873 lines
31 KiB
OCaml
873 lines
31 KiB
OCaml
(* Lexer specification for LIGO, to be processed by [ocamllex]. *)
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{
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(* START HEADER *)
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type lexeme = string
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(* STRING PROCESSING *)
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(* The value of [mk_str len p] ("make string") is a string of length
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[len] containing the [len] characters in the list [p], in reverse
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order. For instance, [mk_str 3 ['c';'b';'a'] = "abc"]. *)
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let mk_str (len: int) (p: char list) : string =
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let bytes = Bytes.make len ' ' in
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let rec fill i = function
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[] -> bytes
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| char::l -> Bytes.set bytes i char; fill (i-1) l
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in fill (len-1) p |> Bytes.to_string
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(* The call [explode s a] is the list made by pushing the characters
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in the string [s] on top of [a], in reverse order. For example,
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[explode "ba" ['c';'d'] = ['a'; 'b'; 'c'; 'd']]. *)
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let explode s acc =
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let rec push = function
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0 -> acc
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| i -> s.[i-1] :: push (i-1)
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in push (String.length s)
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(* LEXER ENGINE *)
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(* Resetting file name and line number in the lexing buffer
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The call [reset ~file ~line buffer] modifies in-place the lexing
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buffer [buffer] so the lexing engine records that the file
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associated with [buffer] is named [file], and the current line is
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[line]. This function is useful when lexing a file that has been
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previously preprocessed by the C preprocessor, in which case the
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argument [file] is the name of the file that was preprocessed,
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_not_ the preprocessed file (of which the user is not normally
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aware). By default, the [line] argument is [1].
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*)
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let reset_file ~file buffer =
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let open Lexing in
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buffer.lex_curr_p <- {buffer.lex_curr_p with pos_fname = file}
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let reset_line ~line buffer =
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assert (line >= 0);
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let open Lexing in
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buffer.lex_curr_p <- {buffer.lex_curr_p with pos_lnum = line}
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let reset_offset ~offset buffer =
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assert (offset >= 0);
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Printf.printf "[reset] offset=%i\n" offset;
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let open Lexing in
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let bol = buffer.lex_curr_p.pos_bol in
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buffer.lex_curr_p <- {buffer.lex_curr_p with pos_cnum = bol (*+ offset*)}
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let reset ?file ?line ?offset buffer =
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let () =
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match file with
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Some file -> reset_file ~file buffer
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| None -> () in
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let () =
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match line with
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Some line -> reset_line ~line buffer
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| None -> () in
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match offset with
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Some offset -> reset_offset ~offset buffer
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| None -> ()
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(* Rolling back one lexeme _within the current semantic action_ *)
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let rollback buffer =
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let open Lexing in
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let len = String.length (lexeme buffer) in
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let pos_cnum = buffer.lex_curr_p.pos_cnum - len in
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buffer.lex_curr_pos <- buffer.lex_curr_pos - len;
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buffer.lex_curr_p <- {buffer.lex_curr_p with pos_cnum}
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(* ALIASES *)
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let sprintf = Printf.sprintf
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(* TOKENS *)
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(* The signature [TOKEN] exports an abstract type [token], so a lexer
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can be a functor over tokens. Consequently, generic functions to
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construct tokens are provided. Note predicate [is_eof], which
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caracterises the virtual token for end-of-file, because it requires
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special handling. *)
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module type TOKEN =
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sig
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type token
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(* Errors *)
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type int_err = Non_canonical_zero
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type ident_err = Reserved_name
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(* Injections *)
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val mk_string : lexeme -> Region.t -> token
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val mk_bytes : lexeme -> Region.t -> token
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val mk_int : lexeme -> Region.t -> (token, int_err) result
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val mk_ident : lexeme -> Region.t -> (token, ident_err) result
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val mk_constr : lexeme -> Region.t -> token
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val mk_sym : lexeme -> Region.t -> token
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val eof : Region.t -> token
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(* Predicates *)
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val is_string : token -> bool
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val is_bytes : token -> bool
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val is_int : token -> bool
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val is_ident : token -> bool
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val is_kwd : token -> bool
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val is_constr : token -> bool
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val is_sym : token -> bool
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val is_eof : token -> bool
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(* Projections *)
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val to_lexeme : token -> lexeme
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val to_string : token -> ?offsets:bool -> [`Byte | `Point] -> string
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val to_region : token -> Region.t
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end
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(* The module type for lexers is [S]. *)
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module type S = sig
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module Token : TOKEN
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type token = Token.token
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type file_path = string
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type logger = Markup.t list -> token -> unit
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val output_token :
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?offsets:bool -> [`Byte | `Point] ->
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EvalOpt.command -> out_channel -> logger
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type instance = {
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read : ?log:logger -> Lexing.lexbuf -> token;
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buffer : Lexing.lexbuf;
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get_pos : unit -> Pos.t;
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get_last : unit -> Region.t;
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close : unit -> unit
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}
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val open_token_stream : file_path option -> instance
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(* Error reporting *)
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exception Error of Error.t Region.reg
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val print_error :
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?offsets:bool -> [`Byte | `Point] -> Error.t Region.reg -> unit
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(* Standalone tracer *)
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val trace :
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?offsets:bool -> [`Byte | `Point] ->
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file_path option -> EvalOpt.command -> unit
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end
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(* The functorised interface
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Note that the module parameter [Token] is re-exported as a
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submodule in [S].
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*)
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module Make (Token: TOKEN) : (S with module Token = Token) =
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struct
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module Token = Token
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type token = Token.token
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type file_path = string
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(* THREAD FOR STRUCTURED CONSTRUCTS (STRINGS, COMMENTS) *)
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(* When scanning structured constructs, like strings and comments,
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we need to keep the region of the opening symbol (like double
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quote, "//" or "(*") in order to report any error more
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precisely. Since ocamllex is byte-oriented, we need to store
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the parsed bytes as characters in an accumulator [acc] and
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also its length [len], so, we are done, it is easy to build the
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string making up the structured construct with [mk_str] (see
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above).
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The resulting data structure is called a _thread_.
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(Note for Emacs: "*)".)
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*)
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type thread = {
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opening : Region.t;
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len : int;
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acc : char list
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}
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let push_char char {opening; len; acc} = {opening; len=len+1; acc=char::acc}
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let push_string str {opening; len; acc} =
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{opening;
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len = len + String.length str;
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acc = explode str acc}
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(* STATE *)
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(* Beyond tokens, the result of lexing is a state. The type
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[state] represents the logical state of the lexing engine, that
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is, a value which is threaded during scanning and which denotes
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useful, high-level information beyond what the type
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[Lexing.lexbuf] in the standard library already provides for
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all generic lexers.
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Tokens are the smallest units used by the parser to build the
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abstract syntax tree. The state includes a queue of recognised
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tokens, with the markup at the left of its lexeme until either
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the start of the file or the end of the previously recognised
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token.
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The markup from the last recognised token or, if the first
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token has not been recognised yet, from the beginning of the
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file is stored in the field [markup] of the state because it is
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a side-effect, with respect to the output token list, and we
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use a record with a single field [units] because that record
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may be easily extended during the future maintenance of this
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lexer.
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The state also includes a field [pos] which holds the current
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position in the LIGO source file. The position is not always
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updated after a single character has been matched: that depends
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on the regular expression that matched the lexing buffer.
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The fields [decoder] and [supply] offer the support needed
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for the lexing of UTF-8 encoded characters in comments (the
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only place where they are allowed in LIGO). The former is the
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decoder proper and the latter is the effectful function
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[supply] that takes a byte, a start index and a length and feed
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it to [decoder]. See the documentation of the third-party
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library Uutf.
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*)
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type state = {
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units : (Markup.t list * token) FQueue.t;
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markup : Markup.t list;
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last : Region.t;
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pos : Pos.t;
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decoder : Uutf.decoder;
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supply : Bytes.t -> int -> int -> unit
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}
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(* The call [enqueue (token, state)] updates functionally the
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state [state] by associating the token [token] with the stored
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markup and enqueuing the pair into the units queue. The field
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[markup] is then reset to the empty list. *)
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let enqueue (token, state) = {
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state with
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units = FQueue.enq (state.markup, token) state.units;
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markup = []
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}
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(* The call [sync state buffer] updates the current position in
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accordance with the contents of the lexing buffer, more
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precisely, depending on the length of the string which has just
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been recognised by the scanner: that length is used as a
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positive offset to the current column. *)
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let sync state buffer =
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let lex = Lexing.lexeme buffer in
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let len = String.length lex in
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let start = state.pos in
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let stop = start#shift_bytes len in
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let state = {state with pos = stop}
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in Region.make ~start ~stop, lex, state
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(* MARKUP *)
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(* Committing markup to the current logical state *)
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let push_newline state buffer =
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let value = Lexing.lexeme buffer
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and () = Lexing.new_line buffer
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and start = state.pos in
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let stop = start#new_line value in
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let state = {state with pos = stop}
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and region = Region.make ~start ~stop in
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let unit = Markup.Newline Region.{region; value} in
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let markup = unit :: state.markup
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in {state with markup}
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let push_line (thread, state) =
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let start = thread.opening#start in
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let region = Region.make ~start ~stop:state.pos
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and value = mk_str thread.len thread.acc in
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let unit = Markup.LineCom Region.{region; value} in
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let markup = unit :: state.markup
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in {state with markup}
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let push_block (thread, state) =
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let start = thread.opening#start in
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let region = Region.make ~start ~stop:state.pos
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and value = mk_str thread.len thread.acc in
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let unit = Markup.BlockCom Region.{region; value} in
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let markup = unit :: state.markup
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in {state with markup}
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let push_space state buffer =
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let region, lex, state = sync state buffer in
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let value = String.length lex in
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let unit = Markup.Space Region.{region; value} in
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let markup = unit :: state.markup
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in {state with markup}
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let push_tabs state buffer =
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let region, lex, state = sync state buffer in
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let value = String.length lex in
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let unit = Markup.Tabs Region.{region; value} in
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let markup = unit :: state.markup
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in {state with markup}
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let push_bom state buffer =
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let region, value, state = sync state buffer in
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let unit = Markup.BOM Region.{region; value} in
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let markup = unit :: state.markup
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in {state with markup}
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(* ERRORS *)
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type Error.t += Invalid_utf8_sequence
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type Error.t += Unexpected_character of char
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type Error.t += Undefined_escape_sequence
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type Error.t += Missing_break
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type Error.t += Unterminated_string
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type Error.t += Unterminated_integer
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type Error.t += Odd_lengthed_bytes
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type Error.t += Unterminated_comment
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type Error.t += Orphan_minus
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type Error.t += Non_canonical_zero
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type Error.t += Negative_byte_sequence
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type Error.t += Broken_string
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type Error.t += Invalid_character_in_string
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type Error.t += Reserved_name
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let error_to_string = function
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Invalid_utf8_sequence ->
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"Invalid UTF-8 sequence.\n"
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| Unexpected_character c ->
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sprintf "Unexpected character '%s'.\n" (Char.escaped c)
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| Undefined_escape_sequence ->
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"Undefined escape sequence.\n\
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Hint: Remove or replace the sequence.\n"
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| Missing_break ->
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"Missing break.\n\
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Hint: Insert some space.\n"
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| Unterminated_string ->
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"Unterminated string.\n\
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Hint: Close with double quotes.\n"
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| Unterminated_integer ->
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"Unterminated integer.\n\
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Hint: Remove the sign or proceed with a natural number.\n"
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| Odd_lengthed_bytes ->
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"The length of the byte sequence is an odd number.\n\
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Hint: Add or remove a digit.\n"
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| Unterminated_comment ->
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"Unterminated comment.\n\
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Hint: Close with \"*)\".\n"
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| Orphan_minus ->
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"Orphan minus sign.\n\
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Hint: Remove the trailing space.\n"
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| Non_canonical_zero ->
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"Non-canonical zero.\n\
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Hint: Use 0.\n"
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| Negative_byte_sequence ->
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"Negative byte sequence.\n\
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Hint: Remove the leading minus sign.\n"
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| Broken_string ->
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"The string starting here is interrupted by a line break.\n\
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Hint: Remove the break or close the string before.\n"
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| Invalid_character_in_string ->
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"Invalid character in string.\n\
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Hint: Remove or replace the character.\n"
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| Reserved_name ->
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"Reserved named.\n\
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Hint: Change the name.\n"
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| _ -> assert false
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exception Error of Error.t Region.reg
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let fail region value = raise (Error Region.{region; value})
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(* TOKENS *)
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(* Making tokens *)
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let mk_string (thread, state) =
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let start = thread.opening#start in
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let stop = state.pos in
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let region = Region.make ~start ~stop in
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let lexeme = mk_str thread.len thread.acc in
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let token = Token.mk_string lexeme region
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in token, state
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let mk_bytes bytes state buffer =
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let region, _, state = sync state buffer in
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let token = Token.mk_bytes bytes region
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in token, state
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let mk_int state buffer =
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let region, lexeme, state = sync state buffer in
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match Token.mk_int lexeme region with
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Ok token -> token, state
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| Error Token.Non_canonical_zero ->
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fail region Non_canonical_zero
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let mk_ident state buffer =
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let region, lexeme, state = sync state buffer in
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match Token.mk_ident lexeme region with
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Ok token -> token, state
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| Error Token.Reserved_name -> fail region Reserved_name
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let mk_constr state buffer =
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let region, lexeme, state = sync state buffer
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in Token.mk_constr lexeme region, state
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let mk_sym state buffer =
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let region, lexeme, state = sync state buffer
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in Token.mk_sym lexeme region, state
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let mk_eof state buffer =
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let region, _, state = sync state buffer
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in Token.eof region, state
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(* END HEADER *)
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}
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(* START LEXER DEFINITION *)
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(* Named regular expressions *)
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let utf8_bom = "\xEF\xBB\xBF" (* Byte Order Mark for UTF-8 *)
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let nl = ['\n' '\r'] | "\r\n"
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let blank = ' ' | '\t'
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let digit = ['0'-'9']
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let natural = digit | digit (digit | '_')* digit
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let integer = '-'? natural
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let small = ['a'-'z']
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let capital = ['A'-'Z']
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let letter = small | capital
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let ident = small (letter | '_' | digit)*
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let constr = capital (letter | '_' | digit)*
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let hexa_digit = digit | ['A'-'F']
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let byte = hexa_digit hexa_digit
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let byte_seq = byte | byte (byte | '_')* byte
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let bytes = "0x" (byte_seq? as seq)
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let esc = "\\n" | "\\\"" | "\\\\" | "\\b"
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| "\\r" | "\\t" | "\\x" byte
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let symbol = ';' | ',' | '(' | ')'| '[' | ']'
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| '#' | '|' | "->" | ":=" | '=' | ':'
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| '<' | "<=" | '>' | ">=" | "=/="
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| '+' | '-' | '*' | '.' | '_' | '^'
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let string = [^'"' '\\' '\n']* (* For strings of #include *)
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(* RULES *)
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(* Except for the first rule [init], all rules bear a name starting
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with "scan".
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All have a parameter [state] that they thread through their
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recursive calls. The rules for the structured constructs (strings
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and comments) have an extra parameter of type [thread] (see above).
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*)
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rule init state = parse
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utf8_bom { scan (push_bom state lexbuf) lexbuf }
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| _ { rollback lexbuf; scan state lexbuf }
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and scan state = parse
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nl { scan (push_newline state lexbuf) lexbuf }
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| ' '+ { scan (push_space state lexbuf) lexbuf }
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| '\t'+ { scan (push_tabs state lexbuf) lexbuf }
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| ident { mk_ident state lexbuf |> enqueue }
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| constr { mk_constr state lexbuf |> enqueue }
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| bytes { (mk_bytes seq) state lexbuf |> enqueue }
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| integer { mk_int state lexbuf |> enqueue }
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| symbol { mk_sym state lexbuf |> enqueue }
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| eof { mk_eof state lexbuf |> enqueue }
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| '"' { let opening, _, state = sync state lexbuf in
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let thread = {opening; len=1; acc=['"']} in
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scan_string thread state lexbuf |> mk_string |> enqueue }
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| "(*" { let opening, _, state = sync state lexbuf in
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let thread = {opening; len=2; acc=['*';'(']} in
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let state = scan_block thread state lexbuf |> push_block
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in scan state lexbuf }
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| "//" { let opening, _, state = sync state lexbuf in
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let thread = {opening; len=2; acc=['/';'/']} in
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let state = scan_line thread state lexbuf |> push_line
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in scan state lexbuf }
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(* Management of #include CPP directives
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An input LIGO program may contain GNU CPP (C preprocessor)
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directives, and the entry modules (named *Main.ml) run CPP on them
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in traditional mode:
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https://gcc.gnu.org/onlinedocs/cpp/Traditional-Mode.html
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The main interest in using CPP is that it can stand for a poor
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man's (flat) module system for LIGO thanks to #include
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directives, and the traditional mode leaves the markup mostly
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undisturbed.
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Some of the #line resulting from processing #include directives
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deal with system file headers and thus have to be ignored for our
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purpose. Moreover, these #line directives may also carry some
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additional flags:
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https://gcc.gnu.org/onlinedocs/cpp/Preprocessor-Output.html
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of which 1 and 2 indicate, respectively, the start of a new file
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and the return from a file (after its inclusion has been
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processed).
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*)
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| '#' blank* ("line" blank+)? (integer as line) blank+
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'"' (string as file) '"' {
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let _, _, state = sync state lexbuf in
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let flags, state = scan_flags state [] lexbuf in
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let () = ignore flags in
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let line = int_of_string line
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and file = Filename.basename file in
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let pos = state.pos#set ~file ~line ~offset:0 in
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let state = {state with pos} in
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scan state lexbuf
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}
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(* Some special errors
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Some special errors are recognised in the semantic actions of the
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following regular expressions. The first error is a minus sign
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separated from the integer it modifies by some markup (space or
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tabs). The second is a minus sign immediately followed by
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anything else than a natural number (matched above) or markup and
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a number (previous error). The third is the strange occurrence of
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an attempt at defining a negative byte sequence. Finally, the
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catch-all rule reports unexpected characters in the buffer (and
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is not so special, after all).
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*)
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| '-' { let region, _, state = sync state lexbuf in
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let state = scan state lexbuf in
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let open Markup in
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match FQueue.peek state.units with
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None -> assert false
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| Some (_, ((Space _ | Tabs _)::_, token))
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when Token.is_int token ->
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fail region Orphan_minus
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| _ -> fail region Unterminated_integer }
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| '-' "0x" byte_seq?
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{ let region, _, _ = sync state lexbuf
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in fail region Negative_byte_sequence }
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| _ as c { let region, _, _ = sync state lexbuf
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in fail region (Unexpected_character c) }
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(* Scanning CPP #include flags *)
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and scan_flags state acc = parse
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blank+ { let _, _, state = sync state lexbuf
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in scan_flags state acc lexbuf }
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| integer as code { let _, _, state = sync state lexbuf in
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let acc = int_of_string code :: acc
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in scan_flags state acc lexbuf }
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| nl { List.rev acc, push_newline state lexbuf }
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| eof { let _, _, state = sync state lexbuf
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in List.rev acc, state (* TODO *) }
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(* Finishing a string *)
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and scan_string thread state = parse
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nl { fail thread.opening Broken_string }
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| eof { fail thread.opening Unterminated_string }
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| ['\t' '\r' '\b']
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{ let region, _, _ = sync state lexbuf
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in fail region Invalid_character_in_string }
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| '"' { let _, _, state = sync state lexbuf
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in push_char '"' thread, state }
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| esc { let _, lexeme, state = sync state lexbuf
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in scan_string (push_string lexeme thread) state lexbuf }
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| '\\' _ { let region, _, _ = sync state lexbuf
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in fail region Undefined_escape_sequence }
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| _ as c { let _, _, state = sync state lexbuf in
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scan_string (push_char c thread) state lexbuf }
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(* Finishing a block comment
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(Note for Emacs: ("(*")
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The lexing of block comments must take care of embedded block
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comments that may occur within, as well as strings, so no substring
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"*)" may inadvertently close the block. This is the purpose
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of the first case of the scanner [scan_block].
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*)
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and scan_block thread state = parse
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'"' | "(*" { let opening = thread.opening in
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let opening', lexeme, state = sync state lexbuf in
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let thread = push_string lexeme thread in
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let thread = {thread with opening=opening'} in
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let next = if lexeme = "\"" then scan_string
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else scan_block in
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let thread, state = next thread state lexbuf in
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let thread = {thread with opening}
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in scan_block thread state lexbuf }
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| "*)" { let _, lexeme, state = sync state lexbuf
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in push_string lexeme thread, state }
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| nl as nl { let () = Lexing.new_line lexbuf
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and state = {state with pos = state.pos#new_line nl}
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and thread = push_string nl thread
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in scan_block thread state lexbuf }
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| eof { fail thread.opening Unterminated_comment }
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| _ { let () = rollback lexbuf in
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let len = thread.len in
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let thread,
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status = scan_utf8 thread state lexbuf in
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let delta = thread.len - len in
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let pos = state.pos#shift_one_uchar delta in
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match status with
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None -> scan_block thread {state with pos} lexbuf
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| Some error ->
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let region = Region.make ~start:state.pos ~stop:pos
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in fail region error }
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(* Finishing a line comment *)
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and scan_line thread state = parse
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nl as nl { let () = Lexing.new_line lexbuf
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and thread = push_string nl thread
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and state = {state with pos = state.pos#new_line nl}
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in thread, state }
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| eof { fail thread.opening Unterminated_comment }
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| _ { let () = rollback lexbuf in
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let len = thread.len in
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let thread,
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status = scan_utf8 thread state lexbuf in
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let delta = thread.len - len in
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let pos = state.pos#shift_one_uchar delta in
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match status with
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None -> scan_line thread {state with pos} lexbuf
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| Some error ->
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let region = Region.make ~start:state.pos ~stop:pos
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in fail region error }
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and scan_utf8 thread state = parse
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eof { fail thread.opening Unterminated_comment }
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| _ as c { let thread = push_char c thread in
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let lexeme = Lexing.lexeme lexbuf in
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let () = state.supply (Bytes.of_string lexeme) 0 1 in
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match Uutf.decode state.decoder with
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`Uchar _ -> thread, None
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| `Malformed _ -> thread, Some Invalid_utf8_sequence
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| `Await -> scan_utf8 thread state lexbuf
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| `End -> assert false }
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(* END LEXER DEFINITION *)
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{
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(* START TRAILER *)
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(* Scanning the lexing buffer for tokens (and markup, as a
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side-effect).
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Because we want the lexer to have access to the right lexical
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context of a recognised lexeme (to enforce stylistic constraints or
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report special error patterns), we need to keep a hidden reference
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to a queue of recognised lexical units (that is, tokens and markup)
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|
that acts as a mutable state between the calls to
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[read_token]. When [read_token] is called, that queue is consulted
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first and, if it contains at least one token, that token is
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returned; otherwise, the lexing buffer is scanned for at least one
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more new token. That is the general principle: we put a high-level
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buffer (our queue) on top of the low-level lexing buffer.
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One tricky and important detail is that we must make any parser
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generated by Menhir (and calling [read_token]) believe that the
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last region of the input source that was matched indeed corresponds
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to the returned token, despite that many tokens and markup may have
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been matched since it was actually read from the input. In other
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words, the parser requests a token that is taken from the
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high-level buffer, but the parser requests the source regions from
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the _low-level_ lexing buffer, and they may disagree if more than
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one token has actually been recognised.
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Consequently, in order to maintain a consistent view for the
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parser, we have to patch some fields of the lexing buffer, namely
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[lex_start_p] and [lex_curr_p], as these fields are read by parsers
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generated by Menhir when querying source positions (regions). This
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is the purpose of the function [patch_buffer]. After reading one
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ore more tokens and markup by the scanning rule [scan], we have to
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save in the hidden reference [buf_reg] the region of the source
|
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that was matched by [scan]. This atomic sequence of patching,
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scanning and saving is implemented by the _function_ [scan]
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(beware: it shadows the scanning rule [scan]). The function
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[patch_buffer] is, of course, also called just before returning the
|
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token, so the parser has a view of the lexing buffer consistent
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with the token.
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Note that an additional reference [first_call] is needed to
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distinguish the first call to the function [scan], as the first
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scanning rule is actually [init] (which can handle the BOM), not
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[scan].
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*)
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type logger = Markup.t list -> token -> unit
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type instance = {
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read : ?log:logger -> Lexing.lexbuf -> token;
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buffer : Lexing.lexbuf;
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get_pos : unit -> Pos.t;
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get_last : unit -> Region.t;
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close : unit -> unit
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}
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let file_path = match EvalOpt.input with
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None | Some "-" -> ""
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| Some file_path -> file_path
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let pos = Pos.min#set_file file_path
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let buf_reg = ref (pos#byte, pos#byte)
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and first_call = ref true
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and decoder = Uutf.decoder ~encoding:`UTF_8 `Manual
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let supply = Uutf.Manual.src decoder
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let state = ref {units = FQueue.empty;
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last = Region.ghost;
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pos;
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markup = [];
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decoder;
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supply}
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let get_pos () = !state.pos
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let get_last () = !state.last
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let patch_buffer (start, stop) buffer =
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let open Lexing in
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let file_path = buffer.lex_curr_p.pos_fname in
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buffer.lex_start_p <- {start with pos_fname = file_path};
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buffer.lex_curr_p <- {stop with pos_fname = file_path}
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and save_region buffer =
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buf_reg := Lexing.(buffer.lex_start_p, buffer.lex_curr_p)
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let scan buffer =
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patch_buffer !buf_reg buffer;
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(if !first_call
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then (state := init !state buffer; first_call := false)
|
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else state := scan !state buffer);
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save_region buffer
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|
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let next_token buffer =
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scan buffer;
|
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match FQueue.peek !state.units with
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None -> assert false
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| Some (units, ext_token) ->
|
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state := {!state with units}; Some ext_token
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|
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let check_right_context token buffer =
|
|
let open Token in
|
|
if is_int token || is_bytes token then
|
|
match next_token buffer with
|
|
Some ([], next) ->
|
|
let pos = (Token.to_region token)#stop in
|
|
let region = Region.make ~start:pos ~stop:pos in
|
|
if is_bytes token && is_int next then
|
|
fail region Odd_lengthed_bytes
|
|
else
|
|
if is_ident next || is_string next
|
|
|| is_bytes next || is_int next then
|
|
fail region Missing_break
|
|
| _ -> ()
|
|
else
|
|
if Token.is_ident token || Token.is_string token then
|
|
match next_token buffer with
|
|
Some ([], next) ->
|
|
if Token.is_ident next || Token.is_string next
|
|
|| Token.is_bytes next || Token.is_int next
|
|
then
|
|
let pos = (Token.to_region token)#stop in
|
|
let region = Region.make ~start:pos ~stop:pos
|
|
in fail region Missing_break
|
|
| _ -> ()
|
|
|
|
let rec read_token ?(log=fun _ _ -> ()) buffer =
|
|
match FQueue.deq !state.units with
|
|
None ->
|
|
scan buffer;
|
|
read_token ~log buffer
|
|
| Some (units, (left_mark, token)) ->
|
|
log left_mark token;
|
|
state := {!state with units; last = Token.to_region token};
|
|
check_right_context token buffer;
|
|
patch_buffer (Token.to_region token)#byte_pos buffer;
|
|
token
|
|
|
|
let open_token_stream file_path_opt =
|
|
let cin = match file_path_opt with
|
|
None | Some "-" -> stdin
|
|
| Some file_path -> open_in file_path in
|
|
let buffer = Lexing.from_channel cin in
|
|
let () = match file_path_opt with
|
|
None | Some "-" -> ()
|
|
| Some file_path -> reset ~file:file_path buffer
|
|
and close () = close_in cin in
|
|
{read = read_token; buffer; get_pos; get_last; close}
|
|
|
|
(* Standalone lexer for debugging purposes *)
|
|
|
|
(* Pretty-printing in a string the lexemes making up the markup
|
|
between two tokens, concatenated with the last lexeme itself. *)
|
|
|
|
let output_token ?(offsets=true) mode command
|
|
channel left_mark token : unit =
|
|
let output str = Printf.fprintf channel "%s%!" str in
|
|
let output_nl str = output (str ^ "\n") in
|
|
match command with
|
|
EvalOpt.Quiet -> ()
|
|
| EvalOpt.Tokens -> Token.to_string token ~offsets mode |> output_nl
|
|
| EvalOpt.Copy ->
|
|
let lexeme = Token.to_lexeme token
|
|
and apply acc markup = Markup.to_lexeme markup :: acc
|
|
in List.fold_left apply [lexeme] left_mark
|
|
|> String.concat "" |> output
|
|
| EvalOpt.Units ->
|
|
let abs_token = Token.to_string token ~offsets mode
|
|
and apply acc markup =
|
|
Markup.to_string markup ~offsets mode :: acc
|
|
in List.fold_left apply [abs_token] left_mark
|
|
|> String.concat "\n" |> output_nl
|
|
|
|
let print_error ?(offsets=true) mode Region.{region; value} =
|
|
let msg = error_to_string value in
|
|
let file = match EvalOpt.input with
|
|
None | Some "-" -> false
|
|
| Some _ -> true in
|
|
let reg = region#to_string ~file ~offsets mode in
|
|
Utils.highlight (sprintf "Lexical error %s:\n%s%!" reg msg)
|
|
|
|
let trace ?(offsets=true) mode file_path_opt command : unit =
|
|
try
|
|
let {read; buffer; close; _} = open_token_stream file_path_opt
|
|
and cout = stdout in
|
|
let log = output_token ~offsets mode command cout
|
|
and close_all () = close (); close_out cout in
|
|
let rec iter () =
|
|
match read ~log buffer with
|
|
token ->
|
|
if Token.is_eof token then close_all ()
|
|
else iter ()
|
|
| exception Error e -> print_error ~offsets mode e; close_all ()
|
|
in iter ()
|
|
with Sys_error msg -> Utils.highlight (sprintf "%s\n" msg)
|
|
|
|
end (* of functor [Make] in HEADER *)
|
|
(* END TRAILER *)
|
|
}
|