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flex(1) [osf1 man page]

flex(1) 						      General Commands Manual							   flex(1)

flex - Generates a C Language lexical analyzer SYNOPSIS
flex [-bcdfinpstvFILT8] -C[efmF] [-Sskeleton] [file...] OPTIONS
Generates backtracking information to lex.backtrack. This is a list of scanner states that require backtracking and the input characters on which they do so. By adding rules you can remove backtracking states. If all backtracking states are eliminated and -f or -F is used, the generated scanner will run faster. Makes the generated scanner run in debug mode. Whenever a pattern is recognized and the global yy_lex_debug is nonzero (which is the default), the scanner writes to stderr a line of the form: --accepting rule at line 53 ("the matched text") The line number refers to the location of the rule in the file defining the scanner (the input to lex). Messages are also generated when the scanner backtracks, accepts the default rule, reaches the end of its input buffer (or encounters a NULL), or reaches an End-of-File. Specifies full table (no table compression is done). The result is large but fast. This option is equivalent to -Cf. Instructs flex to generate a case-insensitive scanner. The case of letters given in the flex input patterns will be ignored, and tokens in the input will be matched regardless of case. The matched text given in yytext will have the original case (as read by the scanner). Generates a performance report to stderr. This identifies features of the flex input file that will cause a loss of performance in the resulting scanner. Causes the default rule (that unmatched scanner input is echoed to stdout) to be suppressed. If the scanner encounters input that does not match any of its rules, it aborts with an error. Instructs flex to write the scanner it generates to standard output instead of lex.yy.c. Specifies that flex should write to stderr a summary of statistics regarding the scanner it generates. Specifies that the fast scanner table representation should be used. This representation is about as fast as the full table representation (-f), and for some sets of patterns will be considerably smaller (and for others, larger). This option is equivalent to -CF. Instructs flex to generate an interactive scanner; that is, a scanner that stops immediately rather than looking ahead if it knows that the currently scanned text cannot be part of a longer rule's match. Note, -I cannot be used in conjunction with full or fast tables; that is, the -f, -F, -Cf, or -CF options. Instructs flex not to generate #line direc- tives in lex.yy.c. The default is to generate such directives so error messages in the actions will be correctly located with respect to the original lex input file. Makes flex run in trace mode. It will generate a lot of messages to stdout concerning the form of the input and the resultant nondeterministic and deterministic finite automata. This option is mostly for use in maintain- ing flex. Instructs flex to generate an 8-bit scanner (which is the default). Controls the degree of table compression. The default setting is -Cem which provides the highest degree of table compression. Faster-executing scanners can be traded off at the cost of larger tables with the following generally being true: Slowest and smallest -Cem -Cm -Ce -C -C{f,F}e -C{f,F} Fastest and largest The -C options are not cumulative; whenever the option is encountered, the previous -C settings are forgotten. The -f or -F and -Cm options do not make sense together; there is no opportunity for meta-equivalence classes if the table is not being compressed. Oth- erwise, the options may be freely mixed. A lone -C specifies that the scanner tables should be compressed and neither equivalence classes nor meta-equivalence classes should be used. Directs flex to construct equivalence classes; for example, sets of characters that have identical lexical properties. Equivalence classes usually give dramatic reductions in the final table/object file sizes (typically a factor of 2 to 5) and are inexpensive performance-wise (one array look-up per character scanned). Directs flex to con- struct meta-equivalence classes, which are sets of equivalence classes (or characters, if equivalence classes are not being used) that are commonly used together. Meta-equivalence classes are often a big win when using compressed tables, but they have a moder- ate performance impact (one or two "if" tests and one array look-up per character scanned). Specifies that the full scanner tables should be generated; flex should not compress the tables by taking advantage of similar transition functions for different states. Specifies that the alternative fast scanner representation should be used. Overrides the default skeleton file from which flex con- structs its scanners. This is useful for flex maintenance or development. Specifies table-compression options. (Obsolescent) Sup- presses the statistics summaries that the -v option typically generates. (Obsolete) DESCRIPTION
The flex command is a tool for generating scanners: programs which recognize lexical patterns in text. The flex command reads the given input files, or its standard input if no filenames are given or if a file operand is - (dash) for a description of a scanner to generate. The description is in the form of pairs of regular expressions and C code, called rules. The flex command generates as output a C source file, lex.yy.c, which defines a routine yylex(). This file is compiled and linked with the -ll library to produce an executable. When the executable is run, it scans its input and the regular expressions in its rules looking for the best match (longest input). When it has selected a rule it executes the associated C code which has access to the matched input sequence (commonly referred to as a token). This process then repeats until input is exhausted. The flex command treats multiple input files as one. Syntax for Input This section contains a description of the flex input file, which is normally named with a suffix. The section provides a listing of the special values, macros, and functions recognized by flex. The flex input file consists of three sections, separated by a line with just %% in it: [ definitions ] %% [ rules ] [ %% [ user functions ]] Contains declarations to simplify the scanner specification, and declarations of start states which are explained below. Describes what the scanner is to do. Contains user-supplied functions that copied straight through to lex.yy.c. With the exception of the first %% sequence all sections are optional. The minimal scanner %%, copies its input to standard output. Each line in the definitions section can be: Defines name to expand to regexp. name is a word beginning with a letter or an underscore (_) followed by zero or more letters, digits, underscores or dashes (-). In the regular-expression parts of the rules section, flex substitutes regexp wherever you refer to {name} (name within braces). Defines names for states used in the rules section. A rule may be made condi- tionally active based on the current scanner state. Multiple lines defining states can appear, and each can contain multiple state names, separated by white space. The name of a state follows the same syntax as that of regexp names except that dashes ('-') are not permitted. Unlike regexp names, state names share the C #define namespace. In the rules section states are recognized as <state> (state within angle brackets). The %x directive names exclusive states. When a scanner is in an exclusive state, only rules prefixed with that state are active. Inclusive states are named with the %s directive. When placed on lines by themselves, these symbols enclose C code to be passed verbatim into the global definitions of the output file. Such lines commonly include preprocessor directives and declarations of external variables and functions. Lines beginning with a space or tab in the definitions section are passed directly into the lex.yy.c output file, as part of the initial global definitions. The rules section follows the definitions, separated by a line consisting of %%. The rules section contains rules for matching input and taking actions, in the following format: pattern [action] The pattern starts in the first column of the line and extends until the first non-escaped white space character. The flex command attempts to find the pattern that matches the longest input sequence and execute the associated action. If two or more patterns match the same input the one which appears first in the rules section is chosen. If no action exists the matched input is discarded. If no pattern matches the input the default is to copy it to standard output. All action code is placed in the yylex() function. Text (C code or declarations) placed at the beginning of the rules section is copied to the beginning of the yylex() function and may be used in actions. This text must begin with a space or a tab (to distinguish it from rules). In addition, any input (beginning with a space or within %{ and %} delimiter lines) appearing at the beginning of the rules sec- tion before any rules are specified will be written to lex.yy.c after the declarations of variables for the yylex() function and before the first line of code in yylex(). Elements of each rule are: A pattern may begin with a comma separated list of state names enclosed by angle brackets (< state [,state...] >). These states are entered via the BEGIN statement. If a pattern begins with a state, the scanner can only recognize it when in that state. The initial state is 0 (zero). A regular expression to match against the input stream. The regular expressions in flex provide a rich character matching syntax. The following characters, shown in order of decreasing precedence have special meanings: Matches the character x. Enclose charac- ters and treat them as literal strings. For example, "*+" is treated as the asterisk character followed by the plus character. If str is one of the characters a, b, f, n, r, t, or v, then the ANSI C interpretation is adopted (for example, is a newline). If str is a string of octal digits it is interpreted as a character with octal value str. If str is a string of hexadecimal digits with a leading x it is interpreted as a character with that value. Otherwise, it is interpreted literally with no special meaning. For example, x*yz represents the four characters x*yz. Represents a character class in the enclosed range ([.-.]) or the enclosed list ([...]). The dash character is used to define a range of characters from the ASCII value or the 8-bit class of the character that comes before it to the ASCII value or the 8-bit class of the character that follows it. For example, [abcx-z] matches a, b, c, x, y, or z. The circumflex when it appears as the first character in a character class, indicates the complement of the set of characters within that class. For example, [^abc] matches any character except a, b or c, including special characters like newline. Groups regular expressions. For example, (ab) will be considered as a single regular expression. When enclosing numbers, indicates a number of consecutive occurrences of the expression that comes before it. For example, (ab){1,5} indicates a match for from 1 to 5 occur- rences of the string ab. When enclosing a name, the name represents a regular expression defined in the definitions section. For example, {digit} is replaced by the defined regular expression for digit. Note that the expansion takes place as if the definition were enclosed in parentheses. Matches any single character except newline. Matches zero or one of the preceding expressions. For example, ab?c matches both ac and abc. Matches zero or more of the preceding expressions. For example, a* is zero or more consecutive a characters. The utility of matching zero occurrences is more obvious in complicated expressions. For example, the expression, [A-Za-z][A-Za-z0-9]* indi- cates all alphanumeric strings with a leading alphabetic character, including strings that are only one alphabetic character. Matches one or more of the preceding expressions. For example, [a-z]+ is all strings of lowercase letters. Matches the expression x followed by the expression y. Matches either the preceding expression or the following expression. For example, a(br matches either ab or cd. Matches expression x only if expression y (trailing context) immediately follows it. For example, ab/cd matches the string ab but only if followed by cd. Only one trailing context is permitted per pattern. When it appears at the beginning of the pattern matches the beginning of a line. For example, ^abc will match the string abc if it is found at the beginning of a line. When it appears at the end of a pattern matches the end of a line. It is equivalent to / . For example, abc$ will match the string abc if it is found at the end of a line. Matches an End-of-File. Identifies a state name (see above) and may only appear at the beginning of a pattern. For example, <done><<EOF>> matches an End-of-File, but only if it is in state done. In addition, the following rules apply for bracket expressions: These represent the set of collating elements in an equivalence class and are enclosed within bracket-equal delimiters ([= =]). An equivalence class generally is designed to deal with primary-sec- ondary sorting; that is, for languages like French that define groups of characters as sorting to the same primary location, and then have a tie-breaking, secondary sort. For example, if a, `, and ^ belong to the same equivalence class, then [[=a=]b], [[=`=]b], and [[=^=]b] are each equivalent to [a`^b]. These represent the set of characters in the current locale belonging to the named ctype class. These are expressed as a ctype class name enclosed in bracket-colon delimiters ([: :]). In the C or POSIX locale, this operating system supports the following character class expressions: [:alpha:], [:upper:], [:lower:], [:digit:], [:alnum:], [:xdigit:], [:space:], [:print:], [:punct:], [:graph:], [:cntrl:]. Other locales may define additional character classes. Letters and digits never have special meanings. A character such as ^ or -, which has a special meaning in particular contexts, refers simply to itself when found outside that context. Spaces and tabs must be escaped to appear in a regular expression; other- wise they indicate the end of the expression. Each pattern in a rule has a corresponding action, which can be any arbitrary C statement. The pattern ends at the first non-escaped white space character; the remainder of the line is its action. If the action is empty, then when the pattern is matched the input which matched it is discarded. If the action contains a {, then the action spans till the balancing } is found, and the action may cross multiple lines. Using a return statement in an action returns from yylex(). An action consisting solely of a vertical bar (|) means same as the action for the next rule. The flex variables which can be used within actions are: A string (char *) containing the current matched input. It cannot be modi- fied. The length (int) of the current matched input. It cannot be modified. A stream (FILE *) that flex reads from (stdin by default). It may be changed but because of the buffering flex uses this makes sense only before scanning begins. Once scanning ter- minates because an End-of-File was seen, void yyrestart (FILE *new_file) may be called to point yyin at a new input file. Alterna- tively, yyin may be changed whenever a new or different buffer is selected (see yy_switch_to_buffer()). A stream (FILE *) to which ECHO output is written (stdout by default). It can be changed by the user. Returns the current buffer (YY_BUFFER_STATE) used for scanner input. The flex command macros and functions that may be used within actions are: Copies yytext to the scanner's output. Changes the scan- ner state to be state. This affects which rules are active. The state must be defined in a %s, or %x definition. The initial state of the scanner is INITIAL or 0 (zero). Directs the scanner to proceed immediately to the next best pattern that matches the input (which may be a prefix of the current match). yytext and yyleng are reset appropriately. Note that REJECT is a particularly expen- sive feature in terms of scanner performance; if it is used in any of the scanner's actions, it will slow down all of the scanner's pattern matching operations. REJECT cannot be used if flex is invoked with either -f or -F options. Indicates that the next matched text should be appended to the currently matched text in yytext (rather than replace it). Returns all but the first n char- acters of the current token back to the input stream, where they will be rescanned when the scanner looks for the next match. yytext and yyleng are adjusted accordingly. Returns 0 (zero) if there is more input to scan or 1 if there is not. The default yywrap() always returns 1. Currently it is implemented as a macro, however in future implementations it may become a function. Can be used in lieu of a return statement in an action. It terminates the scanner and returns a 0 (zero) to the scanner's caller. yyterminate() is automatically called when an End-of-File is encountered. It is a macro and may be redefined. Returns a YY_BUF- FER_STATE handle to a new input buffer large enough to accommodate size characters and associated with the given file. When in doubt, use YY_BUF_SIZE for the size. Switches the scanner's processing to scan for tokens from the given buffer, which must be a YY_BUFFER_STATE. Deletes the given buffer. Enables scanning to continue after yyin has been pointed at a new file to process. Controls how the scanning function, yylex() is declared. By default, it is int yylex(), or, if prototypes are being used, int yylex(void). This definition may be changed by redefining the YY_DECL macro. This macro is expanded immediately before the {...} (braces) that delimit the scanner function body. Controls scanner input. By default, YY_INPUT reads from the file-pointer yyin. Its action is to place up to max_size characters in the character array buf and return in the integer variable result either the number of characters read or the constant YY_NULL to indicate EOF. Following is a sample redefinition of YY_INPUT, in the defini- tions section of the input file: %{ #undef YY_INPUT #define YY_INPUT(buf,result,max_size) { int c = getchar(); result = (c == EOF) ? YY_NULL : (buf[0] = c, 1); } %} When the scanner receives an End-of-File indication from YY_INPUT, it checks the yywrap() function. If yywrap() returns zero, it is assumed that the yyin has been set up to point to another input file, and scanning continues. If it returns non-zero, then the scan- ner terminates, returning zero to its caller. Redefinable to provide an action which is always executed prior to the matched pat- tern's action. Redefinable to provide an action which is always executed before the first scan. Is used in the scanner to separate different actions. By default, it is simply a break, but may be redefined if necessary. The user functions section consists of complete C functions, which are passed directly into the output file (the effect is similar to defining the functions in separate files and linking them with This section is separated from the rules section by the %% delimiter. Comments, in C syntax, can appear anywhere in the user functions or definitions sections. In the rules section, comments can be embedded within actions. Empty lines or lines consisting of white space are ignored. The following macros are not normally called explicitly within an action, but are used internally by flex to handle the input and output streams. Reads the next character from the input stream. You cannot redefine input(). Writes the next character to the output stream. Puts the character c back onto the input stream. It will be the next character scanned. You cannot redefine unput(). The libl.a contains default functions to support testing or quick use of a flex program without yacc; these functions can be linked in through -ll. They can also be provided by the user. A simple wrapper that simply calls setlocale() and then calls the yylex() function. The function called when the scanner reaches the end of an input stream. The default definition simply returns 1, which causes the scanner in turn to return 0 (zero). NOTES
Some trailing context patterns cannot be properly matched and generate warning messages Dangerous trailing context These are patterns where the ending of the first part of the rule matches the beginning of the second part, such as zx*/xy*, where the x* matches the x at the beginning of the trailing context. For some trailing context rules, parts that are actually fixed length are not recognized as such, leading to the previously mentioned performance loss. In particular, patterns using {n} (such as test{3}) are always considered variable length. Combining trailing context with the special | (vertical bar) action can result in fixed trailing context being turned into the more expensive variable trailing context. This happens in the following example: %% abc| xyz/def Use of unput() invalidates the contents of yytext and yyleng within the current flex action. Use of unput() to push back more text than was matched can result in the pushed-back text matching a beginning-of-line (^) rule even though it did not come at the beginning of the line. Pattern matching of NULLs is substantially slower than matching other characters. The flex command does not generate correct #line directives for code internal to the scanner; thus, bugs in flex.skel yield invalid line numbers. Due to both buffering of input and read-ahead, you cannot intermix calls to <stdio.h> routines, such as, for example, getchar(), with flex rules and expect it to work. Call input() instead. The total table entries listed by the -v option excludes the number of table entries needed to determine what rule was matched. The number of entries is equal to the number of deterministic finite- state automaton (DFA) states if the scanner does not use REJECT, and somewhat greater than the number of states if it does. REJECT cannot be used with the -f or -F options. EXAMPLES
The following command processes the file lexcommands to produce the scanner file lex.yy.c: flex lexcommands This is then compiled and linked by the command: cc -oscanner lex.yy.c -ll This produces a program scanner. The scanner program converts uppercase to lowercase letters, removes spaces at the end of a line, and replaces multiple spaces with single spaces. The lexcommands command contains: %% [A-Z] putchar(tolower(yytext[0])); [ ]+$ [ ]+ putchar(' '); FILES
Skeleton scanner. Generated scanner C source. Backtracking information generated from -b option. SEE ALSO
Commands: yacc(1), sed(1), awk(1) Files: locale(4) flex(1)
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