert.equal_block_hash_list ~msg:__LOC__ (List.sort Block_hash.compare elts) (List.sort Block_hash.compare [bh2 ; bh3']) ; SubBlocksMap.known s bh1 >>= fun known -> Assert.is_false ~msg:__LOC__ known ; let v1 = (3, "Non!") and v2 = (12, "Beurk.") in SubBlocksMap.store s bh1 v1 >>= fun () -> SubBlocksMap.store s bh2 v2 >>= fun () -> SubBlocksMap.read_opt s bh1 >>= fun v1' -> SubBlocksMap.known s bh1 >>= fun known -> Assert.is_true ~msg:__LOC__ known ; let map = Block_hash.Map.empty |> Block_hash.Map.add bh1 v1 |> Block_hash.Map.add bh2 v2 in SubBlocksMap.read_all s >>= fun map' -> Assert.equal_block_map ~eq:(=) ~msg:__LOC__ map map' ; SubBlocksSet.remove_all s >>= fun () -> SubBlocksSet.elements s >>= fun elts -> Assert.equal_block_hash_list ~msg:__LOC__ elts [] ; SubBlocksMap.read_all s >>= fun map' -> Assert.equal_block_map ~eq:(=) ~msg:__LOC__ map map' ; SubBlocksSet.store s bh3 >>= fun () -> SubBlocks.indexes s >>= fun keys -> Assert.equal_block_hash_list ~msg:__LOC__ (List.sort Block_hash.compare keys) (List.sort Block_hash.compare [bh1;bh2;bh3]) ; Lwt.return_unit module SubSubBlocks = Make_indexed_substore (Make_substore(SubBlocks.Store)(struct let name = ["sub_blocks"] end)) (Block_hash) (** *) let tests_raw : (string * (Raw_store.t -> unit Lwt.t)) list = [ "init", test_init ; "generic", test_generic (module Raw_store) ; "generic_substore", test_generic (module Sub) ; "generic_indexedstore", (fun s -> test_generic (module SubBlocks.Store) (s, bh1)) ; "generic_indexedsubstore", (fun s -> test_generic (module SubSubBlocks.Store) ((s, bh1), bh2)) ; "single", test_single (module Raw_store) ; "single_substore", test_single (module Sub) ; "single_indexedstore", (fun s -> test_single (module SubBlocks.Store) (s, bh1)) ; "single_indexedsubstore", (fun s -> test_single (module SubSubBlocks.Store) ((s, bh1), bh2)) ; "generic_list", test_generic_list (module Raw_store); "generic_substore_list", test_generic_list (module Sub); "generic_indexedstore_list", (fun s -> test_generic_list (module SubBlocks.Store) (s, bh1)); "generic_indexedsubstore_list", (fun s -> test_generic_list (module SubSubBlocks.Store) ((s, bh1), bh2)) ; "hashset", test_hashset (module Raw_store) ; "hashset_substore", test_hashset (module Sub) ; "hashset_indexedstore", (fun s -> test_hashset (module SubBlocks.Store) (s, bh1)); "hashset_indexedsubstore", (fun s -> test_hashset (module SubSubBlocks.Store) ((s, bh1), bh2)) ; "hashmap", test_hashmap (module Raw_store) ; "hashmap_substore", test_hashmap (module Sub) ; "hashmap_indexedstore", (fun s -> test_hashmap (module SubBlocks.Store) (s, bh1)); "hashmap_indexedsubstore", (fun s -> test_hashmap (module SubSubBlocks.Store) ((s, bh1), bh2)) ; "subblock", test_subblock ; ] let tests : (string * (Store.t -> unit Lwt.t)) list = [ (* "expand", test_expand ; *) (* FIXME GRGR *) "operation", test_operation ; "block", test_block ; ] let () = Test.run "store." (List.map (fun (s, f) -> s, wrap_raw_store_init f) tests_raw @ List.map (fun (s, f) -> s, wrap_store_init f) tests)