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(************************************************************************)
(*  v      *   The Coq Proof Assistant  /  The Coq Development Team     *)
(* <O___,, *   INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2010     *)
(*   \VV/  **************************************************************)
(*    //   *      This file is distributed under the terms of the       *)
(*         *       GNU Lesser General Public License Version 2.1        *)
(************************************************************************)

(*s Utility functions for the scanners *)

{
  open Printf
  open Lexing

  (* A function that emulates Lexing.new_line (which does not exist in OCaml < 3.11.0) *)
  let new_line lexbuf =
    let pos = lexbuf.lex_curr_p in
      lexbuf.lex_curr_p <- { pos with
	pos_lnum = pos.pos_lnum + 1;
	pos_bol = pos.pos_cnum }

  (* A list function we need *)
  let rec take n ls =
    if n = 0 then [] else
      match ls with
        | [] -> []
        | (l :: ls) -> l :: (take (n-1) ls)

  (* count the number of spaces at the beginning of a string *)
  let count_spaces s =
    let n = String.length s in
    let rec count c i =
      if i == n then c,i else match s.[i] with
	| '\t' -> count (c + (8 - (c mod 8))) (i + 1)
	| ' ' -> count (c + 1) (i + 1)
	| _ -> c,i
    in
      count 0 0

  let remove_newline s =
    let n = String.length s in
    let rec count i = if i == n || s.[i] <> '\n' then i else count (i + 1) in
    let i = count 0 in
    i, String.sub s i (n - i)

  let count_dashes s =
    let c = ref 0 in
    for i = 0 to String.length s - 1 do if s.[i] = '-' then incr c done;
    !c

  let cut_head_tail_spaces s =
    let n = String.length s in
    let rec look_up i = if i == n || s.[i] <> ' ' then i else look_up (i+1) in
    let rec look_dn i = if i == -1 || s.[i] <> ' ' then i else look_dn (i-1) in
    let l = look_up 0 in
    let r = look_dn (n-1) in
    if l <= r then String.sub s l (r-l+1) else s

  let sec_title s =
    let rec count lev i =
      if s.[i] = '*' then
	count (succ lev) (succ i)
      else
	let t = String.sub s i (String.length s - i) in
	lev, cut_head_tail_spaces t
    in
    count 0 (String.index s '*')

  let strip_eol s =
    let eol = s.[String.length s - 1] = '\n' in
    (eol, if eol then String.sub s 1 (String.length s - 1) else s)


  let formatted = ref false
  let brackets = ref 0
  let comment_level = ref 0
  let in_proof = ref None
  let in_emph = ref false

  let start_emph () = in_emph := true; Output.start_emph ()
  let stop_emph () = if !in_emph then (Output.stop_emph (); in_emph := false)

  let backtrack lexbuf = lexbuf.lex_curr_pos <- lexbuf.lex_start_pos;
    lexbuf.lex_curr_p <- lexbuf.lex_start_p

  let backtrack_past_newline lexbuf =
    let buf = lexeme lexbuf in
    let splits = Str.bounded_split_delim (Str.regexp "['\n']") buf 2 in
      match splits with
        | [] -> ()
        | (_ :: []) -> ()
        | (s1 :: rest :: _) ->
            let length_skip = 1 + String.length s1 in
              lexbuf.lex_curr_pos <- lexbuf.lex_start_pos + length_skip

  let is_space = function ' ' | '\t' | '\n' | '\r' -> true | _ -> false

  (* saving/restoring the PP state *)

  type state = {
    st_gallina : bool;
    st_light : bool
  }

  let state_stack = Stack.create ()

  let save_state () =
    Stack.push { st_gallina = !Cdglobals.gallina; st_light = !Cdglobals.light } state_stack

  let restore_state () =
    let s = Stack.pop state_stack in
    Cdglobals.gallina := s.st_gallina;
    Cdglobals.light := s.st_light

  let without_ref r f x = save_state (); r := false; f x; restore_state ()

  let without_gallina = without_ref Cdglobals.gallina

  let without_light = without_ref Cdglobals.light

  let show_all f = without_gallina (without_light f)

  let begin_show () = save_state (); Cdglobals.gallina := false; Cdglobals.light := false
  let end_show () = restore_state ()

  (* Reset the globals *)

  let reset () =
    formatted := false;
    brackets := 0;
    comment_level := 0

  (* erasing of Section/End *)

  let section_re = Str.regexp "[ \t]*Section"
  let end_re = Str.regexp "[ \t]*End"
  let is_section s = Str.string_match section_re s 0
  let is_end s = Str.string_match end_re s 0

  let sections_to_close = ref 0

  let section_or_end s =
    if is_section s then begin
      incr sections_to_close; true
    end else if is_end s then begin
      if !sections_to_close > 0 then begin
	decr sections_to_close; true
      end else
	false
    end else
      true

  (* for item lists *)
  type list_compare =
      | Before
      | StartLevel of int
      | InLevel of int * bool

  (* Before : we're before any levels
     StartLevel : at the same column as the dash in a level
     InLevel : after the dash of this level, but before any deeper dashes.
               bool is true if this is the last level *)
  let find_level levels cur_indent =
    match levels with
    | [] -> Before
    | (l::ls) ->
        if cur_indent < l then Before
        else
          (* cur_indent will never be less than the head of the list *)
          let rec findind ls n =
            match ls with
            | [] -> InLevel (n,true)
            | (l :: []) -> if cur_indent = l then StartLevel n
                           else InLevel (n,true)
            | (l1 :: l2 :: ls) ->
                if cur_indent = l1 then StartLevel n
                else if cur_indent < l2 then InLevel (n,false)
                     else findind (l2 :: ls) (n+1)
          in
            findind (l::ls) 1

  type is_start_list =
    | Rule
    | List of int
    | Neither

  let check_start_list str =
    let n_dashes = count_dashes str in
    let (n_spaces,_) = count_spaces str in
      if n_dashes >= 4 && not !Cdglobals.plain_comments then
        Rule
      else
        if n_dashes = 1 && not !Cdglobals.plain_comments then
          List n_spaces
        else
          Neither

   (* examine a string for subtitleness *)
  let subtitle m s =
    match Str.split_delim (Str.regexp ":") s with
    | [] -> false
    | (name::_) ->
        if (cut_head_tail_spaces name) = m then
          true
        else
          false


  (* tokens pretty-print *)

  let token_buffer = Buffer.create 1024

  let token_re =
    Str.regexp "[ \t]*(\\*\\*[ \t]+printing[ \t]+\\([^ \t]+\\)"
  let printing_token_re =
    Str.regexp
      "[ \t]*\\(\\(%\\([^%]*\\)%\\)\\|\\(\\$[^$]*\\$\\)\\)?[ \t]*\\(#\\(\\(&#\\|[^#]\\)*\\)#\\)?"

  let add_printing_token toks pps =
    try
      if Str.string_match token_re toks 0 then
	let tok = Str.matched_group 1 toks in
	if Str.string_match printing_token_re pps 0 then
	  let pp =
	    (try Some (Str.matched_group 3 pps) with _ ->
             try Some (Str.matched_group 4 pps) with _ -> None),
	    (try Some (Str.matched_group 6 pps) with _ -> None)
	  in
	  Output.add_printing_token tok pp
    with _ ->
      ()

  let remove_token_re =
    Str.regexp
      "[ \t]*(\\*\\*[ \t]+remove[ \t]+printing[ \t]+\\([^ \t]+\\)[ \t]*\\*)"

  let remove_printing_token toks =
    try
      if Str.string_match remove_token_re toks 0 then
	let tok = Str.matched_group 1 toks in
	Output.remove_printing_token tok
    with _ ->
      ()

  let extract_ident_re = Str.regexp "([ \t]*\\([^ \t]+\\)[ \t]*:="
  let extract_ident s =
    assert (String.length s >= 3);
    if Str.string_match extract_ident_re s 0 then
      Str.matched_group 1 s
    else
      String.sub s 1 (String.length s - 3)

  let output_indented_keyword s lexbuf =
    let nbsp,isp = count_spaces s in
    Output.indentation nbsp;
    let s = String.sub s isp (String.length s - isp) in
    Output.ident s (lexeme_start lexbuf + isp)

}

(*s Regular expressions *)

let space = [' ' '\t']
let space_nl = [' ' '\t' '\n' '\r']
let nl = "\r\n" | '\n'

let firstchar =
  ['A'-'Z' 'a'-'z' '_'] |
  (* superscript 1 *)
  '\194' '\185' |
  (* utf-8 latin 1 supplement *)
  '\195' ['\128'-'\191'] |
  (* utf-8 letterlike symbols *)
  (* '\206' ([ '\145' - '\183'] | '\187') | *)
  (* '\xCF' [ '\x00' - '\xCE' ] |  *)
  (* utf-8 letterlike symbols *)
  '\206' ('\160' | [ '\177'-'\183'] | '\187') |
  '\226' ('\130' [ '\128'-'\137' ] (* subscripts *)
    | '\129' [ '\176'-'\187' ] (* superscripts *)
    | '\132' ['\128'-'\191'] | '\133' ['\128'-'\143'])
let identchar =
  firstchar | ['\'' '0'-'9' '@' ]
let id = firstchar identchar*
let pfx_id = (id '.')*
let identifier =
  id | pfx_id id

(* This misses unicode stuff, and it adds "[" and "]".  It's only an
   approximation of idents - used for detecting whether an underscore
   is part of an identifier or meant to indicate emphasis *)
let nonidentchar = [^ 'A'-'Z' 'a'-'z' '_' '[' ']' '\'' '0'-'9' '@' ]

let printing_token = [^ ' ' '\t']*

let thm_token =
  "Theorem"
  | "Lemma"
  | "Fact"
  | "Remark"
  | "Corollary"
  | "Proposition"
  | "Property"
  | "Goal"

let prf_token =
  "Next" space+ "Obligation"
  | "Proof" (space* "." | space+ "with")

let def_token =
  "Definition"
  | "Let"
  | "Class"
  | "SubClass"
  | "Example"
  | "Local"
  | "Fixpoint"
  | "Function"
  | "Boxed"
  | "CoFixpoint"
  | "Record"
  | "Structure"
  | "Scheme"
  | "Inductive"
  | "CoInductive"
  | "Equations"
  | "Instance"
  | "Declare" space+ "Instance"
  | "Global" space+ "Instance"

let decl_token =
  "Hypothesis"
  | "Hypotheses"
  | "Parameter"
  | "Axiom" 's'?
  | "Conjecture"

let gallina_ext =
  "Module"
  | "Include" space+ "Type"
  | "Include"
  | "Declare" space+ "Module"
  | "Transparent"
  | "Opaque"
  | "Canonical"
  | "Coercion"
  | "Identity"
  | "Implicit"
  | "Tactic" space+ "Notation"
  | "Section"
  | "Context"
  | "Variable" 's'?
  | ("Hypothesis" | "Hypotheses")
  | "End"

let notation_kw =
    "Notation"
  | "Infix"
  | "Reserved" space+ "Notation"

let commands =
  "Pwd"
  | "Cd"
  | "Drop"
  | "ProtectedLoop"
  | "Quit"
  | "Load"
  | "Add"
  | "Remove" space+ "Loadpath"
  | "Print"
  | "Inspect"
  | "About"
  | "Search"
  | "Eval"
  | "Reset"
  | "Check"
  | "Type"

  | "Section"
  | "Chapter"
  | "Variable" 's'?
  | ("Hypothesis" | "Hypotheses")
  | "End"

let end_kw = "Qed" | "Defined" | "Save" | "Admitted" | "Abort"

let extraction =
  "Extraction"
  | "Recursive" space+ "Extraction"
  | "Extract"

let gallina_kw = thm_token | def_token | decl_token | gallina_ext | commands | extraction

let prog_kw =
  "Program" space+ gallina_kw
  | "Obligation"
  | "Obligations"
  | "Solve"

let gallina_kw_to_hide =
    "Implicit" space+ "Arguments"
  | "Ltac"
  | "Require"
  | "Import"
  | "Export"
  | "Load"
  | "Hint"
  | "Open"
  | "Close"
  | "Delimit"
  | "Transparent"
  | "Opaque"
  | ("Declare" space+ ("Morphism" | "Step") )
  | ("Set" | "Unset") space+ "Printing" space+ "Coercions"
  | "Declare" space+ ("Left" | "Right") space+ "Step"


let section = "*" | "**" | "***" | "****"

let item_space = "    "

let begin_hide = "(*" space* "begin" space+ "hide" space* "*)" space* nl
let end_hide = "(*" space* "end" space+ "hide" space* "*)" space* nl
let begin_show = "(*" space* "begin" space+ "show" space* "*)" space* nl
let end_show = "(*" space* "end" space+ "show" space* "*)" space* nl
(*
let begin_verb = "(*" space* "begin" space+ "verb" space* "*)"
let end_verb = "(*" space* "end" space+ "verb" space* "*)"
*)

(*s Scanning Coq, at beginning of line *)

rule coq_bol = parse
  | space* nl+
      { if not (!in_proof <> None && (!Cdglobals.gallina || !Cdglobals.light))
        then Output.empty_line_of_code ();
        coq_bol lexbuf }
  | space* "(**" space_nl
      { Output.end_coq (); Output.start_doc ();
	let eol = doc_bol lexbuf in
	  Output.end_doc (); Output.start_coq ();
	  if eol then coq_bol lexbuf else coq lexbuf }
  | space* "Comments" space_nl
      { Output.end_coq (); Output.start_doc (); comments lexbuf; Output.end_doc ();
	Output.start_coq (); coq lexbuf }
  | space* begin_hide
      { skip_hide lexbuf; coq_bol lexbuf }
  | space* begin_show
      { begin_show (); coq_bol lexbuf }
  | space* end_show
      { end_show (); coq_bol lexbuf }
  | space* gallina_kw_to_hide
      { let s = lexeme lexbuf in
	  if !Cdglobals.light && section_or_end s then
	    let eol = skip_to_dot lexbuf in
	      if eol then (coq_bol lexbuf) else coq lexbuf
	  else
	    begin
	      output_indented_keyword s lexbuf;
	      let eol = body lexbuf in
	      if eol then coq_bol lexbuf else coq lexbuf
	    end }
  | space* thm_token
      { let s = lexeme lexbuf in
        output_indented_keyword s lexbuf;
        let eol = body lexbuf in
	in_proof := Some eol;
	if eol then coq_bol lexbuf else coq lexbuf }
  | space* prf_token
      { in_proof := Some true;
	let eol =
	  if not !Cdglobals.gallina then
	    begin backtrack lexbuf; body_bol lexbuf end
	  else
	    let s = lexeme lexbuf in
	      if s.[String.length s - 1] = '.' then false
	      else skip_to_dot lexbuf
	in if eol then coq_bol lexbuf else coq lexbuf }
  | space* end_kw {
      let eol =
	if not (!in_proof <> None && !Cdglobals.gallina) then
	  begin backtrack lexbuf; body_bol lexbuf end
	else skip_to_dot lexbuf
      in
	in_proof := None;
	if eol then coq_bol lexbuf else coq lexbuf }
  | space* gallina_kw
      {
	in_proof := None;
	let s = lexeme lexbuf in
	output_indented_keyword s lexbuf;
	let eol= body lexbuf in
	if eol then coq_bol lexbuf else coq lexbuf }
  | space* prog_kw
      {
	in_proof := None;
	let s = lexeme lexbuf in
	output_indented_keyword s lexbuf;
	let eol= body lexbuf in
	if eol then coq_bol lexbuf else coq lexbuf }
  | space* notation_kw space*
      {	let s = lexeme lexbuf in
	output_indented_keyword s lexbuf;
	let eol= start_notation_string lexbuf in
	if eol then coq_bol lexbuf else coq lexbuf }

  | space* "(**" space+ "printing" space+ printing_token space+
      { let tok = lexeme lexbuf in
	let s = printing_token_body lexbuf in
	  add_printing_token tok s;
	  coq_bol lexbuf }
  | space* "(**" space+ "printing" space+
      { eprintf "warning: bad 'printing' command at character %d\n"
	  (lexeme_start lexbuf); flush stderr;
	comment_level := 1;
	ignore (comment lexbuf);
	coq_bol lexbuf }
  | space* "(**" space+ "remove" space+ "printing" space+
      printing_token space* "*)"
      { remove_printing_token (lexeme lexbuf);
	coq_bol lexbuf }
  | space* "(**" space+ "remove" space+ "printing" space+
      { eprintf "warning: bad 'remove printing' command at character %d\n"
	  (lexeme_start lexbuf); flush stderr;
	comment_level := 1;
	ignore (comment lexbuf);
	coq_bol lexbuf }
  | space* "(*"
      { comment_level := 1;
	if !Cdglobals.parse_comments then begin
	  let s = lexeme lexbuf in
	  let nbsp,isp = count_spaces s in
	    Output.indentation nbsp;
	    Output.start_comment ();
	end;
	let eol = comment lexbuf in
	  if eol then coq_bol lexbuf else coq lexbuf }
  | eof
      { () }
  | _
      { let eol =
	  if not !Cdglobals.gallina then
	    begin backtrack lexbuf; body_bol lexbuf end
	  else
	    skip_to_dot lexbuf
	in
	  if eol then coq_bol lexbuf else coq lexbuf }

(*s Scanning Coq elsewhere *)

and coq = parse
  | nl
      { if not (!in_proof <> None && !Cdglobals.gallina) then Output.line_break(); coq_bol lexbuf }
  | "(**" space_nl
      { Output.end_coq (); Output.start_doc ();
	let eol = doc_bol lexbuf in
	  Output.end_doc (); Output.start_coq ();
	  if eol then coq_bol lexbuf else coq lexbuf }
  | "(*"
      { comment_level := 1;
	if !Cdglobals.parse_comments then begin
	  let s = lexeme lexbuf in
	  let nbsp,isp = count_spaces s in
	    Output.indentation nbsp;
	    Output.start_comment ();
	end;
	let eol = comment lexbuf in
	  if eol then coq_bol lexbuf
          else coq lexbuf
      }
  | nl+ space* "]]"
      { if not !formatted then
	begin
	  (* Isn't this an anomaly *)
	  let s = lexeme lexbuf in
	  let nlsp,s = remove_newline s in
	  let nbsp,isp = count_spaces s in
	  Output.indentation nbsp;
	  let loc = lexeme_start lexbuf + isp + nlsp in
	  Output.sublexer ']' loc;
	  Output.sublexer ']' (loc+1);
	  coq lexbuf
	end }
  | eof
      { () }
  | gallina_kw_to_hide
      { let s = lexeme lexbuf in
	  if !Cdglobals.light && section_or_end s then
	    begin
	      let eol = skip_to_dot lexbuf in
		if eol then coq_bol lexbuf else coq lexbuf
	    end
	  else
	    begin
	      Output.ident s (lexeme_start lexbuf);
	      let eol=body lexbuf in
		if eol then coq_bol lexbuf else coq lexbuf
	    end }
  | prf_token
      { let eol =
	  if not !Cdglobals.gallina then
	    begin backtrack lexbuf; body_bol lexbuf end
	  else
	    let s = lexeme lexbuf in
	    let eol =
	      if s.[String.length s - 1] = '.' then false
	      else skip_to_dot lexbuf
	    in
	      eol
	in if eol then coq_bol lexbuf else coq lexbuf }
  | end_kw {
      let eol =
	if not !Cdglobals.gallina then
	  begin backtrack lexbuf; body lexbuf end
	else
	  let eol = skip_to_dot lexbuf in
	    if !in_proof <> Some true && eol then
	      Output.line_break ();
	    eol
      in
	in_proof := None;
	if eol then coq_bol lexbuf else coq lexbuf }
  | gallina_kw
      { let s = lexeme lexbuf in
	  Output.ident s (lexeme_start lexbuf);
	let eol = body lexbuf in
	  if eol then coq_bol lexbuf else coq lexbuf }
  | notation_kw space*
      { let s = lexeme lexbuf in
	Output.ident s (lexeme_start lexbuf);
	let eol= start_notation_string lexbuf in
	if eol then coq_bol lexbuf else coq lexbuf }
  | prog_kw
      { let s = lexeme lexbuf in
	  Output.ident s (lexeme_start lexbuf);
	let eol = body lexbuf in
	  if eol then coq_bol lexbuf else coq lexbuf }
  | space+ { Output.char ' '; coq lexbuf }
  | eof
      { () }
  | _ {	let eol =
	  if not !Cdglobals.gallina then
	    begin backtrack lexbuf; body lexbuf end
	  else
	    skip_to_dot lexbuf
	in
	  if eol then coq_bol lexbuf else coq lexbuf}

(*s Scanning documentation, at beginning of line *)

and doc_bol = parse
  | space* section space+ ([^'\n' '*'] | '*'+ [^'\n' ')' '*'])* ('*'+ '\n')?
      { let eol, lex = strip_eol (lexeme lexbuf) in
        let lev, s = sec_title lex in
          if (!Cdglobals.lib_subtitles) &&
             (subtitle (Output.get_module false) s) then
            ()
          else
            Output.section lev (fun () -> ignore (doc None (from_string s)));
	    if eol then doc_bol lexbuf else doc None lexbuf }
  | space_nl* '-'+
      { let buf' = lexeme lexbuf in
        let bufs = Str.split_delim (Str.regexp "['\n']") buf' in
        let lines = (List.length bufs) - 1 in
        let line = 
          match bufs with
          | [] -> eprintf "Internal error bad_split1 - please report\n";
                  exit 1
          | _ -> List.nth bufs lines
        in
          match check_start_list line with
          | Neither -> backtrack_past_newline lexbuf; doc None lexbuf
          | List n -> Output.paragraph ();
                      Output.item 1; doc (Some [n]) lexbuf
          | Rule -> Output.rule (); doc None lexbuf
      }
  | space* nl+
      { Output.paragraph (); doc_bol lexbuf }
  | "<<" space*
      { Output.start_verbatim (); verbatim lexbuf; doc_bol lexbuf }
  | eof
      { true }
  | '_'
      { if !Cdglobals.plain_comments then Output.char '_' else start_emph ();
        doc None lexbuf }
  | _
      { backtrack lexbuf; doc None lexbuf }

(*s Scanning lists - using whitespace *)
and doc_list_bol indents = parse
  | space* '-'
      { let (n_spaces,_) = count_spaces (lexeme lexbuf) in
        match find_level indents n_spaces with
        | Before -> backtrack lexbuf; doc_bol lexbuf
        | StartLevel n -> Output.item n; doc (Some (take n indents)) lexbuf
        | InLevel (n,true) ->
            let items = List.length indents in
              Output.item (items+1);
              doc (Some (List.append indents [n_spaces])) lexbuf
        | InLevel (_,false) ->
            backtrack lexbuf; doc_bol lexbuf
      }
  | "<<" space*
      { Output.start_verbatim ();
        verbatim lexbuf;
        doc_list_bol indents lexbuf }
  | "[[" nl
      { formatted := true;
        Output.start_inline_coq_block ();
        ignore(body_bol lexbuf);
        Output.end_inline_coq_block ();
        formatted := false;
        doc_list_bol indents lexbuf }
  | "[[[" nl
      { inf_rules (Some indents) lexbuf }
  | space* nl space* '-'
      { (* Like in the doc_bol production, these two productions
           exist only to deal properly with whitespace *)
        Output.paragraph ();
        backtrack_past_newline lexbuf;
        doc_list_bol indents lexbuf }
  | space* nl space* _
      { let buf' = lexeme lexbuf in
        let buf =
          let bufs = Str.split_delim (Str.regexp "['\n']") buf' in
            match bufs with
              | (_ :: s :: []) -> s
              | (_ :: _ :: s :: _) -> s
              | _ -> eprintf "Internal error bad_split2 - please report\n";
                     exit 1
        in
        let (n_spaces,_) = count_spaces buf in
        match find_level indents n_spaces with
        | InLevel _ ->
            Output.paragraph ();
            backtrack_past_newline lexbuf;
            doc_list_bol indents lexbuf
        | StartLevel n ->
            if n = 1 then
              begin
                Output.stop_item ();
                backtrack_past_newline lexbuf;
                doc_bol lexbuf
              end
            else
              begin
                Output.paragraph ();
                backtrack_past_newline lexbuf;
                doc_list_bol indents lexbuf
              end
        | Before -> 
        (* Here we were at the beginning of a line, and it was blank.
           The next line started before any list items.  So: insert
           a paragraph for the empty line, rewind to whatever's just
           after the newline, then toss over to doc_bol for whatever
           comes next. *)
            Output.stop_item ();
            Output.paragraph ();
            backtrack_past_newline lexbuf;
            doc_bol lexbuf

      }
  | space* _
      { let (n_spaces,_) = count_spaces (lexeme lexbuf) in
        match find_level indents n_spaces with
        | Before -> Output.stop_item (); backtrack lexbuf;
                    doc_bol lexbuf
        | StartLevel n ->
            (if n = 1 then
               Output.stop_item ()
             else
               Output.reach_item_level (n-1));
            backtrack lexbuf;
            doc (Some (take (n-1) indents)) lexbuf
        | InLevel (n,_) ->
            Output.reach_item_level n;
            backtrack lexbuf;
            doc (Some (take n indents)) lexbuf
      }

(*s Scanning documentation elsewhere *)
and doc indents = parse
  | nl
      { Output.char '\n';
        match indents with
        | Some ls -> doc_list_bol ls lexbuf
        | None -> doc_bol lexbuf }
  | "[[" nl
      { if !Cdglobals.plain_comments
        then (Output.char '['; Output.char '['; doc indents lexbuf)
        else (formatted := true;
              Output.start_inline_coq_block ();
	      let eol = body_bol lexbuf in
	        Output.end_inline_coq_block (); formatted := false;
	        if eol then
		  match indents with
		  | Some ls -> doc_list_bol ls lexbuf
		  | None -> doc_bol lexbuf
		else doc indents lexbuf)}
  | "[[[" nl
      { inf_rules indents lexbuf }
  | "[]"
      { Output.proofbox (); doc indents lexbuf }
  | "["
      { if !Cdglobals.plain_comments then Output.char '['
        else (brackets := 1;  Output.start_inline_coq (); escaped_coq lexbuf;
              Output.end_inline_coq ()); doc indents lexbuf }
  | "(*"
      { backtrack lexbuf ;
        let bol_parse = match indents with
                        | Some is -> doc_list_bol is
                        | None   -> doc_bol
        in
        let eol = comment lexbuf in
          if eol then bol_parse lexbuf else doc indents lexbuf
      }
  | '*'* "*)" space_nl* "(**"
      {(match indents with
        | Some _ -> Output.stop_item ()
        | None -> ());
       (* this says - if there is a blank line between the two comments,
          insert one in the output too *)
       let lines = List.length (Str.split_delim (Str.regexp "['\n']") 
                                                (lexeme lexbuf))
       in 
         if lines > 2 then Output.paragraph ();
       doc_bol lexbuf
      }
  | '*'* "*)" space* nl
      { true }
  | '*'* "*)"
      { false }
  | "$"
      { if !Cdglobals.plain_comments then Output.char '$'
        else (Output.start_latex_math (); escaped_math_latex lexbuf);
        doc indents lexbuf }
  | "$$"
      { if !Cdglobals.plain_comments then Output.char '$';
        Output.char '$'; doc indents lexbuf }
  | "%"
      { if !Cdglobals.plain_comments then Output.char '%'
        else escaped_latex lexbuf; doc indents lexbuf }
  | "%%"
      { if !Cdglobals.plain_comments then Output.char '%';
        Output.char '%'; doc indents lexbuf }
  | "#"
      { if !Cdglobals.plain_comments then Output.char '#'
        else escaped_html lexbuf; doc indents lexbuf }
  | "##"
      { if !Cdglobals.plain_comments then Output.char '#';
        Output.char '#'; doc indents lexbuf }
  | nonidentchar '_' nonidentchar
      { List.iter (fun x -> Output.char (lexeme_char lexbuf x)) [0;1;2];
        doc indents lexbuf}
  | nonidentchar '_'
      { Output.char (lexeme_char lexbuf 0);
        if !Cdglobals.plain_comments then Output.char '_' else  start_emph () ;
        doc indents lexbuf }
  | '_' nonidentchar
      { if !Cdglobals.plain_comments then Output.char '_' else stop_emph () ;
        Output.char (lexeme_char lexbuf 1);
        doc indents lexbuf }
  | eof
      { false }
  | _
      { Output.char (lexeme_char lexbuf 0); doc indents lexbuf }

(*s Various escapings *)

and escaped_math_latex = parse
  | "$" { Output.stop_latex_math () }
  | eof { Output.stop_latex_math () }
  | _   { Output.latex_char (lexeme_char lexbuf 0); escaped_math_latex lexbuf }

and escaped_latex = parse
  | "%" { () }
  | eof { () }
  | _   { Output.latex_char (lexeme_char lexbuf 0); escaped_latex lexbuf }

and escaped_html = parse
  | "#" { () }
  | "&#"
        { Output.html_char '&'; Output.html_char '#'; escaped_html lexbuf }
  | "##"
        { Output.html_char '#'; escaped_html lexbuf }
  | eof { () }
  | _   { Output.html_char (lexeme_char lexbuf 0); escaped_html lexbuf }

and verbatim = parse
  | nl ">>" space* nl { Output.verbatim_char '\n'; Output.stop_verbatim () }
  | nl ">>" { Output.verbatim_char '\n'; Output.stop_verbatim () }
  | eof { Output.stop_verbatim () }
  | _ { Output.verbatim_char (lexeme_char lexbuf 0); verbatim lexbuf }

(*s Coq, inside quotations *)

and escaped_coq = parse
  | "]"
      { decr brackets;
	if !brackets > 0 then
	  (Output.sublexer ']' (lexeme_start lexbuf); escaped_coq lexbuf)
	else Tokens.flush_sublexer () }
  | "["
      { incr brackets;
        Output.sublexer '[' (lexeme_start lexbuf); escaped_coq lexbuf }
  | "(*"
      { Tokens.flush_sublexer (); comment_level := 1;
        ignore (comment lexbuf); escaped_coq lexbuf }
  | "*)"
      { (* likely to be a syntax error: we escape *) backtrack lexbuf }
  | eof
      { Tokens.flush_sublexer () }
  | (identifier '.')* identifier
      { Output.ident (lexeme lexbuf) (lexeme_start lexbuf); escaped_coq lexbuf }
  | space_nl*
      { let str = lexeme lexbuf in
          Tokens.flush_sublexer();
          (if !Cdglobals.inline_notmono then () 
                                        else Output.end_inline_coq ()); 
          String.iter Output.char str; 
          (if !Cdglobals.inline_notmono then () 
                                        else Output.start_inline_coq ());
          escaped_coq lexbuf }
  | _ 
      { Output.sublexer (lexeme_char lexbuf 0) (lexeme_start lexbuf);
        escaped_coq lexbuf }

(*s Coq "Comments" command. *)

and comments = parse
  | space_nl+
      { Output.char ' '; comments lexbuf }
  | '"' [^ '"']* '"'
      { let s = lexeme lexbuf in
	let s = String.sub s 1 (String.length s - 2) in
	ignore (doc None (from_string s)); comments lexbuf }
  | ([^ '.' '"'] | '.' [^ ' ' '\t' '\n'])+
      { escaped_coq (from_string (lexeme lexbuf)); comments lexbuf }
  | "." (space_nl | eof)
      { () }
  | eof
      { () }
  | _
      { Output.char (lexeme_char lexbuf 0); comments lexbuf }

(*s Skip comments *)

and comment = parse
  | "(*" { incr comment_level;
	   if !Cdglobals.parse_comments then Output.start_comment ();
	   comment lexbuf }
  | "*)" space* nl {
      if !Cdglobals.parse_comments then
	(Output.end_comment (); Output.line_break ());
      decr comment_level; if !comment_level > 0 then comment lexbuf else true }
  | "*)" {
      if !Cdglobals.parse_comments then (Output.end_comment ());
      decr comment_level; if !comment_level > 0 then comment lexbuf else false }
  | "[" {
      if !Cdglobals.parse_comments then
	if !Cdglobals.plain_comments then Output.char '['
        else (brackets := 1; Output.start_inline_coq ();
              escaped_coq lexbuf; Output.end_inline_coq ());
      comment lexbuf }
  | "[[" nl {
      if !Cdglobals.parse_comments then
        if !Cdglobals.plain_comments then (Output.char '['; Output.char '[')
        else (formatted := true;
              Output.start_inline_coq_block ();
              let _ = body_bol lexbuf in
                Output.end_inline_coq_block (); formatted := false);
      comment lexbuf}
  | "$"
      { if !Cdglobals.parse_comments then
          if !Cdglobals.plain_comments then Output.char '$'
          else (Output.start_latex_math (); escaped_math_latex lexbuf);
        comment lexbuf }
  | "$$"
      { if !Cdglobals.parse_comments
        then
          (if !Cdglobals.plain_comments then Output.char '$'; Output.char '$');
        doc None lexbuf }
  | "%"
      { if !Cdglobals.parse_comments
          then
            if !Cdglobals.plain_comments then Output.char '%'
            else escaped_latex lexbuf; comment lexbuf }
  | "%%"
      { if !Cdglobals.parse_comments
        then
          (if !Cdglobals.plain_comments then Output.char '%'; Output.char '%');
        comment lexbuf }
  | "#"
      { if !Cdglobals.parse_comments
        then
          if !Cdglobals.plain_comments then Output.char '$'
          else escaped_html lexbuf; comment lexbuf }
  | "##"
      { if !Cdglobals.parse_comments
        then
          (if !Cdglobals.plain_comments then Output.char '#'; Output.char '#');
        comment lexbuf }
  | eof  { false }
  | space+ { if !Cdglobals.parse_comments
             then Output.indentation (fst (count_spaces (lexeme lexbuf)));
             comment lexbuf }
  | nl   { if !Cdglobals.parse_comments
           then Output.line_break (); comment lexbuf }
  | _    { if !Cdglobals.parse_comments then Output.char (lexeme_char lexbuf 0);
           comment lexbuf }

and skip_to_dot = parse
  | '.' space* nl { true }
  | eof | '.' space+ { false }
  | "(*" { comment_level := 1; ignore (comment lexbuf); skip_to_dot lexbuf }
  | _ { skip_to_dot lexbuf }

and body_bol = parse
  | space+
      { Output.indentation (fst (count_spaces (lexeme lexbuf))); body lexbuf }
  | _ { backtrack lexbuf; Output.indentation 0; body lexbuf }

and body = parse
  | nl {Tokens.flush_sublexer(); Output.line_break(); new_line lexbuf; body_bol lexbuf}
  | nl+ space* "]]" space* nl
      { Tokens.flush_sublexer();
        if not !formatted then
          begin
            let s = lexeme lexbuf in
            let nlsp,s = remove_newline s in
            let _,isp = count_spaces s in
            let loc = lexeme_start lexbuf + nlsp + isp in
            Output.sublexer ']' loc;
            Output.sublexer ']' (loc+1);
            Tokens.flush_sublexer();
            body lexbuf
          end
        else
          begin
            Output.paragraph ();
            true
          end }
  | "]]" space* nl
      { Tokens.flush_sublexer();
        if not !formatted then
          begin
	    let loc = lexeme_start lexbuf in
	    Output.sublexer ']' loc;
	    Output.sublexer ']' (loc+1);
	    Tokens.flush_sublexer();
	    Output.line_break();
            body lexbuf
          end
        else
          begin
            Output.paragraph ();
            true
          end }
  | eof { Tokens.flush_sublexer(); false }
  | '.' space* nl | '.' space* eof
	{ Tokens.flush_sublexer(); Output.char '.'; Output.line_break();
	  if not !formatted then true else body_bol lexbuf }
  | '.' space* nl "]]" space* nl
	{ Tokens.flush_sublexer(); Output.char '.';
        if not !formatted then
          begin
            eprintf "Error: stray ]] at %d\n"  (lexeme_start lexbuf);
            flush stderr;
            exit 1
          end
	  else
          begin
            Output.paragraph ();
            true
          end
      }
  | '.' space+
        { Tokens.flush_sublexer(); Output.char '.'; Output.char ' ';
	  if not !formatted then false else body lexbuf }
  | "(**" space_nl
      { Tokens.flush_sublexer(); Output.end_coq (); Output.start_doc ();
	let eol = doc_bol lexbuf in
	  Output.end_doc (); Output.start_coq ();
	  if eol then body_bol lexbuf else body lexbuf }
  | "(*" { Tokens.flush_sublexer(); comment_level := 1;
	   if !Cdglobals.parse_comments then Output.start_comment ();
	   let eol = comment lexbuf in
	     if eol
	     then begin if not !Cdglobals.parse_comments then Output.line_break(); body_bol lexbuf end
	     else body lexbuf }
  | "where" space*
      { Tokens.flush_sublexer();
        Output.ident (lexeme lexbuf) (lexeme_start lexbuf);
	start_notation_string lexbuf }
  | identifier
      { Tokens.flush_sublexer();
        Output.ident (lexeme lexbuf) (lexeme_start lexbuf);
	body lexbuf }
  | ".."
      { Tokens.flush_sublexer(); Output.char '.'; Output.char '.';
        body lexbuf }
  | '"'
      { Tokens.flush_sublexer(); Output.char '"';
        string lexbuf;
        body lexbuf }
  | space
      { Tokens.flush_sublexer(); Output.char (lexeme_char lexbuf 0);
        body lexbuf }

  | _ { let c = lexeme_char lexbuf 0 in
	Output.sublexer c (lexeme_start lexbuf);
        body lexbuf }

and start_notation_string = parse
  | '"' (* a true notation *)
      { Output.sublexer '"' (lexeme_start lexbuf);
        notation_string lexbuf;
	body lexbuf }
  | _ (* an abbreviation *)
      { backtrack lexbuf; body lexbuf }

and notation_string = parse
  | "\"\""
      { Output.char '"'; Output.char '"'; (* Unlikely! *)
        notation_string lexbuf }
  | '"'
      { Tokens.flush_sublexer(); Output.char '"' }
  | _ { let c = lexeme_char lexbuf 0 in
        Output.sublexer c (lexeme_start lexbuf);
        notation_string lexbuf }

and string = parse
  | "\"\"" { Output.char '"'; Output.char '"'; string lexbuf }
  | '"'    { Output.char '"' }
  | _      { let c = lexeme_char lexbuf 0 in Output.char c; string lexbuf }

and skip_hide = parse
  | eof | end_hide { () }
  | _ { skip_hide lexbuf }

(*s Reading token pretty-print *)

and printing_token_body = parse
  | "*)" nl? | eof
	{ let s = Buffer.contents token_buffer in
	  Buffer.clear token_buffer;
	  s }
  | _   { Buffer.add_string token_buffer (lexeme lexbuf);
	  printing_token_body lexbuf }

(*s These handle inference rules, parsing the body segments of things
    enclosed in [[[  ]]] brackets *)
and inf_rules indents = parse
  | space* nl     (* blank line, before or between definitions *)
      { inf_rules indents lexbuf }
  | "]]]" nl      (* end of the inference rules block *)
      { match indents with
        | Some ls -> doc_list_bol ls lexbuf
        | None -> doc_bol lexbuf }
  | _ 
      { backtrack lexbuf;  (* anything else must be the first line in a rule *)
        inf_rules_assumptions indents [] lexbuf}

(* The inference rule parsing just collects the inference rule and then
   calls the output function once, instead of doing things incrementally
   like the rest of the lexer.  If only there were a real parsing phase...
*)
and inf_rules_assumptions indents assumptions = parse
  | space* "---" '-'* [^ '\n']* nl (* hit the horizontal line *)
      { let line = lexeme lexbuf in
        let (spaces,_) = count_spaces line in
        let dashes_and_name = 
               cut_head_tail_spaces (String.sub line 0 (String.length line - 1))
        in
        let ldn = String.length dashes_and_name in
        let (dashes,name) = 
          try (let i = String.index dashes_and_name ' ' in
               let d = String.sub dashes_and_name 0 i in
               let n = cut_head_tail_spaces 
                        (String.sub dashes_and_name (i+1) (ldn-i-1))
               in
                 (d, Some n))
          with _ -> (dashes_and_name, None)
            
        in
          inf_rules_conclusion indents (List.rev assumptions) 
                               (spaces, dashes, name) [] lexbuf }
  | [^ '\n']* nl (* if it's not the horizontal line, it's an assumption *)
      { let line = lexeme lexbuf in
        let (spaces,_) = count_spaces line in
        let assumption = cut_head_tail_spaces 
                            (String.sub line 0 (String.length line - 1))
        in
          inf_rules_assumptions indents ((spaces,assumption)::assumptions)
                                lexbuf }

(*s The conclusion is required to come immediately after the
    horizontal bar.  It is allowed to contain multiple lines of
    text, like the assumptions.  The conclusion ends when we spot a
    blank line or a ']]]'. *)
and inf_rules_conclusion indents assumptions middle conclusions = parse
  | space* nl | space* "]]]" nl (* end of conclusions. *)
      { backtrack lexbuf;
        Output.inf_rule assumptions middle (List.rev conclusions);
        inf_rules indents lexbuf }
  | space* [^ '\n']+ nl (* this is a line in the conclusion *)
      { let line = lexeme lexbuf in
        let (spaces,_) = count_spaces line in
        let conc = cut_head_tail_spaces (String.sub line 0 
                                                    (String.length line - 1))
        in
          inf_rules_conclusion indents assumptions middle 
                               ((spaces,conc) :: conclusions) lexbuf
      }

(*s A small scanner to support the chapter subtitle feature *)
and st_start m = parse
  | "(*" "*"+ space+ "*" space+
      { st_modname m lexbuf }
  | _
      { None }

and st_modname m = parse
  | identifier space* ":" space*
      { if subtitle m (lexeme lexbuf) then
          st_subtitle lexbuf
        else
          None
      }
  | _
      { None }

and st_subtitle = parse
  | [^ '\n']* '\n'
      { let st = lexeme lexbuf in
        let i = try Str.search_forward (Str.regexp "\\**)") st 0 with
                   Not_found ->
                     (eprintf "unterminated comment at beginning of file\n";
                      exit 1)
        in
          Some (cut_head_tail_spaces (String.sub st 0 i))
      }
  | _
      { None }
(*s Applying the scanners to files *)

{
  let coq_file f m =
    reset ();
    let c = open_in f in
    let lb = from_channel c in
      (Index.current_library := m;
       Output.initialize ();
       Output.start_module ();
       Output.start_coq (); coq_bol lb; Output.end_coq ();
       close_in c)

  let detect_subtitle f m =
    let c = open_in f in
    let lb = from_channel c in
    let sub = st_start m lb in
      close_in c;
      sub
}