package alba
Alba compiler
Install
Dune Dependency
Authors
Maintainers
Sources
0.4.4.tar.gz
sha256=4817038301d3e45bac9edf7e6f2fc8bf0a6d78e76e02ad7ea33ef69bcc17df3b
md5=25234357587126685d64f16236167937
doc/src/alba.fmlib_node/node_io.ml.html
Source file node_io.ml
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files: file Pool.t} let make (size:int): t = {size; files = Pool.make_empty ()} let is_open_read (s:t) (i:int): bool = Pool.has s.files i && match Pool.elem s.files i with | Read _ -> true | Write _ -> false let is_open_write (s:t) (i:int): bool = Pool.has s.files i && match Pool.elem s.files i with | Read _ -> false | Write _ -> true let capacity (s:t): int = Pool.capacity s.files let occupy (s:t) (f:B.t -> file): int = let buf = B.alloc s.size in Pool.occupy s.files (f buf) let occupy_readable (s:t) (fd:int): int = occupy s (fun b -> Read(fd,b)) let occupy_writable (s:t) (fd:int): int = occupy s (fun b -> Write(fd,b)) let release (s: t) (fd: int): unit = Pool.release s.files fd let unix_file_descriptor (s: t) (i: int): int = match Pool.elem s.files i with | Write (fd, _) | Read (fd, _) -> fd let readable_file (s:t) (i:int): int * B.t = match Pool.elem s.files i with | Write _ -> assert false (* Illegal call! *) | Read (fd,b) -> fd, b let writable_file (s:t) (i:int): int * B.t = match Pool.elem s.files i with | Read _ -> assert false (* Illegal call! *) | Write (fd,b) -> fd, b end (* Buffers *) module World = struct include Buffers (Io_buffer) let buffer_size = 4096 (* 16K: 16384, 32K: 32768, 64K: 65536, 2000 loc ~ 56K, 3000 loc ~ 85K *) let stdin: int = 0 let stdout: int = 1 let stderr: int = 2 let init () = let w = make buffer_size in let i0 = occupy_readable w stdin in assert (i0 = stdin); let i1 = occupy_writable w stdout in assert (i1 = stdout); let i2 = occupy_writable w stderr in assert (i2 = stderr); w end module IO0: Make_io.SIG = struct type 'a io_result = ('a, Io.Error.t) result type in_file = int type out_file = int let stdin: in_file = 0 let stdout: out_file = 1 let stderr: out_file = 2 type program = | More of (World.t * (World.t -> program)) | Done module M = Monad.Of_sig_min( struct type 'a t = World.t -> ('a -> World.t -> program) -> program let return (a:'a): 'a t = fun w k -> More (w, k a) let (>>=) (m:'a t) (f:'a -> 'b t): 'b t = fun w k -> More (w, fun w -> m w (fun a w -> f a w k)) end) include M let rec execute_program (p:program): unit = match p with | Done -> () | More (w,f) -> execute_program (f w) let world: World.t t = fun w k -> k w w let fill_buffer (fd: int) (buf: Io_buffer.t): int io_result t = fun w k -> File_system.read fd buf (fun res -> match res with | Error error -> execute_program (k (Error error) w) | Ok n -> execute_program (k (Ok n) w)); Done let write1 (fd:int) (buf:Io_buffer.t) (w:World.t) (k:int -> World.t -> program): program = File_system.write fd buf (fun n -> execute_program @@ k n w); Done let flush_buffer (fd:int) (buf:Io_buffer.t): unit option t = let rec write () = if Io_buffer.is_empty buf then return (Some ()) else write1 fd buf >>= fun n -> if n = 0 then return None else write () in write () let flush (fd:int): unit option t = fun w k -> assert (World.is_open_write w fd); let fd,buf = World.writable_file w fd in flush_buffer fd buf w k let readable_file (fd: out_file): (int * Io_buffer.t) t = fun w k -> assert (World.is_open_read w fd); let fd,buf = World.readable_file w fd in k (fd,buf) w let writable_file (fd: out_file): (int * Io_buffer.t) t = fun w k -> assert (World.is_open_write w fd); let fd,buf = World.writable_file w fd in k (fd,buf) w let write (fd: out_file): unit option t = writable_file fd >>= fun (fd,buf) -> flush_buffer fd buf let flush_all: unit t = world >>= fun w -> let rec flush i = if i = World.capacity w then return () else if World.is_open_write w i then write i >>= fun _ -> flush (i + 1) else flush (i + 1) in flush 0 let make_program (m:unit t): program = (m >>= fun _ -> flush_all) (World.init ()) (fun _ _ -> Done) let execute (m:unit t): unit = execute_program @@ make_program m let exit (code:int): 'a t = flush_all >>= fun _ -> Process.exit code let command_line: string array t = return Process.command_line let current_working_directory: string t = return (Process.current_working_directory ()) let path_separator: char = Path.separator let path_delimiter: char = Path.delimiter let read_directory (path:string): string array option t = fun w k -> File_system.readdir path (fun arr -> Printf.printf "read_directory %s\n" path; execute_program @@ k arr w); Done let cli_loop (s: 'a) (get_prompt: 'a -> string option) (next: 'a -> string -> 'a t) (stop: 'a -> 'a t) : 'a t = let rl = Readline.create_interface () in let rec loop s: 'a t = flush stdout >>= fun _ -> fun w k -> match get_prompt s with | None -> Readline.close rl; execute_program @@ stop s w k; Done | Some prompt_str -> Readline.question rl prompt_str (fun answer -> execute_program @@ (next s answer >>= loop) w k) (fun () -> execute_program @@ stop s w k); Done in loop s let open_ (path: string) (flags: string) (occupy: World.t -> int -> int): in_file io_result t = fun w k -> let kk unix_fd w = let fd = Result.map (fun unix_fd -> occupy w unix_fd) unix_fd in k fd w in File_system.open_ path flags (fun fd -> execute_program @@ kk fd w ); Done let open_for_read (path: string): in_file io_result t = open_ path "r" World.occupy_readable let open_for_write (path: string): out_file io_result t = open_ path "w" World.occupy_writable let create (path: string): out_file io_result t = open_ path "wx" World.occupy_writable let close (fd: int): unit t = fun w k -> let unix_fd = World.unix_file_descriptor w fd in File_system.close unix_fd (fun _ -> World.release w fd; execute_program @@ k () w); Done let close_in (fd: in_file): unit t = close fd let close_out (fd: out_file): unit t = flush fd >>= fun _ -> close fd module Read (W: WRITABLE) = struct module BR = Io_buffer.Read (W) let read_buffer (fd: in_file) (w: W.t): W.t t = readable_file fd >>= fun (_, buf) -> return (BR.read buf w) let read (fd: in_file) (w: W.t): (W.t, W.t * Error.t) result t = readable_file fd >>= fun (unix_fd, buf) -> let rec read w = if W.needs_more w then if Io_buffer.is_empty buf then fill_buffer unix_fd buf >>= fun res -> match res with | Ok n -> if n = 0 then return (Ok (W.put_end w)) else ( assert (not (Io_buffer.is_empty buf)); read w ) | Error error -> return (Error (w, error)) else read_buffer fd w >>= read else return (Ok w) in read w end module Write (R: READABLE) = struct let rec extract_readable (n_max:int) (r:R.t): string = if n_max <> 0 && R.has_more r then String.one (R.peek r) ^ extract_readable (n_max - 1) (R.advance r) else "" let _ = extract_readable (* might be used for debugging *) module BW = Io_buffer.Write (R) let write_buffer (fd:out_file) (r:R.t): R.t t = writable_file fd >>= fun (_,buf) -> return (BW.write buf r) let write (fd: out_file) (r: R.t): R.t t = writable_file fd >>= fun (fd,buf) -> let rec write i r = if R.has_more r then if Io_buffer.is_full buf then flush_buffer fd buf >>= function | None -> return r | Some () -> assert (not (Io_buffer.is_full buf)); write (i+1) r else return @@ BW.write buf r >>= write (i+1) else return r in write 0 r end end (* IO0 *) module IO: Io.SIG = Make_io.Make (IO0)