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    1: <html>
    2: <head>
    3: <title>The Lemon Parser Generator</title>
    4: </head>
    5: <body bgcolor=white>
    6: <h1 align=center>The Lemon Parser Generator</h1>
    7: 
    8: <p>Lemon is an LALR(1) parser generator for C or C++.  
    9: It does the same job as ``bison'' and ``yacc''.
   10: But lemon is not another bison or yacc clone.  It
   11: uses a different grammar syntax which is designed to
   12: reduce the number of coding errors.  Lemon also uses a more
   13: sophisticated parsing engine that is faster than yacc and
   14: bison and which is both reentrant and thread-safe.
   15: Furthermore, Lemon implements features that can be used
   16: to eliminate resource leaks, making is suitable for use
   17: in long-running programs such as graphical user interfaces
   18: or embedded controllers.</p>
   19: 
   20: <p>This document is an introduction to the Lemon
   21: parser generator.</p>
   22: 
   23: <h2>Theory of Operation</h2>
   24: 
   25: <p>The main goal of Lemon is to translate a context free grammar (CFG)
   26: for a particular language into C code that implements a parser for
   27: that language.
   28: The program has two inputs:
   29: <ul>
   30: <li>The grammar specification.
   31: <li>A parser template file.
   32: </ul>
   33: Typically, only the grammar specification is supplied by the programmer.
   34: Lemon comes with a default parser template which works fine for most
   35: applications.  But the user is free to substitute a different parser
   36: template if desired.</p>
   37: 
   38: <p>Depending on command-line options, Lemon will generate between
   39: one and three files of outputs.
   40: <ul>
   41: <li>C code to implement the parser.
   42: <li>A header file defining an integer ID for each terminal symbol.
   43: <li>An information file that describes the states of the generated parser
   44:     automaton.
   45: </ul>
   46: By default, all three of these output files are generated.
   47: The header file is suppressed if the ``-m'' command-line option is
   48: used and the report file is omitted when ``-q'' is selected.</p>
   49: 
   50: <p>The grammar specification file uses a ``.y'' suffix, by convention.
   51: In the examples used in this document, we'll assume the name of the
   52: grammar file is ``gram.y''.  A typical use of Lemon would be the
   53: following command:
   54: <pre>
   55:    lemon gram.y
   56: </pre>
   57: This command will generate three output files named ``gram.c'',
   58: ``gram.h'' and ``gram.out''.
   59: The first is C code to implement the parser.  The second
   60: is the header file that defines numerical values for all
   61: terminal symbols, and the last is the report that explains
   62: the states used by the parser automaton.</p>
   63: 
   64: <h3>Command Line Options</h3>
   65: 
   66: <p>The behavior of Lemon can be modified using command-line options.
   67: You can obtain a list of the available command-line options together
   68: with a brief explanation of what each does by typing
   69: <pre>
   70:    lemon -?
   71: </pre>
   72: As of this writing, the following command-line options are supported:
   73: <ul>
   74: <li><tt>-b</tt>
   75: <li><tt>-c</tt>
   76: <li><tt>-g</tt>
   77: <li><tt>-m</tt>
   78: <li><tt>-q</tt>
   79: <li><tt>-s</tt>
   80: <li><tt>-x</tt>
   81: </ul>
   82: The ``-b'' option reduces the amount of text in the report file by
   83: printing only the basis of each parser state, rather than the full
   84: configuration.
   85: The ``-c'' option suppresses action table compression.  Using -c
   86: will make the parser a little larger and slower but it will detect
   87: syntax errors sooner.
   88: The ``-g'' option causes no output files to be generated at all.
   89: Instead, the input grammar file is printed on standard output but
   90: with all comments, actions and other extraneous text deleted.  This
   91: is a useful way to get a quick summary of a grammar.
   92: The ``-m'' option causes the output C source file to be compatible
   93: with the ``makeheaders'' program.
   94: Makeheaders is a program that automatically generates header files
   95: from C source code.  When the ``-m'' option is used, the header
   96: file is not output since the makeheaders program will take care
   97: of generated all header files automatically.
   98: The ``-q'' option suppresses the report file.
   99: Using ``-s'' causes a brief summary of parser statistics to be
  100: printed.  Like this:
  101: <pre>
  102:    Parser statistics: 74 terminals, 70 nonterminals, 179 rules
  103:                       340 states, 2026 parser table entries, 0 conflicts
  104: </pre>
  105: Finally, the ``-x'' option causes Lemon to print its version number
  106: and then stops without attempting to read the grammar or generate a parser.</p>
  107: 
  108: <h3>The Parser Interface</h3>
  109: 
  110: <p>Lemon doesn't generate a complete, working program.  It only generates
  111: a few subroutines that implement a parser.  This section describes
  112: the interface to those subroutines.  It is up to the programmer to
  113: call these subroutines in an appropriate way in order to produce a
  114: complete system.</p>
  115: 
  116: <p>Before a program begins using a Lemon-generated parser, the program
  117: must first create the parser.
  118: A new parser is created as follows:
  119: <pre>
  120:    void *pParser = ParseAlloc( malloc );
  121: </pre>
  122: The ParseAlloc() routine allocates and initializes a new parser and
  123: returns a pointer to it.
  124: The actual data structure used to represent a parser is opaque --
  125: its internal structure is not visible or usable by the calling routine.
  126: For this reason, the ParseAlloc() routine returns a pointer to void
  127: rather than a pointer to some particular structure.
  128: The sole argument to the ParseAlloc() routine is a pointer to the
  129: subroutine used to allocate memory.  Typically this means ``malloc()''.</p>
  130: 
  131: <p>After a program is finished using a parser, it can reclaim all
  132: memory allocated by that parser by calling
  133: <pre>
  134:    ParseFree(pParser, free);
  135: </pre>
  136: The first argument is the same pointer returned by ParseAlloc().  The
  137: second argument is a pointer to the function used to release bulk
  138: memory back to the system.</p>
  139: 
  140: <p>After a parser has been allocated using ParseAlloc(), the programmer
  141: must supply the parser with a sequence of tokens (terminal symbols) to
  142: be parsed.  This is accomplished by calling the following function
  143: once for each token:
  144: <pre>
  145:    Parse(pParser, hTokenID, sTokenData, pArg);
  146: </pre>
  147: The first argument to the Parse() routine is the pointer returned by
  148: ParseAlloc().
  149: The second argument is a small positive integer that tells the parse the
  150: type of the next token in the data stream.
  151: There is one token type for each terminal symbol in the grammar.
  152: The gram.h file generated by Lemon contains #define statements that
  153: map symbolic terminal symbol names into appropriate integer values.
  154: (A value of 0 for the second argument is a special flag to the
  155: parser to indicate that the end of input has been reached.)
  156: The third argument is the value of the given token.  By default,
  157: the type of the third argument is integer, but the grammar will
  158: usually redefine this type to be some kind of structure.
  159: Typically the second argument will be a broad category of tokens
  160: such as ``identifier'' or ``number'' and the third argument will
  161: be the name of the identifier or the value of the number.</p>
  162: 
  163: <p>The Parse() function may have either three or four arguments,
  164: depending on the grammar.  If the grammar specification file request
  165: it, the Parse() function will have a fourth parameter that can be
  166: of any type chosen by the programmer.  The parser doesn't do anything
  167: with this argument except to pass it through to action routines.
  168: This is a convenient mechanism for passing state information down
  169: to the action routines without having to use global variables.</p>
  170: 
  171: <p>A typical use of a Lemon parser might look something like the
  172: following:
  173: <pre>
  174:    01 ParseTree *ParseFile(const char *zFilename){
  175:    02    Tokenizer *pTokenizer;
  176:    03    void *pParser;
  177:    04    Token sToken;
  178:    05    int hTokenId;
  179:    06    ParserState sState;
  180:    07
  181:    08    pTokenizer = TokenizerCreate(zFilename);
  182:    09    pParser = ParseAlloc( malloc );
  183:    10    InitParserState(&sState);
  184:    11    while( GetNextToken(pTokenizer, &hTokenId, &sToken) ){
  185:    12       Parse(pParser, hTokenId, sToken, &sState);
  186:    13    }
  187:    14    Parse(pParser, 0, sToken, &sState);
  188:    15    ParseFree(pParser, free );
  189:    16    TokenizerFree(pTokenizer);
  190:    17    return sState.treeRoot;
  191:    18 }
  192: </pre>
  193: This example shows a user-written routine that parses a file of
  194: text and returns a pointer to the parse tree.
  195: (We've omitted all error-handling from this example to keep it
  196: simple.)
  197: We assume the existence of some kind of tokenizer which is created
  198: using TokenizerCreate() on line 8 and deleted by TokenizerFree()
  199: on line 16.  The GetNextToken() function on line 11 retrieves the
  200: next token from the input file and puts its type in the 
  201: integer variable hTokenId.  The sToken variable is assumed to be
  202: some kind of structure that contains details about each token,
  203: such as its complete text, what line it occurs on, etc. </p>
  204: 
  205: <p>This example also assumes the existence of structure of type
  206: ParserState that holds state information about a particular parse.
  207: An instance of such a structure is created on line 6 and initialized
  208: on line 10.  A pointer to this structure is passed into the Parse()
  209: routine as the optional 4th argument.
  210: The action routine specified by the grammar for the parser can use
  211: the ParserState structure to hold whatever information is useful and
  212: appropriate.  In the example, we note that the treeRoot field of
  213: the ParserState structure is left pointing to the root of the parse
  214: tree.</p>
  215: 
  216: <p>The core of this example as it relates to Lemon is as follows:
  217: <pre>
  218:    ParseFile(){
  219:       pParser = ParseAlloc( malloc );
  220:       while( GetNextToken(pTokenizer,&hTokenId, &sToken) ){
  221:          Parse(pParser, hTokenId, sToken);
  222:       }
  223:       Parse(pParser, 0, sToken);
  224:       ParseFree(pParser, free );
  225:    }
  226: </pre>
  227: Basically, what a program has to do to use a Lemon-generated parser
  228: is first create the parser, then send it lots of tokens obtained by
  229: tokenizing an input source.  When the end of input is reached, the
  230: Parse() routine should be called one last time with a token type
  231: of 0.  This step is necessary to inform the parser that the end of
  232: input has been reached.  Finally, we reclaim memory used by the
  233: parser by calling ParseFree().</p>
  234: 
  235: <p>There is one other interface routine that should be mentioned
  236: before we move on.
  237: The ParseTrace() function can be used to generate debugging output
  238: from the parser.  A prototype for this routine is as follows:
  239: <pre>
  240:    ParseTrace(FILE *stream, char *zPrefix);
  241: </pre>
  242: After this routine is called, a short (one-line) message is written
  243: to the designated output stream every time the parser changes states
  244: or calls an action routine.  Each such message is prefaced using
  245: the text given by zPrefix.  This debugging output can be turned off
  246: by calling ParseTrace() again with a first argument of NULL (0).</p>
  247: 
  248: <h3>Differences With YACC and BISON</h3>
  249: 
  250: <p>Programmers who have previously used the yacc or bison parser
  251: generator will notice several important differences between yacc and/or
  252: bison and Lemon.
  253: <ul>
  254: <li>In yacc and bison, the parser calls the tokenizer.  In Lemon,
  255:     the tokenizer calls the parser.
  256: <li>Lemon uses no global variables.  Yacc and bison use global variables
  257:     to pass information between the tokenizer and parser.
  258: <li>Lemon allows multiple parsers to be running simultaneously.  Yacc
  259:     and bison do not.
  260: </ul>
  261: These differences may cause some initial confusion for programmers
  262: with prior yacc and bison experience.
  263: But after years of experience using Lemon, I firmly
  264: believe that the Lemon way of doing things is better.</p>
  265: 
  266: <h2>Input File Syntax</h2>
  267: 
  268: <p>The main purpose of the grammar specification file for Lemon is
  269: to define the grammar for the parser.  But the input file also
  270: specifies additional information Lemon requires to do its job.
  271: Most of the work in using Lemon is in writing an appropriate
  272: grammar file.</p>
  273: 
  274: <p>The grammar file for lemon is, for the most part, free format.
  275: It does not have sections or divisions like yacc or bison.  Any
  276: declaration can occur at any point in the file.
  277: Lemon ignores whitespace (except where it is needed to separate
  278: tokens) and it honors the same commenting conventions as C and C++.</p>
  279: 
  280: <h3>Terminals and Nonterminals</h3>
  281: 
  282: <p>A terminal symbol (token) is any string of alphanumeric
  283: and underscore characters
  284: that begins with an upper case letter.
  285: A terminal can contain lowercase letters after the first character,
  286: but the usual convention is to make terminals all upper case.
  287: A nonterminal, on the other hand, is any string of alphanumeric
  288: and underscore characters than begins with a lower case letter.
  289: Again, the usual convention is to make nonterminals use all lower
  290: case letters.</p>
  291: 
  292: <p>In Lemon, terminal and nonterminal symbols do not need to 
  293: be declared or identified in a separate section of the grammar file.
  294: Lemon is able to generate a list of all terminals and nonterminals
  295: by examining the grammar rules, and it can always distinguish a
  296: terminal from a nonterminal by checking the case of the first
  297: character of the name.</p>
  298: 
  299: <p>Yacc and bison allow terminal symbols to have either alphanumeric
  300: names or to be individual characters included in single quotes, like
  301: this: ')' or '$'.  Lemon does not allow this alternative form for
  302: terminal symbols.  With Lemon, all symbols, terminals and nonterminals,
  303: must have alphanumeric names.</p>
  304: 
  305: <h3>Grammar Rules</h3>
  306: 
  307: <p>The main component of a Lemon grammar file is a sequence of grammar
  308: rules.
  309: Each grammar rule consists of a nonterminal symbol followed by
  310: the special symbol ``::='' and then a list of terminals and/or nonterminals.
  311: The rule is terminated by a period.
  312: The list of terminals and nonterminals on the right-hand side of the
  313: rule can be empty.
  314: Rules can occur in any order, except that the left-hand side of the
  315: first rule is assumed to be the start symbol for the grammar (unless
  316: specified otherwise using the <tt>%start</tt> directive described below.)
  317: A typical sequence of grammar rules might look something like this:
  318: <pre>
  319:   expr ::= expr PLUS expr.
  320:   expr ::= expr TIMES expr.
  321:   expr ::= LPAREN expr RPAREN.
  322:   expr ::= VALUE.
  323: </pre>
  324: </p>
  325: 
  326: <p>There is one non-terminal in this example, ``expr'', and five
  327: terminal symbols or tokens: ``PLUS'', ``TIMES'', ``LPAREN'',
  328: ``RPAREN'' and ``VALUE''.</p>
  329: 
  330: <p>Like yacc and bison, Lemon allows the grammar to specify a block
  331: of C code that will be executed whenever a grammar rule is reduced
  332: by the parser.
  333: In Lemon, this action is specified by putting the C code (contained
  334: within curly braces <tt>{...}</tt>) immediately after the
  335: period that closes the rule.
  336: For example:
  337: <pre>
  338:   expr ::= expr PLUS expr.   { printf("Doing an addition...\n"); }
  339: </pre>
  340: </p>
  341: 
  342: <p>In order to be useful, grammar actions must normally be linked to
  343: their associated grammar rules.
  344: In yacc and bison, this is accomplished by embedding a ``$$'' in the
  345: action to stand for the value of the left-hand side of the rule and
  346: symbols ``$1'', ``$2'', and so forth to stand for the value of
  347: the terminal or nonterminal at position 1, 2 and so forth on the
  348: right-hand side of the rule.
  349: This idea is very powerful, but it is also very error-prone.  The
  350: single most common source of errors in a yacc or bison grammar is
  351: to miscount the number of symbols on the right-hand side of a grammar
  352: rule and say ``$7'' when you really mean ``$8''.</p>
  353: 
  354: <p>Lemon avoids the need to count grammar symbols by assigning symbolic
  355: names to each symbol in a grammar rule and then using those symbolic
  356: names in the action.
  357: In yacc or bison, one would write this:
  358: <pre>
  359:   expr -> expr PLUS expr  { $$ = $1 + $3; };
  360: </pre>
  361: But in Lemon, the same rule becomes the following:
  362: <pre>
  363:   expr(A) ::= expr(B) PLUS expr(C).  { A = B+C; }
  364: </pre>
  365: In the Lemon rule, any symbol in parentheses after a grammar rule
  366: symbol becomes a place holder for that symbol in the grammar rule.
  367: This place holder can then be used in the associated C action to
  368: stand for the value of that symbol.<p>
  369: 
  370: <p>The Lemon notation for linking a grammar rule with its reduce
  371: action is superior to yacc/bison on several counts.
  372: First, as mentioned above, the Lemon method avoids the need to
  373: count grammar symbols.
  374: Secondly, if a terminal or nonterminal in a Lemon grammar rule
  375: includes a linking symbol in parentheses but that linking symbol
  376: is not actually used in the reduce action, then an error message
  377: is generated.
  378: For example, the rule
  379: <pre>
  380:   expr(A) ::= expr(B) PLUS expr(C).  { A = B; }
  381: </pre>
  382: will generate an error because the linking symbol ``C'' is used
  383: in the grammar rule but not in the reduce action.</p>
  384: 
  385: <p>The Lemon notation for linking grammar rules to reduce actions
  386: also facilitates the use of destructors for reclaiming memory
  387: allocated by the values of terminals and nonterminals on the
  388: right-hand side of a rule.</p>
  389: 
  390: <h3>Precedence Rules</h3>
  391: 
  392: <p>Lemon resolves parsing ambiguities in exactly the same way as
  393: yacc and bison.  A shift-reduce conflict is resolved in favor
  394: of the shift, and a reduce-reduce conflict is resolved by reducing
  395: whichever rule comes first in the grammar file.</p>
  396: 
  397: <p>Just like in
  398: yacc and bison, Lemon allows a measure of control 
  399: over the resolution of paring conflicts using precedence rules.
  400: A precedence value can be assigned to any terminal symbol
  401: using the %left, %right or %nonassoc directives.  Terminal symbols
  402: mentioned in earlier directives have a lower precedence that
  403: terminal symbols mentioned in later directives.  For example:</p>
  404: 
  405: <p><pre>
  406:    %left AND.
  407:    %left OR.
  408:    %nonassoc EQ NE GT GE LT LE.
  409:    %left PLUS MINUS.
  410:    %left TIMES DIVIDE MOD.
  411:    %right EXP NOT.
  412: </pre></p>
  413: 
  414: <p>In the preceding sequence of directives, the AND operator is
  415: defined to have the lowest precedence.  The OR operator is one
  416: precedence level higher.  And so forth.  Hence, the grammar would
  417: attempt to group the ambiguous expression
  418: <pre>
  419:      a AND b OR c
  420: </pre>
  421: like this
  422: <pre>
  423:      a AND (b OR c).
  424: </pre>
  425: The associativity (left, right or nonassoc) is used to determine
  426: the grouping when the precedence is the same.  AND is left-associative
  427: in our example, so
  428: <pre>
  429:      a AND b AND c
  430: </pre>
  431: is parsed like this
  432: <pre>
  433:      (a AND b) AND c.
  434: </pre>
  435: The EXP operator is right-associative, though, so
  436: <pre>
  437:      a EXP b EXP c
  438: </pre>
  439: is parsed like this
  440: <pre>
  441:      a EXP (b EXP c).
  442: </pre>
  443: The nonassoc precedence is used for non-associative operators.
  444: So
  445: <pre>
  446:      a EQ b EQ c
  447: </pre>
  448: is an error.</p>
  449: 
  450: <p>The precedence of non-terminals is transferred to rules as follows:
  451: The precedence of a grammar rule is equal to the precedence of the
  452: left-most terminal symbol in the rule for which a precedence is
  453: defined.  This is normally what you want, but in those cases where
  454: you want to precedence of a grammar rule to be something different,
  455: you can specify an alternative precedence symbol by putting the
  456: symbol in square braces after the period at the end of the rule and
  457: before any C-code.  For example:</p>
  458: 
  459: <p><pre>
  460:    expr = MINUS expr.  [NOT]
  461: </pre></p>
  462: 
  463: <p>This rule has a precedence equal to that of the NOT symbol, not the
  464: MINUS symbol as would have been the case by default.</p>
  465: 
  466: <p>With the knowledge of how precedence is assigned to terminal
  467: symbols and individual
  468: grammar rules, we can now explain precisely how parsing conflicts
  469: are resolved in Lemon.  Shift-reduce conflicts are resolved
  470: as follows:
  471: <ul>
  472: <li> If either the token to be shifted or the rule to be reduced
  473:      lacks precedence information, then resolve in favor of the
  474:      shift, but report a parsing conflict.
  475: <li> If the precedence of the token to be shifted is greater than
  476:      the precedence of the rule to reduce, then resolve in favor
  477:      of the shift.  No parsing conflict is reported.
  478: <li> If the precedence of the token it be shifted is less than the
  479:      precedence of the rule to reduce, then resolve in favor of the
  480:      reduce action.  No parsing conflict is reported.
  481: <li> If the precedences are the same and the shift token is
  482:      right-associative, then resolve in favor of the shift.
  483:      No parsing conflict is reported.
  484: <li> If the precedences are the same the the shift token is
  485:      left-associative, then resolve in favor of the reduce.
  486:      No parsing conflict is reported.
  487: <li> Otherwise, resolve the conflict by doing the shift and
  488:      report the parsing conflict.
  489: </ul>
  490: Reduce-reduce conflicts are resolved this way:
  491: <ul>
  492: <li> If either reduce rule 
  493:      lacks precedence information, then resolve in favor of the
  494:      rule that appears first in the grammar and report a parsing
  495:      conflict.
  496: <li> If both rules have precedence and the precedence is different
  497:      then resolve the dispute in favor of the rule with the highest
  498:      precedence and do not report a conflict.
  499: <li> Otherwise, resolve the conflict by reducing by the rule that
  500:      appears first in the grammar and report a parsing conflict.
  501: </ul>
  502: 
  503: <h3>Special Directives</h3>
  504: 
  505: <p>The input grammar to Lemon consists of grammar rules and special
  506: directives.  We've described all the grammar rules, so now we'll
  507: talk about the special directives.</p>
  508: 
  509: <p>Directives in lemon can occur in any order.  You can put them before
  510: the grammar rules, or after the grammar rules, or in the mist of the
  511: grammar rules.  It doesn't matter.  The relative order of
  512: directives used to assign precedence to terminals is important, but
  513: other than that, the order of directives in Lemon is arbitrary.</p>
  514: 
  515: <p>Lemon supports the following special directives:
  516: <ul>
  517: <li><tt>%code</tt>
  518: <li><tt>%default_destructor</tt>
  519: <li><tt>%default_type</tt>
  520: <li><tt>%destructor</tt>
  521: <li><tt>%extra_argument</tt>
  522: <li><tt>%include</tt>
  523: <li><tt>%left</tt>
  524: <li><tt>%name</tt>
  525: <li><tt>%nonassoc</tt>
  526: <li><tt>%parse_accept</tt>
  527: <li><tt>%parse_failure </tt>
  528: <li><tt>%right</tt>
  529: <li><tt>%stack_overflow</tt>
  530: <li><tt>%stack_size</tt>
  531: <li><tt>%start_symbol</tt>
  532: <li><tt>%syntax_error</tt>
  533: <li><tt>%token_destructor</tt>
  534: <li><tt>%token_prefix</tt>
  535: <li><tt>%token_type</tt>
  536: <li><tt>%type</tt>
  537: </ul>
  538: Each of these directives will be described separately in the
  539: following sections:</p>
  540: 
  541: <h4>The <tt>%code</tt> directive</h4>
  542: 
  543: <p>The %code directive is used to specify addition C/C++ code that
  544: is added to the end of the main output file.  This is similar to
  545: the %include directive except that %include is inserted at the
  546: beginning of the main output file.</p>
  547: 
  548: <p>%code is typically used to include some action routines or perhaps
  549: a tokenizer as part of the output file.</p>
  550: 
  551: <h4>The <tt>%default_destructor</tt> directive</h4>
  552: 
  553: <p>The %default_destructor directive specifies a destructor to 
  554: use for non-terminals that do not have their own destructor
  555: specified by a separate %destructor directive.  See the documentation
  556: on the %destructor directive below for additional information.</p>
  557: 
  558: <p>In some grammers, many different non-terminal symbols have the
  559: same datatype and hence the same destructor.  This directive is
  560: a convenience way to specify the same destructor for all those
  561: non-terminals using a single statement.</p>
  562: 
  563: <h4>The <tt>%default_type</tt> directive</h4>
  564: 
  565: <p>The %default_type directive specifies the datatype of non-terminal
  566: symbols that do no have their own datatype defined using a separate
  567: %type directive.  See the documentation on %type below for addition
  568: information.</p>
  569: 
  570: <h4>The <tt>%destructor</tt> directive</h4>
  571: 
  572: <p>The %destructor directive is used to specify a destructor for
  573: a non-terminal symbol.
  574: (See also the %token_destructor directive which is used to
  575: specify a destructor for terminal symbols.)</p>
  576: 
  577: <p>A non-terminal's destructor is called to dispose of the
  578: non-terminal's value whenever the non-terminal is popped from
  579: the stack.  This includes all of the following circumstances:
  580: <ul>
  581: <li> When a rule reduces and the value of a non-terminal on
  582:      the right-hand side is not linked to C code.
  583: <li> When the stack is popped during error processing.
  584: <li> When the ParseFree() function runs.
  585: </ul>
  586: The destructor can do whatever it wants with the value of
  587: the non-terminal, but its design is to deallocate memory
  588: or other resources held by that non-terminal.</p>
  589: 
  590: <p>Consider an example:
  591: <pre>
  592:    %type nt {void*}
  593:    %destructor nt { free($$); }
  594:    nt(A) ::= ID NUM.   { A = malloc( 100 ); }
  595: </pre>
  596: This example is a bit contrived but it serves to illustrate how
  597: destructors work.  The example shows a non-terminal named
  598: ``nt'' that holds values of type ``void*''.  When the rule for
  599: an ``nt'' reduces, it sets the value of the non-terminal to
  600: space obtained from malloc().  Later, when the nt non-terminal
  601: is popped from the stack, the destructor will fire and call
  602: free() on this malloced space, thus avoiding a memory leak.
  603: (Note that the symbol ``$$'' in the destructor code is replaced
  604: by the value of the non-terminal.)</p>
  605: 
  606: <p>It is important to note that the value of a non-terminal is passed
  607: to the destructor whenever the non-terminal is removed from the
  608: stack, unless the non-terminal is used in a C-code action.  If
  609: the non-terminal is used by C-code, then it is assumed that the
  610: C-code will take care of destroying it if it should really
  611: be destroyed.  More commonly, the value is used to build some
  612: larger structure and we don't want to destroy it, which is why
  613: the destructor is not called in this circumstance.</p>
  614: 
  615: <p>By appropriate use of destructors, it is possible to
  616: build a parser using Lemon that can be used within a long-running
  617: program, such as a GUI, that will not leak memory or other resources.
  618: To do the same using yacc or bison is much more difficult.</p>
  619: 
  620: <h4>The <tt>%extra_argument</tt> directive</h4>
  621: 
  622: The %extra_argument directive instructs Lemon to add a 4th parameter
  623: to the parameter list of the Parse() function it generates.  Lemon
  624: doesn't do anything itself with this extra argument, but it does
  625: make the argument available to C-code action routines, destructors,
  626: and so forth.  For example, if the grammar file contains:</p>
  627: 
  628: <p><pre>
  629:     %extra_argument { MyStruct *pAbc }
  630: </pre></p>
  631: 
  632: <p>Then the Parse() function generated will have an 4th parameter
  633: of type ``MyStruct*'' and all action routines will have access to
  634: a variable named ``pAbc'' that is the value of the 4th parameter
  635: in the most recent call to Parse().</p>
  636: 
  637: <h4>The <tt>%include</tt> directive</h4>
  638: 
  639: <p>The %include directive specifies C code that is included at the
  640: top of the generated parser.  You can include any text you want --
  641: the Lemon parser generator copies it blindly.  If you have multiple
  642: %include directives in your grammar file the value of the last
  643: %include directive overwrites all the others.</p.
  644: 
  645: <p>The %include directive is very handy for getting some extra #include
  646: preprocessor statements at the beginning of the generated parser.
  647: For example:</p>
  648: 
  649: <p><pre>
  650:    %include {#include &lt;unistd.h&gt;}
  651: </pre></p>
  652: 
  653: <p>This might be needed, for example, if some of the C actions in the
  654: grammar call functions that are prototyed in unistd.h.</p>
  655: 
  656: <h4>The <tt>%left</tt> directive</h4>
  657: 
  658: The %left directive is used (along with the %right and
  659: %nonassoc directives) to declare precedences of terminal
  660: symbols.  Every terminal symbol whose name appears after
  661: a %left directive but before the next period (``.'') is
  662: given the same left-associative precedence value.  Subsequent
  663: %left directives have higher precedence.  For example:</p>
  664: 
  665: <p><pre>
  666:    %left AND.
  667:    %left OR.
  668:    %nonassoc EQ NE GT GE LT LE.
  669:    %left PLUS MINUS.
  670:    %left TIMES DIVIDE MOD.
  671:    %right EXP NOT.
  672: </pre></p>
  673: 
  674: <p>Note the period that terminates each %left, %right or %nonassoc
  675: directive.</p>
  676: 
  677: <p>LALR(1) grammars can get into a situation where they require
  678: a large amount of stack space if you make heavy use or right-associative
  679: operators.  For this reason, it is recommended that you use %left
  680: rather than %right whenever possible.</p>
  681: 
  682: <h4>The <tt>%name</tt> directive</h4>
  683: 
  684: <p>By default, the functions generated by Lemon all begin with the
  685: five-character string ``Parse''.  You can change this string to something
  686: different using the %name directive.  For instance:</p>
  687: 
  688: <p><pre>
  689:    %name Abcde
  690: </pre></p>
  691: 
  692: <p>Putting this directive in the grammar file will cause Lemon to generate
  693: functions named
  694: <ul>
  695: <li> AbcdeAlloc(),
  696: <li> AbcdeFree(),
  697: <li> AbcdeTrace(), and
  698: <li> Abcde().
  699: </ul>
  700: The %name directive allows you to generator two or more different
  701: parsers and link them all into the same executable.
  702: </p>
  703: 
  704: <h4>The <tt>%nonassoc</tt> directive</h4>
  705: 
  706: <p>This directive is used to assign non-associative precedence to
  707: one or more terminal symbols.  See the section on precedence rules
  708: or on the %left directive for additional information.</p>
  709: 
  710: <h4>The <tt>%parse_accept</tt> directive</h4>
  711: 
  712: <p>The %parse_accept directive specifies a block of C code that is
  713: executed whenever the parser accepts its input string.  To ``accept''
  714: an input string means that the parser was able to process all tokens
  715: without error.</p>
  716: 
  717: <p>For example:</p>
  718: 
  719: <p><pre>
  720:    %parse_accept {
  721:       printf("parsing complete!\n");
  722:    }
  723: </pre></p>
  724: 
  725: 
  726: <h4>The <tt>%parse_failure</tt> directive</h4>
  727: 
  728: <p>The %parse_failure directive specifies a block of C code that
  729: is executed whenever the parser fails complete.  This code is not
  730: executed until the parser has tried and failed to resolve an input
  731: error using is usual error recovery strategy.  The routine is
  732: only invoked when parsing is unable to continue.</p>
  733: 
  734: <p><pre>
  735:    %parse_failure {
  736:      fprintf(stderr,"Giving up.  Parser is hopelessly lost...\n");
  737:    }
  738: </pre></p>
  739: 
  740: <h4>The <tt>%right</tt> directive</h4>
  741: 
  742: <p>This directive is used to assign right-associative precedence to
  743: one or more terminal symbols.  See the section on precedence rules
  744: or on the %left directive for additional information.</p>
  745: 
  746: <h4>The <tt>%stack_overflow</tt> directive</h4>
  747: 
  748: <p>The %stack_overflow directive specifies a block of C code that
  749: is executed if the parser's internal stack ever overflows.  Typically
  750: this just prints an error message.  After a stack overflow, the parser
  751: will be unable to continue and must be reset.</p>
  752: 
  753: <p><pre>
  754:    %stack_overflow {
  755:      fprintf(stderr,"Giving up.  Parser stack overflow\n");
  756:    }
  757: </pre></p>
  758: 
  759: <p>You can help prevent parser stack overflows by avoiding the use
  760: of right recursion and right-precedence operators in your grammar.
  761: Use left recursion and and left-precedence operators instead, to
  762: encourage rules to reduce sooner and keep the stack size down.
  763: For example, do rules like this:
  764: <pre>
  765:    list ::= list element.      // left-recursion.  Good!
  766:    list ::= .
  767: </pre>
  768: Not like this:
  769: <pre>
  770:    list ::= element list.      // right-recursion.  Bad!
  771:    list ::= .
  772: </pre>
  773: 
  774: <h4>The <tt>%stack_size</tt> directive</h4>
  775: 
  776: <p>If stack overflow is a problem and you can't resolve the trouble
  777: by using left-recursion, then you might want to increase the size
  778: of the parser's stack using this directive.  Put an positive integer
  779: after the %stack_size directive and Lemon will generate a parse
  780: with a stack of the requested size.  The default value is 100.</p>
  781: 
  782: <p><pre>
  783:    %stack_size 2000
  784: </pre></p>
  785: 
  786: <h4>The <tt>%start_symbol</tt> directive</h4>
  787: 
  788: <p>By default, the start-symbol for the grammar that Lemon generates
  789: is the first non-terminal that appears in the grammar file.  But you
  790: can choose a different start-symbol using the %start_symbol directive.</p>
  791: 
  792: <p><pre>
  793:    %start_symbol  prog
  794: </pre></p>
  795: 
  796: <h4>The <tt>%token_destructor</tt> directive</h4>
  797: 
  798: <p>The %destructor directive assigns a destructor to a non-terminal
  799: symbol.  (See the description of the %destructor directive above.)
  800: This directive does the same thing for all terminal symbols.</p>
  801: 
  802: <p>Unlike non-terminal symbols which may each have a different data type
  803: for their values, terminals all use the same data type (defined by
  804: the %token_type directive) and so they use a common destructor.  Other
  805: than that, the token destructor works just like the non-terminal
  806: destructors.</p>
  807: 
  808: <h4>The <tt>%token_prefix</tt> directive</h4>
  809: 
  810: <p>Lemon generates #defines that assign small integer constants
  811: to each terminal symbol in the grammar.  If desired, Lemon will
  812: add a prefix specified by this directive
  813: to each of the #defines it generates.
  814: So if the default output of Lemon looked like this:
  815: <pre>
  816:     #define AND              1
  817:     #define MINUS            2
  818:     #define OR               3
  819:     #define PLUS             4
  820: </pre>
  821: You can insert a statement into the grammar like this:
  822: <pre>
  823:     %token_prefix    TOKEN_
  824: </pre>
  825: to cause Lemon to produce these symbols instead:
  826: <pre>
  827:     #define TOKEN_AND        1
  828:     #define TOKEN_MINUS      2
  829:     #define TOKEN_OR         3
  830:     #define TOKEN_PLUS       4
  831: </pre>
  832: 
  833: <h4>The <tt>%token_type</tt> and <tt>%type</tt> directives</h4>
  834: 
  835: <p>These directives are used to specify the data types for values
  836: on the parser's stack associated with terminal and non-terminal
  837: symbols.  The values of all terminal symbols must be of the same
  838: type.  This turns out to be the same data type as the 3rd parameter
  839: to the Parse() function generated by Lemon.  Typically, you will
  840: make the value of a terminal symbol by a pointer to some kind of
  841: token structure.  Like this:</p>
  842: 
  843: <p><pre>
  844:    %token_type    {Token*}
  845: </pre></p>
  846: 
  847: <p>If the data type of terminals is not specified, the default value
  848: is ``int''.</p>
  849: 
  850: <p>Non-terminal symbols can each have their own data types.  Typically
  851: the data type  of a non-terminal is a pointer to the root of a parse-tree
  852: structure that contains all information about that non-terminal.
  853: For example:</p>
  854: 
  855: <p><pre>
  856:    %type   expr  {Expr*}
  857: </pre></p>
  858: 
  859: <p>Each entry on the parser's stack is actually a union containing
  860: instances of all data types for every non-terminal and terminal symbol.
  861: Lemon will automatically use the correct element of this union depending
  862: on what the corresponding non-terminal or terminal symbol is.  But
  863: the grammar designer should keep in mind that the size of the union
  864: will be the size of its largest element.  So if you have a single
  865: non-terminal whose data type requires 1K of storage, then your 100
  866: entry parser stack will require 100K of heap space.  If you are willing
  867: and able to pay that price, fine.  You just need to know.</p>
  868: 
  869: <h3>Error Processing</h3>
  870: 
  871: <p>After extensive experimentation over several years, it has been
  872: discovered that the error recovery strategy used by yacc is about
  873: as good as it gets.  And so that is what Lemon uses.</p>
  874: 
  875: <p>When a Lemon-generated parser encounters a syntax error, it
  876: first invokes the code specified by the %syntax_error directive, if
  877: any.  It then enters its error recovery strategy.  The error recovery
  878: strategy is to begin popping the parsers stack until it enters a
  879: state where it is permitted to shift a special non-terminal symbol
  880: named ``error''.  It then shifts this non-terminal and continues
  881: parsing.  But the %syntax_error routine will not be called again
  882: until at least three new tokens have been successfully shifted.</p>
  883: 
  884: <p>If the parser pops its stack until the stack is empty, and it still
  885: is unable to shift the error symbol, then the %parse_failed routine
  886: is invoked and the parser resets itself to its start state, ready
  887: to begin parsing a new file.  This is what will happen at the very
  888: first syntax error, of course, if there are no instances of the 
  889: ``error'' non-terminal in your grammar.</p>
  890: 
  891: </body>
  892: </html>

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