Provided by: peg_0.1.15-1_amd64 bug

NAME

       peg, leg - parser generators

SYNOPSIS

       peg [-hvV -ooutput] [filename ...]
       leg [-hvV -ooutput] [filename ...]

DESCRIPTION

       peg  and  leg  are  tools  for generating recursive-descent parsers: programs that perform
       pattern matching on text.  They process a Parsing Expression Grammar (PEG) [Ford 2004]  to
       produce  a  program  that  recognises legal sentences of that grammar.  peg processes PEGs
       written using the original syntax described by Ford;  leg  processes  PEGs  written  using
       slightly  different  syntax  and  conventions  that  are intended to make it an attractive
       replacement for parsers built with lex(1) and yacc(1).  Unlike lex and yacc, peg  and  leg
       support  unlimited backtracking, provide ordered choice as a means for disambiguation, and
       can combine scanning (lexical analysis) and parsing (syntactic  analysis)  into  a  single
       activity.

       peg  reads  the  specified  filenames,  or standard input if no filenames are given, for a
       grammar describing the parser to generate.  peg  then  generates  a  C  source  file  that
       defines a function yyparse().  This C source file can be included in, or compiled and then
       linked with, a client program.  Each time the client program calls  yyparse()  the  parser
       consumes  input  text  according to the parsing rules, starting from the first rule in the
       grammar.  yyparse() returns non-zero if  the  input  could  be  parsed  according  to  the
       grammar; it returns zero if the input could not be parsed.

       The  prefix  'yy'  or 'YY' is prepended to all externally-visible symbols in the generated
       parser.  This is intended to reduce the risk of namespace pollution  in  client  programs.
       (The choice of 'yy' is historical; see lex(1) and yacc(1), for example.)

OPTIONS

       peg and leg provide the following options:

       -h     prints a summary of available options and then exits.

       -ooutput
              writes the generated parser to the file output instead of the standard output.

       -v     writes verbose information to standard error while working.

       -V     writes version information to standard error then exits.

A SIMPLE EXAMPLE

       The  following  peg  input specifies a grammar with a single rule (called 'start') that is
       satisfied when the input contains the string "username".

           start <- "username"

       (The quotation marks are not part of the matched text; they serve to  indicate  a  literal
       string  to  be  matched.)  In other words, yyparse() in the generated C source will return
       non-zero only if the next eight characters read from the input spell the word  "username".
       If  the  input  contains anything else, yyparse() returns zero and no input will have been
       consumed.  (Subsequent calls to yyparse() will also  return  zero,  since  the  parser  is
       effectively  blocked looking for the string "username".)  To ensure progress we can add an
       alternative clause to the 'start' rule that will match any single character if  "username"
       is not found.

           start <- "username"
                  / .

       yyparse()  now  always  returns  non-zero  (except  at  the very end of the input).  To do
       something useful we can add actions to the rules.  These actions  are  performed  after  a
       complete  match  is  found  (starting from the first rule) and are chosen according to the
       'path' taken through the grammar to match the input.  (Linguists would call  this  path  a
       'phrase marker'.)

           start <- "username"    { printf("%s\n", getlogin()); }
                  / < . >         { putchar(yytext[0]); }

       The  first  line  instructs  the  parser  to  print the user's login name whenever it sees
       "username" in the input.  If that match fails, the second line tells the  parser  to  echo
       the  next character on the input the standard output.  Our parser is now performing useful
       work: it will copy the input to the output, replacing all occurrences of  "username"  with
       the user's account name.

       Note  the  angle  brackets ('<' and '>') that were added to the second alternative.  These
       have no effect on the meaning of the rule, but serve to delimit the text made available to
       the following action in the variable yytext.

       If the above grammar is placed in the file username.peg, running the command

           peg -o username.c username.peg

       will  save  the corresponding parser in the file username.c.  To create a complete program
       this parser could be included by a C program as follows.

           #include <stdio.h>      /* printf(), putchar() */
           #include <unistd.h>     /* getlogin() */

           #include "username.c"   /* yyparse() */

           int main()
           {
             while (yyparse())     /* repeat until EOF */
               ;
             return 0;
           }

PEG GRAMMARS

       A grammar consists of a set of named rules.

           name <- pattern

       The pattern contains one or more of the following elements.

       name   The element stands for the entire pattern in the rule with the given name.

       "characters"
              A character or string enclosed in double quotes is matched literally.  The  ANSI  C
              escape sequences are recognised within the characters.

       'characters'
              A character or string enclosed in single quotes is matched literally, as above.

       [characters]
              A  set  of characters enclosed in square brackets matches any single character from
              the set, with escape characters recognised as above.  If the  set  begins  with  an
              uparrow  (^)  then the set is negated (the element matches any character not in the
              set).  Any pair of characters separated with a dash (-)  represents  the  range  of
              characters  from the first to the second, inclusive.  A single alphabetic character
              or underscore is matched by the following set.

                  [a-zA-Z_]

              Similarly, the following matches  any single non-digit character.

                  [^0-9]

       .      A dot matches any character.  Note that the only time this fails is at the  end  of
              file, where there is no character to match.

       ( pattern )
              Parentheses  are  used  for  grouping  (modifying  the  precedence of the operators
              described below).

       { action }
              Curly braces surround actions.  The  action  is  arbitrary  C  source  code  to  be
              executed  at  the  end  of matching.  Any braces within the action must be properly
              nested.  Any input text that was matched before the action and delimited  by  angle
              brackets  (see  below)  is  made available within the action as the contents of the
              character array yytext.   The  length  of  (number  of  characters  in)  yytext  is
              available  in  the  variable  yyleng.   (These  variable  names are historical; see
              lex(1).)

       <      An opening angle bracket always matches (consuming no input) and causes the  parser
              to begin accumulating matched text.  This text will be made available to actions in
              the variable yytext.

       >      A closing angle bracket always matches (consuming no input) and causes  the  parser
              to stop accumulating text for yytext.

       The above elements can be made optional and/or repeatable with the following suffixes:

       element ?
              The  element  is  optional.   If present on the input, it is consumed and the match
              succeeds.  If not present on the input, no text is consumed and the match  succeeds
              anyway.

       element +
              The  element  is  repeatable.   If present on the input, one or more occurrences of
              element are consumed and the match succeeds.  If  no  occurrences  of  element  are
              present on the input, the match fails.

       element *
              The  element  is  optional  and  repeatable.   If present on the input, one or more
              occurrences of element are consumed and the match succeeds.  If no  occurrences  of
              element are present on the input, the match succeeds anyway.

       The  above  elements  and  suffixes can be converted into predicates (that match arbitrary
       input text and subsequently succeed  or  fail  without  consuming  that  input)  with  the
       following prefixes:

       & element
              The  predicate  succeeds  only if element can be matched.  Input text scanned while
              matching element  is  not  consumed  from  the  input  and  remains  available  for
              subsequent matching.

       ! element
              The predicate succeeds only if element cannot be matched.  Input text scanned while
              matching element  is  not  consumed  from  the  input  and  remains  available  for
              subsequent matching.  A popular idiom is

                  !.

              which  matches  the  end of file, after the last character of the input has already
              been consumed.

       A special form of the '&' predicate is provided:

       &{ expression }
              In this predicate the simple C expression (not statement) is evaluated  immediately
              when  the  parser  reaches the predicate.  If the expression yields non-zero (true)
              the 'match' succeeds and the parser continues with the next element in the pattern.
              If  the expression yields zero (false) the 'match' fails and the parser backs up to
              look for an alternative parse of the input.

       Several elements (with or without prefixes and suffixes) can be combined into  a  sequence
       by  writing them one after the other.  The entire sequence matches only if each individual
       element within it matches, from left to right.

       Sequences can be separated into disjoint alternatives by the alternation operator '/'.

       sequence-1 / sequence-2 / ... / sequence-N
              Each sequence is tried in turn until one of them matches, at  which  time  matching
              for  the overall pattern succeeds.  If none of the sequences matches then the match
              of the overall pattern fails.

       Finally, the pound sign (#) introduces a comment (discarded) that continues until the  end
       of the line.

       To  summarise  the  above,  the  parser  tries  to  match the input text against a pattern
       containing literals, names (representing other rules), and various operators  (written  as
       prefixes,  suffixes, juxtaposition for sequencing and and infix alternation operator) that
       modify how the elements within the pattern are matched.  Matches are  made  from  left  to
       right, 'descending' into named sub-rules as they are encountered.  If the matching process
       fails, the parser 'back tracks' ('rewinding' the input appropriately in  the  process)  to
       find  the  nearest  alternative  'path'  through  the  grammar.  In other words the parser
       performs a depth-first, left-to-right search  for  the  first  successfully-matching  path
       through  the  rules.  If found, the actions along the successful path are executed (in the
       order they were encountered).

       Note that predicates are evaluated immediately during the search for a  successful  match,
       since  they  contribute  to  the  success or failure of the search.  Actions, however, are
       evaluated only after a successful match has been found.

PEG GRAMMAR FOR PEG GRAMMARS

       The grammar for peg grammars is shown below.  This will both illustrate and formalise  the
       above description.

           Grammar         <- Spacing Definition+ EndOfFile

           Definition      <- Identifier LEFTARROW Expression
           Expression      <- Sequence ( SLASH Sequence )*
           Sequence        <- Prefix*
           Prefix          <- AND Action
                            / ( AND | NOT )? Suffix
           Suffix          <- Primary ( QUERY / STAR / PLUS )?
           Primary         <- Identifier !LEFTARROW
                            / OPEN Expression CLOSE
                            / Literal
                            / Class
                            / DOT
                            / Action
                            / BEGIN
                            / END

           Identifier      <- < IdentStart IdentCont* > Spacing
           IdentStart      <- [a-zA-Z_]
           IdentCont       <- IdentStart / [0-9]
           Literal         <- ['] < ( !['] Char  )* > ['] Spacing
                            / ["] < ( !["] Char  )* > ["] Spacing
           Class           <- '[' < ( !']' Range )* > ']' Spacing
           Range           <- Char '-' Char / Char
           Char            <- '\\' [abefnrtv'"\[\]\\]
                            / '\\' [0-3][0-7][0-7]
                            / '\\' [0-7][0-7]?
                            / '\\' '-'
                            / !'\\' .
           LEFTARROW       <- '<-' Spacing
           SLASH           <- '/' Spacing
           AND             <- '&' Spacing
           NOT             <- '!' Spacing
           QUERY           <- '?' Spacing
           STAR            <- '*' Spacing
           PLUS            <- '+' Spacing
           OPEN            <- '(' Spacing
           CLOSE           <- ')' Spacing
           DOT             <- '.' Spacing
           Spacing         <- ( Space / Comment )*
           Comment         <- '#' ( !EndOfLine . )* EndOfLine
           Space           <- ' ' / '\t' / EndOfLine
           EndOfLine       <- '\r\n' / '\n' / '\r'
           EndOfFile       <- !.
           Action          <- '{' < [^}]* > '}' Spacing
           BEGIN           <- '<' Spacing
           END             <- '>' Spacing

LEG GRAMMARS

       leg  is  a  variant of peg that adds some features of lex(1) and yacc(1).  It differs from
       peg in the following ways.

       %{ text... %}
              A declaration section can appear anywhere that a rule definition is expected.   The
              text  between  the  delimiters  '%{' and '%}' is copied verbatim to the generated C
              parser code before the code that implements the parser itself.

       name = pattern
              The 'assignment' operator replaces the left arrow operator '<-'.

       rule-name
              Hyphens can appear as letters in the names of rules.  Each hyphen is converted into
              an  underscore  in  the  generated  C source code.  A single single hyphen '-' is a
              legal rule name.

                  -       = [ \t\n\r]*
                  number  = [0-9]+                 -
                  name    = [a-zA-Z_][a-zA_Z_0-9]* -
                  l-paren = '('                    -
                  r-paren = ')'                    -

              This example shows how ignored whitespace can be obvious when reading  the  grammar
              and  yet unobtrusive when placed liberally at the end of every rule associated with
              a lexical element.

       seq-1 | seq-2
              The alternation operator is vertical bar '|' rather than forward  slash  '/'.   The
              peg rule

                  name <- sequence-1
                        / sequence-2
                        / sequence-3

              is therefore written

                  name = sequence-1
                       | sequence-2
                       | sequence-3
                       ;

              in leg (with the final semicolon being optional, as described next).

       exp ~ { action }
              A  postfix  operator ~{ action } can be placed after any expression and will behave
              like a normal action (arbitrary C code) except that it is  invoked  only  when  exp
              fails.   It  binds  less  tightly  than  any  other operator except alternation and
              sequencing, and is intended to make error handling  and  recovery  code  easier  to
              write.  Note that yytext and yyleng are not available inside these actions, but the
              pointer variable yy is available to  give  the  code  access  to  any  user-defined
              members  of  the parser state (see "CUSTOMISING THE PARSER" below).  Note also that
              exp is always a single expression; to invoke an error action for any failure within
              a  sequence,  parentheses  must  be  used  to  group  the  sequence  into  a single
              expression.

                  rule = e1 e2 e3 ~{ error("e[12] ok; e3 has failed"); }
                       | ...

                  rule = (e1 e2 e3) ~{ error("one of e[123] has failed"); }
                       | ...

       pattern ;
              A semicolon punctuator can optionally terminate a pattern.

       %% text...
              A double percent '%%' terminates  the  rules  (and  declarations)  section  of  the
              grammar.  All text following '%%' is copied verbatim to the generated C parser code
              after the parser implementation code.

       $$ = value
              A sub-rule can return a semantic value from  an  action  by  assigning  it  to  the
              pseudo-variable  '$$'.  All semantic values must have the same type (which defaults
              to 'int').  This type can be changed by defining YYSTYPE in a declaration section.

       identifier:name
              The semantic value returned (by assigning  to  '$$')  from  the  sub-rule  name  is
              associated with the identifier and can be referred to in subsequent actions.

       The desk calculator example below illustrates the use of '$$' and ':'.

LEG EXAMPLE: A DESK CALCULATOR

       The  extensions  in  leg  described  above  allow useful parsers and evaluators (including
       declarations, grammar rules, and supporting C functions such as 'main') to be kept  within
       a  single source file.  To illustrate this we show a simple desk calculator supporting the
       four common arithmetic  operators  and  named  variables.   The  intermediate  results  of
       arithmetic  evaluation  will  be  accumulated  on  an  implicit stack by returning them as
       semantic values from sub-rules.

           %{
           #include <stdio.h>     /* printf() */
           #include <stdlib.h>    /* atoi() */
           int vars[26];
           %}

           Stmt    = - e:Expr EOL                  { printf("%d\n", e); }
                   | ( !EOL . )* EOL               { printf("error\n"); }

           Expr    = i:ID ASSIGN s:Sum             { $$ = vars[i] = s; }
                   | s:Sum                         { $$ = s; }

           Sum     = l:Product
                           ( PLUS  r:Product       { l += r; }
                           | MINUS r:Product       { l -= r; }
                           )*                      { $$ = l; }

           Product = l:Value
                           ( TIMES  r:Value        { l *= r; }
                           | DIVIDE r:Value        { l /= r; }
                           )*                      { $$ = l; }

           Value   = i:NUMBER                      { $$ = atoi(yytext); }
                   | i:ID !ASSIGN                  { $$ = vars[i]; }
                   | OPEN i:Expr CLOSE             { $$ = i; }

           NUMBER  = < [0-9]+ >    -               { $$ = atoi(yytext); }
           ID      = < [a-z]  >    -               { $$ = yytext[0] - 'a'; }
           ASSIGN  = '='           -
           PLUS    = '+'           -
           MINUS   = '-'           -
           TIMES   = '*'           -
           DIVIDE  = '/'           -
           OPEN    = '('           -
           CLOSE   = ')'           -

           -       = [ \t]*
           EOL     = '\n' | '\r\n' | '\r' | ';'

           %%

           int main()
           {
             while (yyparse())
               ;
             return 0;
           }

LEG GRAMMAR FOR LEG GRAMMARS

       The grammar for leg grammars is shown below.  This will both illustrate and formalise  the
       above description.

           grammar =       -
                           ( declaration | definition )+
                           trailer? end-of-file

           declaration =   '%{' < ( !'%}' . )* > RPERCENT

           trailer =       '%%' < .* >

           definition =    identifier EQUAL expression SEMICOLON?

           expression =    sequence ( BAR sequence )*

           sequence =      error+

           error =         prefix ( TILDE action )?

           prefix =        AND action
           |               ( AND | NOT )? suffix

           suffix =        primary ( QUERY | STAR | PLUS )?

           primary =       identifier COLON identifier !EQUAL
           |               identifier !EQUAL
           |               OPEN expression CLOSE
           |               literal
           |               class
           |               DOT
           |               action
           |               BEGIN
           |               END

           identifier =    < [-a-zA-Z_][-a-zA-Z_0-9]* > -

           literal =       ['] < ( !['] char )* > ['] -
           |               ["] < ( !["] char )* > ["] -

           class =         '[' < ( !']' range )* > ']' -

           range =         char '-' char | char

           char =          '\\' [abefnrtv'"\[\]\\]
           |               '\\' [0-3][0-7][0-7]
           |               '\\' [0-7][0-7]?
           |               !'\\' .

           action =        '{' < braces* > '}' -

           braces =        '{' braces* '}'
           |               !'}' .

           EQUAL =         '=' -
           COLON =         ':' -
           SEMICOLON =     ';' -
           BAR =           '|' -
           AND =           '&' -
           NOT =           '!' -
           QUERY =         '?' -
           STAR =          '*' -
           PLUS =          '+' -
           OPEN =          '(' -
           CLOSE =         ')' -
           DOT =           '.' -
           BEGIN =         '<' -
           END =           '>' -
           TILDE =         '~' -
           RPERCENT =      '%}' -

           - =             ( space | comment )*
           space =         ' ' | '\t' | end-of-line
           comment =       '#' ( !end-of-line . )* end-of-line
           end-of-line =   '\r\n' | '\n' | '\r'
           end-of-file =   !.

CUSTOMISING THE PARSER

       The  following  symbols  can  be redefined in declaration sections to modify the generated
       parser code.

       YYSTYPE
              The semantic value type.  The pseudo-variable '$$' and the identifiers  'bound'  to
              rule results with the colon operator ':' should all be considered as being declared
              to have this type.  The default value is 'int'.

       YYPARSE
              The name of the main entry point to the parser.  The default value is 'yyparse'.

       YYPARSEFROM
              The name of an alternative entry point to the parser.  This  function  expects  one
              argument:  the function corresponding to the rule from which the search for a match
              should begin.  The default is 'yyparsefrom'.  Note that yyparse() is defined as

                  int yyparse() { return yyparsefrom(yy_foo); }

              where 'foo' is the name of the first rule in the grammar.

       YY_INPUT(buf, result, max_size)
              This macro is invoked by the parser to obtain more input text.  buf  points  to  an
              area  of  memory  that can hold at most max_size characters.  The macro should copy
              input text to buf and then assign the  integer  variable  result  to  indicate  the
              number  of  characters  copied.   If  no  more input is available, the macro should
              assign 0 to result.  By default, the YY_INPUT macro is defined as follows.

                  #define YY_INPUT(buf, result, max_size)        \
                  {                                              \
                    int yyc= getchar();                          \
                    result= (EOF == yyc) ? 0 : (*(buf)= yyc, 1); \
                  }

              Note that if YY_CTX_LOCAL is defined (see below) then an additional first argument,
              containing the parser context, is passed to YY_INPUT.

       YY_DEBUG
              If this symbols is defined then additional code will be included in the parser that
              prints vast quantities of arcane information to the standard error while the parser
              is running.

       YY_BEGIN
              This  macro  is invoked to mark the start of input text that will be made available
              in actions as 'yytext'.  This corresponds to occurrences of  '<'  in  the  grammar.
              These  are  converted  into  predicates  that are expected to succeed.  The default
              definition

                  #define YY_BEGIN (yybegin= yypos, 1)

              therefore saves the current input position and returns 1 ('true') as the result  of
              the predicate.

       YY_END This  macros  corresponds  to  '>' in the grammar.  Again, it is a predicate so the
              default definition saves the input position before 'succeeding'.

                  #define YY_END (yyend= yypos, 1)

       YY_PARSE(T)
              This macro declares the parser entry points (yyparse and yyparsefrom) to be of type
              T.  The default definition

                  #define YY_PARSE(T) T

              leaves  yyparse()  and yyparsefrom() with global visibility.  If they should not be
              externally visible in other source files, this macro can be  redefined  to  declare
              them 'static'.

                  #define YY_PARSE(T) static T

       YY_CTX_LOCAL
              If  this  symbol  is  defined  during compilation of a generated parser then global
              parser state will be kept in a structure of type 'yycontext' which can be  declared
              as  a  local variable.  This allows multiple instances of parsers to coexist and to
              be thread-safe.  The parsing function yyparse() will be declared to expect a  first
              argument  of  type  'yycontext  *', an instance of the structure holding the global
              state for the parser.  This instance must be allocated and initialised to  zero  by
              the client.  A trivial but complete example is as follows.

                  #include <stdio.h>

                  #define YY_CTX_LOCAL

                  #include "the-generated-parser.peg.c"

                  int main()
                  {
                    yycontext ctx;
                    memset(&ctx, 0, sizeof(yycontext));
                    while (yyparse(&ctx));
                    return 0;
                  }

              Note  that  if  this  symbol  is undefined then the compiled parser will statically
              allocate its global state and will be neither reentrant nor thread-safe.  Note also
              that  the  parser  yycontext  structure is initialised automatically the first time
              yyparse() is called; this structure must therefore be properly initialised to  zero
              before the first call to yyparse().

       YY_CTX_MEMBERS
              If YY_CTX_LOCAL is defined (see above) then the macro YY_CTX_MEMBERS can be defined
              to expand to any additional member field declarations that the  client  would  like
              included  in  the  declaration of the 'yycontext' structure type.  These additional
              members are otherwise ignored by the generated parser.  The instance of 'yycontext'
              associated  with  the  currently-active  parser  is available within actions as the
              pointer variable yy.

       YY_BUFFER_SIZE
              The initial size of the text buffer, in bytes.  The default is 1024 and the  buffer
              size  is  doubled  whenever required to meet demand during parsing.  An application
              that typically parses much longer strings could increase this to avoid  unnecessary
              buffer reallocation.

       YY_STACK_SIZE
              The  initial  size of the variable and action stacks.  The default is 128, which is
              doubled whenever required to meet demand during parsing.   Applications  that  have
              deep  call  stacks  with many local variables, or that perform many actions after a
              single  successful  match,  could  increase  this  to  avoid   unnecessary   buffer
              reallocation.

       YY_MALLOC(YY, SIZE)
              The  memory  allocator  for  all  parser-related  storage.   The parameters are the
              current yycontext structure and the number  of  bytes  to  allocate.   The  default
              definition is: malloc(SIZE)

       YY_REALLOC(YY, PTR, SIZE)
              The  memory  reallocator  for  dynamically-grown  storage (such as text buffers and
              variable  stacks).   The  parameters  are  the  current  yycontext  structure,  the
              previously-allocated  storage, and the number of bytes to which that storage should
              be grown.  The default definition is: realloc(PTR, SIZE)

       YY_FREE(YY, PTR)
              The memory deallocator.  The parameters are the current yycontext structure and the
              storage to deallocate.  The default definition is: free(PTR)

       YYRELEASE
              The name of the function that releases all resources held by a yycontext structure.
              The default value is 'yyrelease'.

       The following variables can be referred to within actions.

       char *yybuf
              This variable points to the parser's input buffer used to store input text that has
              not yet been matched.

       int yypos
              This is the offset (in yybuf) of the next character to be matched and consumed.

       char *yytext
              The most recent matched text delimited by '<' and '>' is stored in this variable.

       int yyleng
              This variable indicates the number of characters in 'yytext'.

       yycontext *yy
              This   variable   points  to  the  instance  of  'yycontext'  associated  with  the
              currently-active parser.

       Programs that wish to release all the resources associated  with  a  parser  can  use  the
       following function.

       yyrelease(yycontext*yy)
              Returns all parser-allocated storage associated with yy to the system.  The storage
              will be reallocated on the next call to yyparse().

       Note that the storage for the yycontext structure itself is never allocated  or  reclaimed
       implicitly.   The  application must allocate these structures in automatic storage, or use
       calloc() and free() to manage them explicitly.   The  example  in  the  following  section
       demonstrates one approach to resource management.

LEG EXAMPLE: EXTENDING THE PARSER'S CONTEXT

       The  yy  variable  passed  to actions contains the state of the parser plus any additional
       fields defined by YY_CTX_MEMBERS.  Theses fields can be used to store application-specific
       information  that is global to a particular call of yyparse().  A trivial but complete leg
       example follows in which the yycontext structure is extended with a count of the number of
       newline  characters  seen  in the input so far (the grammar otherwise consumes and ignores
       the entire input).  The caller of yyparse() uses count to print the  number  of  lines  of
       input that were read.

           %{
           #define YY_CTX_LOCAL 1
           #define YY_CTX_MEMBERS \
             int count;
           %}

           Char    = ('\n' | '\r\n' | '\r')        { yy->count++ }
                   | .

           %%

           #include <stdio.h>
           #include <string.h>

           int main()
           {
               /* create a local parser context in automatic storage */
               yycontext yy;
               /* the context *must* be initialised to zero before first use*/
               memset(&yy, 0, sizeof(yy));

               while (yyparse(&yy))
                   ;
               printf("%d newlines\n", yy.count);

               /* release all resources associated with the context */
               yyrelease(&yy);

               return 0;
           }

DIAGNOSTICS

       peg and leg warn about the following conditions while converting a grammar into a parser.

       syntax error
              The  input  grammar  was malformed in some way.  The error message will include the
              text about to be matched (often backed up a huge amount from the actual location of
              the  error) and the line number of the most recently considered character (which is
              often the real location of the problem).

       rule 'foo' used but not defined
              The grammar referred to a rule named 'foo' but no  definition  for  it  was  given.
              Attempting to use the generated parser will likely result in errors from the linker
              due to undefined symbols associated with the missing rule.

       rule 'foo' defined but not used
              The grammar defined a rule named 'foo' and then ignored it.   The  code  associated
              with  the rule is included in the generated parser which will in all other respects
              be healthy.

       possible infinite left recursion in rule 'foo'
              There exists at least one path through the grammar that leads from the  rule  'foo'
              back to (a recursive invocation of) the same rule without consuming any input.

       Left  recursion,  especially  that  found  in  standards  documents, is often 'direct' and
       implies trivial repetition.

           # (6.7.6)
           direct-abstract-declarator =
               LPAREN abstract-declarator RPAREN
           |   direct-abstract-declarator? LBRACKET assign-expr? RBRACKET
           |   direct-abstract-declarator? LBRACKET STAR RBRACKET
           |   direct-abstract-declarator? LPAREN param-type-list? RPAREN

       The recursion can easily be eliminated by converting the parts of  the  pattern  following
       the recursion into a repeatable suffix.

           # (6.7.6)
           direct-abstract-declarator =
               direct-abstract-declarator-head?
               direct-abstract-declarator-tail*

           direct-abstract-declarator-head =
               LPAREN abstract-declarator RPAREN

           direct-abstract-declarator-tail =
               LBRACKET assign-expr? RBRACKET
           |   LBRACKET STAR RBRACKET
           |   LPAREN param-type-list? RPAREN

CAVEATS

       A  parser  that  accepts empty input will always succeed.  Consider the following example,
       not atypical of a first attempt to write a PEG-based parser:

           Program = Expression*
           Expression = "whatever"
           %%
           int main() {
             while (yyparse())
               puts("success!");
             return 0;
           }

       This program loops forever, no matter what (if any) input  is  provided  on  stdin.   Many
       fixes  are  possible,  the  easiest  being  to insist that the parser always consumes some
       non-empty input.  Changing the first line to

           Program = Expression+

       accomplishes this.  If the parser is expected to consume the entire input, then explicitly
       requiring the end-of-file is also highly recommended:

           Program = Expression+ !.

       This works because the parser will only fail to match ("!" predicate) any character at all
       ("." expression) when it attempts to read beyond the end of the input.

BUGS

       You have to type 'man peg' to read the manual page for leg(1).

       The 'yy' and 'YY' prefixes cannot be changed.

       Left recursion is detected in the input grammar  but  is  not  handled  correctly  in  the
       generated parser.

       Diagnostics for errors in the input grammar are obscure and not particularly helpful.

       The operators ! and ~ should really be named the other way around.

       Several commonly-used lex(1) features (yywrap(), yyin, etc.) are completely absent.

       The  generated parser does not contain '#line' directives to direct C compiler errors back
       to the grammar description when appropriate.

SEE ALSO

       D. Val Schorre, META II, a syntax-oriented compiler writing language,  19th  ACM  National
       Conference,  1964, pp. 41.301--41.311.  Describes a self-implementing parser generator for
       analytic grammars with no backtracking.

       Alexander Birman, The TMG Recognition Schema,  Ph.D.  dissertation,  Princeton,  1970.   A
       mathematical  treatment  of  the  power  and  complexity of recursive-descent parsing with
       backtracking.

       Bryan Ford, Parsing Expression Grammars: A  Recognition-Based  Syntactic  Foundation,  ACM
       SIGPLAN Symposium on Principles of Programming Languages, 2004.  Defines PEGs and analyses
       them in relation to context-free and regular grammars.  Introduces the syntax  adopted  in
       peg.

       The standard Unix utilities lex(1) and yacc(1) which influenced the syntax and features of
       leg.

       The source code for peg and leg whose grammar parsers are written using themselves.

       The latest version of this software and documentation:

           http://piumarta.com/software/peg

AUTHOR

       peg, leg and this manual page were written by Ian Piumarta (first-name  at  last-name  dot
       com)  while  investigating  the  viability  of regular and parsing-expression grammars for
       efficiently extracting type and signature information from C header files.

       Please send bug reports and suggestions for  improvements  to  the  author  at  the  above
       address.