(************************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* None with | Some tt' -> CharMap.add c (insert tt' (i + 1)) (CharMap.remove c tt.branch) | None -> let tt' = {node = None; branch = CharMap.empty} in CharMap.add c (insert tt' (i + 1)) tt.branch in { node = tt.node; branch = br } in insert ttree 0 (* Search a string in a dictionary: raises [Not_found] if the word is not present. *) let ttree_find ttree str = let rec proc_rec tt i = if i == String.length str then tt else proc_rec (CharMap.find str.[i] tt.branch) (i+1) in proc_rec ttree 0 (* Removes a string from a dictionary: returns an equal dictionary if the word not present. *) let ttree_remove ttree str = let rec remove tt i = if i == String.length str then {node = None; branch = tt.branch} else let c = str.[i] in let br = match try Some (CharMap.find c tt.branch) with Not_found -> None with | Some tt' -> CharMap.add c (remove tt' (i + 1)) (CharMap.remove c tt.branch) | None -> tt.branch in { node = tt.node; branch = br } in remove ttree 0 (* Errors occuring while lexing (explained as "Lexer error: ...") *) module Error = struct type t = | Illegal_character | Unterminated_comment | Unterminated_string | Undefined_token | Bad_token of string | UnsupportedUnicode of int exception E of t let to_string x = "Syntax Error: Lexer: " ^ (match x with | Illegal_character -> "Illegal character" | Unterminated_comment -> "Unterminated comment" | Unterminated_string -> "Unterminated string" | Undefined_token -> "Undefined token" | Bad_token tok -> Format.sprintf "Bad token %S" tok | UnsupportedUnicode x -> Printf.sprintf "Unsupported Unicode character (0x%x)" x) (* Require to fix the Camlp4 signature *) let print ppf x = Pp.pp_with ppf (Pp.str (to_string x)) end open Error let err loc str = Loc.raise (Loc.make_loc loc) (Error.E str) let bad_token str = raise (Error.E (Bad_token str)) (* Lexer conventions on tokens *) type token_kind = | Utf8Token of (Unicode.status * int) | AsciiChar | EmptyStream let error_unsupported_unicode_character n unicode cs = let bp = Stream.count cs in err (bp,bp+n) (UnsupportedUnicode unicode) let error_utf8 cs = let bp = Stream.count cs in Stream.junk cs; (* consume the char to avoid read it and fail again *) err (bp, bp+1) Illegal_character let utf8_char_size cs = function (* Utf8 leading byte *) | '\x00'..'\x7F' -> 1 | '\xC0'..'\xDF' -> 2 | '\xE0'..'\xEF' -> 3 | '\xF0'..'\xF7' -> 4 | _ (* '\x80'..\xBF'|'\xF8'..'\xFF' *) -> error_utf8 cs let njunk n = Util.repeat n Stream.junk let check_utf8_trailing_byte cs c = if not (Int.equal (Char.code c land 0xC0) 0x80) then error_utf8 cs (* Recognize utf8 blocks (of length less than 4 bytes) *) (* but don't certify full utf8 compliance (e.g. no emptyness check) *) let lookup_utf8_tail c cs = let c1 = Char.code c in if Int.equal (c1 land 0x40) 0 or Int.equal (c1 land 0x38) 0x38 then error_utf8 cs else let n, unicode = if Int.equal (c1 land 0x20) 0 then match Stream.npeek 2 cs with | [_;c2] -> check_utf8_trailing_byte cs c2; 2, (c1 land 0x1F) lsl 6 + (Char.code c2 land 0x3F) | _ -> error_utf8 cs else if Int.equal (c1 land 0x10) 0 then match Stream.npeek 3 cs with | [_;c2;c3] -> check_utf8_trailing_byte cs c2; check_utf8_trailing_byte cs c3; 3, (c1 land 0x0F) lsl 12 + (Char.code c2 land 0x3F) lsl 6 + (Char.code c3 land 0x3F) | _ -> error_utf8 cs else match Stream.npeek 4 cs with | [_;c2;c3;c4] -> check_utf8_trailing_byte cs c2; check_utf8_trailing_byte cs c3; check_utf8_trailing_byte cs c4; 4, (c1 land 0x07) lsl 18 + (Char.code c2 land 0x3F) lsl 12 + (Char.code c3 land 0x3F) lsl 6 + (Char.code c4 land 0x3F) | _ -> error_utf8 cs in try Unicode.classify unicode, n with Unicode.Unsupported -> njunk n cs; error_unsupported_unicode_character n unicode cs let lookup_utf8 cs = match Stream.peek cs with | Some ('\x00'..'\x7F') -> AsciiChar | Some ('\x80'..'\xFF' as c) -> Utf8Token (lookup_utf8_tail c cs) | None -> EmptyStream let unlocated f x = try f x with Loc.Exc_located (_, exc) -> raise exc let check_keyword str = let rec loop_symb = parser | [< ' (' ' | '\n' | '\r' | '\t' | '"') >] -> bad_token str | [< s >] -> match unlocated lookup_utf8 s with | Utf8Token (_,n) -> njunk n s; loop_symb s | AsciiChar -> Stream.junk s; loop_symb s | EmptyStream -> () in loop_symb (Stream.of_string str) let check_keyword_to_add s = try check_keyword s with Error.E (UnsupportedUnicode unicode) -> Flags.if_verbose msg_warning (strbrk (Printf.sprintf "Token '%s' contains unicode character 0x%x which will not be parsable." s unicode)) let check_ident str = let rec loop_id intail = parser | [< ' ('a'..'z' | 'A'..'Z' | '_'); s >] -> loop_id true s | [< ' ('0'..'9' | ''') when intail; s >] -> loop_id true s | [< s >] -> match unlocated lookup_utf8 s with | Utf8Token (Unicode.Letter, n) -> njunk n s; loop_id true s | Utf8Token (Unicode.IdentPart, n) when intail -> njunk n s; loop_id true s | EmptyStream -> () | Utf8Token _ | AsciiChar -> bad_token str in loop_id false (Stream.of_string str) let is_ident str = try let _ = check_ident str in true with Error.E _ -> false (* Keyword and symbol dictionary *) let token_tree = ref empty_ttree let is_keyword s = try match (ttree_find !token_tree s).node with None -> false | Some _ -> true with Not_found -> false let add_keyword str = if not (is_keyword str) then begin check_keyword_to_add str; token_tree := ttree_add !token_tree str end let remove_keyword str = token_tree := ttree_remove !token_tree str (* Freeze and unfreeze the state of the lexer *) type frozen_t = ttree let freeze () = !token_tree let unfreeze tt = token_tree := tt let init () = unfreeze empty_ttree let _ = init() (* The string buffering machinery *) let buff = ref (String.create 80) let store len x = if len >= String.length !buff then buff := !buff ^ String.create (String.length !buff); !buff.[len] <- x; succ len let rec nstore n len cs = if n>0 then nstore (n-1) (store len (Stream.next cs)) cs else len let get_buff len = String.sub !buff 0 len (* The classical lexer: idents, numbers, quoted strings, comments *) let rec ident_tail len = parser | [< ' ('a'..'z' | 'A'..'Z' | '0'..'9' | ''' | '_' as c); s >] -> ident_tail (store len c) s | [< s >] -> match lookup_utf8 s with | Utf8Token ((Unicode.IdentPart | Unicode.Letter), n) -> ident_tail (nstore n len s) s | _ -> len let rec number len = parser | [< ' ('0'..'9' as c); s >] -> number (store len c) s | [< >] -> len let rec string in_comments bp len = parser | [< ''"'; esc=(parser [<''"' >] -> true | [< >] -> false); s >] -> if esc then string in_comments bp (store len '"') s else len | [< ''('; s >] -> (parser | [< ''*'; s >] -> string (Option.map succ in_comments) bp (store (store len '(') '*') s | [< >] -> string in_comments bp (store len '(') s) s | [< ''*'; s >] -> (parser | [< '')'; s >] -> let () = match in_comments with | Some 0 -> msg_warning (strbrk "Not interpreting \"*)\" as the end of current non-terminated comment because it occurs in a non-terminated string of the comment.") | _ -> () in let in_comments = Option.map pred in_comments in string in_comments bp (store (store len '*') ')') s | [< >] -> string in_comments bp (store len '*') s) s | [< 'c; s >] -> string in_comments bp (store len c) s | [< _ = Stream.empty >] ep -> err (bp, ep) Unterminated_string (* Hook for exporting comment into xml theory files *) let xml_output_comment = ref (fun _ -> ()) let set_xml_output_comment f = xml_output_comment := f (* Utilities for comments in beautify *) let comment_begin = ref None let comm_loc bp = match !comment_begin with | None -> comment_begin := Some bp | _ -> () let current = Buffer.create 8192 let between_com = ref true type com_state = int option * string * bool let restore_com_state (o,s,b) = comment_begin := o; Buffer.clear current; Buffer.add_string current s; between_com := b let dflt_com = (None,"",true) let com_state () = let s = (!comment_begin, Buffer.contents current, !between_com) in restore_com_state dflt_com; s let real_push_char c = Buffer.add_char current c (* Add a char if it is between two commands, if it is a newline or if the last char is not a space itself. *) let push_char c = if !between_com || List.mem c ['\n';'\r'] || (List.mem c [' ';'\t']&& (Int.equal (Buffer.length current) 0 || not (let s = Buffer.contents current in List.mem s.[String.length s - 1] [' ';'\t';'\n';'\r']))) then real_push_char c let push_string s = Buffer.add_string current s let null_comment s = let rec null i = i<0 || (List.mem s.[i] [' ';'\t';'\n';'\r'] && null (i-1)) in null (String.length s - 1) let comment_stop ep = let current_s = Buffer.contents current in if !Flags.xml_export && Buffer.length current > 0 && (!between_com || not(null_comment current_s)) then !xml_output_comment current_s; (if Flags.do_beautify() && Buffer.length current > 0 && (!between_com || not(null_comment current_s)) then let bp = match !comment_begin with Some bp -> bp | None -> msgerrnl(str"No begin location for comment '"++str current_s ++str"' ending at "++int ep); ep-1 in Pp.comments := ((bp,ep),current_s) :: !Pp.comments); Buffer.clear current; comment_begin := None; between_com := false (* Does not unescape!!! *) let rec comm_string bp = parser | [< ''"' >] -> push_string "\"" | [< ''\\'; _ = (parser [< ' ('"' | '\\' as c) >] -> let () = match c with | '"' -> real_push_char c | _ -> () in real_push_char c | [< >] -> real_push_char '\\'); s >] -> comm_string bp s | [< _ = Stream.empty >] ep -> err (bp, ep) Unterminated_string | [< 'c; s >] -> real_push_char c; comm_string bp s let rec comment bp = parser bp2 | [< ''('; _ = (parser | [< ''*'; s >] -> push_string "(*"; comment bp s | [< >] -> push_string "(" ); s >] -> comment bp s | [< ''*'; _ = parser | [< '')' >] -> push_string "*)"; | [< s >] -> real_push_char '*'; comment bp s >] -> () | [< ''"'; s >] -> if Flags.do_beautify() then (push_string"\"";comm_string bp2 s) else ignore (string (Some 0) bp2 0 s); comment bp s | [< _ = Stream.empty >] ep -> err (bp, ep) Unterminated_comment | [< 'z; s >] -> real_push_char z; comment bp s (* Parse a special token, using the [token_tree] *) (* Peek as much utf-8 lexemes as possible *) (* and retain the longest valid special token obtained *) let rec progress_further last nj tt cs = try progress_from_byte last nj tt cs (List.nth (Stream.npeek (nj+1) cs) nj) with Failure _ -> last and update_longest_valid_token last nj tt cs = match tt.node with | Some _ as last' -> stream_njunk nj cs; progress_further last' 0 tt cs | None -> progress_further last nj tt cs (* nj is the number of char peeked since last valid token *) (* n the number of char in utf8 block *) and progress_utf8 last nj n c tt cs = try let tt = CharMap.find c tt.branch in if Int.equal n 1 then update_longest_valid_token last (nj+n) tt cs else match Util.List.skipn (nj+1) (Stream.npeek (nj+n) cs) with | l when Int.equal (List.length l) (n - 1) -> List.iter (check_utf8_trailing_byte cs) l; let tt = List.fold_left (fun tt c -> CharMap.find c tt.branch) tt l in update_longest_valid_token last (nj+n) tt cs | _ -> error_utf8 cs with Not_found -> last and progress_from_byte last nj tt cs c = progress_utf8 last nj (utf8_char_size cs c) c tt cs let find_keyword id s = let tt = ttree_find !token_tree id in match progress_further tt.node 0 tt s with | None -> raise Not_found | Some c -> KEYWORD c (* Must be a special token *) let process_chars bp c cs = let t = progress_from_byte None (-1) !token_tree cs c in let ep = Stream.count cs in match t with | Some t -> (KEYWORD t, (bp, ep)) | None -> let ep' = bp + utf8_char_size cs c in njunk (ep' - ep) cs; err (bp, ep') Undefined_token let token_of_special c s = match c with | '$' -> METAIDENT s | '.' -> FIELD s | _ -> assert false (* Parse what follows a dot / a dollar *) let parse_after_special c bp = parser | [< ' ('a'..'z' | 'A'..'Z' | '_' as d); len = ident_tail (store 0 d) >] -> token_of_special c (get_buff len) | [< s >] -> match lookup_utf8 s with | Utf8Token (Unicode.Letter, n) -> token_of_special c (get_buff (ident_tail (nstore n 0 s) s)) | AsciiChar | Utf8Token _ | EmptyStream -> fst (process_chars bp c s) (* Parse what follows a question mark *) let parse_after_qmark bp s = match Stream.peek s with | Some ('a'..'z' | 'A'..'Z' | '_') -> LEFTQMARK | None -> KEYWORD "?" | _ -> match lookup_utf8 s with | Utf8Token (Unicode.Letter, _) -> LEFTQMARK | AsciiChar | Utf8Token _ | EmptyStream -> fst (process_chars bp '?' s) let blank_or_eof cs = match Stream.peek cs with | None -> true | Some (' ' | '\t' | '\n' |'\r') -> true | _ -> false (* Parse a token in a char stream *) let rec next_token = parser bp | [< '' ' | '\t' | '\n' |'\r' as c; s >] -> comm_loc bp; push_char c; next_token s | [< ''$' as c; t = parse_after_special c bp >] ep -> comment_stop bp; (t, (ep, bp)) | [< ''.' as c; t = parse_after_special c bp; s >] ep -> comment_stop bp; (* We enforce that "." should either be part of a larger keyword, for instance ".(", or followed by a blank or eof. *) let () = match t with | KEYWORD "." -> if not (blank_or_eof s) then err (bp,ep+1) Undefined_token; if Flags.do_beautify() then between_com := true; | _ -> () in (t, (bp,ep)) | [< ''?'; s >] ep -> let t = parse_after_qmark bp s in comment_stop bp; (t, (ep, bp)) | [< ' ('a'..'z' | 'A'..'Z' | '_' as c); len = ident_tail (store 0 c); s >] ep -> let id = get_buff len in comment_stop bp; (try find_keyword id s with Not_found -> IDENT id), (bp, ep) | [< ' ('0'..'9' as c); len = number (store 0 c) >] ep -> comment_stop bp; (INT (get_buff len), (bp, ep)) | [< ''\"'; len = string None bp 0 >] ep -> comment_stop bp; (STRING (get_buff len), (bp, ep)) | [< ' ('(' as c); t = parser | [< ''*'; s >] -> comm_loc bp; push_string "(*"; comment bp s; next_token s | [< t = process_chars bp c >] -> comment_stop bp; t >] -> t | [< s >] -> match lookup_utf8 s with | Utf8Token (Unicode.Letter, n) -> let len = ident_tail (nstore n 0 s) s in let id = get_buff len in let ep = Stream.count s in comment_stop bp; (try find_keyword id s with Not_found -> IDENT id), (bp, ep) | AsciiChar | Utf8Token ((Unicode.Symbol | Unicode.IdentPart), _) -> let t = process_chars bp (Stream.next s) s in comment_stop bp; t | EmptyStream -> comment_stop bp; (EOI, (bp, bp + 1)) (* (* Debug: uncomment this for tracing tokens seen by coq...*) let next_token s = let (t,(bp,ep)) = next_token s in Printf.eprintf "[%s]\n%!" (Tok.to_string t); (t,(bp,ep)) *) (* Location table system for creating tables associating a token count to its location in a char stream (the source) *) let locerr () = invalid_arg "Lexer: location function" let loct_create () = Hashtbl.create 207 let loct_func loct i = try Hashtbl.find loct i with Not_found -> locerr () let loct_add loct i loc = Hashtbl.add loct i loc let current_location_table = ref (loct_create ()) type location_table = (int, CompatLoc.t) Hashtbl.t let location_table () = !current_location_table let restore_location_table t = current_location_table := t (** {6 The lexer of Coq} *) (** Note: removing a token. We do nothing because [remove_token] is called only when removing a grammar rule with [Grammar.delete_rule]. The latter command is called only when unfreezing the state of the grammar entries (see GRAMMAR summary, file env/metasyntax.ml). Therefore, instead of removing tokens one by one, we unfreeze the state of the lexer. This restores the behaviour of the lexer. B.B. *) IFDEF CAMLP5 THEN type te = Tok.t (** Names of tokens, for this lexer, used in Grammar error messages *) let token_text = function | ("", t) -> "'" ^ t ^ "'" | ("IDENT", "") -> "identifier" | ("IDENT", t) -> "'" ^ t ^ "'" | ("INT", "") -> "integer" | ("INT", s) -> "'" ^ s ^ "'" | ("STRING", "") -> "string" | ("EOI", "") -> "end of input" | (con, "") -> con | (con, prm) -> con ^ " \"" ^ prm ^ "\"" let func cs = let loct = loct_create () in let ts = Stream.from (fun i -> let (tok, loc) = next_token cs in loct_add loct i (make_loc loc); Some tok) in current_location_table := loct; (ts, loct_func loct) let lexer = { Token.tok_func = func; Token.tok_using = (fun pat -> match Tok.of_pattern pat with | KEYWORD s -> add_keyword s | _ -> ()); Token.tok_removing = (fun _ -> ()); Token.tok_match = Tok.match_pattern; Token.tok_comm = None; Token.tok_text = token_text } ELSE (* official camlp4 for ocaml >= 3.10 *) module M_ = Camlp4.ErrorHandler.Register (Error) module Loc = CompatLoc module Token = struct include Tok (* Cf. tok.ml *) module Loc = CompatLoc module Error = Camlp4.Struct.EmptyError module Filter = struct type token_filter = (Tok.t * Loc.t) Stream.t -> (Tok.t * Loc.t) Stream.t type t = unit let mk _is_kwd = () let keyword_added () kwd _ = add_keyword kwd let keyword_removed () _ = () let filter () x = x let define_filter () _ = () end end let mk () _init_loc(*FIXME*) cs = let loct = loct_create () in let rec self = parser i [< (tok, loc) = next_token; s >] -> let loc = make_loc loc in loct_add loct i loc; [< '(tok, loc); self s >] | [< >] -> [< >] in current_location_table := loct; self cs END (** Terminal symbols interpretation *) let is_ident_not_keyword s = is_ident s && not (is_keyword s) let is_number s = let rec aux i = Int.equal (String.length s) i || match s.[i] with '0'..'9' -> aux (i+1) | _ -> false in aux 0 let strip s = let len = let rec loop i len = if Int.equal i (String.length s) then len else if s.[i] == ' ' then loop (i + 1) len else loop (i + 1) (len + 1) in loop 0 0 in if len == String.length s then s else let s' = String.create len in let rec loop i i' = if i == String.length s then s' else if s.[i] == ' ' then loop (i + 1) i' else begin s'.[i'] <- s.[i]; loop (i + 1) (i' + 1) end in loop 0 0 let terminal s = let s = strip s in let () = match s with "" -> failwith "empty token" | _ -> () in if is_ident_not_keyword s then IDENT s else if is_number s then INT s else KEYWORD s