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diff --git a/third_party/sqlite/doc/lemon.html b/third_party/sqlite/doc/lemon.html new file mode 100755 index 0000000..6a4d6db --- /dev/null +++ b/third_party/sqlite/doc/lemon.html @@ -0,0 +1,892 @@ +<html> +<head> +<title>The Lemon Parser Generator</title> +</head> +<body bgcolor=white> +<h1 align=center>The Lemon Parser Generator</h1> + +<p>Lemon is an LALR(1) parser generator for C or C++. +It does the same job as ``bison'' and ``yacc''. +But lemon is not another bison or yacc clone. It +uses a different grammar syntax which is designed to +reduce the number of coding errors. Lemon also uses a more +sophisticated parsing engine that is faster than yacc and +bison and which is both reentrant and thread-safe. +Furthermore, Lemon implements features that can be used +to eliminate resource leaks, making is suitable for use +in long-running programs such as graphical user interfaces +or embedded controllers.</p> + +<p>This document is an introduction to the Lemon +parser generator.</p> + +<h2>Theory of Operation</h2> + +<p>The main goal of Lemon is to translate a context free grammar (CFG) +for a particular language into C code that implements a parser for +that language. +The program has two inputs: +<ul> +<li>The grammar specification. +<li>A parser template file. +</ul> +Typically, only the grammar specification is supplied by the programmer. +Lemon comes with a default parser template which works fine for most +applications. But the user is free to substitute a different parser +template if desired.</p> + +<p>Depending on command-line options, Lemon will generate between +one and three files of outputs. +<ul> +<li>C code to implement the parser. +<li>A header file defining an integer ID for each terminal symbol. +<li>An information file that describes the states of the generated parser + automaton. +</ul> +By default, all three of these output files are generated. +The header file is suppressed if the ``-m'' command-line option is +used and the report file is omitted when ``-q'' is selected.</p> + +<p>The grammar specification file uses a ``.y'' suffix, by convention. +In the examples used in this document, we'll assume the name of the +grammar file is ``gram.y''. A typical use of Lemon would be the +following command: +<pre> + lemon gram.y +</pre> +This command will generate three output files named ``gram.c'', +``gram.h'' and ``gram.out''. +The first is C code to implement the parser. The second +is the header file that defines numerical values for all +terminal symbols, and the last is the report that explains +the states used by the parser automaton.</p> + +<h3>Command Line Options</h3> + +<p>The behavior of Lemon can be modified using command-line options. +You can obtain a list of the available command-line options together +with a brief explanation of what each does by typing +<pre> + lemon -? +</pre> +As of this writing, the following command-line options are supported: +<ul> +<li><tt>-b</tt> +<li><tt>-c</tt> +<li><tt>-g</tt> +<li><tt>-m</tt> +<li><tt>-q</tt> +<li><tt>-s</tt> +<li><tt>-x</tt> +</ul> +The ``-b'' option reduces the amount of text in the report file by +printing only the basis of each parser state, rather than the full +configuration. +The ``-c'' option suppresses action table compression. Using -c +will make the parser a little larger and slower but it will detect +syntax errors sooner. +The ``-g'' option causes no output files to be generated at all. +Instead, the input grammar file is printed on standard output but +with all comments, actions and other extraneous text deleted. This +is a useful way to get a quick summary of a grammar. +The ``-m'' option causes the output C source file to be compatible +with the ``makeheaders'' program. +Makeheaders is a program that automatically generates header files +from C source code. When the ``-m'' option is used, the header +file is not output since the makeheaders program will take care +of generated all header files automatically. +The ``-q'' option suppresses the report file. +Using ``-s'' causes a brief summary of parser statistics to be +printed. Like this: +<pre> + Parser statistics: 74 terminals, 70 nonterminals, 179 rules + 340 states, 2026 parser table entries, 0 conflicts +</pre> +Finally, the ``-x'' option causes Lemon to print its version number +and then stops without attempting to read the grammar or generate a parser.</p> + +<h3>The Parser Interface</h3> + +<p>Lemon doesn't generate a complete, working program. It only generates +a few subroutines that implement a parser. This section describes +the interface to those subroutines. It is up to the programmer to +call these subroutines in an appropriate way in order to produce a +complete system.</p> + +<p>Before a program begins using a Lemon-generated parser, the program +must first create the parser. +A new parser is created as follows: +<pre> + void *pParser = ParseAlloc( malloc ); +</pre> +The ParseAlloc() routine allocates and initializes a new parser and +returns a pointer to it. +The actual data structure used to represent a parser is opaque -- +its internal structure is not visible or usable by the calling routine. +For this reason, the ParseAlloc() routine returns a pointer to void +rather than a pointer to some particular structure. +The sole argument to the ParseAlloc() routine is a pointer to the +subroutine used to allocate memory. Typically this means ``malloc()''.</p> + +<p>After a program is finished using a parser, it can reclaim all +memory allocated by that parser by calling +<pre> + ParseFree(pParser, free); +</pre> +The first argument is the same pointer returned by ParseAlloc(). The +second argument is a pointer to the function used to release bulk +memory back to the system.</p> + +<p>After a parser has been allocated using ParseAlloc(), the programmer +must supply the parser with a sequence of tokens (terminal symbols) to +be parsed. This is accomplished by calling the following function +once for each token: +<pre> + Parse(pParser, hTokenID, sTokenData, pArg); +</pre> +The first argument to the Parse() routine is the pointer returned by +ParseAlloc(). +The second argument is a small positive integer that tells the parse the +type of the next token in the data stream. +There is one token type for each terminal symbol in the grammar. +The gram.h file generated by Lemon contains #define statements that +map symbolic terminal symbol names into appropriate integer values. +(A value of 0 for the second argument is a special flag to the +parser to indicate that the end of input has been reached.) +The third argument is the value of the given token. By default, +the type of the third argument is integer, but the grammar will +usually redefine this type to be some kind of structure. +Typically the second argument will be a broad category of tokens +such as ``identifier'' or ``number'' and the third argument will +be the name of the identifier or the value of the number.</p> + +<p>The Parse() function may have either three or four arguments, +depending on the grammar. If the grammar specification file request +it, the Parse() function will have a fourth parameter that can be +of any type chosen by the programmer. The parser doesn't do anything +with this argument except to pass it through to action routines. +This is a convenient mechanism for passing state information down +to the action routines without having to use global variables.</p> + +<p>A typical use of a Lemon parser might look something like the +following: +<pre> + 01 ParseTree *ParseFile(const char *zFilename){ + 02 Tokenizer *pTokenizer; + 03 void *pParser; + 04 Token sToken; + 05 int hTokenId; + 06 ParserState sState; + 07 + 08 pTokenizer = TokenizerCreate(zFilename); + 09 pParser = ParseAlloc( malloc ); + 10 InitParserState(&sState); + 11 while( GetNextToken(pTokenizer, &hTokenId, &sToken) ){ + 12 Parse(pParser, hTokenId, sToken, &sState); + 13 } + 14 Parse(pParser, 0, sToken, &sState); + 15 ParseFree(pParser, free ); + 16 TokenizerFree(pTokenizer); + 17 return sState.treeRoot; + 18 } +</pre> +This example shows a user-written routine that parses a file of +text and returns a pointer to the parse tree. +(We've omitted all error-handling from this example to keep it +simple.) +We assume the existence of some kind of tokenizer which is created +using TokenizerCreate() on line 8 and deleted by TokenizerFree() +on line 16. The GetNextToken() function on line 11 retrieves the +next token from the input file and puts its type in the +integer variable hTokenId. The sToken variable is assumed to be +some kind of structure that contains details about each token, +such as its complete text, what line it occurs on, etc. </p> + +<p>This example also assumes the existence of structure of type +ParserState that holds state information about a particular parse. +An instance of such a structure is created on line 6 and initialized +on line 10. A pointer to this structure is passed into the Parse() +routine as the optional 4th argument. +The action routine specified by the grammar for the parser can use +the ParserState structure to hold whatever information is useful and +appropriate. In the example, we note that the treeRoot field of +the ParserState structure is left pointing to the root of the parse +tree.</p> + +<p>The core of this example as it relates to Lemon is as follows: +<pre> + ParseFile(){ + pParser = ParseAlloc( malloc ); + while( GetNextToken(pTokenizer,&hTokenId, &sToken) ){ + Parse(pParser, hTokenId, sToken); + } + Parse(pParser, 0, sToken); + ParseFree(pParser, free ); + } +</pre> +Basically, what a program has to do to use a Lemon-generated parser +is first create the parser, then send it lots of tokens obtained by +tokenizing an input source. When the end of input is reached, the +Parse() routine should be called one last time with a token type +of 0. This step is necessary to inform the parser that the end of +input has been reached. Finally, we reclaim memory used by the +parser by calling ParseFree().</p> + +<p>There is one other interface routine that should be mentioned +before we move on. +The ParseTrace() function can be used to generate debugging output +from the parser. A prototype for this routine is as follows: +<pre> + ParseTrace(FILE *stream, char *zPrefix); +</pre> +After this routine is called, a short (one-line) message is written +to the designated output stream every time the parser changes states +or calls an action routine. Each such message is prefaced using +the text given by zPrefix. This debugging output can be turned off +by calling ParseTrace() again with a first argument of NULL (0).</p> + +<h3>Differences With YACC and BISON</h3> + +<p>Programmers who have previously used the yacc or bison parser +generator will notice several important differences between yacc and/or +bison and Lemon. +<ul> +<li>In yacc and bison, the parser calls the tokenizer. In Lemon, + the tokenizer calls the parser. +<li>Lemon uses no global variables. Yacc and bison use global variables + to pass information between the tokenizer and parser. +<li>Lemon allows multiple parsers to be running simultaneously. Yacc + and bison do not. +</ul> +These differences may cause some initial confusion for programmers +with prior yacc and bison experience. +But after years of experience using Lemon, I firmly +believe that the Lemon way of doing things is better.</p> + +<h2>Input File Syntax</h2> + +<p>The main purpose of the grammar specification file for Lemon is +to define the grammar for the parser. But the input file also +specifies additional information Lemon requires to do its job. +Most of the work in using Lemon is in writing an appropriate +grammar file.</p> + +<p>The grammar file for lemon is, for the most part, free format. +It does not have sections or divisions like yacc or bison. Any +declaration can occur at any point in the file. +Lemon ignores whitespace (except where it is needed to separate +tokens) and it honors the same commenting conventions as C and C++.</p> + +<h3>Terminals and Nonterminals</h3> + +<p>A terminal symbol (token) is any string of alphanumeric +and underscore characters +that begins with an upper case letter. +A terminal can contain lower class letters after the first character, +but the usual convention is to make terminals all upper case. +A nonterminal, on the other hand, is any string of alphanumeric +and underscore characters than begins with a lower case letter. +Again, the usual convention is to make nonterminals use all lower +case letters.</p> + +<p>In Lemon, terminal and nonterminal symbols do not need to +be declared or identified in a separate section of the grammar file. +Lemon is able to generate a list of all terminals and nonterminals +by examining the grammar rules, and it can always distinguish a +terminal from a nonterminal by checking the case of the first +character of the name.</p> + +<p>Yacc and bison allow terminal symbols to have either alphanumeric +names or to be individual characters included in single quotes, like +this: ')' or '$'. Lemon does not allow this alternative form for +terminal symbols. With Lemon, all symbols, terminals and nonterminals, +must have alphanumeric names.</p> + +<h3>Grammar Rules</h3> + +<p>The main component of a Lemon grammar file is a sequence of grammar +rules. +Each grammar rule consists of a nonterminal symbol followed by +the special symbol ``::='' and then a list of terminals and/or nonterminals. +The rule is terminated by a period. +The list of terminals and nonterminals on the right-hand side of the +rule can be empty. +Rules can occur in any order, except that the left-hand side of the +first rule is assumed to be the start symbol for the grammar (unless +specified otherwise using the <tt>%start</tt> directive described below.) +A typical sequence of grammar rules might look something like this: +<pre> + expr ::= expr PLUS expr. + expr ::= expr TIMES expr. + expr ::= LPAREN expr RPAREN. + expr ::= VALUE. +</pre> +</p> + +<p>There is one non-terminal in this example, ``expr'', and five +terminal symbols or tokens: ``PLUS'', ``TIMES'', ``LPAREN'', +``RPAREN'' and ``VALUE''.</p> + +<p>Like yacc and bison, Lemon allows the grammar to specify a block +of C code that will be executed whenever a grammar rule is reduced +by the parser. +In Lemon, this action is specified by putting the C code (contained +within curly braces <tt>{...}</tt>) immediately after the +period that closes the rule. +For example: +<pre> + expr ::= expr PLUS expr. { printf("Doing an addition...\n"); } +</pre> +</p> + +<p>In order to be useful, grammar actions must normally be linked to +their associated grammar rules. +In yacc and bison, this is accomplished by embedding a ``$$'' in the +action to stand for the value of the left-hand side of the rule and +symbols ``$1'', ``$2'', and so forth to stand for the value of +the terminal or nonterminal at position 1, 2 and so forth on the +right-hand side of the rule. +This idea is very powerful, but it is also very error-prone. The +single most common source of errors in a yacc or bison grammar is +to miscount the number of symbols on the right-hand side of a grammar +rule and say ``$7'' when you really mean ``$8''.</p> + +<p>Lemon avoids the need to count grammar symbols by assigning symbolic +names to each symbol in a grammar rule and then using those symbolic +names in the action. +In yacc or bison, one would write this: +<pre> + expr -> expr PLUS expr { $$ = $1 + $3; }; +</pre> +But in Lemon, the same rule becomes the following: +<pre> + expr(A) ::= expr(B) PLUS expr(C). { A = B+C; } +</pre> +In the Lemon rule, any symbol in parentheses after a grammar rule +symbol becomes a place holder for that symbol in the grammar rule. +This place holder can then be used in the associated C action to +stand for the value of that symbol.<p> + +<p>The Lemon notation for linking a grammar rule with its reduce +action is superior to yacc/bison on several counts. +First, as mentioned above, the Lemon method avoids the need to +count grammar symbols. +Secondly, if a terminal or nonterminal in a Lemon grammar rule +includes a linking symbol in parentheses but that linking symbol +is not actually used in the reduce action, then an error message +is generated. +For example, the rule +<pre> + expr(A) ::= expr(B) PLUS expr(C). { A = B; } +</pre> +will generate an error because the linking symbol ``C'' is used +in the grammar rule but not in the reduce action.</p> + +<p>The Lemon notation for linking grammar rules to reduce actions +also facilitates the use of destructors for reclaiming memory +allocated by the values of terminals and nonterminals on the +right-hand side of a rule.</p> + +<h3>Precedence Rules</h3> + +<p>Lemon resolves parsing ambiguities in exactly the same way as +yacc and bison. A shift-reduce conflict is resolved in favor +of the shift, and a reduce-reduce conflict is resolved by reducing +whichever rule comes first in the grammar file.</p> + +<p>Just like in +yacc and bison, Lemon allows a measure of control +over the resolution of paring conflicts using precedence rules. +A precedence value can be assigned to any terminal symbol +using the %left, %right or %nonassoc directives. Terminal symbols +mentioned in earlier directives have a lower precedence that +terminal symbols mentioned in later directives. For example:</p> + +<p><pre> + %left AND. + %left OR. + %nonassoc EQ NE GT GE LT LE. + %left PLUS MINUS. + %left TIMES DIVIDE MOD. + %right EXP NOT. +</pre></p> + +<p>In the preceding sequence of directives, the AND operator is +defined to have the lowest precedence. The OR operator is one +precedence level higher. And so forth. Hence, the grammar would +attempt to group the ambiguous expression +<pre> + a AND b OR c +</pre> +like this +<pre> + a AND (b OR c). +</pre> +The associativity (left, right or nonassoc) is used to determine +the grouping when the precedence is the same. AND is left-associative +in our example, so +<pre> + a AND b AND c +</pre> +is parsed like this +<pre> + (a AND b) AND c. +</pre> +The EXP operator is right-associative, though, so +<pre> + a EXP b EXP c +</pre> +is parsed like this +<pre> + a EXP (b EXP c). +</pre> +The nonassoc precedence is used for non-associative operators. +So +<pre> + a EQ b EQ c +</pre> +is an error.</p> + +<p>The precedence of non-terminals is transferred to rules as follows: +The precedence of a grammar rule is equal to the precedence of the +left-most terminal symbol in the rule for which a precedence is +defined. This is normally what you want, but in those cases where +you want to precedence of a grammar rule to be something different, +you can specify an alternative precedence symbol by putting the +symbol in square braces after the period at the end of the rule and +before any C-code. For example:</p> + +<p><pre> + expr = MINUS expr. [NOT] +</pre></p> + +<p>This rule has a precedence equal to that of the NOT symbol, not the +MINUS symbol as would have been the case by default.</p> + +<p>With the knowledge of how precedence is assigned to terminal +symbols and individual +grammar rules, we can now explain precisely how parsing conflicts +are resolved in Lemon. Shift-reduce conflicts are resolved +as follows: +<ul> +<li> If either the token to be shifted or the rule to be reduced + lacks precedence information, then resolve in favor of the + shift, but report a parsing conflict. +<li> If the precedence of the token to be shifted is greater than + the precedence of the rule to reduce, then resolve in favor + of the shift. No parsing conflict is reported. +<li> If the precedence of the token it be shifted is less than the + precedence of the rule to reduce, then resolve in favor of the + reduce action. No parsing conflict is reported. +<li> If the precedences are the same and the shift token is + right-associative, then resolve in favor of the shift. + No parsing conflict is reported. +<li> If the precedences are the same the the shift token is + left-associative, then resolve in favor of the reduce. + No parsing conflict is reported. +<li> Otherwise, resolve the conflict by doing the shift and + report the parsing conflict. +</ul> +Reduce-reduce conflicts are resolved this way: +<ul> +<li> If either reduce rule + lacks precedence information, then resolve in favor of the + rule that appears first in the grammar and report a parsing + conflict. +<li> If both rules have precedence and the precedence is different + then resolve the dispute in favor of the rule with the highest + precedence and do not report a conflict. +<li> Otherwise, resolve the conflict by reducing by the rule that + appears first in the grammar and report a parsing conflict. +</ul> + +<h3>Special Directives</h3> + +<p>The input grammar to Lemon consists of grammar rules and special +directives. We've described all the grammar rules, so now we'll +talk about the special directives.</p> + +<p>Directives in lemon can occur in any order. You can put them before +the grammar rules, or after the grammar rules, or in the mist of the +grammar rules. It doesn't matter. The relative order of +directives used to assign precedence to terminals is important, but +other than that, the order of directives in Lemon is arbitrary.</p> + +<p>Lemon supports the following special directives: +<ul> +<li><tt>%code</tt> +<li><tt>%default_destructor</tt> +<li><tt>%default_type</tt> +<li><tt>%destructor</tt> +<li><tt>%extra_argument</tt> +<li><tt>%include</tt> +<li><tt>%left</tt> +<li><tt>%name</tt> +<li><tt>%nonassoc</tt> +<li><tt>%parse_accept</tt> +<li><tt>%parse_failure </tt> +<li><tt>%right</tt> +<li><tt>%stack_overflow</tt> +<li><tt>%stack_size</tt> +<li><tt>%start_symbol</tt> +<li><tt>%syntax_error</tt> +<li><tt>%token_destructor</tt> +<li><tt>%token_prefix</tt> +<li><tt>%token_type</tt> +<li><tt>%type</tt> +</ul> +Each of these directives will be described separately in the +following sections:</p> + +<h4>The <tt>%code</tt> directive</h4> + +<p>The %code directive is used to specify addition C/C++ code that +is added to the end of the main output file. This is similar to +the %include directive except that %include is inserted at the +beginning of the main output file.</p> + +<p>%code is typically used to include some action routines or perhaps +a tokenizer as part of the output file.</p> + +<h4>The <tt>%default_destructor</tt> directive</h4> + +<p>The %default_destructor directive specifies a destructor to +use for non-terminals that do not have their own destructor +specified by a separate %destructor directive. See the documentation +on the %destructor directive below for additional information.</p> + +<p>In some grammers, many different non-terminal symbols have the +same datatype and hence the same destructor. This directive is +a convenience way to specify the same destructor for all those +non-terminals using a single statement.</p> + +<h4>The <tt>%default_type</tt> directive</h4> + +<p>The %default_type directive specifies the datatype of non-terminal +symbols that do no have their own datatype defined using a separate +%type directive. See the documentation on %type below for addition +information.</p> + +<h4>The <tt>%destructor</tt> directive</h4> + +<p>The %destructor directive is used to specify a destructor for +a non-terminal symbol. +(See also the %token_destructor directive which is used to +specify a destructor for terminal symbols.)</p> + +<p>A non-terminal's destructor is called to dispose of the +non-terminal's value whenever the non-terminal is popped from +the stack. This includes all of the following circumstances: +<ul> +<li> When a rule reduces and the value of a non-terminal on + the right-hand side is not linked to C code. +<li> When the stack is popped during error processing. +<li> When the ParseFree() function runs. +</ul> +The destructor can do whatever it wants with the value of +the non-terminal, but its design is to deallocate memory +or other resources held by that non-terminal.</p> + +<p>Consider an example: +<pre> + %type nt {void*} + %destructor nt { free($$); } + nt(A) ::= ID NUM. { A = malloc( 100 ); } +</pre> +This example is a bit contrived but it serves to illustrate how +destructors work. The example shows a non-terminal named +``nt'' that holds values of type ``void*''. When the rule for +an ``nt'' reduces, it sets the value of the non-terminal to +space obtained from malloc(). Later, when the nt non-terminal +is popped from the stack, the destructor will fire and call +free() on this malloced space, thus avoiding a memory leak. +(Note that the symbol ``$$'' in the destructor code is replaced +by the value of the non-terminal.)</p> + +<p>It is important to note that the value of a non-terminal is passed +to the destructor whenever the non-terminal is removed from the +stack, unless the non-terminal is used in a C-code action. If +the non-terminal is used by C-code, then it is assumed that the +C-code will take care of destroying it if it should really +be destroyed. More commonly, the value is used to build some +larger structure and we don't want to destroy it, which is why +the destructor is not called in this circumstance.</p> + +<p>By appropriate use of destructors, it is possible to +build a parser using Lemon that can be used within a long-running +program, such as a GUI, that will not leak memory or other resources. +To do the same using yacc or bison is much more difficult.</p> + +<h4>The <tt>%extra_argument</tt> directive</h4> + +The %extra_argument directive instructs Lemon to add a 4th parameter +to the parameter list of the Parse() function it generates. Lemon +doesn't do anything itself with this extra argument, but it does +make the argument available to C-code action routines, destructors, +and so forth. For example, if the grammar file contains:</p> + +<p><pre> + %extra_argument { MyStruct *pAbc } +</pre></p> + +<p>Then the Parse() function generated will have an 4th parameter +of type ``MyStruct*'' and all action routines will have access to +a variable named ``pAbc'' that is the value of the 4th parameter +in the most recent call to Parse().</p> + +<h4>The <tt>%include</tt> directive</h4> + +<p>The %include directive specifies C code that is included at the +top of the generated parser. You can include any text you want -- +the Lemon parser generator copies it blindly. If you have multiple +%include directives in your grammar file the value of the last +%include directive overwrites all the others.</p. + +<p>The %include directive is very handy for getting some extra #include +preprocessor statements at the beginning of the generated parser. +For example:</p> + +<p><pre> + %include {#include <unistd.h>} +</pre></p> + +<p>This might be needed, for example, if some of the C actions in the +grammar call functions that are prototyed in unistd.h.</p> + +<h4>The <tt>%left</tt> directive</h4> + +The %left directive is used (along with the %right and +%nonassoc directives) to declare precedences of terminal +symbols. Every terminal symbol whose name appears after +a %left directive but before the next period (``.'') is +given the same left-associative precedence value. Subsequent +%left directives have higher precedence. For example:</p> + +<p><pre> + %left AND. + %left OR. + %nonassoc EQ NE GT GE LT LE. + %left PLUS MINUS. + %left TIMES DIVIDE MOD. + %right EXP NOT. +</pre></p> + +<p>Note the period that terminates each %left, %right or %nonassoc +directive.</p> + +<p>LALR(1) grammars can get into a situation where they require +a large amount of stack space if you make heavy use or right-associative +operators. For this reason, it is recommended that you use %left +rather than %right whenever possible.</p> + +<h4>The <tt>%name</tt> directive</h4> + +<p>By default, the functions generated by Lemon all begin with the +five-character string ``Parse''. You can change this string to something +different using the %name directive. For instance:</p> + +<p><pre> + %name Abcde +</pre></p> + +<p>Putting this directive in the grammar file will cause Lemon to generate +functions named +<ul> +<li> AbcdeAlloc(), +<li> AbcdeFree(), +<li> AbcdeTrace(), and +<li> Abcde(). +</ul> +The %name directive allows you to generator two or more different +parsers and link them all into the same executable. +</p> + +<h4>The <tt>%nonassoc</tt> directive</h4> + +<p>This directive is used to assign non-associative precedence to +one or more terminal symbols. See the section on precedence rules +or on the %left directive for additional information.</p> + +<h4>The <tt>%parse_accept</tt> directive</h4> + +<p>The %parse_accept directive specifies a block of C code that is +executed whenever the parser accepts its input string. To ``accept'' +an input string means that the parser was able to process all tokens +without error.</p> + +<p>For example:</p> + +<p><pre> + %parse_accept { + printf("parsing complete!\n"); + } +</pre></p> + + +<h4>The <tt>%parse_failure</tt> directive</h4> + +<p>The %parse_failure directive specifies a block of C code that +is executed whenever the parser fails complete. This code is not +executed until the parser has tried and failed to resolve an input +error using is usual error recovery strategy. The routine is +only invoked when parsing is unable to continue.</p> + +<p><pre> + %parse_failure { + fprintf(stderr,"Giving up. Parser is hopelessly lost...\n"); + } +</pre></p> + +<h4>The <tt>%right</tt> directive</h4> + +<p>This directive is used to assign right-associative precedence to +one or more terminal symbols. See the section on precedence rules +or on the %left directive for additional information.</p> + +<h4>The <tt>%stack_overflow</tt> directive</h4> + +<p>The %stack_overflow directive specifies a block of C code that +is executed if the parser's internal stack ever overflows. Typically +this just prints an error message. After a stack overflow, the parser +will be unable to continue and must be reset.</p> + +<p><pre> + %stack_overflow { + fprintf(stderr,"Giving up. Parser stack overflow\n"); + } +</pre></p> + +<p>You can help prevent parser stack overflows by avoiding the use +of right recursion and right-precedence operators in your grammar. +Use left recursion and and left-precedence operators instead, to +encourage rules to reduce sooner and keep the stack size down. +For example, do rules like this: +<pre> + list ::= list element. // left-recursion. Good! + list ::= . +</pre> +Not like this: +<pre> + list ::= element list. // right-recursion. Bad! + list ::= . +</pre> + +<h4>The <tt>%stack_size</tt> directive</h4> + +<p>If stack overflow is a problem and you can't resolve the trouble +by using left-recursion, then you might want to increase the size +of the parser's stack using this directive. Put an positive integer +after the %stack_size directive and Lemon will generate a parse +with a stack of the requested size. The default value is 100.</p> + +<p><pre> + %stack_size 2000 +</pre></p> + +<h4>The <tt>%start_symbol</tt> directive</h4> + +<p>By default, the start-symbol for the grammar that Lemon generates +is the first non-terminal that appears in the grammar file. But you +can choose a different start-symbol using the %start_symbol directive.</p> + +<p><pre> + %start_symbol prog +</pre></p> + +<h4>The <tt>%token_destructor</tt> directive</h4> + +<p>The %destructor directive assigns a destructor to a non-terminal +symbol. (See the description of the %destructor directive above.) +This directive does the same thing for all terminal symbols.</p> + +<p>Unlike non-terminal symbols which may each have a different data type +for their values, terminals all use the same data type (defined by +the %token_type directive) and so they use a common destructor. Other +than that, the token destructor works just like the non-terminal +destructors.</p> + +<h4>The <tt>%token_prefix</tt> directive</h4> + +<p>Lemon generates #defines that assign small integer constants +to each terminal symbol in the grammar. If desired, Lemon will +add a prefix specified by this directive +to each of the #defines it generates. +So if the default output of Lemon looked like this: +<pre> + #define AND 1 + #define MINUS 2 + #define OR 3 + #define PLUS 4 +</pre> +You can insert a statement into the grammar like this: +<pre> + %token_prefix TOKEN_ +</pre> +to cause Lemon to produce these symbols instead: +<pre> + #define TOKEN_AND 1 + #define TOKEN_MINUS 2 + #define TOKEN_OR 3 + #define TOKEN_PLUS 4 +</pre> + +<h4>The <tt>%token_type</tt> and <tt>%type</tt> directives</h4> + +<p>These directives are used to specify the data types for values +on the parser's stack associated with terminal and non-terminal +symbols. The values of all terminal symbols must be of the same +type. This turns out to be the same data type as the 3rd parameter +to the Parse() function generated by Lemon. Typically, you will +make the value of a terminal symbol by a pointer to some kind of +token structure. Like this:</p> + +<p><pre> + %token_type {Token*} +</pre></p> + +<p>If the data type of terminals is not specified, the default value +is ``int''.</p> + +<p>Non-terminal symbols can each have their own data types. Typically +the data type of a non-terminal is a pointer to the root of a parse-tree +structure that contains all information about that non-terminal. +For example:</p> + +<p><pre> + %type expr {Expr*} +</pre></p> + +<p>Each entry on the parser's stack is actually a union containing +instances of all data types for every non-terminal and terminal symbol. +Lemon will automatically use the correct element of this union depending +on what the corresponding non-terminal or terminal symbol is. But +the grammar designer should keep in mind that the size of the union +will be the size of its largest element. So if you have a single +non-terminal whose data type requires 1K of storage, then your 100 +entry parser stack will require 100K of heap space. If you are willing +and able to pay that price, fine. You just need to know.</p> + +<h3>Error Processing</h3> + +<p>After extensive experimentation over several years, it has been +discovered that the error recovery strategy used by yacc is about +as good as it gets. And so that is what Lemon uses.</p> + +<p>When a Lemon-generated parser encounters a syntax error, it +first invokes the code specified by the %syntax_error directive, if +any. It then enters its error recovery strategy. The error recovery +strategy is to begin popping the parsers stack until it enters a +state where it is permitted to shift a special non-terminal symbol +named ``error''. It then shifts this non-terminal and continues +parsing. But the %syntax_error routine will not be called again +until at least three new tokens have been successfully shifted.</p> + +<p>If the parser pops its stack until the stack is empty, and it still +is unable to shift the error symbol, then the %parse_failed routine +is invoked and the parser resets itself to its start state, ready +to begin parsing a new file. This is what will happen at the very +first syntax error, of course, if there are no instances of the +``error'' non-terminal in your grammar.</p> + +</body> +</html> diff --git a/third_party/sqlite/doc/report1.txt b/third_party/sqlite/doc/report1.txt new file mode 100755 index 0000000..a236e7c --- /dev/null +++ b/third_party/sqlite/doc/report1.txt @@ -0,0 +1,121 @@ +An SQLite (version 1.0) database was used in a large military application +where the database contained 105 tables and indices. The following is +a breakdown on the sizes of keys and data within these tables and indices: + +Entries: 967089 +Size: 45896104 +Avg Size: 48 +Key Size: 11112265 +Avg Key Size: 12 +Max Key Size: 99 + + 0..8 263 0% + 9..12 5560 0% + 13..16 71394 7% + 17..24 180717 26% + 25..32 215442 48% + 33..40 151118 64% + 41..48 77479 72% + 49..56 13983 74% + 57..64 14481 75% + 65..80 41342 79% + 81..96 127098 92% + 97..112 38054 96% + 113..128 14197 98% + 129..144 8208 99% + 145..160 3326 99% + 161..176 1242 99% + 177..192 604 99% + 193..208 222 99% + 209..224 213 99% + 225..240 132 99% + 241..256 58 99% + 257..288 515 99% + 289..320 64 99% + 321..352 39 99% + 353..384 44 99% + 385..416 25 99% + 417..448 24 99% + 449..480 26 99% + 481..512 27 99% + 513..1024 470 99% + 1025..2048 396 99% + 2049..4096 187 99% + 4097..8192 78 99% + 8193..16384 35 99% +16385..32768 17 99% +32769..65536 6 99% +65537..65541 3 100% + +If the indices are omitted, the statistics for the 49 tables +become the following: + +Entries: 451103 +Size: 30930282 +Avg Size: 69 +Key Size: 1804412 +Avg Key Size: 4 +Max Key Size: 4 + + 0..24 89 0% + 25..32 9417 2% + 33..40 119162 28% + 41..48 68710 43% + 49..56 9539 45% + 57..64 12435 48% + 65..80 38650 57% + 81..96 126877 85% + 97..112 38030 93% + 113..128 14183 96% + 129..144 7668 98% + 145..160 3302 99% + 161..176 1238 99% + 177..192 597 99% + 193..208 217 99% + 209..224 211 99% + 225..240 130 99% + 241..256 57 99% + 257..288 100 99% + 289..320 62 99% + 321..352 34 99% + 353..384 43 99% + 385..416 24 99% + 417..448 24 99% + 449..480 25 99% + 481..512 27 99% + 513..1024 153 99% + 1025..2048 92 99% + 2049..4096 7 100% + +The 56 indices have these statistics: + +Entries: 512422 +Size: 14879828 +Avg Size: 30 +Key Size: 9253204 +Avg Key Size: 19 +Max Key Size: 99 + + 0..8 246 0% + 9..12 5486 1% + 13..16 70717 14% + 17..24 178246 49% + 25..32 205722 89% + 33..40 31951 96% + 41..48 8768 97% + 49..56 4444 98% + 57..64 2046 99% + 65..80 2691 99% + 81..96 202 99% + 97..112 11 99% + 113..144 527 99% + 145..160 20 99% + 161..288 406 99% + 289..1024 316 99% + 1025..2048 304 99% + 2049..4096 180 99% + 4097..8192 78 99% + 8193..16384 35 99% +16385..32768 17 99% +32769..65536 6 99% +65537..65541 3 100% |