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NAME

       yecc - LALR-1 Parser Generator

DESCRIPTION

       An  LALR-1 parser generator for Erlang, similar to yacc. Takes a BNF grammar definition as
       input, and produces Erlang code for a parser.

       To understand this text, you also have to look at the yacc documentation in  the  UNIX(TM)
       manual.  This  is  most  probably  necessary  in  order to understand the idea of a parser
       generator, and the principle and problems of LALR parsing with finite look-ahead.

DATA TYPES

       error_info() =
           {erl_anno:location() | none,
            module(),
            ErrorDescriptor :: term()}

              The standard  error_info()  structure  that  is  returned  from  all  I/O  modules.
              ErrorDescriptor is formattable by format_error/1.

EXPORTS

       file(FileName) -> yecc_ret()

       file(Grammarfile, Options) -> yecc_ret()

              Types:

                 Grammarfile = file:filename()
                 Options = Option | [Option]
                 Option =
                     {error_location, column | line} |
                     {includefile, Includefile :: file:filename()} |
                     {report_errors, boolean()} |
                     {report_warnings, boolean()} |
                     {report, boolean()} |
                     {return_errors, boolean()} |
                     {return_warnings, boolean()} |
                     {return, boolean()} |
                     {parserfile, Parserfile :: file:filename()} |
                     {verbose, boolean()} |
                     {warnings_as_errors, boolean()} |
                     {deterministic, boolean()} |
                     report_errors | report_warnings | report | return_errors |
                     return_warnings | return | verbose | warnings_as_errors
                 yecc_ret() = ok_ret() | error_ret()
                 ok_ret() =
                     {ok, Parserfile :: file:filename()} |
                     {ok, Parserfile :: file:filename(), warnings()}
                 error_ret() =
                     error | {error, Errors :: errors(), Warnings :: warnings()}
                 errors() = [{file:filename(), [error_info()]}]
                 warnings() = [{file:filename(), [error_info()]}]

              Grammarfile is the file of declarations and grammar rules. Returns ok upon success,
              or error if there are errors. An Erlang file containing the parser  is  created  if
              there are no errors. The options are:

                {includefile, Includefile}.:
                  Indicates  a customized prologue file which the user may want to use instead of
                  the default file lib/parsetools/include/yeccpre.hrl which is otherwise included
                  at the beginning of the resulting parser file. N.B. The Includefile is included
                  'as is' in the parser file, so it must not have a  module  declaration  of  its
                  own,  and  it  should  not be compiled. It must, however, contain the necessary
                  export declarations. The default is indicated by "".

                {parserfile, Parserfile}.:
                  Parserfile is the name of the file that will contain  the  Erlang  parser  code
                  that is generated. The default ("") is to add the extension .erl to Grammarfile
                  stripped of the .yrl extension.

                {report_errors, boolean()}.:
                  Causes errors to be printed as they occur. Default is true.

                {report_warnings, boolean()}.:
                  Causes warnings to be printed as they occur. Default is true.

                {report, boolean()}.:
                  This is a short form for both report_errors and report_warnings.

                {return_errors, boolean()}.:
                  If this flag is set, {error, Errors,  Warnings}  is  returned  when  there  are
                  errors. Default is false.

                {return_warnings, boolean()}.:
                  If  this  flag is set, an extra field containing Warnings is added to the tuple
                  returned upon success. Default is false.

                {return, boolean()}.:
                  This is a short form for both return_errors and return_warnings.

                {verbose, boolean()}. :
                  Determines whether the parser generator  should  give  full  information  about
                  resolved  and  unresolved  parse  action  conflicts (true), or only about those
                  conflicts that prevent a parser from being generated  from  the  input  grammar
                  (false, the default).

                {warnings_as_errors, boolean()}:
                  Causes warnings to be treated as errors.

                {error_location, column | line}.:
                  If  the  value  of  this flag is line, the location of warnings and errors is a
                  line number. If the value is column, the location includes a line number and  a
                  column number. Default is column.

                {deterministic, boolean()}:
                  Causes  generated  -file()  attributes to only include the basename of the file
                  path.

              Any of the Boolean options can be set to true by stating the name  of  the  option.
              For example, verbose is equivalent to {verbose, true}.

              The  value  of the Parserfile option stripped of the .erl extension is used by Yecc
              as the module name of the generated parser file.

              Yecc will add the extension .yrl to the Grammarfile name, the extension .hrl to the
              Includefile  name,  and  the  extension  .erl  to  the  Parserfile name, unless the
              extension is already there.

       format_error(ErrorDescriptor) -> io_lib:chars()

              Types:

                 ErrorDescriptor = term()

              Returns a descriptive string in English of an error reason ErrorDescriptor returned
              by yecc:file/1,2. This function is mainly used by the compiler invoking Yecc.

DEFAULT YECC OPTIONS

       The  (host operating system) environment variable ERL_COMPILER_OPTIONS can be used to give
       default Yecc options. Its value must be a valid Erlang term. If the value is a list, it is
       used as is. If it is not a list, it is put into a list.

       The list is appended to any options given to file/2.

       The list can be retrieved with  compile:env_compiler_options/0.

PRE-PROCESSING

       A scanner to pre-process the text (program, etc.) to be parsed is not provided in the yecc
       module. The scanner serves as a kind of lexicon look-up routine. It is possible to write a
       grammar  that uses only character tokens as terminal symbols, thereby eliminating the need
       for a scanner, but this would make the parser larger and slower.

       The user should implement a scanner that segments the input text, and turns it into one or
       more  lists of tokens. Each token should be a tuple containing information about syntactic
       category, position in the text (e.g. line number), and the actual terminal symbol found in
       the text: {Category, Position, Symbol}.

       If a terminal symbol is the only member of a category, and the symbol name is identical to
       the category name, the token format may be {Symbol, Position}.

       A list of tokens produced by the scanner should end  with  a  special  end_of_input  tuple
       which  the  parser  is  looking  for.  The  format  of  this  tuple  should be {Endsymbol,
       EndPosition}, where Endsymbol is an identifier that is distinguished from all the terminal
       and  non-terminal  categories  of  the  syntax rules. The Endsymbol may be declared in the
       grammar file (see below).

       The simplest case is to segment the input string into a list of  identifiers  (atoms)  and
       use those atoms both as categories and values of the tokens. For example, the input string
       aaa bbb 777, X may be scanned (tokenized) as:

       [{aaa, 1}, {bbb, 1}, {777, 1}, {',' , 1}, {'X', 1},
        {'$end', 1}].

       This assumes that this is the first line of  the  input  text,  and  that  '$end'  is  the
       distinguished end_of_input symbol.

       The  Erlang  scanner  in  the io module can be used as a starting point when writing a new
       scanner. Study yeccscan.erl in order  to  see  how  a  filter  can  be  added  on  top  of
       io:scan_erl_form/3  to  provide  a  scanner  for  Yecc that tokenizes grammar files before
       parsing them with the Yecc parser. A more general approach to scanner implementation is to
       use a scanner generator. A scanner generator in Erlang called leex is under development.

GRAMMAR DEFINITION FORMAT

       Erlang style comments, starting with a '%', are allowed in grammar files.

       Each declaration or rule ends with a dot (the character '.').

       The  grammar  starts  with  an  optional  header  section.  The header is put first in the
       generated file, before the module declaration. The purpose of the header is to  provide  a
       means  to  make the documentation generated by EDoc look nicer. Each header line should be
       enclosed in double quotes, and newlines will be inserted between the lines. For example:

       Header "%% Copyright (C)"
       "%% @private"
       "%% @Author John".

       Next comes a declaration of the nonterminal categories  to  be  used  in  the  rules.  For
       example:

       Nonterminals sentence nounphrase verbphrase.

       A  non-terminal  category  can be used at the left hand side (= lhs, or head) of a grammar
       rule. It can also appear at the right hand side of rules.

       Next comes a declaration of the terminal categories, which are the  categories  of  tokens
       produced by the scanner. For example:

       Terminals article adjective noun verb.

       Terminal categories may only appear in the right hand sides (= rhs) of grammar rules.

       Next comes a declaration of the rootsymbol, or start category of the grammar. For example:

       Rootsymbol sentence.

       This  symbol  should  appear  in  the  lhs  of at least one grammar rule. This is the most
       general syntactic category which the parser ultimately will parse every input string into.

       After the rootsymbol declaration comes an optional declaration of the end_of_input  symbol
       that your scanner is expected to use. For example:

       Endsymbol '$end'.

       Next  comes one or more declarations of operator precedences, if needed. These are used to
       resolve shift/reduce conflicts (see yacc documentation).

       Examples of operator declarations:

       Right 100 '='.
       Nonassoc 200 '==' '=/='.
       Left 300 '+'.
       Left 400 '*'.
       Unary 500 '-'.

       These declarations mean that '=' is defined as a right associative  binary  operator  with
       precedence  100,  '==' and '=/=' are operators with no associativity, '+' and '*' are left
       associative binary operators, where '*' takes precedence over '+' (the normal  case),  and
       '-'  is  a  unary  operator  of  higher  precedence  than  '*'.  The fact that '==' has no
       associativity means that an expression like a == b == c is considered a syntax error.

       Certain rules are assigned precedence:  each  rule  gets  its  precedence  from  the  last
       terminal  symbol  mentioned  in  the  right  hand side of the rule. It is also possible to
       declare precedence for non-terminals, "one level up". This is practical when  an  operator
       is overloaded (see also example 3 below).

       Next come the grammar rules. Each rule has the general form

       Left_hand_side -> Right_hand_side : Associated_code.

       The left hand side is a non-terminal category. The right hand side is a sequence of one or
       more non-terminal or terminal symbols with  spaces  between.  The  associated  code  is  a
       sequence  of  zero  or  more  Erlang  expressions  (with commas ',' as separators). If the
       associated code is empty, the separating colon ':' is also omitted. A final dot marks  the
       end of the rule.

       Symbols such as '{', '.', etc., have to be enclosed in single quotes when used as terminal
       or non-terminal symbols in grammar rules. The use of the  symbols  '$empty',  '$end',  and
       '$undefined' should be avoided.

       The  last  part  of  the  grammar file is an optional section with Erlang code (= function
       definitions) which is included 'as is' in the resulting parser  file.  This  section  must
       start with the pseudo declaration, or key words

       Erlang code.

       No  syntax  rule  definitions  or  other  declarations  may  follow this section. To avoid
       conflicts with internal variables, do not use variable names beginning with two underscore
       characters  ('__')  in the Erlang code in this section, or in the code associated with the
       individual syntax rules.

       The optional expect declaration can be placed anywhere before the  last  optional  section
       with  Erlang  code.  It  is  used  for  suppressing  the  warning  about conflicts that is
       ordinarily given if the grammar is ambiguous. An example:

       Expect 2.

       The warning is given if the number of shift/reduce conflicts differs from 2, or  if  there
       are reduce/reduce conflicts.

EXAMPLES

       A grammar to parse list expressions (with empty associated code):

       Nonterminals list elements element.
       Terminals atom '(' ')'.
       Rootsymbol list.
       list -> '(' ')'.
       list -> '(' elements ')'.
       elements -> element.
       elements -> element elements.
       element -> atom.
       element -> list.

       This  grammar  can be used to generate a parser which parses list expressions, such as (),
       (a), (peter charles), (a (b c) d (())), ... provided  that  your  scanner  tokenizes,  for
       example, the input (peter charles) as follows:

       [{'(', 1} , {atom, 1, peter}, {atom, 1, charles}, {')', 1},
        {'$end', 1}]

       When  a  grammar  rule  is  used  by  the  parser to parse (part of) the input string as a
       grammatical phrase, the associated code is evaluated, and the value of the last expression
       becomes  the  value  of  the  parsed phrase. This value may be used by the parser later to
       build structures that are values of higher phrases of which the current phrase is a  part.
       The values initially associated with terminal category phrases, i.e. input tokens, are the
       token tuples themselves.

       Below is an example of the grammar above with structure building code added:

       list -> '(' ')' : nil.
       list -> '(' elements ')' : '$2'.
       elements -> element : {cons, '$1', nil}.
       elements -> element elements : {cons, '$1', '$2'}.
       element -> atom : '$1'.
       element -> list : '$1'.

       With this code added to the  grammar  rules,  the  parser  produces  the  following  value
       (structure)  when  parsing the input string (a b c).. This still assumes that this was the
       first input line that the scanner tokenized:

       {cons, {atom, 1, a}, {cons, {atom, 1, b},
                                   {cons, {atom, 1, c}, nil}}}

       The associated code contains pseudo variables '$1', '$2', '$3', etc. which refer  to  (are
       bound  to)  the  values  associated previously by the parser with the symbols of the right
       hand side of the rule. When these symbols are terminal categories, the  values  are  token
       tuples of the input string (see above).

       The  associated code may not only be used to build structures associated with phrases, but
       may also be used for syntactic and semantic  tests,  printout  actions  (for  example  for
       tracing),  etc.  during the parsing process. Since tokens contain positional (line number)
       information, it is possible to produce error messages which contain line numbers. If there
       is  no  associated  code  after the right hand side of the rule, the value '$undefined' is
       associated with the phrase.

       The right hand side of a grammar rule may be empty. This is indicated by using the special
       symbol '$empty' as rhs. Then the list grammar above may be simplified to:

       list -> '(' elements ')' : '$2'.
       elements -> element elements : {cons, '$1', '$2'}.
       elements -> '$empty' : nil.
       element -> atom : '$1'.
       element -> list : '$1'.

GENERATING A PARSER

       To call the parser generator, use the following command:

       yecc:file(Grammarfile).

       An  error  message  from  Yecc  will  be shown if the grammar is not of the LALR type (for
       example too ambiguous). Shift/reduce conflicts are resolved in favor of shifting if  there
       are  no  operator  precedence  declarations. Refer to the yacc documentation on the use of
       operator precedence.

       The output file contains Erlang source code for a parser module with module name equal  to
       the  Parserfile  parameter.  After  compilation,  the parser can be called as follows (the
       module name is assumed to be myparser):

       myparser:parse(myscanner:scan(Inport))

       The call format may be different if a customized prologue  file  has  been  included  when
       generating the parser instead of the default file lib/parsetools/include/yeccpre.hrl.

       With  the  standard prologue, this call will return either {ok, Result}, where Result is a
       structure that the Erlang code of the  grammar  file  has  built,  or  {error,  {Position,
       Module, Message}} if there was a syntax error in the input.

       Message   is   something   which   may   be   converted   into   a   string   by   calling
       Module:format_error(Message) and printed with io:format/3.

   Note:
       By default, the parser that was generated will not print out error messages to the screen.
       The  user  will  have  to  do  this  either by printing the returned error messages, or by
       inserting tests and print instructions in the Erlang code associated with the syntax rules
       of the grammar file.

       It  is  also  possible  to  make  the  parser ask for more input tokens when needed if the
       following call format is used:

       myparser:parse_and_scan({Function, Args})
       myparser:parse_and_scan({Mod, Tokenizer, Args})

       The  tokenizer  Function  is  either  a  fun  or  a  tuple  {Mod,  Tokenizer}.  The   call
       apply(Function, Args) or apply({Mod, Tokenizer}, Args) is executed whenever a new token is
       needed. This, for example, makes it possible to parse from a file, token by token.

       The tokenizer used above has to be implemented so as to return one of the following:

       {ok, Tokens, EndPosition}
       {eof, EndPosition}
       {error, Error_description, EndPosition}

       This conforms to the format used by the scanner in the Erlang io library module.

       If {eof, EndPosition} is returned immediately, the call to parse_and_scan/1  returns  {ok,
       eof}.  If  {eof,  EndPosition}  is  returned  before  the  parser  expects  end  of input,
       parse_and_scan/1 will, of course, return an error  message  (see  above).  Otherwise  {ok,
       Result} is returned.

MORE EXAMPLES

       1.  A  grammar  for  parsing  infix  arithmetic  expressions into prefix notation, without
       operator precedence:

       Nonterminals E T F.
       Terminals '+' '*' '(' ')' number.
       Rootsymbol E.
       E -> E '+' T: {'$2', '$1', '$3'}.
       E -> T : '$1'.
       T -> T '*' F: {'$2', '$1', '$3'}.
       T -> F : '$1'.
       F -> '(' E ')' : '$2'.
       F -> number : '$1'.

       2. The same with operator precedence becomes simpler:

       Nonterminals E.
       Terminals '+' '*' '(' ')' number.
       Rootsymbol E.
       Left 100 '+'.
       Left 200 '*'.
       E -> E '+' E : {'$2', '$1', '$3'}.
       E -> E '*' E : {'$2', '$1', '$3'}.
       E -> '(' E ')' : '$2'.
       E -> number : '$1'.

       3. An overloaded minus operator:

       Nonterminals E uminus.
       Terminals '*' '-' number.
       Rootsymbol E.

       Left 100 '-'.
       Left 200 '*'.
       Unary 300 uminus.

       E -> E '-' E.
       E -> E '*' E.
       E -> uminus.
       E -> number.

       uminus -> '-' E.

       4. The Yecc grammar that is used for parsing grammar files, including itself:

       Nonterminals
       grammar declaration rule head symbol symbols attached_code
       token tokens.
       Terminals
       atom float integer reserved_symbol reserved_word string char var
       '->' ':' dot.
       Rootsymbol grammar.
       Endsymbol '$end'.
       grammar -> declaration : '$1'.
       grammar -> rule : '$1'.
       declaration -> symbol symbols dot: {'$1', '$2'}.
       rule -> head '->' symbols attached_code dot: {rule, ['$1' | '$3'],
               '$4'}.
       head -> symbol : '$1'.
       symbols -> symbol : ['$1'].
       symbols -> symbol symbols : ['$1' | '$2'].
       attached_code -> ':' tokens : {erlang_code, '$2'}.
       attached_code -> '$empty' : {erlang_code,
                        [{atom, 0, '$undefined'}]}.
       tokens -> token : ['$1'].
       tokens -> token tokens : ['$1' | '$2'].
       symbol -> var : value_of('$1').
       symbol -> atom : value_of('$1').
       symbol -> integer : value_of('$1').
       symbol -> reserved_word : value_of('$1').
       token -> var : '$1'.
       token -> atom : '$1'.
       token -> float : '$1'.
       token -> integer : '$1'.
       token -> string : '$1'.
       token -> char : '$1'.
       token -> reserved_symbol : {value_of('$1'), line_of('$1')}.
       token -> reserved_word : {value_of('$1'), line_of('$1')}.
       token -> '->' : {'->', line_of('$1')}.
       token -> ':' : {':', line_of('$1')}.
       Erlang code.
       value_of(Token) ->
           element(3, Token).
       line_of(Token) ->
           element(2, Token).

   Note:
       The symbols '->', and ':' have to be treated in a special way, as they are meta symbols of
       the grammar notation, as well as terminal symbols of the Yecc grammar.

       5. The file erl_parse.yrl in the lib/stdlib/src directory contains the grammar for Erlang.

   Note:
       Syntactic  tests  are  used in the code associated with some rules, and an error is thrown
       (and caught by the generated parser to produce an error message) when a  test  fails.  The
       same  effect  can  be achieved with a call to return_error(ErrorPosition, Message_string),
       which is defined in the yeccpre.hrl default header file.

FILES

       lib/parsetools/include/yeccpre.hrl

SEE ALSO

       Aho & Johnson: 'LR Parsing', ACM Computing Surveys, vol. 6:2, 1974.