/usr/share/hol88-2.02.19940316/Library/parser/parser.ml is in hol88-library-source 2.02.19940316-15.
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1422 1423 1424 1425 1426 1427 1428 1429 1430 1431 1432 1433 1434 1435 1436 1437 1438 1439 1440 | % ===================================================================== %
% FILE NAME : parser.ml %
% USES FILES : N/A %
% DESCRIPTION : This file sets up the parser-generator. It uses %
% one big section so that we only export the top- %
% level function (parse) for use by users. %
% %
% AUTHOR : J. Van Tassel %
% <jvt@cl.cam.ac.uk> %
% %
% ORGANIZATION : University of Cambridge %
% Hardware Verification Group %
% ADDRESS : Computer Laboratory %
% New Museums Site %
% Pembroke Street %
% Cambridge CB2 3QG %
% England %
% PHONE : +44-223-334729 %
% %
% DATE : Tue Mar 13 1990 %
% VERSION : 1 %
% REVISION HISTORY : Tue Nov 3 1990 Cleaned up and made ready for the %
% release of HOL 1.12 %
% ===================================================================== %
% ********************************************************************* %
% Set add to the help search path to provide on-line help for the one %
% function exported to the rest of the world. %
% ********************************************************************* %
let path = library_pathname() ^ `/parser/help/` in
set_help_search_path (path . help_search_path());;
begin_section parser;;
% ********************************************************************* %
% We start with some basic functions used by the rest of the generator. %
% ********************************************************************* %
% ===================================================================== %
% EXPECTED: Holds a list of tokens expected on return from individual %
% productions and action symbols. %
% ===================================================================== %
letref EXPECTED = []:string list;;
% ===================================================================== %
% pg_failwith: Enhanced failwith for reporting encountered during the %
% parsing of an input grammar. %
% ===================================================================== %
let pg_failwith symb prdn reason =
EXPECTED := [];
failwith (concat `\L\L ERROR: symbol "`
(concat symb
(concat `" encountered in the wrong place.\L`
(concat ` -- Production: `
(concat prdn
(concat `\L -- Diagnostic: `
(concat reason `\L`)))))));;
% ===================================================================== %
% escaped: Determine if we have escaped to something that's not an %
% "escapable" character. %
% ===================================================================== %
let escaped ch prdn =
if mem ch [` `;` `;`\L`] then
let nch = if ch = ` ` then `<blank>`
else if ch = ` ` then `<tab>`
else `<newline>` in
pg_failwith nch prdn `escaped to whitespace`
else if mem ch [`}`;`{`;`]`;`[`] then
ch
else if ch = `\\` then
`\\\\`
else
pg_failwith ch prdn `escaped to non-special symbol`;;
% ===================================================================== %
% Suite of I/O functions that tie together terminal and file I/O. The %
% string `nil` denotes terminal I/0. %
% ===================================================================== %
let write_string str file =
if file = `nil` then tty_write str else write(file,str);;
let read_char file =
if file = `nil` then tty_read() else (read file);;
letrec split_filename path lst first =
if null (tl lst) then
if first then
(hd lst,`./`)
else
(hd lst,concatl path)
else
split_filename (append path [(hd lst);`/`]) (tl lst) false;;
let close_file file =
if file = `nil` then ()
else close file;;
letrec bad_read (ch) =
if ch = ascii(10) then failwith `bad file name`
else bad_read (tty_read());;
letrec terminal_read_1 (ch) =
if ch = ascii(10) then []
else if mem ch [` ` ; ` `] then bad_read (tty_read())
else (ch . terminal_read_1 (tty_read ()));;
let terminal_read () =
implode (terminal_read_1 (tty_read ()));;
% ===================================================================== %
% make_Makefile: Build a skeleton Makefile for the generated parser. %
% ===================================================================== %
let make_Makefile filename file path =
let decs = (concat filename `_decls`) in
let outf = openw (concatl [path;`Makefile.`;file]) in
write_string `# Generated parser Makefile\L\L` outf;
write_string `# Version of HOL to be used:\L` outf;
write_string `HOL=../../hol\L\L` outf;
write_string `# General definitions for all generated parsers:\L` outf;
write_string (`GENERAL=`^(library_pathname())^`/parser/general\L\L`) outf;
write_string `# Insert entries for user-defined stuff here:\L` outf;
write_string `# Remember to insert the appropriate ` outf;
write_string `dependencies and "load"'s below.\L\L` outf;
write_string `# Now compile the declarations:\L` outf;
write_string (concatl [file;`_decls_ml.o: `;decs;`.ml\L`]) outf;
write_string ` echo 'set_flag(\`abort_when_fail\`,true);;'\\\L` outf;
write_string `\T 'loadf \`$(GENERAL)\`;;'\\\L` outf;
write_string (concatl [`\T 'compilet \``;filename;`_decls\`;;'\\\L`])
outf;
write_string `\T 'quit();;' | $(HOL)\L\L` outf;
write_string `# Finally do the actual functions\L` outf;
write_string (file^`_ml.o: `^filename^`.ml `^file^`_decls_ml.o\L`) outf;
write_string ` echo 'set_flag(\`abort_when_fail\`,true);;'\\\L` outf;
write_string `\T 'loadf \`$(GENERAL)\`;;'\\\L` outf;
write_string (concatl [`\T 'loadf \``;decs;`\`;;'\\\L`])
outf;
write_string (concatl [`\T 'compilet \``;filename;`\`;;'\\\L`]) outf;
write_string ` 'quit();;' | $(HOL)\L\L` outf;
write_string (concatl [`all: `;file;`_ml.o\L`]) outf;
write_string (concatl [` @echo '===> Parser "`;file;`" built.'\L\L`])
outf;
close outf;;
% ===================================================================== %
% make_makefile: Build a skeleton load file for the generated parser. %
% ===================================================================== %
let make_makefile filename =
let (makefile,decs,main) = ((concat filename `_load.ml`),
(concat filename `_decls`),
filename) in
let outf = openw makefile in
write_string `% Generated parser load file\L\L` outf;
write_string ` First load some basic definitions: %\L` outf;
write_string (`loadf \``^(library_pathname())^`/parser/general\`;;\L\L`)
outf;
write_string `% Insert any other files you want loaded here: %\L\L` outf;
write_string `% Now load the declarations: %\L` outf;
write_string (concat `loadf \``
(concat decs `\`;;\L\L`)) outf;
write_string `% Finally load in the function definitions: %\L` outf;
write_string (concat `loadf \``
(concat main `\`;;\L`)) outf;
close outf;;
let open_file direction filename =
if filename = `nil` then (`nil`,`nil`)
else if mem direction [`in` ; `input` ; `i`] then
((openi filename),`nil`)
else if mem direction [`out`; `output`; `o`] then
let first_char = if (hd (explode filename)) = `/` then [`/`] else [] in
let (file,path) = split_filename first_char (words2 `/` filename) true in
write_string `Opening the file ` `nil`;
write_string (concat filename `.ml (MAIN OUTPUT)\L`) `nil`;
write_string `Opening the file ` `nil`;
write_string (concat filename `_decls.ml (DECLARATIONS)\L`) `nil`;
write_string `Load the declarations file before the main output.\L`
`nil`;
make_makefile filename;
write_string (concat `See the file `
(concat filename `_load.ml for a sample.\L`)) `nil`;
make_Makefile filename file path;
write_string (concatl [`See the file `;path;`Makefile.`;file;
` for a sample Makefile.\L`]) `nil`;
(openw (concat filename `.ml`),openw (concat filename `_decls.ml`))
else
failwith (concat `can't open `
(concat filename
(concat ` in direction ` direction)));;
% ===================================================================== %
% Various ways of eating white space to suit different purposes later %
% on in the generator. %
% ===================================================================== %
letrec eat_white_space file chr =
if mem chr [` ` ; `\T` ; `\L` ] then
eat_white_space file (read_char file)
else
chr;;
letrec e_w_s file chr =
if mem chr [` ` ; `\T` ; `\L` ] then e_w_s file (read_char file)
else if chr = `nil` then failwith `unexpected eof`
else chr;;
letrec e_w_s_ok file chr =
if mem chr [` ` ; `\T` ; `\L` ] then e_w_s file (read_char file)
else if chr = `nil` then `nil`
else chr;;
% ===================================================================== %
% The mechanism to read in a source file containing an input grammar is %
% contained in the following functions. %
% ===================================================================== %
% ------------------------------------------------------------------- %
% write_comments: Write out the rest of a comment after it has been %
% started. %
% ------------------------------------------------------------------- %
letrec write_comments ch in_file out_file prdn =
if ch = `nil` then
pg_failwith `EOF` prdn
`Runnaway comment? EOF encountered before end of comment.`
else if ch = `%` then (write_string ch out_file ;
write_string `\L` out_file ;
e_w_s_ok in_file (read_char in_file))
else (write_string ch out_file ;
write_comments (read_char in_file) in_file out_file prdn);;
% ------------------------------------------------------------------- %
% get_word1: Helping function for get_word below to finish reading in %
% a token from the input grammar. %
% ------------------------------------------------------------------- %
letrec get_word1 in_file lst chr out_file prdn flag =
if mem chr [` ` ; `\L` ; ` `] then
(lst, e_w_s in_file (read_char in_file))
else if chr = `.` then
if flag = `terminal` then
get_word1 in_file (append lst [chr]) (read_char in_file)
out_file prdn flag
else
(lst,chr)
else if mem chr [`nil`; `[` ; `(` ; `{` ; `}` ; `|` ;`[`;`]`] then
(lst,chr)
else if chr = `%` then
(write_string (concat `\L` chr) out_file;
(lst, write_comments (read_char in_file) in_file out_file prdn))
else if chr = `-` then
if flag = `terminal` then
get_word1 in_file (append lst [chr]) (read_char in_file)
out_file prdn flag
else
(lst,chr)
else if chr = `\\` then
if flag = `terminal` then
let nch = escaped (read_char in_file) prdn in
get_word1 in_file (append lst [nch]) (read_char in_file)
out_file prdn flag
else
pg_failwith `\\` prdn `escapes can only be done in terminals.`
else
get_word1 in_file (append lst [chr]) (read_char in_file)
out_file prdn flag;;
% ------------------------------------------------------------------- %
% first_test: Is the current character legal? %
% ------------------------------------------------------------------- %
let first_test flag ch =
if flag = `first` then
mem ch (append
(words `a b c d e f g h i j k l m n o p q r s t u v w x y z`)
(words `A B C D E F G H I J K L M N O P Q R S T U V W X Y Z`))
else
true;;
% ------------------------------------------------------------------- %
% get_word: Read in a token from the input grammar. %
% ------------------------------------------------------------------- %
letrec get_word in_file ch out_file prdn flag =
if ch = `nil` then
(`nil`,`nil`)
else if ch = `%` then
(write_string (concat `\L` ch) out_file;
get_word in_file (write_comments (read_char in_file)
in_file out_file prdn)
out_file prdn flag)
else if ch = `\\` then
if flag = `terminal` then
let nch = escaped (read_char in_file) prdn in
let (wrd,next_ch) = get_word1 in_file [`\\`;nch] (read_char in_file)
out_file prdn flag in
(implode wrd,next_ch)
else
pg_failwith `\\` prdn `escapes can only be done in terminals.`
else
(if first_test flag ch then
let (wrd,next_ch) = get_word1 in_file [ch] (read_char in_file)
out_file prdn flag in
(implode wrd,next_ch)
else
pg_failwith ch prdn `not appropriate first character`);;
% ------------------------------------------------------------------- %
% get_inits1: Finish reading in a list of either FIRST_CHARS or CHARS %
% ------------------------------------------------------------------- %
letrec get_inits1 ch lst file =
if ch = `\`` then (lst,e_w_s file ` `)
else if mem ch [`\L`;`\T`] then
get_inits1 (read_char file) (append lst [` `]) file
else get_inits1 (read_char file) (append lst [ch]) file;;
% ------------------------------------------------------------------- %
% get_inits: Read in a list of either FIRST_CHARS or CHARS. %
% ------------------------------------------------------------------- %
let get_inits file ch prdn =
if ch = `\`` then
let (lst,nch) = get_inits1 (e_w_s file ` `) [] file in
if nch = `.` then
if null lst then
pg_failwith (concat prdn ` list`) prdn
(concat `can't have empty list of ` prdn)
else
implode lst
else
pg_failwith nch prdn
`improperly terminated string intialiser`
else
pg_failwith ch prdn
`improperly started string initaliser`;;
% ------------------------------------------------------------------- %
% get_inits_specials1: Finish reading in a list of either USEFUL or %
% IGNORE. %
% ------------------------------------------------------------------- %
letrec get_inits1_specials ch lst file =
if ch = `]` then (append lst [`]`],e_w_s file ` `)
else get_inits1_specials (read_char file) (append lst [ch]) file;;
% ------------------------------------------------------------------- %
% get_inits_specials: Read in a list of either USEFUL or IGNORE. %
% ------------------------------------------------------------------- %
let get_inits_specials file ch prdn =
if ch = `[` then
let (lst,nch) = get_inits1_specials (e_w_s file ` `) [`[`] file in
if nch = `.` then
implode lst
else
pg_failwith nch prdn
`improperly terminated specials list`
else
pg_failwith ch prdn
`improperly started specials list`;;
% ===================================================================== %
% Define some functions to make various boiler-plate statements. %
% ===================================================================== %
% ------------------------------------------------------------------- %
% separator: Determine what the look-ahead charater is. It is used %
% during the generation of function definitions and calls. %
% ------------------------------------------------------------------- %
let separator prev =
if prev = `sep` then `whitespace`
else if prev = `EOF` then `\`nil\``
else prev;;
% ------------------------------------------------------------------- %
% MK_word: Generate a call to gnt (get next token). %
% ------------------------------------------------------------------- %
let MK_word prev =
[`let`;
`(WORD,lst)`;`=`;`gnt lst whitespace`;(separator prev);`in`];;
% ------------------------------------------------------------------- %
% MK_start: Generate the code to make a list of characters from the %
% current token. %
% ------------------------------------------------------------------- %
let MK_start prev =
append (MK_word prev) [`let`;`TOKENS`;`=`;`explode WORD`;`in`];;
% ********************************************************************* %
% We now give the code for retrieving a terminal symbol from the input %
% grammar. %
% ********************************************************************* %
% ===================================================================== %
% EOF: A way of generating escaped backquotes as well as the EOF symbol.%
% ===================================================================== %
let EOF word =
if word = `EOF` then `nil`
else if word = `\`` then `\\\``
else word;;
% ===================================================================== %
% write_conditional: Generate the code for testing a word against a %
% particular string. %
% ===================================================================== %
let write_conditional word =
[(`WORD` . (`=` .
[(concatl [`\``;(EOF word);`\``])]))];;
% ===================================================================== %
% write_if: Generate the "if" test for different situations. %
% ===================================================================== %
let write_if level word =
if level = `if` then
append [[`if`]]
(append (write_conditional word) [[`then`;`(`]])
else
append [[`?`];[`if`]]
(append (write_conditional word) [[`then`;`(`]]);;
% ===================================================================== %
% finish_terminal: Test to see that a terminal symbol was terminated %
% properly. %
% ===================================================================== %
letrec finish_terminal ch prdn_name =
if ch = `]` then []
else pg_failwith ch prdn_name
`improperly terminated terminal symbol.`;;
% ===================================================================== %
% epsilon_start: Start each branch of the production. If we're at the %
% beginning, parenthesize only, otherwise put in a fail %
% trap. %
% ===================================================================== %
let epsilon_start level =
if level = `if` then
[[`(`]]
else
[[`?`];[`(`]];;
% ===================================================================== %
% get_terminal_2: Eat up the characters in a terminal symbol. %
% ===================================================================== %
letrec get_terminal_2 ch in_file prdn_name =
if ch = `\\` then
(escaped (read_char in_file) prdn_name) .
(get_terminal_2 (read_char in_file) in_file prdn_name)
else if ch = `]` then
[]
else if mem ch [` `;`\T`; `\L`] then
finish_terminal (e_w_s in_file (read_char in_file)) prdn_name
else
ch . get_terminal_2 (read_char in_file) in_file prdn_name ;;
% ===================================================================== %
% is_EOF: Make sure we know about the special symbol `EOF`. %
% ===================================================================== %
let is_EOF termnal = if termnal = `EOF` then `EOF` else `sep`;;
% ===================================================================== %
% get_terminal_1: If we are in a terminal symbol, check to see if it's %
% empty. Get the rest of it if it's not. %
% ===================================================================== %
let get_terminal_1 ch in_file prdn_name level pfail =
if ch = `]` then
(epsilon_start level, e_w_s in_file (read_char in_file),
`WORD`,false)
else
let termnal = concatl (get_terminal_2 ch in_file prdn_name) in
(write_if level termnal,
e_w_s in_file (read_char in_file),is_EOF termnal,true) ;;
% ===================================================================== %
% get_terminal: Check to see if we are starting a terminal symbol. Get %
% it from the input grammar if so. %
% ===================================================================== %
let get_terminal level ch in_file prdn_name prev_fail =
if ch = `[` then get_terminal_1 (e_w_s in_file (read_char in_file))
in_file prdn_name level prev_fail
else if level = `if` then ([[`(`]] , ch, `WORD`, false)
else (epsilon_start level, ch, `WORD`, false);;
% ********************************************************************* %
% We now describe the functions that parse action symbols from the %
% input grammar and generate the appropriate function calls. %
% %
% A note on methodology: %
% %
% We need to parse an action symbol that looks like act(arg1,..,argn), %
% where each argn is either a reserved symbol (system function) or the %
% name of some other production in the grammar. The code corresponding %
% to each of these possibilites can best be described by the sequence: %
% %
% A. Simple calls to other productions. %
% Evaluate the function and pass the result to the action. %
% B. POP %
% Take a result off the intermediate results list and pass it as an %
% argument to the action in question. %
% C. TOKEN %
% Check the current input token to see if it meets the constraints %
% of CHARS and FIRST_CHARS, then pass it as an argument to the %
% action. %
% D. Pass the current input token to the action directly. %
% %
% We need to generate two code segments to do this properly. One holds %
% all the POP calls. The other contains the more ordinary calls. The %
% two code segments will be joined together after we are finished with %
% parsing all the arguments. The POP calls appear first to make sure %
% that we get any old data before generating new results. %
% ********************************************************************* %
% ===================================================================== %
% system_function: Check to make sure we are not using a function name %
% that conflicts with one already used by all parsers. %
% ===================================================================== %
let system_function_args next_wd =
mem next_wd [`PARSE_text`;`PARSE_file`;`TOKEN_1`;`push`;`pop`;
`write_string`;`read_char`;`close_file`;`open_file`;`e_w_s`;
`e_w_s_ok`;`determine_lst`;`get_word`;`get_word1`;
`get_word2`;`complete_separator`;`read_input`;
`gnt`;`eat_terminal`;`chop_off`;`do_return`;`do_return_1`;
`debug_enter`;`debug_on`;`debug_off`;`debug_return`];;
% ===================================================================== %
% prdn_errors: Check that we are using names that are legal. %
% ===================================================================== %
let prdn_errors_args prdn_name next_wd =
if system_function_args next_wd then
pg_failwith next_wd prdn_name
(concatl [`"`;next_wd;`" is a system function.`])
else if next_wd = `type` then
pg_failwith `type` prdn_name
`"type" is a reserved word in HOL.`
else if next_wd = `MAIN_LOOP` then
pg_failwith `MAIN_LOOP` prdn_name
`"MAIN_LOOP" may not be called.`
else
();;
% ===================================================================== %
% tmp_var: Generate temporary variable names given a running counter. %
% ===================================================================== %
let tmp_var word number =
if number = (0-1) then word
else if word = `` then ``
else if word = `nil` then ``
else concatl (word . (`_` . [(string_of_int number)]));;
% ===================================================================== %
% HOL_term: Are we starting something from HOL (` or ")? %
% ===================================================================== %
let HOL_term str =
mem (hd (explode str)) [`\``;`"`];;
% ===================================================================== %
% top_or_middle: Generate a call to push something onto the intermedi- %
% ate results list. %
% ===================================================================== %
let top_or_middle new_name =
(`result_list` .
(`=` .
(`push` .
(new_name .
(`result_list` . [])))));;
% ===================================================================== %
% get_args_prdn: Make sure that productions don't have arguments. %
% ===================================================================== %
let get_args_prdn ch file prdn_name prev =
if ch = `(` then
pg_failwith ch prdn_name `arguments not allowed to non-terminals.`
else
(concatl [`lst whitespace `;(separator prev);
` result_list FIRST_CHARS CHARS`], ch);;
% ===================================================================== %
% finish_arg: Make sure that each argument ends with either a comma or %
% a parenthesis. %
% ===================================================================== %
let finish_arg ch prdn call =
if mem ch [`,`;`)`] then []:(string list)
else pg_failwith ch prdn
(concatl [`strange terminator for an argument to `;
call;`.`]);;
% ===================================================================== %
% get_argn1: Helping function for get_arg_name to finish reading in a %
% particular argument name. %
% ===================================================================== %
letrec get_argn1 ch file prdn call flag hol_flag =
if mem ch [`,`;`)`] then []
else if mem ch [` `;`\T`;`\L`] then
finish_arg (e_w_s file (read_char file)) prdn call
else if hol_flag then
ch . get_argn1 (read_char file) file prdn call `any` hol_flag
else if ch = `-` then
pg_failwith ch prdn
(concatl [`use underscores rather than dashes`])
else
(if first_test flag ch then
ch . get_argn1 (read_char file) file prdn call `any` hol_flag
else
pg_failwith ch prdn `not an appropriate first character`);;
% ===================================================================== %
% get_arg_name: Begin reading in an argument name. %
% ===================================================================== %
let get_arg_name ch file prdn call start =
if ch = `,` then
pg_failwith ch prdn
(concatl [`empty argument to `;call;`.`])
else if ch = `)` then
if start then
pg_failwith ch prdn
(concatl [call;` must have at least one argument.`])
else
(`nil`,`)`)
else
let wrd = get_argn1 (e_w_s file ch) file prdn call `any`
(if mem ch [`\``;`"`] then true else false) in
(implode wrd,e_w_s file (read_char file));;
% ===================================================================== %
% add_new_calls: Set things up for code generation for the action's %
% arguments depending on wether or not we're using a %
% system function. %
% ===================================================================== %
let add_new_calls tmp_calls argn calls pops =
if mem argn [`POP`;`TOKEN`;`WORD`] then
(append pops tmp_calls,calls)
else
(pops,append calls tmp_calls);;
% ===================================================================== %
% require_start: Decide if we need to check TOKENS. %
% ===================================================================== %
let require_start prev tmp_name call =
let tmp_calls = if prev = `WORD` then [] else MK_start prev in
if call = `WORD` then
(append tmp_calls [`let`;tmp_name;`= WORD`;`NOMARK`;`in`],`sep`)
else
(append tmp_calls [`let`;tmp_name;`= TOKEN TOKENS`;
`FIRST_CHARS`;`CHARS`;`(hd lst)`;`MARK`;`in`],
`sep`);;
% ===================================================================== %
% neet_to_use_pops: Generate the code to pop things off of the results %
% list if needed. %
% ===================================================================== %
let need_to_use_pops pop_size =
if pop_size = 0 then
[]
else
[`let`;`(result_list,pop_list) = chop_off`;(string_of_int pop_size);
`[] result_list`;`in`];;
% ===================================================================== %
% add_EXPECTED: Add something to the EXPECTED list as required. %
% ===================================================================== %
let add_EXPECTED thing flag =
if flag then
EXPECTED := append EXPECTED [thing]
else
EXPECTED;;
% ===================================================================== %
% pop_or_reg: Generate a call to pop something or a regular function %
% call as required. %
% ===================================================================== %
let pop_or_reg call prev t_par =
if call = `POP` then
([`) = (pop pop_list)`],prev,`pop_list`,t_par)
else
(add_EXPECTED `\`nil\`` (not t_par);
([`, prev, lst) = `;call;` lst whitespace `;(separator prev);
` result_list FIRST_CHARS CHARS`;`MARK`],
`prev`,`result_list`,false));;
% ===================================================================== %
% mk_lets: Generate the appropriate "let" statement. %
% ===================================================================== %
let mk_lets call gen_num prev t_par =
if call = `nil` then
([],``,gen_num,prev,t_par)
else if mem call [`WORD`;`TOKEN`] then
let tmp_name = (tmp_var call gen_num) in
add_EXPECTED `\`nil\`` (not t_par);
let (new_call,nprev) = require_start prev tmp_name call in
(new_call,tmp_name,gen_num+1,nprev,false)
else if HOL_term call then
([],call,gen_num,prev,t_par)
else
let tmp_name = (tmp_var call gen_num) and
(pop_call,nprev,result_list,ntp) = pop_or_reg call prev t_par in
(append [`let`;(concat `(` tmp_name);`,`;result_list]
(append pop_call [`in`]), tmp_name,gen_num+1,nprev,ntp);;
% ===================================================================== %
% comma: Add a comma to an argument if we need to. %
% ===================================================================== %
let comma start arg =
if start then arg
else concat `,` arg;;
% ===================================================================== %
% failed_arg: Make sure we are not doing something improper by calling %
% a function that we shouldn't be. %
% ===================================================================== %
let failed_arg argn =
mem argn [`TOKEN_1`;`PARSE`;`MAIN_LOOP`];;
% ===================================================================== %
% preprocess_args: Go through the argument list putting together the %
% various sequences of calls. %
% ===================================================================== %
letrec preprocess_args ch calls pops args file prdn gen_num
prev call start pop_ctr t_par =
if ch = `}` then
if start then
pg_failwith ch prdn (concatl [`bad argument to `;call;`.`])
else
(append pops calls,e_w_s file (read_char file),gen_num,
append args [`)`],pop_ctr,prev,t_par)
else if ch = `)` then
if start then
pg_failwith ch prdn (concatl [call;` must have some arguments.`])
else
(append pops calls,e_w_s file (read_char file),gen_num,
append args [`)`],pop_ctr,prev,t_par)
else
let (argn,nch) = get_arg_name ch file prdn call start in
if failed_arg argn then
pg_failwith argn prdn
(concatl [`"`;argn;
`" is not allowed as an argument.`])
else
(prdn_errors_args prdn argn;
let (tmp_calls,narg,ngen_num,nprev,ntp) = mk_lets argn gen_num
prev t_par
and npop_ctr = if argn = `POP` then pop_ctr+1 else pop_ctr in
let (npops,ncalls) = add_new_calls tmp_calls argn calls pops in
preprocess_args nch ncalls npops (append args
[(comma start narg)])
file prdn ngen_num nprev call false
npop_ctr ntp);;
% ===================================================================== %
% get_args_act: Parse out the arguments to an action, and put the calls %
% together so that they may be glued into the output. %
% ===================================================================== %
let get_args_act ch file call letrefs gen_num prdn prev t_par =
if ch = `(` then
let (lrefs,nch,ngen_num,args,pop_size,nprev,ntp) =
preprocess_args (e_w_s file (read_char file)) [] [] [`(`] file
prdn gen_num prev call true 0 t_par in
(append letrefs (append [(need_to_use_pops pop_size)] [lrefs]),
call . args,ngen_num,nch,nprev,ntp)
else if ch = `}` then
(letrefs,[(call^`()`)],gen_num,(e_w_s file (read_char file)),prev,t_par)
else pg_failwith ch prdn (concatl [`can't understand symbol "`;ch;
`" after the action "`;call;`".`]);;
% ********************************************************************* %
% We now describe functions that implement a restricted ML pretty %
% printer. This part of the generator is not, strictly speaking, %
% required. BUT, it did make debugging easier. %
% ********************************************************************* %
% ===================================================================== %
% write_tabs: Write out a certain number of blanks. %
% ===================================================================== %
letrec write_tabs tabs file =
if tabs = 0 then ()
else (write_string ` ` file ; write_tabs (tabs-1) file);;
% ===================================================================== %
% then_if: Increment the tab count if the previous token was "else" %
% ===================================================================== %
let then_if t pp =
if pp = `else` then (t + 4) else t;;
% ===================================================================== %
% pop_EXPECTED: Pop something off the EXPECTED list to fill in a blank. %
% ===================================================================== %
let pop_EXPECTED () =
if null EXPECTED then
failwith `bad match in EXPECTED`
else
let tmp = hd EXPECTED in
EXPECTED := tl EXPECTED;
tmp;;
% ===================================================================== %
% write_final: Write a fragment to the named file in a nice (?) format %
% ===================================================================== %
letrec write_final file lst tabs pch =
if null lst then (tabs,pch)
else
(let word = (hd lst) in
if word = `` then
write_final file (tl lst) tabs pch
else if word = `;;` then
(write_string `;;` file;
write_string (ascii 10) file;
write_string (ascii 10) file;
write_final file (tl lst) 0 `st`)
else if word = `NOMARK` then
(pop_EXPECTED();
write_final file (tl lst) tabs pch)
else if word = `MARK` then
(write_string (concat ` ` (pop_EXPECTED ())) file;
write_final file (tl lst) tabs pch)
else if word = `?` then
(write_string `\L` file;
write_tabs 2 file;
write_string `?` file;
write_final file (tl lst) 4 `let`)
else if word = `.` then
(if pch = `st` then
(write_string word file;
write_final file (tl lst) (tabs+4) `let`)
else
(write_string word file;
write_final file (tl lst) tabs pch))
else if mem word [`( `; ` ( ` ; `(`] then
(if (pch = `then`) then
(write_string (ascii 10) file;
write_tabs (then_if tabs pch) file;
write_string `(` file;
write_final file (tl lst) ((then_if tabs pch)+1) `(`)
else
((if tabs > 5 then
write_string `` file
else
(write_string (ascii 10) file;
write_tabs tabs file));
write_string `(` file;
write_final file (tl lst) (tabs+1) `(`))
else if word = `)` then
(write_string `)` file;
write_final file (tl lst) (tabs-1) `)`)
else if word = `if` then
(if pch = `if` then
(write_string (ascii 10) file;
write_tabs (tabs+4) file;
write_string word file;
write_final file (tl lst) (tabs+4) `if`)
else if pch = `(` then
(write_string `if` file;
write_final file (tl lst) (tabs+4) `if`)
else
(write_string (ascii 10) file;
write_tabs tabs file;
write_string word file;
write_final file (tl lst) (tabs+4) `if`))
else if word = `else` then
(write_string (ascii 10) file;
write_tabs (tabs-4) file;
write_string `else\L` file;
write_tabs tabs file;
write_final file (tl lst) tabs `else`)
else if mem word [`in`;`then`] then
(write_string (concat ` ` word) file;
write_final file (tl lst) tabs `then`)
else if mem word [`let`;`letrec`] then
(if pch = `st` then
(write_string word file;
write_final file (tl lst) (tabs+4) `let`)
else if pch = `(` then
(write_string word file;
write_final file (tl lst) tabs `let`)
else if pch = `else` then
(write_string (ascii 10) file;
write_tabs (tabs+4) file;
write_string word file;
write_final file (tl lst) (tabs+4) `let`)
else
(write_string (ascii 10) file;
write_tabs tabs file;
write_string word file;
write_final file (tl lst) tabs `let`))
else if word = `;` then
(write_string `;\L` file;
write_tabs (tabs-1) file;
write_final file (tl lst) tabs pch)
else
(if pch = `then` then
(write_string (ascii 10) file;
write_tabs tabs file;
write_string word file;
write_final file (tl lst) tabs ``)
else if pch = `(` then
(write_string word file;
write_final file (tl lst) tabs ``)
else if pch = `st` then
(write_string word file;
write_final file (tl lst) tabs pch)
else
(write_string ` ` file;
write_string (hd lst) file;
write_final file (tl lst) tabs pch)));;
% ===================================================================== %
% write_final_all: Write each code fragment to the output stream. %
% ===================================================================== %
letrec write_final_all lst file tabs pch =
if null lst then ()
else
let (tabs',pch') = write_final file (hd lst) tabs pch in
write_final_all (tl lst) file tabs' pch';;
% ********************************************************************* %
% We now describe the functions that go through individual productions %
% in the input grammar, and generate ML code for them. %
% ********************************************************************* %
% ===================================================================== %
% eat_arrow: Eat an arrow (the name says it all). %
% ===================================================================== %
letrec eat_arrow prdn_name ch in_file n =
if n = 2 then
if ch = `>` then (e_w_s in_file ` `)
else pg_failwith ch prdn_name `strange ending for an arrow.`
else if ch = `-` then
eat_arrow prdn_name (read_char in_file) in_file (n+1)
else failwith pg_failwith ch prdn_name `strange character in arrow.`;;
% ===================================================================== %
% unwind_parens: Construct enough parentheses to match the open ones. %
% ===================================================================== %
letrec unwind_parens par =
if par = 0 then []
else (`)` . (unwind_parens (par-1)));;
% ===================================================================== %
% finish_arm: Put the code for a given arm of a production together. %
% ===================================================================== %
let finish_arm whole letrefs return failed parens next_thing =
(append whole
(append letrefs
(append [return]
(append [parens]
(append failed next_thing)))));;
% ===================================================================== %
% new_letrefs: Generate a new "let" statement. %
% ===================================================================== %
let new_letrefs new_name next_wd args flag =
[[next_wd;args;(if flag then `MARK` else ``);`in`;`let`];
(top_or_middle new_name);[`in`]];;
% ===================================================================== %
% NT_letrefs: Make a "let" statement for non-terminal symbols. %
% ===================================================================== %
let NT_letrefs new_name next_wd args =
append [[`let`;(concat `(` new_name);`,`; `result_list`;`, prev, lst) =`]]
(new_letrefs new_name next_wd args true);;
% ===================================================================== %
% ACTION_letrefs: Make a "let" statement after returning from an action %
% symbol. %
% ===================================================================== %
let ACTION_letrefs new_name next_wd args =
append [[`let` ; new_name ; `=`]]
(new_letrefs new_name next_wd args false);;
% ===================================================================== %
% MK_failed: If we need to fail here, generate the code. %
% ===================================================================== %
let MK_failed failcond prdn msg update_list =
if failcond then
[[`else`];[`fail`]]
else
[[]];;
% ===================================================================== %
% MK_return: generate a call to the "do_return" function. %
% ===================================================================== %
let MK_return prev flag prdn =
[(`do_return result_list whitespace \``^prdn^`\` `^separator prev^` lst `
^(if flag then `expected` else `\`nil\``))];;
% ===================================================================== %
% system_function: Are we using a system function? %
% ===================================================================== %
let system_function next_wd =
mem next_wd [`TOKEN`;`PARSE_text`;`PARSE_file`;`TOKEN_1`;`push`;`pop`;
`write_string`;`read_char`;`close_file`;`open_file`;`e_w_s`;
`e_w_s_ok`;`determine_lst`;`get_word`;`get_word1`;
`get_word2`;`complete_separator`;`read_input`;
`gnt`;`eat_terminal`;`chop_off`;`do_return`;`do_return_1`;
`debug_enter`;`debug_on`;`debug_off`;`debug_return`];;
% ===================================================================== %
% terminal_errors: Different kinds of errors at the end of terminals. %
% ===================================================================== %
let terminal_errors prdn_name next_wd next_ch =
if next_wd = `]` then
pg_failwith next_wd prdn_name `can't have imbedded epsilons.`
else if not (next_ch = `]`) then
pg_failwith next_ch prdn_name
(concatl [`improper ending to terminal_sybol "`;
next_wd;`" (\``;next_ch;`\`).`])
else
();;
% ===================================================================== %
% prdn_errors: Different errors that can occur when trying to parse a %
% production name. %
% ===================================================================== %
let prdn_errors prdn_name next_wd =
if system_function next_wd then
pg_failwith next_wd prdn_name
(concatl [`"`;next_wd;`" is a system function.`])
else if next_wd = `type` then
pg_failwith `type` prdn_name
`"type" is a reserved word in HOL.`
else if next_wd = `WORD` then
pg_failwith `WORD` prdn_name
`"WORD" is a reserved word.`
else if next_wd = `TOKEN` then
pg_failwith `TOKEN` prdn_name
`calls to "TOKEN" may not be non-terminals.`
else if next_wd = `MAIN_LOOP` then
pg_failwith `MAIN_LOOP` prdn_name
`"MAIN_LOOP" may not be called.`
else if next_wd = `-->` then
pg_failwith `-->` prdn_name
(concatl [`no terminating \`.\` in the production "`;
prdn_name;`".`])
else
();;
% ===================================================================== %
% action_errors: The different things you CAN'T have as action symbol %
% names. %
% ===================================================================== %
let action_errors prdn_name act_name =
if mem act_name [`TOKEN`;`TOKEN_1`;`PARSE_file`;`PARSE_text`;`MAIN_LOOP`;
`push`;`pop`;`write_string`;`read_char`;`close_file`;
`open_file`;`e_w_s`;`e_w_s_ok`;`determine_lst`;`get_word`;
`get_word1`;`get_word2`;`complete_separator`;`read_input`;
`gnt`;`eat_terminal`;`chop_off`;`do_return`;
`do_return_1`;`debug_enter`;`debug_on`;`debug_off`;
`debug_return`;`WORD`] then
pg_failwith act_name prdn_name
(concatl [`can't use "`;act_name;
`" as the name of an action.`])
else
();;
% ===================================================================== %
% final_trap: Generate an ending "fail" if required. %
% ===================================================================== %
let final_trap flag prdn =
if flag then
[[`?`];[`fail`];[`;;`]]
else
[[`;;`]];;
% ===================================================================== %
% get_rest_of_prdn: Here it is, the one you've all been waiting for. %
% We parse in a given productions generating the ML %
% code that implements it. %
% ===================================================================== %
letrec get_rest_of_prdn prdn_name letrefs whole ch in_file par
tmp_num failcond out_file prev t_par =
if ch = `.` then
(add_EXPECTED `expected` (not t_par);
finish_arm whole letrefs (MK_return prev t_par prdn_name)
(MK_failed failcond prdn_name `` true)
(unwind_parens par) (final_trap failcond prdn_name))
else if ch = `|` then
let (condition,next_ch,nprev,nfailcond) = (get_terminal `else`
(e_w_s in_file ` `)
in_file prdn_name
failcond) in
add_EXPECTED `expected` (not t_par);
get_rest_of_prdn prdn_name [[``]]
(finish_arm whole letrefs
(MK_return prev t_par prdn_name)
(MK_failed failcond prdn_name `` false)
(unwind_parens par) condition)
next_ch in_file 1 0 nfailcond out_file
nprev true
else if ch = `{` then
let (act_name,next_ch) = get_word in_file (e_w_s in_file ` `)
out_file prdn_name `first` in
action_errors prdn_name act_name;
let (lrefs,call,t_num,nnext_ch,nprev,ntp) = get_args_act next_ch
in_file act_name
letrefs tmp_num
prdn_name prev
t_par in
get_rest_of_prdn prdn_name (append lrefs
(ACTION_letrefs
(tmp_var `tmp` t_num)
(concatl call) ``))
whole nnext_ch in_file par t_num
failcond out_file nprev ntp
else if ch = `[` then
let (next_wd,next_ch) = get_word in_file (e_w_s in_file
(read_char in_file))
out_file prdn_name `terminal` in
terminal_errors prdn_name next_wd next_ch;
let nxt = EOF next_wd in
add_EXPECTED (`\``^nxt^`\``) (not t_par);
get_rest_of_prdn prdn_name
(append letrefs
[(if prev = `WORD` then []
else MK_word prev);
[`let`;`(WORD,lst)`;`=`;`eat_terminal`;
(concatl [`\``;nxt;`\``]);`WORD`;`lst`;
(concatl [`\``;prdn_name;`\``])];
[`in`];
[`let`;`TOKENS`;`=`;`explode WORD`;`in`]])
whole (e_w_s in_file (read_char in_file)) in_file
par tmp_num failcond out_file `WORD` true
else
let (next_wd , next_ch) = get_word in_file ch out_file
prdn_name `first` in
prdn_errors prdn_name next_wd;
let (args , nnext_ch) = get_args_prdn next_ch in_file prdn_name prev
and new_name = (tmp_var next_wd tmp_num) in
add_EXPECTED `\`nil\`` (not t_par);
get_rest_of_prdn prdn_name (append letrefs (NT_letrefs new_name
next_wd args))
whole nnext_ch in_file par (tmp_num+1)
failcond out_file `prev` false;;
% ===================================================================== %
% process: Drives get_rest_of_prdn by initialising some variables and %
% getting the code for the first terminal symbol if it exists. %
% ===================================================================== %
let process in_file prdn_name ch out_file =
let (args,next_ch) = get_args_prdn ch in_file prdn_name `prev`
in
let nnext_ch = eat_arrow prdn_name next_ch in_file 0
in
let (condition,nnnext_ch,nprev,failcond) = get_terminal `if` nnext_ch
in_file
prdn_name false
in
EXPECTED := [];
get_rest_of_prdn prdn_name [] condition nnnext_ch in_file 1 0
failcond out_file nprev true;;
% ===================================================================== %
% MK_lambda: Start out the lambda expression for a given production. %
% ===================================================================== %
let MK_lambda wrd call_list =
append [[wrd;`:=`;`\L`;
` \\lst `;`whitespace `;`prev `;
`result_list `;`FIRST_CHARS `;`CHARS `; `expected`];
[`.`]]
(append [(MK_start `prev`)]
(append [[(`debug_enter(\``^wrd^`\`,expected,WORD)`);`;`]]
call_list));;
% ===================================================================== %
% write_decs: Output the dummy declaration for a given production. %
% ===================================================================== %
let write_decs wrd out_file out_type =
write_string `letref ` out_file;
write_string wrd out_file;
write_string `\L (lst:string list) (whitespace:string)`
out_file;
write_string `(prev:string)\L` out_file;
write_string ` (result_list:` out_file;
write_string out_type out_file;
write_string ` list)\L` out_file;
write_string ` (FIRST_CHARS:string list) (CHARS:string list) ` out_file;
write_string `(expected:string) =\L` out_file;
write_string ` (fail:` out_file;
write_string out_type out_file;
write_string `,fail:` out_file;
write_string out_type out_file;
write_string ` list,fail:string,fail:string list);;\L\L` out_file;;
% ===================================================================== %
% make_main_wrapper: Generate the functions PARSE_file and PARSE_text %
% when the production MAIN_LOOP is encountered. %
% ===================================================================== %
let make_main_wrapper out_file =
write_string `\L\L Generating PARSE_file and PARSE_text ` `nil`;
write_string `(MAIN_LOOP used).\L\L` `nil`;
write_string `let PARSE_file (in_file,whitespace,separators) =\L` out_file;
write_string ` let white = if null whitespace then\L` out_file;
write_string ` [\` \`;\`\\T\`;\`\\L\`]\L` out_file;
write_string ` else\L` out_file;
write_string ` whitespace and\L` out_file;
write_string ` inf = open_file \`in\` in_file in\L` out_file;
write_string ` let WORD = e_w_s inf (hd white) white in\L` out_file;
write_string ` let lst = read_input inf [] white separators ` out_file;
write_string `WORD IGNORE USEFUL in\L` out_file;
write_string ` let (WORD,lst) = (hd lst,tl lst) in\L` out_file;
write_string ` let result = fst (MAIN_LOOP lst (hd white) ` out_file;
write_string `WORD []\L` out_file;
write_string ` FIRST_CHARS CHARS` out_file;
write_string ` \`nil\`) in\L` out_file;
write_string ` result\L` out_file;
write_string ` ? fail;;\L\L` out_file;
write_string `let PARSE_text (text,whitespace,separators) =\L` out_file;
write_string ` let outf = open_file \`out\` ` out_file;
write_string `\`/tmp/.000HOL\` in\L` out_file;
write_string ` write_string text outf;\L` out_file;
write_string ` close_file outf;\L` out_file;
write_string ` let result = PARSE_file (\`/tmp/.000HOL\`,` out_file;
write_string `whitespace,separators) in\L` out_file;
write_string ` unlink \`/tmp/.000HOL\`; result;;\L\L` out_file;;
% ===================================================================== %
% emit_firsts: Output the code for CHARS or FIRST_CHARS. %
% ===================================================================== %
let emit_firsts wrd firsts file =
if can implode (words firsts) then
write_string (concatl [wrd;` := words \``;firsts;`\`;;\L\L`])
file
else
pg_failwith firsts wrd
(concatl [wrd;` must be a list of single characters.`]);;
% ===================================================================== %
% emit_specials: Output the code for IGNORE or USEFUL. %
% ===================================================================== %
let emit_specials wrd specials file =
write_string (concatl [wrd;` := `;specials;`;;\L\L`]) file;;
% ===================================================================== %
% token_failwith: Error message used while generating the tokeniser. %
% ===================================================================== %
let token_failwith missing =
failwith (concat `\L\L ERROR in tokeniser generator.\L`
(concat ` -- Problem: no definition of `
(concat missing `.\L`)));;
% ===================================================================== %
% make_tokeniser: Generate the functions TOKEN and TOKEN_1 to check the %
% vailidity of an input token against CHARS and %
% FIRST_CHARS. %
% ===================================================================== %
let make_tokeniser out_file firsts chars =
if not firsts then
if chars then
token_failwith `FIRST_CHARS` out_file
else close_file out_file
else if not chars then
if firsts then
token_failwith `CHARS` out_file
else close_file out_file
else
(write_string `letrec TOKEN_1 TOKENS CHARS =\L` out_file;
write_string ` if null TOKENS then ()\L` out_file;
write_string ` else if mem (hd TOKENS) CHARS then\L` out_file;
write_string ` TOKEN_1 (tl TOKENS) CHARS\L` out_file;
write_string ` else\L` out_file;
write_string ` fail;;\L\L` out_file;
write_string `let TOKEN TOKENS FIRST_CHARS CHARS next expected =\L`
out_file;
write_string ` if mem (hd TOKENS) FIRST_CHARS then\L` out_file;
write_string ` (TOKEN_1 (tl TOKENS) CHARS;\L` out_file;
write_string ` let wrd = implode TOKENS in\L` out_file;
write_string ` if expected = \`nil\` then\L` out_file;
write_string ` wrd\L` out_file;
write_string ` else if expected = next then\L` out_file;
write_string ` wrd\L` out_file;
write_string ` else fail)\L` out_file;
write_string ` else\L` out_file;
write_string ` fail\L` out_file;
write_string ` ? fail;;\L\L` out_file;
close_file out_file);;
% ===================================================================== %
% decls_fail: Convenient wrapper for pg_failwith used in decls_errors. %
% ===================================================================== %
let decls_fail wrd =
pg_failwith wrd wrd
(concatl [`multiple definitions of "`;wrd;
`" are not allowed.`]);;
% ===================================================================== %
% decls_errors: Make sure everything is defined as far as CHARS and %
% FIRST_CHARS are concerned. %
% ===================================================================== %
let decls_errors wrd firsts chars =
if wrd = `FIRST_CHARS` then
if firsts then
decls_fail wrd
else
(true,chars)
else
(if chars then
decls_fail wrd
else
(firsts,true));;
% ===================================================================== %
% make_productions: Overall driver for deciding if we're dealing with %
% a declaration or a production. The appropriate %
% function is called, and the code for it is gener- %
% ated. %
% ===================================================================== %
letrec make_productions in_file out_file out_decs out_type firsts chars =
let (wrd , ch) = get_word in_file (eat_white_space in_file ` `) out_file
`UNKNOWN (starting a new one)` `first` in
if ch = `nil` then
(close_file in_file ; close_file out_file;
make_tokeniser out_decs firsts chars)
else if wrd = `type` then
pg_failwith wrd wrd
`"type" is a reserved word in HOL.`
else if mem wrd [`TOKEN`;`PARSE`] then
pg_failwith wrd wrd
(concatl [`can't use "`;wrd;`" as a production name.`])
else if wrd = `TOKEN_1` then
pg_failwith `TOKEN_1` `TOKEN_1`
`"TOKEN_1" is a system function.`
else if mem wrd [`FIRST_CHARS`;`CHARS`] then
let (nfirsts,nchars) = decls_errors wrd firsts chars in
emit_firsts wrd (get_inits in_file ch wrd) out_decs;
make_productions in_file out_file out_decs out_type
nfirsts nchars
else if mem wrd [`USEFUL`;`IGNORE`] then
(emit_specials wrd (get_inits_specials in_file ch wrd) out_decs;
make_productions in_file out_file out_decs out_type firsts chars)
else
(write_decs wrd out_decs out_type;
write_final_all (MK_lambda wrd (process in_file wrd ch out_file))
out_file 0 `st`;
if wrd = `MAIN_LOOP` then
make_main_wrapper out_file
else
();
make_productions in_file out_file out_decs
out_type firsts chars);;
% ===================================================================== %
% get_ty: Make sure the user gave us some input for the output type of %
% the generated parser. %
% ===================================================================== %
letrec get_ty lst flag =
let ch = read_char `nil` in
if ch = `\L` then
if flag then
failwith `Must have a type`
else
implode lst
else get_ty (append lst [ch]) false;;
% ===================================================================== %
% parse: Top-level function for driving the generator. It is the only %
% one exported from the section. %
% ===================================================================== %
let parse () =
tty_write `Input file: `;
let in_file = terminal_read() in
tty_write `Output file: `;
let inf = (fst (open_file `in` in_file)) and
out_file = terminal_read() in
let (outf,outf_decs) = open_file `out` out_file in
tty_write `Output type: `;
let out_type = get_ty [] true in
make_productions inf outf outf_decs out_type false false;;
parse;;
end_section parser;;
let parse = it;;
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