(** Headers *) let prefix_small_block = 0x80 let prefix_small_int = 0x40 let prefix_small_string = 0x20 [@@@ocaml.warning "-32"] let code_int8 = 0x00 let code_int16 = 0x01 let code_int32 = 0x02 let code_int64 = 0x03 let code_shared8 = 0x04 let code_shared16 = 0x05 let code_shared32 = 0x06 let code_double_array32_little = 0x07 let code_block32 = 0x08 let code_string8 = 0x09 let code_string32 = 0x0A let code_double_big = 0x0B let code_double_little = 0x0C let code_double_array8_big = 0x0D let code_double_array8_little = 0x0E let code_double_array32_big = 0x0F let code_codepointer = 0x10 let code_infixpointer = 0x11 let code_custom = 0x12 let code_block64 = 0x13 [@@@ocaml.warning "-37"] type code_descr = | CODE_INT8 | CODE_INT16 | CODE_INT32 | CODE_INT64 | CODE_SHARED8 | CODE_SHARED16 | CODE_SHARED32 | CODE_DOUBLE_ARRAY32_LITTLE | CODE_BLOCK32 | CODE_STRING8 | CODE_STRING32 | CODE_DOUBLE_BIG | CODE_DOUBLE_LITTLE | CODE_DOUBLE_ARRAY8_BIG | CODE_DOUBLE_ARRAY8_LITTLE | CODE_DOUBLE_ARRAY32_BIG | CODE_CODEPOINTER | CODE_INFIXPOINTER | CODE_CUSTOM | CODE_BLOCK64 let code_max = 0x13 let magic_number = "\132\149\166\190" (** Memory reification *) module LargeArray : sig type 'a t val empty : 'a t val length : 'a t -> int val make : int -> 'a -> 'a t val get : 'a t -> int -> 'a val set : 'a t -> int -> 'a -> unit end = struct let max_length = Sys.max_array_length type 'a t = 'a array array * 'a array (** Invariants: - All subarrays of the left array have length [max_length]. - The right array has length < [max_length]. *) let empty = [||], [||] let length (vl, vr) = (max_length * Array.length vl) + Array.length vr let make n x = let k = n / max_length in let r = n mod max_length in let vl = Array.init k (fun _ -> Array.make max_length x) in let vr = Array.make r x in (vl, vr) let get (vl, vr) n = let k = n / max_length in let r = n mod max_length in let len = Array.length vl in if k < len then vl.(k).(r) else if k == len then vr.(r) else invalid_arg "index out of bounds" let set (vl, vr) n x = let k = n / max_length in let r = n mod max_length in let len = Array.length vl in if k < len then vl.(k).(r) <- x else if k == len then vr.(r) <- x else invalid_arg "index out of bounds" end type repr = | RInt of int | RBlock of (int * int) (* tag × len *) | RString of string | RPointer of int | RCode of int type data = | Int of int (* value *) | Ptr of int (* pointer *) | Atm of int (* tag *) | Fun of int (* address *) type obj = | Struct of int * data array (* tag × data *) | String of string module type Input = sig type t val input_byte : t -> int val input_binary_int : t -> int end module type S = sig type input val parse : input -> (data * obj LargeArray.t) end module Make(M : Input) = struct open M type input = M.t let current_offset = ref 0 let input_byte chan = let () = incr current_offset in input_byte chan let input_binary_int chan = let () = current_offset := !current_offset + 4 in input_binary_int chan let input_char chan = Char.chr (input_byte chan) let input_string len chan = String.init len (fun _ -> input_char chan) let parse_header chan = let () = current_offset := 0 in let magic = input_string 4 chan in let length = input_binary_int chan in let objects = input_binary_int chan in let size32 = input_binary_int chan in let size64 = input_binary_int chan in (magic, length, size32, size64, objects) let input_int8s chan = let i = input_byte chan in if i land 0x80 = 0 then i else i lor ((-1) lsl 8) let input_int8u = input_byte let input_int16s chan = let i = input_byte chan in let j = input_byte chan in let ans = (i lsl 8) lor j in if i land 0x80 = 0 then ans else ans lor ((-1) lsl 16) let input_int16u chan = let i = input_byte chan in let j = input_byte chan in (i lsl 8) lor j let input_int32s chan = let i = input_byte chan in let j = input_byte chan in let k = input_byte chan in let l = input_byte chan in let ans = (i lsl 24) lor (j lsl 16) lor (k lsl 8) lor l in if i land 0x80 = 0 then ans else ans lor ((-1) lsl 31) let input_int32u chan = let i = input_byte chan in let j = input_byte chan in let k = input_byte chan in let l = input_byte chan in (i lsl 24) lor (j lsl 16) lor (k lsl 8) lor l let input_int64s chan = let i = input_byte chan in let j = input_byte chan in let k = input_byte chan in let l = input_byte chan in let m = input_byte chan in let n = input_byte chan in let o = input_byte chan in let p = input_byte chan in let ans = (i lsl 56) lor (j lsl 48) lor (k lsl 40) lor (l lsl 32) lor (m lsl 24) lor (n lsl 16) lor (o lsl 8) lor p in if i land 0x80 = 0 then ans else ans lor ((-1) lsl 63) let input_int64u chan = let i = input_byte chan in let j = input_byte chan in let k = input_byte chan in let l = input_byte chan in let m = input_byte chan in let n = input_byte chan in let o = input_byte chan in let p = input_byte chan in (i lsl 56) lor (j lsl 48) lor (k lsl 40) lor (l lsl 32) lor (m lsl 24) lor (n lsl 16) lor (o lsl 8) lor p let input_header32 chan = let i = input_byte chan in let j = input_byte chan in let k = input_byte chan in let l = input_byte chan in let tag = l in let len = (i lsl 14) lor (j lsl 6) lor (k lsr 2) in (tag, len) let input_header64 chan = let i = input_byte chan in let j = input_byte chan in let k = input_byte chan in let l = input_byte chan in let m = input_byte chan in let n = input_byte chan in let o = input_byte chan in let p = input_byte chan in let tag = p in let len = (i lsl 46) lor (j lsl 38) lor (k lsl 30) lor (l lsl 22) lor (m lsl 14) lor (n lsl 6) lor (o lsr 2) in (tag, len) let parse_object chan = let data = input_byte chan in if prefix_small_block <= data then let tag = data land 0x0F in let len = (data lsr 4) land 0x07 in RBlock (tag, len) else if prefix_small_int <= data then RInt (data land 0x3F) else if prefix_small_string <= data then let len = data land 0x1F in RString (input_string len chan) else if data > code_max then assert false else match (Obj.magic data) with | CODE_INT8 -> RInt (input_int8s chan) | CODE_INT16 -> RInt (input_int16s chan) | CODE_INT32 -> RInt (input_int32s chan) | CODE_INT64 -> RInt (input_int64s chan) | CODE_SHARED8 -> RPointer (input_int8u chan) | CODE_SHARED16 -> RPointer (input_int16u chan) | CODE_SHARED32 -> RPointer (input_int32u chan) | CODE_BLOCK32 -> RBlock (input_header32 chan) | CODE_BLOCK64 -> RBlock (input_header64 chan) | CODE_STRING8 -> let len = input_int8u chan in RString (input_string len chan) | CODE_STRING32 -> let len = input_int32u chan in RString (input_string len chan) | CODE_CODEPOINTER -> let addr = input_int32u chan in for _i = 0 to 15 do ignore (input_byte chan); done; RCode addr | CODE_DOUBLE_ARRAY32_LITTLE | CODE_DOUBLE_BIG | CODE_DOUBLE_LITTLE | CODE_DOUBLE_ARRAY8_BIG | CODE_DOUBLE_ARRAY8_LITTLE | CODE_DOUBLE_ARRAY32_BIG | CODE_INFIXPOINTER | CODE_CUSTOM -> Printf.eprintf "Unhandled code %04x\n%!" data; assert false let parse chan = let (magic, len, _, _, size) = parse_header chan in let () = assert (magic = magic_number) in let memory = LargeArray.make size (Struct ((-1), [||])) in let current_object = ref 0 in let fill_obj = function | RPointer n -> let data = Ptr (!current_object - n) in data, None | RInt n -> let data = Int n in data, None | RString s -> let data = Ptr !current_object in let () = LargeArray.set memory !current_object (String s) in let () = incr current_object in data, None | RBlock (tag, 0) -> (* Atoms are never shared *) let data = Atm tag in data, None | RBlock (tag, len) -> let data = Ptr !current_object in let nblock = Array.make len (Atm (-1)) in let () = LargeArray.set memory !current_object (Struct (tag, nblock)) in let () = incr current_object in data, Some nblock | RCode addr -> let data = Fun addr in data, None in let rec fill block off accu = if Array.length block = off then match accu with | [] -> () | (block, off) :: accu -> fill block off accu else let data, nobj = fill_obj (parse_object chan) in let () = block.(off) <- data in let block, off, accu = match nobj with | None -> block, succ off, accu | Some nblock -> nblock, 0, ((block, succ off) :: accu) in fill block off accu in let ans = [|Atm (-1)|] in let () = fill ans 0 [] in (ans.(0), memory) end module IChannel = struct type t = in_channel let input_byte = Pervasives.input_byte let input_binary_int = Pervasives.input_binary_int end module IString = struct type t = (string * int ref) let input_byte (s, off) = let ans = Char.code (s.[!off]) in let () = incr off in ans let input_binary_int chan = let i = input_byte chan in let j = input_byte chan in let k = input_byte chan in let l = input_byte chan in let ans = (i lsl 24) lor (j lsl 16) lor (k lsl 8) lor l in if i land 0x80 = 0 then ans else ans lor ((-1) lsl 31) end module PChannel = Make(IChannel) module PString = Make(IString) let parse_channel = PChannel.parse let parse_string s = PString.parse (s, ref 0) let instantiate (p, mem) = let len = LargeArray.length mem in let ans = LargeArray.make len (Obj.repr 0) in (** First pass: initialize the subobjects *) for i = 0 to len - 1 do let obj = match LargeArray.get mem i with | Struct (tag, blk) -> Obj.new_block tag (Array.length blk) | String str -> Obj.repr str in LargeArray.set ans i obj done; let get_data = function | Int n -> Obj.repr n | Ptr p -> LargeArray.get ans p | Atm tag -> Obj.new_block tag 0 | Fun _ -> assert false (** We shouldn't serialize closures *) in (** Second pass: set the pointers *) for i = 0 to len - 1 do match LargeArray.get mem i with | Struct (_, blk) -> let obj = LargeArray.get ans i in for k = 0 to Array.length blk - 1 do Obj.set_field obj k (get_data blk.(k)) done | String _ -> () done; get_data p