ocaml/stdlib/stream.ml

(***********************************************************************)
(*                                                                     *)
(*                                OCaml                                *)
(*                                                                     *)
(*        Daniel de Rauglaudre, projet Cristal, INRIA Rocquencourt     *)
(*                                                                     *)
(*  Copyright 1997 Institut National de Recherche en Informatique et   *)
(*  en Automatique.  All rights reserved.  This file is distributed    *)
(*  under the terms of the GNU Library General Public License, with    *)
(*  the special exception on linking described in file ../LICENSE.     *)
(*                                                                     *)
(***********************************************************************)

type 'a t = 'a cell option
and 'a cell = { mutable count : int; mutable data : 'a data }
and 'a data =
    Sempty
  | Scons of 'a * 'a data
  | Sapp of 'a data * 'a data
  | Slazy of 'a data Lazy.t
  | Sgen of 'a gen
  | Sbuffio : buffio -> char data
and 'a gen = { mutable curr : 'a option option; func : int -> 'a option }
and buffio =
  { ic : in_channel; buff : bytes; mutable len : int; mutable ind : int }
;;
exception Failure;;
exception Error of string;;

let count = function
  | None -> 0
  | Some { count } -> count
let data = function
  | None -> Sempty
  | Some { data } -> data

let fill_buff b =
  b.len <- input b.ic b.buff 0 (Bytes.length b.buff); b.ind <- 0
;;

let rec get_data : type v. int -> v data -> v data = fun count d -> match d with
 (* Returns either Sempty or Scons(a, _) even when d is a generator
    or a buffer. In those cases, the item a is seen as extracted from
 the generator/buffer.
 The count parameter is used for calling `Sgen-functions'.  *)
   Sempty | Scons (_, _) -> d
 | Sapp (d1, d2) ->
     begin match get_data count d1 with
       Scons (a, d11) -> Scons (a, Sapp (d11, d2))
     | Sempty -> get_data count d2
     | _ -> assert false
     end
 | Sgen {curr = Some None; func = _ } -> Sempty
 | Sgen ({curr = Some(Some a); func = f} as g) ->
     g.curr <- None; Scons(a, d)
 | Sgen g ->
     begin match g.func count with
       None -> g.curr <- Some(None); Sempty
     | Some a -> Scons(a, d)
         (* Warning: anyone using g thinks that an item has been read *)
     end
 | Sbuffio b ->
     if b.ind >= b.len then fill_buff b;
     if b.len == 0 then Sempty else
       let r = Bytes.unsafe_get b.buff b.ind in
       (* Warning: anyone using g thinks that an item has been read *)
       b.ind <- succ b.ind; Scons(r, d)
 | Slazy f -> get_data count (Lazy.force f)
;;

let rec peek_data : type v. v cell -> v option = fun s ->
 (* consult the first item of s *)
 match s.data with
   Sempty -> None
 | Scons (a, _) -> Some a
 | Sapp (_, _) ->
     begin match get_data s.count s.data with
       Scons(a, _) as d -> s.data <- d; Some a
     | Sempty -> None
     | _ -> assert false
     end
 | Slazy f -> s.data <- (Lazy.force f); peek_data s
 | Sgen {curr = Some a} -> a
 | Sgen g -> let x = g.func s.count in g.curr <- Some x; x
 | Sbuffio b ->
     if b.ind >= b.len then fill_buff b;
     if b.len == 0 then begin s.data <- Sempty; None end
     else Some (Bytes.unsafe_get b.buff b.ind)
;;

let peek = function
  | None -> None
  | Some s -> peek_data s
;;

let rec junk_data : type v. v cell -> unit = fun s ->
  match s.data with
    Scons (_, d) -> s.count <- (succ s.count); s.data <- d
  | Sgen ({curr = Some _} as g) -> s.count <- (succ s.count); g.curr <- None
  | Sbuffio b -> s.count <- (succ s.count); b.ind <- succ b.ind
  | _ ->
      match peek_data s with
        None -> ()
      | Some _ -> junk_data s
;;

let junk = function
  | None -> ()
  | Some data -> junk_data data

let rec nget_data n s =
  if n <= 0 then [], s.data, 0
  else
    match peek_data s with
      Some a ->
        junk_data s;
        let (al, d, k) = nget_data (pred n) s in a :: al, Scons (a, d), succ k
    | None -> [], s.data, 0
;;

let npeek_data n s =
  let (al, d, len) = nget_data n s in
  s.count <- (s.count - len);
  s.data <- d;
  al
;;

let npeek n = function
  | None -> []
  | Some d -> npeek_data n d

let next s =
  match peek s with
    Some a -> junk s; a
  | None -> raise Failure
;;

let empty s =
  match peek s with
    Some _ -> raise Failure
  | None -> ()
;;

let iter f strm =
  let rec do_rec () =
    match peek strm with
      Some a -> junk strm; ignore(f a); do_rec ()
    | None -> ()
  in
  do_rec ()
;;

(* Stream building functions *)

let from f = Some {count = 0; data = Sgen {curr = None; func = f}};;

let of_list l =
  Some {count = 0; data = List.fold_right (fun x l -> Scons (x, l)) l Sempty}
;;

let of_string s =
  let count = ref 0 in
  from (fun _ ->
    (* We cannot use the index passed by the [from] function directly
       because it returns the current stream count, with absolutely no
       guarantee that it will start from 0. For example, in the case
       of [Stream.icons 'c' (Stream.from_string "ab")], the first
       access to the string will be made with count [1] already.
    *)
    let c = !count in
    if c < String.length s
    then (incr count; Some s.[c])
    else None)
;;

let of_bytes s =
  let count = ref 0 in
  from (fun _ ->
    let c = !count in
    if c < Bytes.length s
    then (incr count; Some (Bytes.get s c))
    else None)
;;

let of_channel ic =
  Some {count = 0;
        data = Sbuffio {ic = ic; buff = Bytes.create 4096; len = 0; ind = 0}}
;;

(* Stream expressions builders *)

let iapp i s = Some {count = 0; data = Sapp (data i, data s)};;
let icons i s = Some {count = 0; data = Scons (i, data s)};;
let ising i = Some {count = 0; data = Scons (i, Sempty)};;

let lapp f s =
  Some {count = 0; data = Slazy (lazy(Sapp (data (f ()), data s)))}
;;
let lcons f s = Some {count = 0; data = Slazy (lazy(Scons (f (), data s)))};;
let lsing f = Some {count = 0; data = Slazy (lazy(Scons (f (), Sempty)))};;

let sempty = None;;
let slazy f = Some {count = 0; data = Slazy (lazy(data (f ())))};;

(* For debugging use *)

let rec dump : type v. (v -> unit) -> v t -> unit = fun f s ->
  print_string "{count = ";
  print_int (count s);
  print_string "; data = ";
  dump_data f (data s);
  print_string "}";
  print_newline ()
and dump_data : type v. (v -> unit) -> v data -> unit = fun f ->
  function
    Sempty -> print_string "Sempty"
  | Scons (a, d) ->
      print_string "Scons (";
      f a;
      print_string ", ";
      dump_data f d;
      print_string ")"
  | Sapp (d1, d2) ->
      print_string "Sapp (";
      dump_data f d1;
      print_string ", ";
      dump_data f d2;
      print_string ")"
  | Slazy _ -> print_string "Slazy"
  | Sgen _ -> print_string "Sgen"
  | Sbuffio b -> print_string "Sbuffio"
;;