package octez-l2-libs
Octez layer2 libraries
Install
Dune Dependency
Authors
Maintainers
Sources
tezos-octez-v20.1.tag.bz2
sha256=ddfb5076eeb0b32ac21c1eed44e8fc86a6743ef18ab23fff02d36e365bb73d61
sha512=d22a827df5146e0aa274df48bc2150b098177ff7e5eab52c6109e867eb0a1f0ec63e6bfbb0e3645a6c2112de3877c91a17df32ccbff301891ce4ba630c997a65
doc/src/octez-l2-libs.scoru-wasm/host_funcs.ml.html
Source file host_funcs.ml
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copy of this software and associated documentation files (the "Software"),*) (* to deal in the Software without restriction, including without limitation *) (* the rights to use, copy, modify, merge, publish, distribute, sublicense, *) (* and/or sell copies of the Software, and to permit persons to whom the *) (* Software is furnished to do so, subject to the following conditions: *) (* *) (* The above copyright notice and this permission notice shall be included *) (* in all copies or substantial portions of the Software. *) (* *) (* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR*) (* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, *) (* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL *) (* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER*) (* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING *) (* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER *) (* DEALINGS IN THE SOFTWARE. *) (* *) (*****************************************************************************) open Tezos_webassembly_interpreter open Instance module Error = struct type t = | Store_key_too_large | Store_invalid_key | Store_not_a_value | Store_invalid_access | Store_value_size_exceeded | Memory_invalid_access | Input_output_too_large | Generic_invalid_access | Store_readonly_value | Store_not_a_node | Full_outbox | Store_invalid_subkey_index | Store_value_already_exists (** [code error] returns the error code associated to the error. *) let code = function | Store_key_too_large -> -1l | Store_invalid_key -> -2l | Store_not_a_value -> -3l | Store_invalid_access -> -4l | Store_value_size_exceeded -> -5l | Memory_invalid_access -> -6l | Input_output_too_large -> -7l | Generic_invalid_access -> -8l | Store_readonly_value -> -9l | Store_not_a_node -> -10l | Full_outbox -> -11l | Store_invalid_subkey_index -> -12l | Store_value_already_exists -> -13l end module type Memory_access = sig type t (** TODO Use the same type for offsets & memory size *) type size := int type addr := int32 val store_bytes : t -> addr -> string -> unit Lwt.t val load_bytes : t -> addr -> size -> string Lwt.t val store_num : t -> addr -> addr -> Values.num -> unit Lwt.t val bound : t -> int64 val exn_to_error : default:Error.t -> exn -> Error.t end module Memory_access_interpreter : Memory_access with type t = Instance.memory_inst = struct include Memory let exn_to_error ~(default : Error.t) exn = match exn with Memory.Bounds -> Error.Memory_invalid_access | _ -> default end exception Bad_input exception Key_too_large of int let check_key_length key_length = key_length > Durable.max_key_length let return_error e = Lwt.return (Error.code e) let extract_error_code = function | Error error -> return_error error | Ok res -> Lwt.return res let extract_error durable = function | Error error -> Lwt.return (durable, Error.code error) | Ok res -> Lwt.return res let check_memory memories = let crash_with msg = Error (Eval.Crash (Source.no_region, msg)) in match memories with | Host_funcs.No_memories_during_init -> crash_with "host functions must not access memory during initialisation" | Host_funcs.Available_memories memories when Vector.num_elements memories = 1l -> Ok memories | Host_funcs.Available_memories _ -> crash_with "caller module must have exactly 1 memory instance" let retrieve_memory memories = match check_memory memories with | Ok memories -> Vector.get 0l memories | Error exn -> raise exn type read_input_info = {level : int32; id : int32} let read_input_info_encoding = let open Data_encoding in conv (function {level; id} -> (level, id)) (fun (level, id) -> {level; id}) (obj2 (req "level" Data_encoding_utils.Little_endian.int32) (req "id" Data_encoding_utils.Little_endian.int32)) module Aux = struct module type S = sig type memory (** max size of intputs and outputs. *) val input_output_max_size : int val load_bytes : memory:memory -> addr:int32 -> size:int32 -> (string, int32) result Lwt.t (** [write_output ~output_buffer ~memory ~src ~num_bytes] reads num_bytes from the memory of module_inst starting at src and writes this to the output_buffer. It also checks that the input payload is no larger than `max_output`. It returns 0 for Ok. *) val write_output : output_buffer:Output_buffer.t -> memory:memory -> src:int32 -> num_bytes:int32 -> int32 Lwt.t (** [read_input ~input_buffer ~output_buffer ~memory ~level_offset ~id_offset ~dst ~max_bytes] reads `input_buffer` and writes its components to the memory based on the memory addreses offsets described. It also checks that the input payload is no larger than `max_input` and fails with `Input_output_too_large` otherwise. It returns the size of the payload. Note also that, if the level increases this function also updates the level of the output buffer and resets its id to zero. *) val read_input : input_buffer:Input_buffer.t -> memory:memory -> info_addr:int32 -> dst:int32 -> max_bytes:int32 -> int32 Lwt.t val store_exists : durable:Durable.t -> memory:memory -> key_offset:int32 -> key_length:int32 -> int32 Lwt.t val store_has : durable:Durable.t -> memory:memory -> key_offset:int32 -> key_length:int32 -> int32 Lwt.t val generic_store_delete : kind:Durable.kind -> durable:Durable.t -> memory:memory -> key_offset:int32 -> key_length:int32 -> (Durable.t * int32) Lwt.t val store_copy : durable:Durable.t -> memory:memory -> from_key_offset:int32 -> from_key_length:int32 -> to_key_offset:int32 -> to_key_length:int32 -> (Durable.t * int32) Lwt.t val store_move : durable:Durable.t -> memory:memory -> from_key_offset:int32 -> from_key_length:int32 -> to_key_offset:int32 -> to_key_length:int32 -> (Durable.t * int32) Lwt.t val store_create : durable:Durable.t -> memory:memory -> key_offset:int32 -> key_length:int32 -> size:int32 -> (Durable.t * int32) Lwt.t val store_value_size : durable:Durable.t -> memory:memory -> key_offset:int32 -> key_length:int32 -> int32 Lwt.t val store_read : durable:Durable.t -> memory:memory -> key_offset:int32 -> key_length:int32 -> value_offset:int32 -> dest:int32 -> max_bytes:int32 -> int32 Lwt.t val store_write : durable:Durable.t -> memory:memory -> key_offset:int32 -> key_length:int32 -> value_offset:int32 -> src:int32 -> num_bytes:int32 -> (Durable.t * int32) Lwt.t val store_list_size : durable:Durable.t -> memory:memory -> key_offset:int32 -> key_length:int32 -> (Durable.t * int64) Lwt.t val store_get_nth_key : durable:Durable.t -> memory:memory -> key_offset:int32 -> key_length:int32 -> index:int64 -> dst:int32 -> max_size:int32 -> int32 Lwt.t val store_get_hash : durable:Durable.t -> memory:memory -> key_offset:int32 -> key_length:int32 -> dst:int32 -> max_size:int32 -> int32 Lwt.t val reveal : memory:memory -> dst:int32 -> max_bytes:int32 -> payload:bytes -> int32 Lwt.t val read_mem_for_debug : memory:memory -> src:int32 -> num_bytes:int32 -> string Lwt.t val write_debug : implem:Builtins.write_debug -> memory:memory -> src:int32 -> num_bytes:int32 -> unit Lwt.t end module Make (M : Memory_access) : S with type memory = M.t = struct type memory = M.t let input_output_max_size = 4096 let guard func = let open Lwt_result_syntax in Lwt.catch (fun () -> let*! res = func () in return res) (function | Durable.Out_of_bounds _ -> fail Error.Store_invalid_access | Durable.Readonly_value -> fail Error.Store_readonly_value | Durable.Invalid_key _ -> fail Error.Store_invalid_key | Durable.Value_not_found -> fail Error.Store_not_a_value | Durable.Tree_not_found -> fail Error.Store_not_a_node | Durable.IO_too_large -> fail Error.Input_output_too_large | Durable.Index_too_large _ -> fail Error.Store_invalid_subkey_index | Output_buffer.Full_outbox -> fail Error.Full_outbox | exn -> fail @@ M.exn_to_error ~default:Error.Generic_invalid_access exn) module M = struct include M let load_bytes mem addr size = guard @@ fun () -> M.load_bytes mem addr size let store_bytes mem addr data = guard @@ fun () -> M.store_bytes mem addr data end let load_bytes ~memory ~addr ~size = let open Lwt_result_syntax in Lwt_result.map_error Error.code @@ let size = Int32.to_int size in if size > input_output_max_size then fail Error.Input_output_too_large else M.load_bytes memory addr size let load_key_from_memory key_offset key_length memory = let open Lwt_result_syntax in let key_length = Int32.to_int key_length in if check_key_length key_length then fail Error.Store_key_too_large else let* key = M.load_bytes memory key_offset key_length in guard (fun () -> Lwt.return (Durable.key_of_string_exn key)) (* [check_address memory address length] checks a value of size [length] can be safely stored at the [address] in the [memory]. *) let check_address memory address length = let open Result_syntax in let size = M.bound memory in let address = I64_convert.extend_i32_u address in let* length = if length < 0l then fail Error.Memory_invalid_access else return (Int64.of_int32 length) in if Int64.add address length < size then return_unit else fail Error.Memory_invalid_access let read_input ~input_buffer ~memory ~info_addr ~dst ~max_bytes = let open Lwt_result_syntax in let*! res = Lwt.catch (fun () -> (* Check the input info can be safely stored in the memory at the given address. *) let*? () = match Data_encoding.Binary.maximum_length read_input_info_encoding with | Some length -> check_address memory info_addr (Int32.of_int length) | None -> (* According to the representation of read_input_info the size is always fixed (8 bytes), there's no reason this value can fail. *) Error Error.Generic_invalid_access in (* We never read more than the maximum bytes expected from the protocol. Contrary to `write_output` were the control of the size of the output is managed by the kernel and can be bigger than the protocol accepted value, this does not lead to an error since the value is enforced by the protocol. This is purely defensive. *) let max_bytes = Int32.min (Int32.of_int input_output_max_size) max_bytes in (* Check the input payload can be safely stored in the memory at the given address and with the maximum expected size. *) let*? () = check_address memory dst max_bytes in (* Once we know the input can be contained in the memory, we can safely dequeue it. *) let*! {raw_level; message_counter; payload} = Input_buffer.dequeue input_buffer in let input_size = Bytes.length payload in let input_size = if Tezos_webassembly_interpreter.I32.le_u max_bytes (Int32.of_int input_size) then Int32.to_int max_bytes else input_size in (* [input_size] is at most 4,096 bytes (enforced by the protocol), so [Bytes.sub] won't raise an exception. *) let payload = Bytes.sub payload 0 input_size in let* () = M.store_bytes memory dst (Bytes.to_string payload) in let* () = M.store_bytes memory info_addr (Data_encoding.Binary.to_string_exn read_input_info_encoding {level = raw_level; id = Z.to_int32 message_counter}) in return (Int32.of_int input_size)) (fun exn -> match exn with | Input_buffer.Dequeue_from_empty_queue -> return 0l | _ -> fail Error.Generic_invalid_access) in extract_error_code res let write_output ~output_buffer ~memory ~src ~num_bytes = let open Lwt_result_syntax in let*! res = if num_bytes > Int32.of_int input_output_max_size then fail Error.Input_output_too_large else let num_bytes = Int32.to_int num_bytes in let* payload = M.load_bytes memory src num_bytes in let* Output_buffer.{outbox_level = _; message_index = _} = guard (fun () -> Output_buffer.push_message output_buffer (Bytes.of_string payload)) in return 0l in extract_error_code res let store_exists ~durable ~memory ~key_offset ~key_length = let open Lwt_result_syntax in let*! res = let* key = load_key_from_memory key_offset key_length memory in let*! res = Durable.exists durable key in return (if res then 1l else 0l) in extract_error_code res let store_has_unknown_key = 0l let store_has_value_only = 1l let store_has_subtrees_only = 2l let store_has_value_and_subtrees = 3l let store_has ~durable ~memory ~key_offset ~key_length = let open Lwt_result_syntax in let*! res = let* key = load_key_from_memory key_offset key_length memory in let*! value_opt = Durable.find_value durable key in let*! num_subtrees = Durable.count_subtrees durable key in match (value_opt, num_subtrees) with | None, 0 -> return store_has_unknown_key | Some _, 1 -> return store_has_value_only | None, _ -> return store_has_subtrees_only | _ -> return store_has_value_and_subtrees in extract_error_code res let generic_store_delete ~kind ~durable ~memory ~key_offset ~key_length = let open Lwt_result_syntax in let*! res = let* key = load_key_from_memory key_offset key_length memory in let+ durable = guard (fun () -> Durable.delete ~kind durable key) in (durable, 0l) in extract_error durable res let store_list_size ~durable ~memory ~key_offset ~key_length = let open Lwt_result_syntax in let*! res = let* key = load_key_from_memory key_offset key_length memory in let+ num_subtrees = guard (fun () -> Durable.count_subtrees durable key) in (durable, I64.of_int_s num_subtrees) in match res with | Error error -> Lwt.return (durable, Int64.of_int32 (Error.code error)) | Ok res -> Lwt.return res let store_copy ~durable ~memory ~from_key_offset ~from_key_length ~to_key_offset ~to_key_length = let open Lwt_result_syntax in let*! res = let* from_key = load_key_from_memory from_key_offset from_key_length memory in let* to_key = load_key_from_memory to_key_offset to_key_length memory in let+ durable = guard (fun () -> Durable.copy_tree_exn durable from_key to_key) in (durable, 0l) in extract_error durable res let store_move ~durable ~memory ~from_key_offset ~from_key_length ~to_key_offset ~to_key_length = let open Lwt_result_syntax in let*! res = let* from_key = load_key_from_memory from_key_offset from_key_length memory in let* to_key = load_key_from_memory to_key_offset to_key_length memory in let+ durable = guard (fun () -> Durable.move_tree_exn durable from_key to_key) in (durable, 0l) in extract_error durable res let store_create ~durable ~memory ~key_offset ~key_length ~size = let open Lwt_result_syntax in let*! res = let* key = load_key_from_memory key_offset key_length memory in let* () = (* Internally there's no distinction between signed and unsigned value, as such a negative value can be considered as an unsigned 32 bits integer. By convention and construction, we cannot have values above Int32.max_int (`store_value_size` returns a size up tp Int32.max_int, the negative values are error codes, `store_write` checks that the offset + bytes are always within [0 .. Int32.max_int]). The error stating the size exceeded is then correct. *) if size < Int32.zero then fail Error.Store_value_size_exceeded else return_unit in let* allocated_durable = guard (fun () -> Durable.create_value_exn durable key (Int64.of_int32 size)) in match allocated_durable with | None -> fail Error.Store_value_already_exists | Some durable -> return (durable, 0l) in extract_error durable res let store_value_size_aux ~durable ~key = let open Lwt_result_syntax in let* bytes = guard (fun () -> Durable.find_value durable key) in match bytes with | Some bytes -> let size = Tezos_lazy_containers.Chunked_byte_vector.length bytes in return (Int64.to_int32 size) | None -> fail Error.Store_not_a_value let store_value_size ~durable ~memory ~key_offset ~key_length = let open Lwt_result_syntax in let*! res = let* key = load_key_from_memory key_offset key_length memory in store_value_size_aux ~durable ~key in extract_error_code res let store_read ~durable ~memory ~key_offset ~key_length ~value_offset ~dest ~max_bytes = let open Lwt_result_syntax in let*! res = let* key = load_key_from_memory key_offset key_length memory in let value_offset = Int64.of_int32 value_offset in let max_bytes = Int64.of_int32 max_bytes in let* value = guard (fun () -> Durable.read_value_exn durable key value_offset max_bytes) in let* () = M.store_bytes memory dest value in return (Int32.of_int (String.length value)) in extract_error_code res let store_write ~durable ~memory ~key_offset ~key_length ~value_offset ~src ~num_bytes = let open Lwt_result_syntax in let*! res = let* key = load_key_from_memory key_offset key_length memory in let*! value_size_err = store_value_size_aux ~durable ~key in let* value_size = match value_size_err with | Ok s -> return s | Error Error.Store_not_a_value -> return 0l | Error e -> fail e in let* () = (* Checks for overflow. *) if value_size > Int32.add value_size num_bytes then fail Error.Store_value_size_exceeded else return_unit in let value_offset = Int64.of_int32 value_offset in let num_bytes = Int32.to_int num_bytes in let* payload = M.load_bytes memory src num_bytes in let+ durable = guard (fun () -> Durable.write_value_exn durable key value_offset payload) in (durable, 0l) in extract_error durable res let store_get_nth_key ~durable ~memory ~key_offset ~key_length ~index ~dst ~max_size = let open Lwt_result_syntax in let*! res = let index = Int64.to_int index in let* key = load_key_from_memory key_offset key_length memory in let* result = guard (fun () -> Durable.subtree_name_at durable key index) in let result_size = String.length result in let max_size = Int32.to_int max_size in let result = if max_size < result_size then String.sub result 0 max_size else result in let+ () = if result <> "" then M.store_bytes memory dst result else return_unit in Int32.of_int @@ String.length result in extract_error_code res let store_get_hash ~durable ~memory ~key_offset ~key_length ~dst ~max_size = let open Lwt_result_syntax in let*! res = let* key = load_key_from_memory key_offset key_length memory in let* result = guard (fun () -> Durable.hash_exn ~kind:Directory durable key) in let result = Data_encoding.Binary.to_string_exn Context_hash.encoding result in let result_size = String.length result in let max_size = Int32.to_int max_size in let result = if max_size < result_size then String.sub result 0 max_size else result in let+ () = if result <> "" then M.store_bytes memory dst result else return_unit in Int32.of_int @@ String.length result in extract_error_code res let reveal ~memory ~dst ~max_bytes ~payload = let open Lwt_syntax in let* res = let open Lwt_result_syntax in let payload_size = Bytes.length payload in let revealed_bytes = min payload_size (Int32.to_int max_bytes) in let payload = Bytes.sub payload 0 revealed_bytes in let+ () = M.store_bytes memory dst (Bytes.to_string payload) in Int32.of_int revealed_bytes in extract_error_code res let read_mem_for_debug ~memory ~src ~num_bytes = let open Lwt.Syntax in let get_error_message = function | err -> Printf.sprintf "Error code: %ld" @@ Error.code err in let+ result = M.load_bytes memory src (I32.to_int_u num_bytes) in Result.fold ~ok:Fun.id ~error:get_error_message result let write_debug_impl ~memory:_ ~src:_ ~num_bytes:_ = Lwt.return_unit let alternate_write_debug_impl ~f ~memory ~src ~num_bytes = let open Lwt.Syntax in let* result = read_mem_for_debug ~memory ~src ~num_bytes in Lwt.catch (fun () -> f result) (fun _exn -> Lwt_syntax.return_unit) let write_debug ~implem = match implem with | Builtins.Noop -> write_debug_impl | Printer f -> alternate_write_debug_impl ~f end include Make (Memory_access_interpreter) end module Tick_model = struct include Tezos_webassembly_interpreter.Tick_model (* Note that we cannot have negative key length since their unsigned representation is taken into account, and it will result in an error before actually reading the memory. As such, it is safe to use the "unsafe" version here. *) let read_key_in_memory key_length = of_int32_exn key_length * ticks_per_byte_read let value_written_in_memory value_size = of_int32_exn value_size * ticks_per_byte_written let value_read_from_memory value_size = of_int32_exn value_size * ticks_per_byte_read let tree_access = one let tree_move = one let tree_copy = one let tree_deletion = one let tree_write = one let tree_read = one let with_error result compute_ticks = if result < 0l then nop else compute_ticks () end let value i = Values.(Num (I32 i)) let read_input_type = let input_types = Types.[NumType I32Type; NumType I32Type; NumType I32Type] |> Vector.of_list in let output_types = Types.[NumType I32Type] |> Vector.of_list in Types.FuncType (input_types, output_types) let read_input_name = "tezos_read_input" let read_input_ticks input_size = Tick_model.( with_error input_size (fun () -> value_written_in_memory input_size) |> to_z) let read_input = Host_funcs.Host_func (fun input_buffer _output_buffer durable memories inputs -> let open Lwt.Syntax in match inputs with | [ Values.(Num (I32 info_addr)); Values.(Num (I32 dst)); Values.(Num (I32 max_bytes)); ] -> let* memory = retrieve_memory memories in let* written_bytes = Aux.read_input ~input_buffer ~memory ~info_addr ~dst ~max_bytes in Lwt.return (durable, [value written_bytes], read_input_ticks written_bytes) | _ -> raise Bad_input) let write_output_name = "tezos_write_output" let write_output_type = let input_types = Types.[NumType I32Type; NumType I32Type] |> Vector.of_list in let output_types = Types.[NumType I32Type] |> Vector.of_list in Types.FuncType (input_types, output_types) let write_output_ticks output_size = Tick_model.( with_error output_size (fun () -> value_read_from_memory output_size) |> to_z) let write_output = Host_funcs.Host_func (fun _input_buffer output_buffer durable memories inputs -> let open Lwt.Syntax in match inputs with | [Values.(Num (I32 src)); Values.(Num (I32 num_bytes))] -> let* memory = retrieve_memory memories in let* read_bytes = Aux.write_output ~output_buffer ~memory ~src ~num_bytes in Lwt.return (durable, [value read_bytes], write_output_ticks read_bytes) | _ -> raise Bad_input) let write_debug_name = "tezos_write_debug" let write_debug_type = let input_types = Types.[NumType I32Type; NumType I32Type] |> Vector.of_list in let output_types = Vector.empty () in Types.FuncType (input_types, output_types) (* [write_debug ~debug] accepts a pointer to the start of a sequence of bytes, and a length. The PVM, however, does not check that these are valid: from its point of view, [write_debug] is a no-op. *) let write_debug ~implem = let open Lwt.Syntax in let run = Aux.write_debug ~implem in Host_funcs.Host_func (fun _input_buffer _output_buffer durable memories inputs -> let* memory = retrieve_memory memories in match inputs with | [Values.(Num (I32 src)); Values.(Num (I32 num_bytes))] -> let+ () = run ~memory ~src ~num_bytes in (* Write_debug is considered a no-op, it shouldn't take more than the default ticks. *) (durable, [], Tick_model.(to_z nop)) | _ -> raise Bad_input) let store_exists_name = "tezos_store_exists" let store_exists_type = let input_types = Types.[NumType I32Type; NumType I32Type] |> Vector.of_list in let output_types = Types.[NumType I32Type] |> Vector.of_list in Types.FuncType (input_types, output_types) let store_exists_ticks key_size result = Tick_model.( with_error result (fun () -> read_key_in_memory key_size + tree_access) |> to_z) let store_exists = Host_funcs.Host_func (fun _input_buffer _output_buffer durable memories inputs -> let open Lwt.Syntax in match inputs with | [Values.(Num (I32 key_offset)); Values.(Num (I32 key_length))] -> let* memory = retrieve_memory memories in let+ r = Aux.store_exists ~durable:(Durable.of_storage_exn durable) ~memory ~key_offset ~key_length in (durable, [value r], store_exists_ticks key_length r) | _ -> raise Bad_input) let store_has_name = "tezos_store_has" let store_has_type = let input_types = Types.[NumType I32Type; NumType I32Type] |> Vector.of_list in let output_types = Types.[NumType I32Type] |> Vector.of_list in Types.FuncType (input_types, output_types) let store_has_ticks key_size result = Tick_model.( with_error result (fun () -> read_key_in_memory key_size + tree_access) |> to_z) let store_has = Host_funcs.Host_func (fun _input_buffer _output_buffer durable memories inputs -> let open Lwt.Syntax in match inputs with | [Values.(Num (I32 key_offset)); Values.(Num (I32 key_length))] -> let* memory = retrieve_memory memories in let+ r = Aux.store_has ~durable:(Durable.of_storage_exn durable) ~memory ~key_offset ~key_length in (durable, [value r], store_has_ticks key_length r) | _ -> raise Bad_input) let store_delete_ticks key_size result = Tick_model.( with_error result (fun () -> read_key_in_memory key_size + tree_deletion) |> to_z) let generic_store_delete ~kind = Host_funcs.Host_func (fun _input_buffer _output_buffer durable memories inputs -> match inputs with | [Values.(Num (I32 key_offset)); Values.(Num (I32 key_length))] -> let open Lwt.Syntax in let* memory = retrieve_memory memories in let+ durable, code = Aux.generic_store_delete ~kind ~durable:(Durable.of_storage_exn durable) ~memory ~key_offset ~key_length in ( Durable.to_storage durable, [value code], store_delete_ticks key_length code ) | _ -> raise Bad_input) let store_delete_name = "tezos_store_delete" let store_delete_type = let input_types = Types.[NumType I32Type; NumType I32Type] |> Vector.of_list in let output_types = Vector.of_list [Types.NumType I32Type] in Types.FuncType (input_types, output_types) let store_delete = generic_store_delete ~kind:Durable.Directory let store_delete_value_name = "tezos_store_delete_value" let store_delete_value_type = store_delete_type let store_delete_value = generic_store_delete ~kind:Durable.Value let store_create_name = "tezos_store_create" let store_create_type = let open Instance in let input_types = Types.[NumType I32Type; NumType I32Type; NumType I32Type] |> Vector.of_list in let output_types = Vector.of_list Types.[NumType I32Type] in Types.FuncType (input_types, output_types) (* `store_create` does not write anything, simply allocates a new value in the storage. As such, it doesn't need to be tickified more than reading the key and accessing the durable storage. *) let store_create_ticks key_size result = Tick_model.( with_error result (fun () -> read_key_in_memory key_size + tree_access) |> to_z) let store_create = let open Lwt_syntax in let open Values in Host_funcs.Host_func (fun _input _output durable memories inputs -> match inputs with | [Num (I32 key_offset); Num (I32 key_length); Num (I32 size)] -> let* memory = retrieve_memory memories in let+ durable, res = Aux.store_create ~durable:(Durable.of_storage_exn durable) ~memory ~key_offset ~key_length ~size in ( Durable.to_storage durable, [value res], store_create_ticks key_length res ) | _ -> raise Bad_input) let store_value_size_name = "tezos_store_value_size" let store_value_size_type = let open Instance in let input_types = Types.[NumType I32Type; NumType I32Type] |> Vector.of_list in let output_types = Vector.of_list Types.[NumType I32Type] in Types.FuncType (input_types, output_types) let store_value_size_ticks key_size result = Tick_model.( with_error result (fun () -> read_key_in_memory key_size + tree_access) |> to_z) let store_value_size = let open Lwt_syntax in let open Values in Host_funcs.Host_func (fun _input _output durable memories inputs -> match inputs with | [Num (I32 key_offset); Num (I32 key_length)] -> let* memory = retrieve_memory memories in let+ res = Aux.store_value_size ~durable:(Durable.of_storage_exn durable) ~memory ~key_offset ~key_length in (durable, [value res], store_value_size_ticks key_length res) | _ -> raise Bad_input) let store_list_size_name = "tezos_store_list_size" let store_list_size_type = let open Instance in let input_types = Types.[NumType I32Type; NumType I32Type] |> Vector.of_list in let output_types = Types.[NumType I64Type] |> Vector.of_list in Types.FuncType (input_types, output_types) let store_list_size_ticks key_size result = Tick_model.( with_error result (fun () -> read_key_in_memory key_size + tree_access) |> to_z) let store_list_size = Host_funcs.Host_func (fun _input_buffer _output_buffer durable memories inputs -> let open Lwt.Syntax in match inputs with | [Values.(Num (I32 key_offset)); Values.(Num (I32 key_length))] -> let* memory = retrieve_memory memories in let+ durable, result = Aux.store_list_size ~durable:(Durable.of_storage_exn durable) ~memory ~key_offset ~key_length in ( Durable.to_storage durable, [Values.(Num (I64 result))], store_list_size_ticks key_length (Int64.to_int32 result) ) | _ -> raise Bad_input) let store_get_nth_key_name = "tezos_store_get_nth_key_list" let store_get_nth_key_type = let input_types = Types. [ NumType I32Type; NumType I32Type; NumType I64Type; NumType I32Type; NumType I32Type; ] |> Vector.of_list in let output_types = Types.[NumType I32Type] |> Vector.of_list in Types.FuncType (input_types, output_types) let store_get_nth_key_ticks key_size result = Tick_model.( with_error result (fun () -> read_key_in_memory key_size + tree_access) |> to_z) let store_get_nth_key = Host_funcs.Host_func (fun _input_buffer _output_buffer durable memories inputs -> let open Lwt.Syntax in match inputs with | Values. [ Num (I32 key_offset); Num (I32 key_length); Num (I64 index); Num (I32 dst); Num (I32 max_size); ] -> let* memory = retrieve_memory memories in let+ result = Aux.store_get_nth_key ~durable:(Durable.of_storage_exn durable) ~memory ~key_offset ~key_length ~index ~dst ~max_size in (durable, [value result], store_get_nth_key_ticks key_length result) | _ -> raise Bad_input) let store_get_hash_name = "tezos_internal_store_get_hash" let store_get_hash_type = let input_types = Types.[NumType I32Type; NumType I32Type; NumType I32Type; NumType I32Type] |> Vector.of_list in let output_types = Types.[NumType I32Type] |> Vector.of_list in Types.FuncType (input_types, output_types) let store_get_hash_ticks key_size result = Tick_model.( with_error result (fun () -> read_key_in_memory key_size + tree_access) |> to_z) let store_get_hash = Host_funcs.Host_func (fun _input_buffer _output_buffer durable memories inputs -> let open Lwt.Syntax in match inputs with | Values. [ Num (I32 key_offset); Num (I32 key_length); Num (I32 dst); Num (I32 max_size); ] -> let* memory = retrieve_memory memories in let+ result = Aux.store_get_hash ~durable:(Durable.of_storage_exn durable) ~memory ~key_offset ~key_length ~dst ~max_size in (durable, [value result], store_get_hash_ticks key_length result) | _ -> raise Bad_input) let store_copy_name = "tezos_store_copy" let store_copy_type = let open Instance in let input_types = Types.[NumType I32Type; NumType I32Type; NumType I32Type; NumType I32Type] |> Vector.of_list in let output_types = Vector.of_list Types.[NumType I32Type] in Types.FuncType (input_types, output_types) let store_copy_ticks from_key_size to_key_size result = Tick_model.( with_error result (fun () -> read_key_in_memory from_key_size + read_key_in_memory to_key_size + tree_copy) |> to_z) let store_copy = Host_funcs.Host_func (fun _input_buffer _output_buffer durable memories inputs -> match inputs with | [ Values.(Num (I32 from_key_offset)); Values.(Num (I32 from_key_length)); Values.(Num (I32 to_key_offset)); Values.(Num (I32 to_key_length)); ] -> let open Lwt.Syntax in let* memory = retrieve_memory memories in let durable = Durable.of_storage_exn durable in let+ durable, code = Aux.store_copy ~durable ~memory ~from_key_offset ~from_key_length ~to_key_offset ~to_key_length in ( Durable.to_storage durable, [value code], store_copy_ticks from_key_length to_key_length code ) | _ -> raise Bad_input) let store_move_name = "tezos_store_move" let store_move_type = let open Instance in let input_types = Types.[NumType I32Type; NumType I32Type; NumType I32Type; NumType I32Type] |> Vector.of_list in let output_types = Vector.of_list Types.[NumType I32Type] in Types.FuncType (input_types, output_types) let store_move_ticks from_key_size to_key_size result = Tick_model.( with_error result (fun () -> read_key_in_memory from_key_size + read_key_in_memory to_key_size + tree_move) |> to_z) let store_move = Host_funcs.Host_func (fun _input_buffer _output_buffer durable memories inputs -> match inputs with | [ Values.(Num (I32 from_key_offset)); Values.(Num (I32 from_key_length)); Values.(Num (I32 to_key_offset)); Values.(Num (I32 to_key_length)); ] -> let open Lwt.Syntax in let* memory = retrieve_memory memories in let durable = Durable.of_storage_exn durable in let+ durable, code = Aux.store_move ~durable ~memory ~from_key_offset ~from_key_length ~to_key_offset ~to_key_length in ( Durable.to_storage durable, [value code], store_move_ticks to_key_length from_key_length code ) | _ -> raise Bad_input) let store_read_name = "tezos_store_read" let store_read_type = let input_types = Types. [ NumType I32Type; NumType I32Type; NumType I32Type; NumType I32Type; NumType I32Type; ] |> Vector.of_list in let output_types = Vector.of_list Types.[NumType I32Type] in Types.FuncType (input_types, output_types) let store_read_ticks key_size value_size = Tick_model.( with_error value_size (fun () -> read_key_in_memory key_size + tree_access + value_written_in_memory value_size) |> to_z) let store_read = Host_funcs.Host_func (fun _input_buffer _output_buffer durable memories inputs -> match inputs with | [ Values.(Num (I32 key_offset)); Values.(Num (I32 key_length)); Values.(Num (I32 value_offset)); Values.(Num (I32 dest)); Values.(Num (I32 max_bytes)); ] -> let open Lwt.Syntax in let* memory = retrieve_memory memories in let+ len = Aux.store_read ~durable:(Durable.of_storage_exn durable) ~memory ~key_offset ~key_length ~value_offset ~dest ~max_bytes in (durable, [value len], store_read_ticks key_length len) | _ -> raise Bad_input) let reveal_preimage_name = "tezos_reveal_preimage" let reveal_preimage_type = let input_types = Types.[NumType I32Type; NumType I32Type; NumType I32Type; NumType I32Type] |> Vector.of_list in let output_types = Types.[NumType I32Type] |> Vector.of_list in Types.FuncType (input_types, output_types) let reveal_preimage_parse_args memories args = match args with | Values. [ Num (I32 hash_addr); Num (I32 hash_size); Num (I32 base); Num (I32 max_bytes); ] -> let open Lwt_result_syntax in let*! memory = retrieve_memory memories in let* hash = Aux.load_bytes ~memory ~addr:hash_addr ~size:hash_size in Lwt_result.return (Wasm_pvm_state.reveal_raw_data hash, Host_funcs.{base; max_bytes}) | _ -> raise Bad_input let reveal_preimage = Host_funcs.Reveal_func reveal_preimage_parse_args let reveal_metadata_name = "tezos_reveal_metadata" let reveal_metadata_type = let input_types = Types.[NumType I32Type; NumType I32Type] |> Vector.of_list in let output_types = Types.[NumType I32Type] |> Vector.of_list in Types.FuncType (input_types, output_types) (* The rollup address is a 20-byte hash. The origination level is a 4-byte (32bit) integer. *) let metadata_size = Int32.add 20l 4l let reveal_metadata_parse_args _memories args = match args with | Values.[Num (I32 base); Num (I32 max_bytes)] -> Lwt.return (Ok (Wasm_pvm_state.reveal_metadata, Host_funcs.{base; max_bytes})) | _ -> raise Bad_input let reveal_metadata = Host_funcs.Reveal_func reveal_metadata_parse_args let reveal_raw_name = "tezos_reveal" let reveal_raw_type = let input_types = Types.[NumType I32Type; NumType I32Type; NumType I32Type; NumType I32Type] |> Vector.of_list in let output_types = Types.[NumType I32Type] |> Vector.of_list in Types.FuncType (input_types, output_types) let reveal_raw_parse_args memories args = match args with | Values. [ Num (I32 payload_addr); Num (I32 payload_size); Num (I32 destination_addr); Num (I32 max_bytes); ] -> let open Lwt_result_syntax in let*! memory = retrieve_memory memories in let* payload = Aux.load_bytes ~memory ~addr:payload_addr ~size:payload_size in Lwt_result.return ( Host_funcs.(Reveal_raw payload), Host_funcs.{base = destination_addr; max_bytes} ) | _ -> raise Bad_input let reveal_raw = Host_funcs.Reveal_func reveal_raw_parse_args let store_write_name = "tezos_write_read" let store_write_type = let input_types = Types. [ NumType I32Type; NumType I32Type; NumType I32Type; NumType I32Type; NumType I32Type; ] |> Vector.of_list in let output_types = Vector.of_list Types.[NumType I32Type] in Types.FuncType (input_types, output_types) let store_write_ticks key_size value_size result = Tick_model.( with_error result (fun () -> read_key_in_memory key_size + tree_access + value_read_from_memory value_size) |> to_z) let store_write = Host_funcs.Host_func (fun _input_buffer _output_buffer durable memories inputs -> match inputs with | [ Values.(Num (I32 key_offset)); Values.(Num (I32 key_length)); Values.(Num (I32 value_offset)); Values.(Num (I32 src)); Values.(Num (I32 num_bytes)); ] -> let open Lwt.Syntax in let* memory = retrieve_memory memories in let durable = Durable.of_storage_exn durable in let+ durable, code = Aux.store_write ~durable ~memory ~key_offset ~key_length ~value_offset ~src ~num_bytes in ( Durable.to_storage durable, [value code], store_write_ticks key_length num_bytes code ) | _ -> raise Bad_input) let lookup_opt ~version name = let v1_and_above ty name = match version with | Wasm_pvm_state.V0 -> None | V1 | V2 | V3 | V4 -> Some (ExternFunc (HostFunc (ty, name))) in let v2_and_above ty name = match version with | Wasm_pvm_state.V0 | V1 -> None | V2 | V3 | V4 -> Some (ExternFunc (HostFunc (ty, name))) in let v3_and_above ty name = match version with | Wasm_pvm_state.V0 | V1 | V2 -> None | V3 | V4 -> Some (ExternFunc (HostFunc (ty, name))) in match name with | "read_input" -> Some (ExternFunc (HostFunc (read_input_type, read_input_name))) | "write_output" -> Some (ExternFunc (HostFunc (write_output_type, write_output_name))) | "write_debug" -> Some (ExternFunc (HostFunc (write_debug_type, write_debug_name))) | "store_has" -> Some (ExternFunc (HostFunc (store_has_type, store_has_name))) | "store_list_size" -> Some (ExternFunc (HostFunc (store_list_size_type, store_list_size_name))) | "store_get_nth_key" -> Some (ExternFunc (HostFunc (store_get_nth_key_type, store_get_nth_key_name))) | "store_delete" -> Some (ExternFunc (HostFunc (store_delete_type, store_delete_name))) | "store_delete_value" -> v1_and_above store_delete_value_type store_delete_value_name | "store_copy" -> Some (ExternFunc (HostFunc (store_copy_type, store_copy_name))) | "store_move" -> Some (ExternFunc (HostFunc (store_move_type, store_move_name))) | "store_value_size" -> Some (ExternFunc (HostFunc (store_value_size_type, store_value_size_name))) | "reveal_preimage" -> Some (ExternFunc (HostFunc (reveal_preimage_type, reveal_preimage_name))) | "reveal_metadata" -> Some (ExternFunc (HostFunc (reveal_metadata_type, reveal_metadata_name))) | "store_read" -> Some (ExternFunc (HostFunc (store_read_type, store_read_name))) | "store_write" -> Some (ExternFunc (HostFunc (store_write_type, store_write_name))) | "__internal_store_get_hash" -> v1_and_above store_get_hash_type store_get_hash_name | "store_create" -> v1_and_above store_create_type store_create_name | "store_exists" -> v2_and_above store_exists_type store_exists_name | "reveal" -> v3_and_above reveal_raw_type reveal_raw_name | _ -> None let lookup ~version name = match lookup_opt ~version name with Some f -> f | None -> raise Not_found let base = List.fold_left (fun registry (global_name, implem) -> Host_funcs.with_host_function ~global_name ~implem registry) Host_funcs.empty_builder [ (read_input_name, read_input); (write_output_name, write_output); (store_has_name, store_has); (store_list_size_name, store_list_size); (store_get_nth_key_name, store_get_nth_key); (store_delete_name, store_delete); (store_copy_name, store_copy); (store_move_name, store_move); (store_value_size_name, store_value_size); (reveal_preimage_name, reveal_preimage); (reveal_metadata_name, reveal_metadata); (store_read_name, store_read); (store_write_name, store_write); ] let with_write_debug ~write_debug:implem builder = Host_funcs.with_host_function ~global_name:write_debug_name ~implem:(write_debug ~implem) builder let registry_V0 ~write_debug = Host_funcs.(base |> with_write_debug ~write_debug |> construct) let registry_V0_noop = registry_V0 ~write_debug:Noop let base_V1 = Host_funcs.( base |> with_host_function ~global_name:store_get_hash_name ~implem:store_get_hash |> with_host_function ~global_name:store_delete_value_name ~implem:store_delete_value |> with_host_function ~global_name:store_create_name ~implem:store_create) let registry_V1 ~write_debug = Host_funcs.(base_V1 |> with_write_debug ~write_debug |> construct) let registry_V1_noop = registry_V1 ~write_debug:Noop let base_V2 = Host_funcs.( base_V1 |> with_host_function ~global_name:store_exists_name ~implem:store_exists) let registry_V2 ~write_debug = Host_funcs.(base_V2 |> with_write_debug ~write_debug |> construct) let registry_V2_noop = registry_V2 ~write_debug:Noop let base_V3 = Host_funcs.( base_V2 |> with_host_function ~global_name:reveal_raw_name ~implem:reveal_raw) let registry_V3 ~write_debug = Host_funcs.(base_V3 |> with_write_debug ~write_debug |> construct) let registry_V3_noop = registry_V3 ~write_debug:Noop let base_V4 = base_V3 let registry_V4 ~write_debug = Host_funcs.(base_V4 |> with_write_debug ~write_debug |> construct) let registry_V4_noop = registry_V4 ~write_debug:Noop let registry ~version ~write_debug = (* We need to keep a top-level definition for the [Noop] case to be able to run the tests related to the tick models. Besides, by doing so, we should optimize (even slightly) the creation of the registry since it is done at compile time for this particular case. *) match (version, write_debug) with | Wasm_pvm_state.V0, Builtins.Noop -> registry_V0_noop | Wasm_pvm_state.V0, _ -> registry_V0 ~write_debug | Wasm_pvm_state.V1, Noop -> registry_V1_noop | Wasm_pvm_state.V1, _ -> registry_V1 ~write_debug | Wasm_pvm_state.V2, Noop -> registry_V2_noop | Wasm_pvm_state.V2, _ -> registry_V2 ~write_debug | Wasm_pvm_state.V3, Noop -> registry_V3_noop | Wasm_pvm_state.V3, _ -> registry_V3 ~write_debug | Wasm_pvm_state.V4, Noop -> registry_V4_noop | Wasm_pvm_state.V4, _ -> registry_V4 ~write_debug module Internal_for_tests = struct let metadata_size = Int32.to_int metadata_size let write_output = Func.HostFunc (write_output_type, write_output_name) let read_input = Func.HostFunc (read_input_type, read_input_name) let store_has = Func.HostFunc (store_has_type, store_has_name) let store_exists = Func.HostFunc (store_exists_type, store_exists_name) let store_delete = Func.HostFunc (store_delete_type, store_delete_name) let store_delete_value = Func.HostFunc (store_delete_value_type, store_delete_value_name) let store_copy = Func.HostFunc (store_copy_type, store_copy_name) let store_move = Func.HostFunc (store_move_type, store_move_name) let store_create = Func.HostFunc (store_create_type, store_create_name) let store_read = Func.HostFunc (store_read_type, store_read_name) let store_write = Func.HostFunc (store_write_type, store_write_name) let store_value_size = Func.HostFunc (store_value_size_type, store_value_size_name) let store_list_size = Func.HostFunc (store_list_size_type, store_list_size_name) let store_get_nth_key = Func.HostFunc (store_get_nth_key_type, store_get_nth_key_name) let store_get_hash = Func.HostFunc (store_get_hash_type, store_get_hash_name) let write_debug = Func.HostFunc (write_debug_type, write_debug_name) end