xref: /dragonfly/lib/libevtr/ktrfmt.yy.c (revision 944681d7)
1 #line 2 "ktrfmt.yy.c"
2 
3 #line 4 "ktrfmt.yy.c"
4 
5 #define  YY_INT_ALIGNED short int
6 
7 /* A lexical scanner generated by flex */
8 
9 #define yy_create_buffer __ktrfmt_create_buffer
10 #define yy_delete_buffer __ktrfmt_delete_buffer
11 #define yy_flex_debug __ktrfmt_flex_debug
12 #define yy_init_buffer __ktrfmt_init_buffer
13 #define yy_flush_buffer __ktrfmt_flush_buffer
14 #define yy_load_buffer_state __ktrfmt_load_buffer_state
15 #define yy_switch_to_buffer __ktrfmt_switch_to_buffer
16 #define yyin __ktrfmtin
17 #define yyleng __ktrfmtleng
18 #define yylex __ktrfmtlex
19 #define yylineno __ktrfmtlineno
20 #define yyout __ktrfmtout
21 #define yyrestart __ktrfmtrestart
22 #define yytext __ktrfmttext
23 #define yywrap __ktrfmtwrap
24 #define yyalloc __ktrfmtalloc
25 #define yyrealloc __ktrfmtrealloc
26 #define yyfree __ktrfmtfree
27 
28 #define FLEX_SCANNER
29 #define YY_FLEX_MAJOR_VERSION 2
30 #define YY_FLEX_MINOR_VERSION 5
31 #define YY_FLEX_SUBMINOR_VERSION 37
32 #if YY_FLEX_SUBMINOR_VERSION > 0
33 #define FLEX_BETA
34 #endif
35 
36 /* First, we deal with  platform-specific or compiler-specific issues. */
37 
38 /* begin standard C headers. */
39 #include <stdio.h>
40 #include <string.h>
41 #include <errno.h>
42 #include <stdlib.h>
43 
44 /* end standard C headers. */
45 
46 /* flex integer type definitions */
47 
48 #ifndef FLEXINT_H
49 #define FLEXINT_H
50 
51 /* C99 systems have <inttypes.h>. Non-C99 systems may or may not. */
52 
53 #if defined (__STDC_VERSION__) && __STDC_VERSION__ >= 199901L
54 
55 /* C99 says to define __STDC_LIMIT_MACROS before including stdint.h,
56  * if you want the limit (max/min) macros for int types.
57  */
58 #ifndef __STDC_LIMIT_MACROS
59 #define __STDC_LIMIT_MACROS 1
60 #endif
61 
62 #include <inttypes.h>
63 typedef int8_t flex_int8_t;
64 typedef uint8_t flex_uint8_t;
65 typedef int16_t flex_int16_t;
66 typedef uint16_t flex_uint16_t;
67 typedef int32_t flex_int32_t;
68 typedef uint32_t flex_uint32_t;
69 #else
70 typedef signed char flex_int8_t;
71 typedef short int flex_int16_t;
72 typedef int flex_int32_t;
73 typedef unsigned char flex_uint8_t;
74 typedef unsigned short int flex_uint16_t;
75 typedef unsigned int flex_uint32_t;
76 
77 /* Limits of integral types. */
78 #ifndef INT8_MIN
79 #define INT8_MIN               (-128)
80 #endif
81 #ifndef INT16_MIN
82 #define INT16_MIN              (-32767-1)
83 #endif
84 #ifndef INT32_MIN
85 #define INT32_MIN              (-2147483647-1)
86 #endif
87 #ifndef INT8_MAX
88 #define INT8_MAX               (127)
89 #endif
90 #ifndef INT16_MAX
91 #define INT16_MAX              (32767)
92 #endif
93 #ifndef INT32_MAX
94 #define INT32_MAX              (2147483647)
95 #endif
96 #ifndef UINT8_MAX
97 #define UINT8_MAX              (255U)
98 #endif
99 #ifndef UINT16_MAX
100 #define UINT16_MAX             (65535U)
101 #endif
102 #ifndef UINT32_MAX
103 #define UINT32_MAX             (4294967295U)
104 #endif
105 
106 #endif /* ! C99 */
107 
108 #endif /* ! FLEXINT_H */
109 
110 #ifdef __cplusplus
111 
112 /* The "const" storage-class-modifier is valid. */
113 #define YY_USE_CONST
114 
115 #else	/* ! __cplusplus */
116 
117 /* C99 requires __STDC__ to be defined as 1. */
118 #if defined (__STDC__)
119 
120 #define YY_USE_CONST
121 
122 #endif	/* defined (__STDC__) */
123 #endif	/* ! __cplusplus */
124 
125 #ifdef YY_USE_CONST
126 #define yyconst const
127 #else
128 #define yyconst
129 #endif
130 
131 /* Returned upon end-of-file. */
132 #define YY_NULL 0
133 
134 /* Promotes a possibly negative, possibly signed char to an unsigned
135  * integer for use as an array index.  If the signed char is negative,
136  * we want to instead treat it as an 8-bit unsigned char, hence the
137  * double cast.
138  */
139 #define YY_SC_TO_UI(c) ((unsigned int) (unsigned char) c)
140 
141 /* Enter a start condition.  This macro really ought to take a parameter,
142  * but we do it the disgusting crufty way forced on us by the ()-less
143  * definition of BEGIN.
144  */
145 #define BEGIN (yy_start) = 1 + 2 *
146 
147 /* Translate the current start state into a value that can be later handed
148  * to BEGIN to return to the state.  The YYSTATE alias is for lex
149  * compatibility.
150  */
151 #define YY_START (((yy_start) - 1) / 2)
152 #define YYSTATE YY_START
153 
154 /* Action number for EOF rule of a given start state. */
155 #define YY_STATE_EOF(state) (YY_END_OF_BUFFER + state + 1)
156 
157 /* Special action meaning "start processing a new file". */
158 #define YY_NEW_FILE __ktrfmtrestart(__ktrfmtin  )
159 
160 #define YY_END_OF_BUFFER_CHAR 0
161 
162 /* Size of default input buffer. */
163 #ifndef YY_BUF_SIZE
164 #define YY_BUF_SIZE 16384
165 #endif
166 
167 /* The state buf must be large enough to hold one state per character in the main buffer.
168  */
169 #define YY_STATE_BUF_SIZE   ((YY_BUF_SIZE + 2) * sizeof(yy_state_type))
170 
171 #ifndef YY_TYPEDEF_YY_BUFFER_STATE
172 #define YY_TYPEDEF_YY_BUFFER_STATE
173 typedef struct yy_buffer_state *YY_BUFFER_STATE;
174 #endif
175 
176 #ifndef YY_TYPEDEF_YY_SIZE_T
177 #define YY_TYPEDEF_YY_SIZE_T
178 typedef size_t yy_size_t;
179 #endif
180 
181 extern yy_size_t __ktrfmtleng;
182 
183 extern FILE *__ktrfmtin, *__ktrfmtout;
184 
185 #define EOB_ACT_CONTINUE_SCAN 0
186 #define EOB_ACT_END_OF_FILE 1
187 #define EOB_ACT_LAST_MATCH 2
188 
189     #define YY_LESS_LINENO(n)
190 
191 /* Return all but the first "n" matched characters back to the input stream. */
192 #define yyless(n) \
193 	do \
194 		{ \
195 		/* Undo effects of setting up __ktrfmttext. */ \
196         int yyless_macro_arg = (n); \
197         YY_LESS_LINENO(yyless_macro_arg);\
198 		*yy_cp = (yy_hold_char); \
199 		YY_RESTORE_YY_MORE_OFFSET \
200 		(yy_c_buf_p) = yy_cp = yy_bp + yyless_macro_arg - YY_MORE_ADJ; \
201 		YY_DO_BEFORE_ACTION; /* set up __ktrfmttext again */ \
202 		} \
203 	while ( 0 )
204 
205 #define unput(c) yyunput( c, (yytext_ptr)  )
206 
207 #ifndef YY_STRUCT_YY_BUFFER_STATE
208 #define YY_STRUCT_YY_BUFFER_STATE
209 struct yy_buffer_state
210 	{
211 	FILE *yy_input_file;
212 
213 	char *yy_ch_buf;		/* input buffer */
214 	char *yy_buf_pos;		/* current position in input buffer */
215 
216 	/* Size of input buffer in bytes, not including room for EOB
217 	 * characters.
218 	 */
219 	yy_size_t yy_buf_size;
220 
221 	/* Number of characters read into yy_ch_buf, not including EOB
222 	 * characters.
223 	 */
224 	yy_size_t yy_n_chars;
225 
226 	/* Whether we "own" the buffer - i.e., we know we created it,
227 	 * and can realloc() it to grow it, and should free() it to
228 	 * delete it.
229 	 */
230 	int yy_is_our_buffer;
231 
232 	/* Whether this is an "interactive" input source; if so, and
233 	 * if we're using stdio for input, then we want to use getc()
234 	 * instead of fread(), to make sure we stop fetching input after
235 	 * each newline.
236 	 */
237 	int yy_is_interactive;
238 
239 	/* Whether we're considered to be at the beginning of a line.
240 	 * If so, '^' rules will be active on the next match, otherwise
241 	 * not.
242 	 */
243 	int yy_at_bol;
244 
245     int yy_bs_lineno; /**< The line count. */
246     int yy_bs_column; /**< The column count. */
247 
248 	/* Whether to try to fill the input buffer when we reach the
249 	 * end of it.
250 	 */
251 	int yy_fill_buffer;
252 
253 	int yy_buffer_status;
254 
255 #define YY_BUFFER_NEW 0
256 #define YY_BUFFER_NORMAL 1
257 	/* When an EOF's been seen but there's still some text to process
258 	 * then we mark the buffer as YY_EOF_PENDING, to indicate that we
259 	 * shouldn't try reading from the input source any more.  We might
260 	 * still have a bunch of tokens to match, though, because of
261 	 * possible backing-up.
262 	 *
263 	 * When we actually see the EOF, we change the status to "new"
264 	 * (via __ktrfmtrestart()), so that the user can continue scanning by
265 	 * just pointing __ktrfmtin at a new input file.
266 	 */
267 #define YY_BUFFER_EOF_PENDING 2
268 
269 	};
270 #endif /* !YY_STRUCT_YY_BUFFER_STATE */
271 
272 /* Stack of input buffers. */
273 static size_t yy_buffer_stack_top = 0; /**< index of top of stack. */
274 static size_t yy_buffer_stack_max = 0; /**< capacity of stack. */
275 static YY_BUFFER_STATE * yy_buffer_stack = 0; /**< Stack as an array. */
276 
277 /* We provide macros for accessing buffer states in case in the
278  * future we want to put the buffer states in a more general
279  * "scanner state".
280  *
281  * Returns the top of the stack, or NULL.
282  */
283 #define YY_CURRENT_BUFFER ( (yy_buffer_stack) \
284                           ? (yy_buffer_stack)[(yy_buffer_stack_top)] \
285                           : NULL)
286 
287 /* Same as previous macro, but useful when we know that the buffer stack is not
288  * NULL or when we need an lvalue. For internal use only.
289  */
290 #define YY_CURRENT_BUFFER_LVALUE (yy_buffer_stack)[(yy_buffer_stack_top)]
291 
292 /* yy_hold_char holds the character lost when __ktrfmttext is formed. */
293 static char yy_hold_char;
294 static yy_size_t yy_n_chars;		/* number of characters read into yy_ch_buf */
295 yy_size_t __ktrfmtleng;
296 
297 /* Points to current character in buffer. */
298 static char *yy_c_buf_p = (char *) 0;
299 static int yy_init = 0;		/* whether we need to initialize */
300 static int yy_start = 0;	/* start state number */
301 
302 /* Flag which is used to allow __ktrfmtwrap()'s to do buffer switches
303  * instead of setting up a fresh __ktrfmtin.  A bit of a hack ...
304  */
305 static int yy_did_buffer_switch_on_eof;
306 
307 void __ktrfmtrestart (FILE *input_file  );
308 void __ktrfmt_switch_to_buffer (YY_BUFFER_STATE new_buffer  );
309 YY_BUFFER_STATE __ktrfmt_create_buffer (FILE *file,int size  );
310 void __ktrfmt_delete_buffer (YY_BUFFER_STATE b  );
311 void __ktrfmt_flush_buffer (YY_BUFFER_STATE b  );
312 void __ktrfmtpush_buffer_state (YY_BUFFER_STATE new_buffer  );
313 void __ktrfmtpop_buffer_state (void );
314 
315 static void __ktrfmtensure_buffer_stack (void );
316 static void __ktrfmt_load_buffer_state (void );
317 static void __ktrfmt_init_buffer (YY_BUFFER_STATE b,FILE *file  );
318 
319 #define YY_FLUSH_BUFFER __ktrfmt_flush_buffer(YY_CURRENT_BUFFER )
320 
321 YY_BUFFER_STATE __ktrfmt_scan_buffer (char *base,yy_size_t size  );
322 YY_BUFFER_STATE __ktrfmt_scan_string (yyconst char *yy_str  );
323 YY_BUFFER_STATE __ktrfmt_scan_bytes (yyconst char *bytes,yy_size_t len  );
324 
325 void *__ktrfmtalloc (yy_size_t  );
326 void *__ktrfmtrealloc (void *,yy_size_t  );
327 void __ktrfmtfree (void *  );
328 
329 #define yy_new_buffer __ktrfmt_create_buffer
330 
331 #define yy_set_interactive(is_interactive) \
332 	{ \
333 	if ( ! YY_CURRENT_BUFFER ){ \
334         __ktrfmtensure_buffer_stack (); \
335 		YY_CURRENT_BUFFER_LVALUE =    \
336             __ktrfmt_create_buffer(__ktrfmtin,YY_BUF_SIZE ); \
337 	} \
338 	YY_CURRENT_BUFFER_LVALUE->yy_is_interactive = is_interactive; \
339 	}
340 
341 #define yy_set_bol(at_bol) \
342 	{ \
343 	if ( ! YY_CURRENT_BUFFER ){\
344         __ktrfmtensure_buffer_stack (); \
345 		YY_CURRENT_BUFFER_LVALUE =    \
346             __ktrfmt_create_buffer(__ktrfmtin,YY_BUF_SIZE ); \
347 	} \
348 	YY_CURRENT_BUFFER_LVALUE->yy_at_bol = at_bol; \
349 	}
350 
351 #define YY_AT_BOL() (YY_CURRENT_BUFFER_LVALUE->yy_at_bol)
352 
353 /* Begin user sect3 */
354 
355 #define __ktrfmtwrap() 1
356 #define YY_SKIP_YYWRAP
357 
358 typedef unsigned char YY_CHAR;
359 
360 FILE *__ktrfmtin = (FILE *) 0, *__ktrfmtout = (FILE *) 0;
361 
362 typedef int yy_state_type;
363 
364 extern int __ktrfmtlineno;
365 
366 int __ktrfmtlineno = 1;
367 
368 extern char *__ktrfmttext;
369 #define yytext_ptr __ktrfmttext
370 
371 static yy_state_type yy_get_previous_state (void );
372 static yy_state_type yy_try_NUL_trans (yy_state_type current_state  );
373 static int yy_get_next_buffer (void );
374 static void yy_fatal_error (yyconst char msg[]  );
375 
376 /* Done after the current pattern has been matched and before the
377  * corresponding action - sets up __ktrfmttext.
378  */
379 #define YY_DO_BEFORE_ACTION \
380 	(yytext_ptr) = yy_bp; \
381 	__ktrfmtleng = (size_t) (yy_cp - yy_bp); \
382 	(yy_hold_char) = *yy_cp; \
383 	*yy_cp = '\0'; \
384 	(yy_c_buf_p) = yy_cp;
385 
386 #define YY_NUM_RULES 11
387 #define YY_END_OF_BUFFER 12
388 /* This struct is not used in this scanner,
389    but its presence is necessary. */
390 struct yy_trans_info
391 	{
392 	flex_int32_t yy_verify;
393 	flex_int32_t yy_nxt;
394 	};
395 static yyconst flex_int16_t yy_accept[26] =
396     {   0,
397         0,    0,   12,   11,    1,   11,    3,    8,    5,    5,
398         7,    4,    9,   10,    1,    0,    0,    3,    5,    0,
399         4,    2,    2,    6,    0
400     } ;
401 
402 static yyconst flex_int32_t yy_ec[256] =
403     {   0,
404         1,    1,    1,    1,    1,    1,    1,    1,    2,    3,
405         1,    1,    2,    1,    1,    1,    1,    1,    1,    1,
406         1,    1,    1,    1,    1,    1,    1,    1,    1,    1,
407         1,    2,    1,    4,    1,    5,    1,    1,    1,    1,
408         1,    1,    1,    1,    1,    6,    1,    7,    8,    8,
409         8,    8,    8,    8,    8,    8,    8,    1,    1,    1,
410         9,    1,    1,    1,   10,   10,   10,   10,   10,   10,
411        11,   11,   11,   11,   11,   11,   11,   11,   11,   11,
412        11,   11,   11,   11,   11,   11,   11,   11,   11,   11,
413        12,   13,   14,    1,   15,    1,   16,   16,   16,   16,
414 
415        16,   16,   15,   15,   15,   15,   15,   15,   15,   15,
416        15,   15,   15,   15,   15,   15,   15,   15,   15,   17,
417        15,   15,    1,    1,    1,    1,    1,    1,    1,    1,
418         1,    1,    1,    1,    1,    1,    1,    1,    1,    1,
419         1,    1,    1,    1,    1,    1,    1,    1,    1,    1,
420         1,    1,    1,    1,    1,    1,    1,    1,    1,    1,
421         1,    1,    1,    1,    1,    1,    1,    1,    1,    1,
422         1,    1,    1,    1,    1,    1,    1,    1,    1,    1,
423         1,    1,    1,    1,    1,    1,    1,    1,    1,    1,
424         1,    1,    1,    1,    1,    1,    1,    1,    1,    1,
425 
426         1,    1,    1,    1,    1,    1,    1,    1,    1,    1,
427         1,    1,    1,    1,    1,    1,    1,    1,    1,    1,
428         1,    1,    1,    1,    1,    1,    1,    1,    1,    1,
429         1,    1,    1,    1,    1,    1,    1,    1,    1,    1,
430         1,    1,    1,    1,    1,    1,    1,    1,    1,    1,
431         1,    1,    1,    1,    1
432     } ;
433 
434 static yyconst flex_int32_t yy_meta[18] =
435     {   0,
436         1,    1,    2,    2,    1,    1,    3,    3,    1,    4,
437         5,    1,    1,    1,    5,    4,    6
438     } ;
439 
440 static yyconst flex_int16_t yy_base[31] =
441     {   0,
442         0,    0,   31,   54,   26,   14,    0,   54,    9,   11,
443        54,    0,   54,   54,   23,   16,   17,    0,   15,    0,
444         0,   54,   20,    0,   54,   33,   37,   41,   45,   49
445     } ;
446 
447 static yyconst flex_int16_t yy_def[31] =
448     {   0,
449        25,    1,   25,   25,   25,   26,   27,   25,   28,   25,
450        25,   29,   25,   25,   25,   26,   26,   27,   25,   30,
451        29,   25,   26,   30,    0,   25,   25,   25,   25,   25
452     } ;
453 
454 static yyconst flex_int16_t yy_nxt[72] =
455     {   0,
456         4,    5,    4,    6,    7,    8,    9,   10,   11,   12,
457        12,   13,    4,   14,    7,    7,    7,   19,   19,   22,
458        23,   19,   19,   22,   15,   20,   17,   15,   17,   17,
459        25,   25,   17,   16,   25,   16,   16,   16,   16,   18,
460        18,   18,   18,   19,   25,   25,   19,   21,   21,   21,
461        21,   24,   24,    3,   25,   25,   25,   25,   25,   25,
462        25,   25,   25,   25,   25,   25,   25,   25,   25,   25,
463        25
464     } ;
465 
466 static yyconst flex_int16_t yy_chk[72] =
467     {   0,
468         1,    1,    1,    1,    1,    1,    1,    1,    1,    1,
469         1,    1,    1,    1,    1,    1,    1,   10,   10,   16,
470        17,   19,   19,   23,   15,    9,    6,    5,   16,   17,
471         3,    0,   23,   26,    0,   26,   26,   26,   26,   27,
472        27,   27,   27,   28,    0,    0,   28,   29,   29,   29,
473        29,   30,   30,   25,   25,   25,   25,   25,   25,   25,
474        25,   25,   25,   25,   25,   25,   25,   25,   25,   25,
475        25
476     } ;
477 
478 static yy_state_type yy_last_accepting_state;
479 static char *yy_last_accepting_cpos;
480 
481 extern int __ktrfmt_flex_debug;
482 int __ktrfmt_flex_debug = 0;
483 
484 /* The intent behind this definition is that it'll catch
485  * any uses of REJECT which flex missed.
486  */
487 #define REJECT reject_used_but_not_detected
488 #define yymore() yymore_used_but_not_detected
489 #define YY_MORE_ADJ 0
490 #define YY_RESTORE_YY_MORE_OFFSET
491 char *__ktrfmttext;
492 #line 1 "ktrfmt.l"
493 #line 2 "ktrfmt.l"
494 
495 #include <assert.h>
496 //#define YYSTYPE struct token
497 #define YY_NO_INPUT
498 #include <stdlib.h>
499 #include "internal.h"
500 #include "ktrfmt.tab.h"
501 #include "tok.h"
502 
503 enum {
504 	NR_TOKENS = 18,
505 };
506 
507 /* XXX: need to switch to reentrant lexer */
508 static struct token tokens[NR_TOKENS];
509 static int curr_tok;
510 static struct symtab *strtab;
511 
512 static
513 struct token *
tok_new(void)514 tok_new(void)
515 {
516 	++curr_tok;
517 	if (curr_tok == NR_TOKENS) {
518 		/* can't happen */
519 		fprintf(stderr, "Reached max number of tokens\n");
520 		abort();
521 	}
522 	return &tokens[curr_tok];
523 }
524 
525 void
tok_free(struct token * tok)526 tok_free(struct token *tok)
527 {
528 	assert(&tokens[curr_tok] == tok);
529 	--curr_tok;
530 }
531 
532 /*
533  * We keep track of strings we've seen before so string comparison
534  * can be done w/ a simple pointer comparison
535  */
536 static
537 char *
newstr(const char * s)538 newstr(const char *s)
539 {
540 	void *r;
541 	if (!strtab)
542 		strtab = symtab_new();
543 	if ((r = symtab_find(strtab, s)))
544 		return r;
545 	if (!(r = strdup(s)))
546 		return r;
547 	symtab_insert(strtab, r, r);
548 	return r;
549 }
550 
551 #line 552 "ktrfmt.yy.c"
552 
553 #define INITIAL 0
554 
555 #ifndef YY_NO_UNISTD_H
556 /* Special case for "unistd.h", since it is non-ANSI. We include it way
557  * down here because we want the user's section 1 to have been scanned first.
558  * The user has a chance to override it with an option.
559  */
560 #include <unistd.h>
561 #endif
562 
563 #ifndef YY_EXTRA_TYPE
564 #define YY_EXTRA_TYPE void *
565 #endif
566 
567 static int yy_init_globals (void );
568 
569 /* Accessor methods to globals.
570    These are made visible to non-reentrant scanners for convenience. */
571 
572 int __ktrfmtlex_destroy (void );
573 
574 int __ktrfmtget_debug (void );
575 
576 void __ktrfmtset_debug (int debug_flag  );
577 
578 YY_EXTRA_TYPE __ktrfmtget_extra (void );
579 
580 void __ktrfmtset_extra (YY_EXTRA_TYPE user_defined  );
581 
582 FILE *__ktrfmtget_in (void );
583 
584 void __ktrfmtset_in  (FILE * in_str  );
585 
586 FILE *__ktrfmtget_out (void );
587 
588 void __ktrfmtset_out  (FILE * out_str  );
589 
590 yy_size_t __ktrfmtget_leng (void );
591 
592 char *__ktrfmtget_text (void );
593 
594 int __ktrfmtget_lineno (void );
595 
596 void __ktrfmtset_lineno (int line_number  );
597 
598 YYSTYPE * __ktrfmtget_lval (void );
599 
600 void __ktrfmtset_lval (YYSTYPE * yylval_param  );
601 
602 /* Macros after this point can all be overridden by user definitions in
603  * section 1.
604  */
605 
606 #ifndef YY_SKIP_YYWRAP
607 #ifdef __cplusplus
608 extern "C" int __ktrfmtwrap (void );
609 #else
610 extern int __ktrfmtwrap (void );
611 #endif
612 #endif
613 
614 #ifndef yytext_ptr
615 static void yy_flex_strncpy (char *,yyconst char *,int );
616 #endif
617 
618 #ifdef YY_NEED_STRLEN
619 static int yy_flex_strlen (yyconst char * );
620 #endif
621 
622 #ifndef YY_NO_INPUT
623 
624 #ifdef __cplusplus
625 static int yyinput (void );
626 #else
627 static int input (void );
628 #endif
629 
630 #endif
631 
632 /* Amount of stuff to slurp up with each read. */
633 #ifndef YY_READ_BUF_SIZE
634 #define YY_READ_BUF_SIZE 8192
635 #endif
636 
637 /* Copy whatever the last rule matched to the standard output. */
638 #ifndef ECHO
639 /* This used to be an fputs(), but since the string might contain NUL's,
640  * we now use fwrite().
641  */
642 #define ECHO do { if (fwrite( __ktrfmttext, __ktrfmtleng, 1, __ktrfmtout )) {} } while (0)
643 #endif
644 
645 /* Gets input and stuffs it into "buf".  number of characters read, or YY_NULL,
646  * is returned in "result".
647  */
648 #ifndef YY_INPUT
649 #define YY_INPUT(buf,result,max_size) \
650 	if ( YY_CURRENT_BUFFER_LVALUE->yy_is_interactive ) \
651 		{ \
652 		int c = '*'; \
653 		size_t n; \
654 		for ( n = 0; n < max_size && \
655 			     (c = getc( __ktrfmtin )) != EOF && c != '\n'; ++n ) \
656 			buf[n] = (char) c; \
657 		if ( c == '\n' ) \
658 			buf[n++] = (char) c; \
659 		if ( c == EOF && ferror( __ktrfmtin ) ) \
660 			YY_FATAL_ERROR( "input in flex scanner failed" ); \
661 		result = n; \
662 		} \
663 	else \
664 		{ \
665 		errno=0; \
666 		while ( (result = fread(buf, 1, max_size, __ktrfmtin))==0 && ferror(__ktrfmtin)) \
667 			{ \
668 			if( errno != EINTR) \
669 				{ \
670 				YY_FATAL_ERROR( "input in flex scanner failed" ); \
671 				break; \
672 				} \
673 			errno=0; \
674 			clearerr(__ktrfmtin); \
675 			} \
676 		}\
677 \
678 
679 #endif
680 
681 /* No semi-colon after return; correct usage is to write "yyterminate();" -
682  * we don't want an extra ';' after the "return" because that will cause
683  * some compilers to complain about unreachable statements.
684  */
685 #ifndef yyterminate
686 #define yyterminate() return YY_NULL
687 #endif
688 
689 /* Number of entries by which start-condition stack grows. */
690 #ifndef YY_START_STACK_INCR
691 #define YY_START_STACK_INCR 25
692 #endif
693 
694 /* Report a fatal error. */
695 #ifndef YY_FATAL_ERROR
696 #define YY_FATAL_ERROR(msg) yy_fatal_error( msg )
697 #endif
698 
699 /* end tables serialization structures and prototypes */
700 
701 /* Default declaration of generated scanner - a define so the user can
702  * easily add parameters.
703  */
704 #ifndef YY_DECL
705 #define YY_DECL_IS_OURS 1
706 
707 extern int __ktrfmtlex \
708                (YYSTYPE * yylval_param );
709 
710 #define YY_DECL int __ktrfmtlex \
711                (YYSTYPE * yylval_param )
712 #endif /* !YY_DECL */
713 
714 /* Code executed at the beginning of each rule, after __ktrfmttext and __ktrfmtleng
715  * have been set up.
716  */
717 #ifndef YY_USER_ACTION
718 #define YY_USER_ACTION
719 #endif
720 
721 /* Code executed at the end of each rule. */
722 #ifndef YY_BREAK
723 #define YY_BREAK break;
724 #endif
725 
726 #define YY_RULE_SETUP \
727 	YY_USER_ACTION
728 
729 /** The main scanner function which does all the work.
730  */
731 YY_DECL
732 {
733 	register yy_state_type yy_current_state;
734 	register char *yy_cp, *yy_bp;
735 	register int yy_act;
736 
737         YYSTYPE * yylval;
738 
739 #line 73 "ktrfmt.l"
740 
741 #line 742 "ktrfmt.yy.c"
742 
743     yylval = yylval_param;
744 
745 	if ( !(yy_init) )
746 		{
747 		(yy_init) = 1;
748 
749 #ifdef YY_USER_INIT
750 		YY_USER_INIT;
751 #endif
752 
753 		if ( ! (yy_start) )
754 			(yy_start) = 1;	/* first start state */
755 
756 		if ( ! __ktrfmtin )
757 			__ktrfmtin = stdin;
758 
759 		if ( ! __ktrfmtout )
760 			__ktrfmtout = stdout;
761 
762 		if ( ! YY_CURRENT_BUFFER ) {
763 			__ktrfmtensure_buffer_stack ();
764 			YY_CURRENT_BUFFER_LVALUE =
765 				__ktrfmt_create_buffer(__ktrfmtin,YY_BUF_SIZE );
766 		}
767 
768 		__ktrfmt_load_buffer_state( );
769 		}
770 
771 	while ( 1 )		/* loops until end-of-file is reached */
772 		{
773 		yy_cp = (yy_c_buf_p);
774 
775 		/* Support of __ktrfmttext. */
776 		*yy_cp = (yy_hold_char);
777 
778 		/* yy_bp points to the position in yy_ch_buf of the start of
779 		 * the current run.
780 		 */
781 		yy_bp = yy_cp;
782 
783 		yy_current_state = (yy_start);
784 yy_match:
785 		do
786 			{
787 			register YY_CHAR yy_c = yy_ec[YY_SC_TO_UI(*yy_cp)];
788 			if ( yy_accept[yy_current_state] )
789 				{
790 				(yy_last_accepting_state) = yy_current_state;
791 				(yy_last_accepting_cpos) = yy_cp;
792 				}
793 			while ( yy_chk[yy_base[yy_current_state] + yy_c] != yy_current_state )
794 				{
795 				yy_current_state = (int) yy_def[yy_current_state];
796 				if ( yy_current_state >= 26 )
797 					yy_c = yy_meta[(unsigned int) yy_c];
798 				}
799 			yy_current_state = yy_nxt[yy_base[yy_current_state] + (unsigned int) yy_c];
800 			++yy_cp;
801 			}
802 		while ( yy_base[yy_current_state] != 54 );
803 
804 yy_find_action:
805 		yy_act = yy_accept[yy_current_state];
806 		if ( yy_act == 0 )
807 			{ /* have to back up */
808 			yy_cp = (yy_last_accepting_cpos);
809 			yy_current_state = (yy_last_accepting_state);
810 			yy_act = yy_accept[yy_current_state];
811 			}
812 
813 		YY_DO_BEFORE_ACTION;
814 
815 do_action:	/* This label is used only to access EOF actions. */
816 
817 		switch ( yy_act )
818 	{ /* beginning of action switch */
819 			case 0: /* must back up */
820 			/* undo the effects of YY_DO_BEFORE_ACTION */
821 			*yy_cp = (yy_hold_char);
822 			yy_cp = (yy_last_accepting_cpos);
823 			yy_current_state = (yy_last_accepting_state);
824 			goto yy_find_action;
825 
826 case 1:
827 YY_RULE_SETUP
828 #line 74 "ktrfmt.l"
829 { /* ignore */ }
830 	YY_BREAK
831 case 2:
832 YY_RULE_SETUP
833 #line 75 "ktrfmt.l"
834 {
835 	size_t len;
836 	yylval->tok = tok_new();
837 	yylval->tok->type = TOK_STR;
838 	len = strlen(__ktrfmttext);
839 	assert(__ktrfmttext[len - 1] == '"');
840 	__ktrfmttext[len - 1] = '\0';	/* kill trailing quote */
841 	printd(LEX, "newstr(\"%s\")\n", __ktrfmttext + 1);
842 	yylval->tok->str = newstr(__ktrfmttext + 1);	/* parser detects oom */
843 	__ktrfmttext[len - 1] = '"';	/* restore quote */
844 	printd(LEX, "TOK_STR: \"%s\"\n", yylval->tok->str);
845 	return TOK_STR;
846 	}
847 	YY_BREAK
848 case 3:
849 YY_RULE_SETUP
850 #line 88 "ktrfmt.l"
851 {
852 	yylval->tok = tok_new();
853 	yylval->tok->type = TOK_ID;
854 	printd(LEX, "tok %p TOK_ID %p:%s\n", yylval->tok, __ktrfmttext, __ktrfmttext);
855 	yylval->tok->str = newstr(__ktrfmttext);	/* parser detects oom */
856 	return TOK_ID;
857 	}
858 	YY_BREAK
859 case 4:
860 YY_RULE_SETUP
861 #line 95 "ktrfmt.l"
862 {
863 	yylval->tok = tok_new();
864 	yylval->tok->type = TOK_CTOR;
865 	printd(LEX, "tok %p TOK_CTOR %p:%s\n", yylval->tok, __ktrfmttext, __ktrfmttext);
866 	yylval->tok->str = newstr(__ktrfmttext);	/* parser detects oom */
867 	return TOK_CTOR;
868 	}
869 	YY_BREAK
870 case 5:
871 YY_RULE_SETUP
872 #line 102 "ktrfmt.l"
873 {
874 	yylval->tok = tok_new();
875 	yylval->tok->type = TOK_INT;
876 	yylval->tok->str = strdup(__ktrfmttext);	/* parser detects oom */
877 	printd(LEX, "TOK_INT\n");
878 	return TOK_INT;
879 	}
880 	YY_BREAK
881 case 6:
882 YY_RULE_SETUP
883 #line 109 "ktrfmt.l"
884 {
885 	yylval->tok = tok_new();
886 	yylval->tok->type = TOK_INT;
887 	yylval->tok->str = strdup(__ktrfmttext);	/* parser detects oom */
888 	printd(LEX, "TOK_INT\n");
889 	return TOK_INT;
890 	}
891 	YY_BREAK
892 case 7:
893 YY_RULE_SETUP
894 #line 116 "ktrfmt.l"
895 {
896 	yylval = NULL;
897 	printd(LEX, "TOK_EQ\n");
898 	return TOK_EQ;
899 	}
900 	YY_BREAK
901 case 8:
902 YY_RULE_SETUP
903 #line 121 "ktrfmt.l"
904 {
905 	yylval = NULL;
906 	printd(LEX, "TOK_DOT\n");
907 	return TOK_DOT;
908 	}
909 	YY_BREAK
910 case 9:
911 YY_RULE_SETUP
912 #line 126 "ktrfmt.l"
913 {
914 	yylval = NULL;
915 	printd(LEX, "TOK_LEFT_BRACK\n");
916 	return TOK_LEFT_BRACK;
917 	}
918 	YY_BREAK
919 case 10:
920 YY_RULE_SETUP
921 #line 131 "ktrfmt.l"
922 {
923 	yylval = NULL;
924 	printd(LEX, "TOK_RIGHT_BRACK\n");
925 	return TOK_RIGHT_BRACK;
926 	}
927 	YY_BREAK
928 case 11:
929 YY_RULE_SETUP
930 #line 137 "ktrfmt.l"
931 ECHO;
932 	YY_BREAK
933 #line 934 "ktrfmt.yy.c"
934 case YY_STATE_EOF(INITIAL):
935 	yyterminate();
936 
937 	case YY_END_OF_BUFFER:
938 		{
939 		/* Amount of text matched not including the EOB char. */
940 		int yy_amount_of_matched_text = (int) (yy_cp - (yytext_ptr)) - 1;
941 
942 		/* Undo the effects of YY_DO_BEFORE_ACTION. */
943 		*yy_cp = (yy_hold_char);
944 		YY_RESTORE_YY_MORE_OFFSET
945 
946 		if ( YY_CURRENT_BUFFER_LVALUE->yy_buffer_status == YY_BUFFER_NEW )
947 			{
948 			/* We're scanning a new file or input source.  It's
949 			 * possible that this happened because the user
950 			 * just pointed __ktrfmtin at a new source and called
951 			 * __ktrfmtlex().  If so, then we have to assure
952 			 * consistency between YY_CURRENT_BUFFER and our
953 			 * globals.  Here is the right place to do so, because
954 			 * this is the first action (other than possibly a
955 			 * back-up) that will match for the new input source.
956 			 */
957 			(yy_n_chars) = YY_CURRENT_BUFFER_LVALUE->yy_n_chars;
958 			YY_CURRENT_BUFFER_LVALUE->yy_input_file = __ktrfmtin;
959 			YY_CURRENT_BUFFER_LVALUE->yy_buffer_status = YY_BUFFER_NORMAL;
960 			}
961 
962 		/* Note that here we test for yy_c_buf_p "<=" to the position
963 		 * of the first EOB in the buffer, since yy_c_buf_p will
964 		 * already have been incremented past the NUL character
965 		 * (since all states make transitions on EOB to the
966 		 * end-of-buffer state).  Contrast this with the test
967 		 * in input().
968 		 */
969 		if ( (yy_c_buf_p) <= &YY_CURRENT_BUFFER_LVALUE->yy_ch_buf[(yy_n_chars)] )
970 			{ /* This was really a NUL. */
971 			yy_state_type yy_next_state;
972 
973 			(yy_c_buf_p) = (yytext_ptr) + yy_amount_of_matched_text;
974 
975 			yy_current_state = yy_get_previous_state(  );
976 
977 			/* Okay, we're now positioned to make the NUL
978 			 * transition.  We couldn't have
979 			 * yy_get_previous_state() go ahead and do it
980 			 * for us because it doesn't know how to deal
981 			 * with the possibility of jamming (and we don't
982 			 * want to build jamming into it because then it
983 			 * will run more slowly).
984 			 */
985 
986 			yy_next_state = yy_try_NUL_trans( yy_current_state );
987 
988 			yy_bp = (yytext_ptr) + YY_MORE_ADJ;
989 
990 			if ( yy_next_state )
991 				{
992 				/* Consume the NUL. */
993 				yy_cp = ++(yy_c_buf_p);
994 				yy_current_state = yy_next_state;
995 				goto yy_match;
996 				}
997 
998 			else
999 				{
1000 				yy_cp = (yy_c_buf_p);
1001 				goto yy_find_action;
1002 				}
1003 			}
1004 
1005 		else switch ( yy_get_next_buffer(  ) )
1006 			{
1007 			case EOB_ACT_END_OF_FILE:
1008 				{
1009 				(yy_did_buffer_switch_on_eof) = 0;
1010 
1011 				if ( __ktrfmtwrap( ) )
1012 					{
1013 					/* Note: because we've taken care in
1014 					 * yy_get_next_buffer() to have set up
1015 					 * __ktrfmttext, we can now set up
1016 					 * yy_c_buf_p so that if some total
1017 					 * hoser (like flex itself) wants to
1018 					 * call the scanner after we return the
1019 					 * YY_NULL, it'll still work - another
1020 					 * YY_NULL will get returned.
1021 					 */
1022 					(yy_c_buf_p) = (yytext_ptr) + YY_MORE_ADJ;
1023 
1024 					yy_act = YY_STATE_EOF(YY_START);
1025 					goto do_action;
1026 					}
1027 
1028 				else
1029 					{
1030 					if ( ! (yy_did_buffer_switch_on_eof) )
1031 						YY_NEW_FILE;
1032 					}
1033 				break;
1034 				}
1035 
1036 			case EOB_ACT_CONTINUE_SCAN:
1037 				(yy_c_buf_p) =
1038 					(yytext_ptr) + yy_amount_of_matched_text;
1039 
1040 				yy_current_state = yy_get_previous_state(  );
1041 
1042 				yy_cp = (yy_c_buf_p);
1043 				yy_bp = (yytext_ptr) + YY_MORE_ADJ;
1044 				goto yy_match;
1045 
1046 			case EOB_ACT_LAST_MATCH:
1047 				(yy_c_buf_p) =
1048 				&YY_CURRENT_BUFFER_LVALUE->yy_ch_buf[(yy_n_chars)];
1049 
1050 				yy_current_state = yy_get_previous_state(  );
1051 
1052 				yy_cp = (yy_c_buf_p);
1053 				yy_bp = (yytext_ptr) + YY_MORE_ADJ;
1054 				goto yy_find_action;
1055 			}
1056 		break;
1057 		}
1058 
1059 	default:
1060 		YY_FATAL_ERROR(
1061 			"fatal flex scanner internal error--no action found" );
1062 	} /* end of action switch */
1063 		} /* end of scanning one token */
1064 } /* end of __ktrfmtlex */
1065 
1066 /* yy_get_next_buffer - try to read in a new buffer
1067  *
1068  * Returns a code representing an action:
1069  *	EOB_ACT_LAST_MATCH -
1070  *	EOB_ACT_CONTINUE_SCAN - continue scanning from current position
1071  *	EOB_ACT_END_OF_FILE - end of file
1072  */
yy_get_next_buffer(void)1073 static int yy_get_next_buffer (void)
1074 {
1075     	register char *dest = YY_CURRENT_BUFFER_LVALUE->yy_ch_buf;
1076 	register char *source = (yytext_ptr);
1077 	register int number_to_move, i;
1078 	int ret_val;
1079 
1080 	if ( (yy_c_buf_p) > &YY_CURRENT_BUFFER_LVALUE->yy_ch_buf[(yy_n_chars) + 1] )
1081 		YY_FATAL_ERROR(
1082 		"fatal flex scanner internal error--end of buffer missed" );
1083 
1084 	if ( YY_CURRENT_BUFFER_LVALUE->yy_fill_buffer == 0 )
1085 		{ /* Don't try to fill the buffer, so this is an EOF. */
1086 		if ( (yy_c_buf_p) - (yytext_ptr) - YY_MORE_ADJ == 1 )
1087 			{
1088 			/* We matched a single character, the EOB, so
1089 			 * treat this as a final EOF.
1090 			 */
1091 			return EOB_ACT_END_OF_FILE;
1092 			}
1093 
1094 		else
1095 			{
1096 			/* We matched some text prior to the EOB, first
1097 			 * process it.
1098 			 */
1099 			return EOB_ACT_LAST_MATCH;
1100 			}
1101 		}
1102 
1103 	/* Try to read more data. */
1104 
1105 	/* First move last chars to start of buffer. */
1106 	number_to_move = (int) ((yy_c_buf_p) - (yytext_ptr)) - 1;
1107 
1108 	for ( i = 0; i < number_to_move; ++i )
1109 		*(dest++) = *(source++);
1110 
1111 	if ( YY_CURRENT_BUFFER_LVALUE->yy_buffer_status == YY_BUFFER_EOF_PENDING )
1112 		/* don't do the read, it's not guaranteed to return an EOF,
1113 		 * just force an EOF
1114 		 */
1115 		YY_CURRENT_BUFFER_LVALUE->yy_n_chars = (yy_n_chars) = 0;
1116 
1117 	else
1118 		{
1119 			yy_size_t num_to_read =
1120 			YY_CURRENT_BUFFER_LVALUE->yy_buf_size - number_to_move - 1;
1121 
1122 		while ( num_to_read <= 0 )
1123 			{ /* Not enough room in the buffer - grow it. */
1124 
1125 			/* just a shorter name for the current buffer */
1126 			YY_BUFFER_STATE b = YY_CURRENT_BUFFER_LVALUE;
1127 
1128 			int yy_c_buf_p_offset =
1129 				(int) ((yy_c_buf_p) - b->yy_ch_buf);
1130 
1131 			if ( b->yy_is_our_buffer )
1132 				{
1133 				yy_size_t new_size = b->yy_buf_size * 2;
1134 
1135 				if ( new_size <= 0 )
1136 					b->yy_buf_size += b->yy_buf_size / 8;
1137 				else
1138 					b->yy_buf_size *= 2;
1139 
1140 				b->yy_ch_buf = (char *)
1141 					/* Include room in for 2 EOB chars. */
1142 					__ktrfmtrealloc((void *) b->yy_ch_buf,b->yy_buf_size + 2  );
1143 				}
1144 			else
1145 				/* Can't grow it, we don't own it. */
1146 				b->yy_ch_buf = 0;
1147 
1148 			if ( ! b->yy_ch_buf )
1149 				YY_FATAL_ERROR(
1150 				"fatal error - scanner input buffer overflow" );
1151 
1152 			(yy_c_buf_p) = &b->yy_ch_buf[yy_c_buf_p_offset];
1153 
1154 			num_to_read = YY_CURRENT_BUFFER_LVALUE->yy_buf_size -
1155 						number_to_move - 1;
1156 
1157 			}
1158 
1159 		if ( num_to_read > YY_READ_BUF_SIZE )
1160 			num_to_read = YY_READ_BUF_SIZE;
1161 
1162 		/* Read in more data. */
1163 		YY_INPUT( (&YY_CURRENT_BUFFER_LVALUE->yy_ch_buf[number_to_move]),
1164 			(yy_n_chars), num_to_read );
1165 
1166 		YY_CURRENT_BUFFER_LVALUE->yy_n_chars = (yy_n_chars);
1167 		}
1168 
1169 	if ( (yy_n_chars) == 0 )
1170 		{
1171 		if ( number_to_move == YY_MORE_ADJ )
1172 			{
1173 			ret_val = EOB_ACT_END_OF_FILE;
1174 			__ktrfmtrestart(__ktrfmtin  );
1175 			}
1176 
1177 		else
1178 			{
1179 			ret_val = EOB_ACT_LAST_MATCH;
1180 			YY_CURRENT_BUFFER_LVALUE->yy_buffer_status =
1181 				YY_BUFFER_EOF_PENDING;
1182 			}
1183 		}
1184 
1185 	else
1186 		ret_val = EOB_ACT_CONTINUE_SCAN;
1187 
1188 	if ((yy_size_t) ((yy_n_chars) + number_to_move) > YY_CURRENT_BUFFER_LVALUE->yy_buf_size) {
1189 		/* Extend the array by 50%, plus the number we really need. */
1190 		yy_size_t new_size = (yy_n_chars) + number_to_move + ((yy_n_chars) >> 1);
1191 		YY_CURRENT_BUFFER_LVALUE->yy_ch_buf = (char *) __ktrfmtrealloc((void *) YY_CURRENT_BUFFER_LVALUE->yy_ch_buf,new_size  );
1192 		if ( ! YY_CURRENT_BUFFER_LVALUE->yy_ch_buf )
1193 			YY_FATAL_ERROR( "out of dynamic memory in yy_get_next_buffer()" );
1194 	}
1195 
1196 	(yy_n_chars) += number_to_move;
1197 	YY_CURRENT_BUFFER_LVALUE->yy_ch_buf[(yy_n_chars)] = YY_END_OF_BUFFER_CHAR;
1198 	YY_CURRENT_BUFFER_LVALUE->yy_ch_buf[(yy_n_chars) + 1] = YY_END_OF_BUFFER_CHAR;
1199 
1200 	(yytext_ptr) = &YY_CURRENT_BUFFER_LVALUE->yy_ch_buf[0];
1201 
1202 	return ret_val;
1203 }
1204 
1205 /* yy_get_previous_state - get the state just before the EOB char was reached */
1206 
yy_get_previous_state(void)1207     static yy_state_type yy_get_previous_state (void)
1208 {
1209 	register yy_state_type yy_current_state;
1210 	register char *yy_cp;
1211 
1212 	yy_current_state = (yy_start);
1213 
1214 	for ( yy_cp = (yytext_ptr) + YY_MORE_ADJ; yy_cp < (yy_c_buf_p); ++yy_cp )
1215 		{
1216 		register YY_CHAR yy_c = (*yy_cp ? yy_ec[YY_SC_TO_UI(*yy_cp)] : 1);
1217 		if ( yy_accept[yy_current_state] )
1218 			{
1219 			(yy_last_accepting_state) = yy_current_state;
1220 			(yy_last_accepting_cpos) = yy_cp;
1221 			}
1222 		while ( yy_chk[yy_base[yy_current_state] + yy_c] != yy_current_state )
1223 			{
1224 			yy_current_state = (int) yy_def[yy_current_state];
1225 			if ( yy_current_state >= 26 )
1226 				yy_c = yy_meta[(unsigned int) yy_c];
1227 			}
1228 		yy_current_state = yy_nxt[yy_base[yy_current_state] + (unsigned int) yy_c];
1229 		}
1230 
1231 	return yy_current_state;
1232 }
1233 
1234 /* yy_try_NUL_trans - try to make a transition on the NUL character
1235  *
1236  * synopsis
1237  *	next_state = yy_try_NUL_trans( current_state );
1238  */
yy_try_NUL_trans(yy_state_type yy_current_state)1239     static yy_state_type yy_try_NUL_trans  (yy_state_type yy_current_state )
1240 {
1241 	register int yy_is_jam;
1242     	register char *yy_cp = (yy_c_buf_p);
1243 
1244 	register YY_CHAR yy_c = 1;
1245 	if ( yy_accept[yy_current_state] )
1246 		{
1247 		(yy_last_accepting_state) = yy_current_state;
1248 		(yy_last_accepting_cpos) = yy_cp;
1249 		}
1250 	while ( yy_chk[yy_base[yy_current_state] + yy_c] != yy_current_state )
1251 		{
1252 		yy_current_state = (int) yy_def[yy_current_state];
1253 		if ( yy_current_state >= 26 )
1254 			yy_c = yy_meta[(unsigned int) yy_c];
1255 		}
1256 	yy_current_state = yy_nxt[yy_base[yy_current_state] + (unsigned int) yy_c];
1257 	yy_is_jam = (yy_current_state == 25);
1258 
1259 		return yy_is_jam ? 0 : yy_current_state;
1260 }
1261 
1262 #ifndef YY_NO_INPUT
1263 #ifdef __cplusplus
yyinput(void)1264     static int yyinput (void)
1265 #else
1266     static int input  (void)
1267 #endif
1268 
1269 {
1270 	int c;
1271 
1272 	*(yy_c_buf_p) = (yy_hold_char);
1273 
1274 	if ( *(yy_c_buf_p) == YY_END_OF_BUFFER_CHAR )
1275 		{
1276 		/* yy_c_buf_p now points to the character we want to return.
1277 		 * If this occurs *before* the EOB characters, then it's a
1278 		 * valid NUL; if not, then we've hit the end of the buffer.
1279 		 */
1280 		if ( (yy_c_buf_p) < &YY_CURRENT_BUFFER_LVALUE->yy_ch_buf[(yy_n_chars)] )
1281 			/* This was really a NUL. */
1282 			*(yy_c_buf_p) = '\0';
1283 
1284 		else
1285 			{ /* need more input */
1286 			yy_size_t offset = (yy_c_buf_p) - (yytext_ptr);
1287 			++(yy_c_buf_p);
1288 
1289 			switch ( yy_get_next_buffer(  ) )
1290 				{
1291 				case EOB_ACT_LAST_MATCH:
1292 					/* This happens because yy_g_n_b()
1293 					 * sees that we've accumulated a
1294 					 * token and flags that we need to
1295 					 * try matching the token before
1296 					 * proceeding.  But for input(),
1297 					 * there's no matching to consider.
1298 					 * So convert the EOB_ACT_LAST_MATCH
1299 					 * to EOB_ACT_END_OF_FILE.
1300 					 */
1301 
1302 					/* Reset buffer status. */
1303 					__ktrfmtrestart(__ktrfmtin );
1304 
1305 					/*FALLTHROUGH*/
1306 
1307 				case EOB_ACT_END_OF_FILE:
1308 					{
1309 					if ( __ktrfmtwrap( ) )
1310 						return EOF;
1311 
1312 					if ( ! (yy_did_buffer_switch_on_eof) )
1313 						YY_NEW_FILE;
1314 #ifdef __cplusplus
1315 					return yyinput();
1316 #else
1317 					return input();
1318 #endif
1319 					}
1320 
1321 				case EOB_ACT_CONTINUE_SCAN:
1322 					(yy_c_buf_p) = (yytext_ptr) + offset;
1323 					break;
1324 				}
1325 			}
1326 		}
1327 
1328 	c = *(unsigned char *) (yy_c_buf_p);	/* cast for 8-bit char's */
1329 	*(yy_c_buf_p) = '\0';	/* preserve __ktrfmttext */
1330 	(yy_hold_char) = *++(yy_c_buf_p);
1331 
1332 	return c;
1333 }
1334 #endif	/* ifndef YY_NO_INPUT */
1335 
1336 /** Immediately switch to a different input stream.
1337  * @param input_file A readable stream.
1338  *
1339  * @note This function does not reset the start condition to @c INITIAL .
1340  */
__ktrfmtrestart(FILE * input_file)1341     void __ktrfmtrestart  (FILE * input_file )
1342 {
1343 
1344 	if ( ! YY_CURRENT_BUFFER ){
1345         __ktrfmtensure_buffer_stack ();
1346 		YY_CURRENT_BUFFER_LVALUE =
1347             __ktrfmt_create_buffer(__ktrfmtin,YY_BUF_SIZE );
1348 	}
1349 
1350 	__ktrfmt_init_buffer(YY_CURRENT_BUFFER,input_file );
1351 	__ktrfmt_load_buffer_state( );
1352 }
1353 
1354 /** Switch to a different input buffer.
1355  * @param new_buffer The new input buffer.
1356  *
1357  */
__ktrfmt_switch_to_buffer(YY_BUFFER_STATE new_buffer)1358     void __ktrfmt_switch_to_buffer  (YY_BUFFER_STATE  new_buffer )
1359 {
1360 
1361 	/* TODO. We should be able to replace this entire function body
1362 	 * with
1363 	 *		__ktrfmtpop_buffer_state();
1364 	 *		__ktrfmtpush_buffer_state(new_buffer);
1365      */
1366 	__ktrfmtensure_buffer_stack ();
1367 	if ( YY_CURRENT_BUFFER == new_buffer )
1368 		return;
1369 
1370 	if ( YY_CURRENT_BUFFER )
1371 		{
1372 		/* Flush out information for old buffer. */
1373 		*(yy_c_buf_p) = (yy_hold_char);
1374 		YY_CURRENT_BUFFER_LVALUE->yy_buf_pos = (yy_c_buf_p);
1375 		YY_CURRENT_BUFFER_LVALUE->yy_n_chars = (yy_n_chars);
1376 		}
1377 
1378 	YY_CURRENT_BUFFER_LVALUE = new_buffer;
1379 	__ktrfmt_load_buffer_state( );
1380 
1381 	/* We don't actually know whether we did this switch during
1382 	 * EOF (__ktrfmtwrap()) processing, but the only time this flag
1383 	 * is looked at is after __ktrfmtwrap() is called, so it's safe
1384 	 * to go ahead and always set it.
1385 	 */
1386 	(yy_did_buffer_switch_on_eof) = 1;
1387 }
1388 
__ktrfmt_load_buffer_state(void)1389 static void __ktrfmt_load_buffer_state  (void)
1390 {
1391     	(yy_n_chars) = YY_CURRENT_BUFFER_LVALUE->yy_n_chars;
1392 	(yytext_ptr) = (yy_c_buf_p) = YY_CURRENT_BUFFER_LVALUE->yy_buf_pos;
1393 	__ktrfmtin = YY_CURRENT_BUFFER_LVALUE->yy_input_file;
1394 	(yy_hold_char) = *(yy_c_buf_p);
1395 }
1396 
1397 /** Allocate and initialize an input buffer state.
1398  * @param file A readable stream.
1399  * @param size The character buffer size in bytes. When in doubt, use @c YY_BUF_SIZE.
1400  *
1401  * @return the allocated buffer state.
1402  */
__ktrfmt_create_buffer(FILE * file,int size)1403     YY_BUFFER_STATE __ktrfmt_create_buffer  (FILE * file, int  size )
1404 {
1405 	YY_BUFFER_STATE b;
1406 
1407 	b = (YY_BUFFER_STATE) __ktrfmtalloc(sizeof( struct yy_buffer_state )  );
1408 	if ( ! b )
1409 		YY_FATAL_ERROR( "out of dynamic memory in __ktrfmt_create_buffer()" );
1410 
1411 	b->yy_buf_size = size;
1412 
1413 	/* yy_ch_buf has to be 2 characters longer than the size given because
1414 	 * we need to put in 2 end-of-buffer characters.
1415 	 */
1416 	b->yy_ch_buf = (char *) __ktrfmtalloc(b->yy_buf_size + 2  );
1417 	if ( ! b->yy_ch_buf )
1418 		YY_FATAL_ERROR( "out of dynamic memory in __ktrfmt_create_buffer()" );
1419 
1420 	b->yy_is_our_buffer = 1;
1421 
1422 	__ktrfmt_init_buffer(b,file );
1423 
1424 	return b;
1425 }
1426 
1427 /** Destroy the buffer.
1428  * @param b a buffer created with __ktrfmt_create_buffer()
1429  *
1430  */
__ktrfmt_delete_buffer(YY_BUFFER_STATE b)1431     void __ktrfmt_delete_buffer (YY_BUFFER_STATE  b )
1432 {
1433 
1434 	if ( ! b )
1435 		return;
1436 
1437 	if ( b == YY_CURRENT_BUFFER ) /* Not sure if we should pop here. */
1438 		YY_CURRENT_BUFFER_LVALUE = (YY_BUFFER_STATE) 0;
1439 
1440 	if ( b->yy_is_our_buffer )
1441 		__ktrfmtfree((void *) b->yy_ch_buf  );
1442 
1443 	__ktrfmtfree((void *) b  );
1444 }
1445 
1446 /* Initializes or reinitializes a buffer.
1447  * This function is sometimes called more than once on the same buffer,
1448  * such as during a __ktrfmtrestart() or at EOF.
1449  */
__ktrfmt_init_buffer(YY_BUFFER_STATE b,FILE * file)1450     static void __ktrfmt_init_buffer  (YY_BUFFER_STATE  b, FILE * file )
1451 
1452 {
1453 	int oerrno = errno;
1454 
1455 	__ktrfmt_flush_buffer(b );
1456 
1457 	b->yy_input_file = file;
1458 	b->yy_fill_buffer = 1;
1459 
1460     /* If b is the current buffer, then __ktrfmt_init_buffer was _probably_
1461      * called from __ktrfmtrestart() or through yy_get_next_buffer.
1462      * In that case, we don't want to reset the lineno or column.
1463      */
1464     if (b != YY_CURRENT_BUFFER){
1465         b->yy_bs_lineno = 1;
1466         b->yy_bs_column = 0;
1467     }
1468 
1469         b->yy_is_interactive = file ? (isatty( fileno(file) ) > 0) : 0;
1470 
1471 	errno = oerrno;
1472 }
1473 
1474 /** Discard all buffered characters. On the next scan, YY_INPUT will be called.
1475  * @param b the buffer state to be flushed, usually @c YY_CURRENT_BUFFER.
1476  *
1477  */
__ktrfmt_flush_buffer(YY_BUFFER_STATE b)1478     void __ktrfmt_flush_buffer (YY_BUFFER_STATE  b )
1479 {
1480     	if ( ! b )
1481 		return;
1482 
1483 	b->yy_n_chars = 0;
1484 
1485 	/* We always need two end-of-buffer characters.  The first causes
1486 	 * a transition to the end-of-buffer state.  The second causes
1487 	 * a jam in that state.
1488 	 */
1489 	b->yy_ch_buf[0] = YY_END_OF_BUFFER_CHAR;
1490 	b->yy_ch_buf[1] = YY_END_OF_BUFFER_CHAR;
1491 
1492 	b->yy_buf_pos = &b->yy_ch_buf[0];
1493 
1494 	b->yy_at_bol = 1;
1495 	b->yy_buffer_status = YY_BUFFER_NEW;
1496 
1497 	if ( b == YY_CURRENT_BUFFER )
1498 		__ktrfmt_load_buffer_state( );
1499 }
1500 
1501 /** Pushes the new state onto the stack. The new state becomes
1502  *  the current state. This function will allocate the stack
1503  *  if necessary.
1504  *  @param new_buffer The new state.
1505  *
1506  */
__ktrfmtpush_buffer_state(YY_BUFFER_STATE new_buffer)1507 void __ktrfmtpush_buffer_state (YY_BUFFER_STATE new_buffer )
1508 {
1509     	if (new_buffer == NULL)
1510 		return;
1511 
1512 	__ktrfmtensure_buffer_stack();
1513 
1514 	/* This block is copied from __ktrfmt_switch_to_buffer. */
1515 	if ( YY_CURRENT_BUFFER )
1516 		{
1517 		/* Flush out information for old buffer. */
1518 		*(yy_c_buf_p) = (yy_hold_char);
1519 		YY_CURRENT_BUFFER_LVALUE->yy_buf_pos = (yy_c_buf_p);
1520 		YY_CURRENT_BUFFER_LVALUE->yy_n_chars = (yy_n_chars);
1521 		}
1522 
1523 	/* Only push if top exists. Otherwise, replace top. */
1524 	if (YY_CURRENT_BUFFER)
1525 		(yy_buffer_stack_top)++;
1526 	YY_CURRENT_BUFFER_LVALUE = new_buffer;
1527 
1528 	/* copied from __ktrfmt_switch_to_buffer. */
1529 	__ktrfmt_load_buffer_state( );
1530 	(yy_did_buffer_switch_on_eof) = 1;
1531 }
1532 
1533 /** Removes and deletes the top of the stack, if present.
1534  *  The next element becomes the new top.
1535  *
1536  */
__ktrfmtpop_buffer_state(void)1537 void __ktrfmtpop_buffer_state (void)
1538 {
1539     	if (!YY_CURRENT_BUFFER)
1540 		return;
1541 
1542 	__ktrfmt_delete_buffer(YY_CURRENT_BUFFER );
1543 	YY_CURRENT_BUFFER_LVALUE = NULL;
1544 	if ((yy_buffer_stack_top) > 0)
1545 		--(yy_buffer_stack_top);
1546 
1547 	if (YY_CURRENT_BUFFER) {
1548 		__ktrfmt_load_buffer_state( );
1549 		(yy_did_buffer_switch_on_eof) = 1;
1550 	}
1551 }
1552 
1553 /* Allocates the stack if it does not exist.
1554  *  Guarantees space for at least one push.
1555  */
__ktrfmtensure_buffer_stack(void)1556 static void __ktrfmtensure_buffer_stack (void)
1557 {
1558 	yy_size_t num_to_alloc;
1559 
1560 	if (!(yy_buffer_stack)) {
1561 
1562 		/* First allocation is just for 2 elements, since we don't know if this
1563 		 * scanner will even need a stack. We use 2 instead of 1 to avoid an
1564 		 * immediate realloc on the next call.
1565          */
1566 		num_to_alloc = 1;
1567 		(yy_buffer_stack) = (struct yy_buffer_state**)__ktrfmtalloc
1568 								(num_to_alloc * sizeof(struct yy_buffer_state*)
1569 								);
1570 		if ( ! (yy_buffer_stack) )
1571 			YY_FATAL_ERROR( "out of dynamic memory in __ktrfmtensure_buffer_stack()" );
1572 
1573 		memset((yy_buffer_stack), 0, num_to_alloc * sizeof(struct yy_buffer_state*));
1574 
1575 		(yy_buffer_stack_max) = num_to_alloc;
1576 		(yy_buffer_stack_top) = 0;
1577 		return;
1578 	}
1579 
1580 	if ((yy_buffer_stack_top) >= ((yy_buffer_stack_max)) - 1){
1581 
1582 		/* Increase the buffer to prepare for a possible push. */
1583 		int grow_size = 8 /* arbitrary grow size */;
1584 
1585 		num_to_alloc = (yy_buffer_stack_max) + grow_size;
1586 		(yy_buffer_stack) = (struct yy_buffer_state**)__ktrfmtrealloc
1587 								((yy_buffer_stack),
1588 								num_to_alloc * sizeof(struct yy_buffer_state*)
1589 								);
1590 		if ( ! (yy_buffer_stack) )
1591 			YY_FATAL_ERROR( "out of dynamic memory in __ktrfmtensure_buffer_stack()" );
1592 
1593 		/* zero only the new slots.*/
1594 		memset((yy_buffer_stack) + (yy_buffer_stack_max), 0, grow_size * sizeof(struct yy_buffer_state*));
1595 		(yy_buffer_stack_max) = num_to_alloc;
1596 	}
1597 }
1598 
1599 /** Setup the input buffer state to scan directly from a user-specified character buffer.
1600  * @param base the character buffer
1601  * @param size the size in bytes of the character buffer
1602  *
1603  * @return the newly allocated buffer state object.
1604  */
__ktrfmt_scan_buffer(char * base,yy_size_t size)1605 YY_BUFFER_STATE __ktrfmt_scan_buffer  (char * base, yy_size_t  size )
1606 {
1607 	YY_BUFFER_STATE b;
1608 
1609 	if ( size < 2 ||
1610 	     base[size-2] != YY_END_OF_BUFFER_CHAR ||
1611 	     base[size-1] != YY_END_OF_BUFFER_CHAR )
1612 		/* They forgot to leave room for the EOB's. */
1613 		return 0;
1614 
1615 	b = (YY_BUFFER_STATE) __ktrfmtalloc(sizeof( struct yy_buffer_state )  );
1616 	if ( ! b )
1617 		YY_FATAL_ERROR( "out of dynamic memory in __ktrfmt_scan_buffer()" );
1618 
1619 	b->yy_buf_size = size - 2;	/* "- 2" to take care of EOB's */
1620 	b->yy_buf_pos = b->yy_ch_buf = base;
1621 	b->yy_is_our_buffer = 0;
1622 	b->yy_input_file = 0;
1623 	b->yy_n_chars = b->yy_buf_size;
1624 	b->yy_is_interactive = 0;
1625 	b->yy_at_bol = 1;
1626 	b->yy_fill_buffer = 0;
1627 	b->yy_buffer_status = YY_BUFFER_NEW;
1628 
1629 	__ktrfmt_switch_to_buffer(b  );
1630 
1631 	return b;
1632 }
1633 
1634 /** Setup the input buffer state to scan a string. The next call to __ktrfmtlex() will
1635  * scan from a @e copy of @a str.
1636  * @param yystr a NUL-terminated string to scan
1637  *
1638  * @return the newly allocated buffer state object.
1639  * @note If you want to scan bytes that may contain NUL values, then use
1640  *       __ktrfmt_scan_bytes() instead.
1641  */
__ktrfmt_scan_string(yyconst char * yystr)1642 YY_BUFFER_STATE __ktrfmt_scan_string (yyconst char * yystr )
1643 {
1644 
1645 	return __ktrfmt_scan_bytes(yystr,strlen(yystr) );
1646 }
1647 
1648 /** Setup the input buffer state to scan the given bytes. The next call to __ktrfmtlex() will
1649  * scan from a @e copy of @a bytes.
1650  * @param yybytes the byte buffer to scan
1651  * @param _yybytes_len the number of bytes in the buffer pointed to by @a bytes.
1652  *
1653  * @return the newly allocated buffer state object.
1654  */
__ktrfmt_scan_bytes(yyconst char * yybytes,yy_size_t _yybytes_len)1655 YY_BUFFER_STATE __ktrfmt_scan_bytes  (yyconst char * yybytes, yy_size_t  _yybytes_len )
1656 {
1657 	YY_BUFFER_STATE b;
1658 	char *buf;
1659 	yy_size_t n;
1660 	int i;
1661 
1662 	/* Get memory for full buffer, including space for trailing EOB's. */
1663 	n = _yybytes_len + 2;
1664 	buf = (char *) __ktrfmtalloc(n  );
1665 	if ( ! buf )
1666 		YY_FATAL_ERROR( "out of dynamic memory in __ktrfmt_scan_bytes()" );
1667 
1668 	for ( i = 0; i < _yybytes_len; ++i )
1669 		buf[i] = yybytes[i];
1670 
1671 	buf[_yybytes_len] = buf[_yybytes_len+1] = YY_END_OF_BUFFER_CHAR;
1672 
1673 	b = __ktrfmt_scan_buffer(buf,n );
1674 	if ( ! b )
1675 		YY_FATAL_ERROR( "bad buffer in __ktrfmt_scan_bytes()" );
1676 
1677 	/* It's okay to grow etc. this buffer, and we should throw it
1678 	 * away when we're done.
1679 	 */
1680 	b->yy_is_our_buffer = 1;
1681 
1682 	return b;
1683 }
1684 
1685 #ifndef YY_EXIT_FAILURE
1686 #define YY_EXIT_FAILURE 2
1687 #endif
1688 
yy_fatal_error(yyconst char * msg)1689 static void yy_fatal_error (yyconst char* msg )
1690 {
1691     	(void) fprintf( stderr, "%s\n", msg );
1692 	exit( YY_EXIT_FAILURE );
1693 }
1694 
1695 /* Redefine yyless() so it works in section 3 code. */
1696 
1697 #undef yyless
1698 #define yyless(n) \
1699 	do \
1700 		{ \
1701 		/* Undo effects of setting up __ktrfmttext. */ \
1702         int yyless_macro_arg = (n); \
1703         YY_LESS_LINENO(yyless_macro_arg);\
1704 		__ktrfmttext[__ktrfmtleng] = (yy_hold_char); \
1705 		(yy_c_buf_p) = __ktrfmttext + yyless_macro_arg; \
1706 		(yy_hold_char) = *(yy_c_buf_p); \
1707 		*(yy_c_buf_p) = '\0'; \
1708 		__ktrfmtleng = yyless_macro_arg; \
1709 		} \
1710 	while ( 0 )
1711 
1712 /* Accessor  methods (get/set functions) to struct members. */
1713 
1714 /** Get the current line number.
1715  *
1716  */
__ktrfmtget_lineno(void)1717 int __ktrfmtget_lineno  (void)
1718 {
1719 
1720     return __ktrfmtlineno;
1721 }
1722 
1723 /** Get the input stream.
1724  *
1725  */
__ktrfmtget_in(void)1726 FILE *__ktrfmtget_in  (void)
1727 {
1728         return __ktrfmtin;
1729 }
1730 
1731 /** Get the output stream.
1732  *
1733  */
__ktrfmtget_out(void)1734 FILE *__ktrfmtget_out  (void)
1735 {
1736         return __ktrfmtout;
1737 }
1738 
1739 /** Get the length of the current token.
1740  *
1741  */
__ktrfmtget_leng(void)1742 yy_size_t __ktrfmtget_leng  (void)
1743 {
1744         return __ktrfmtleng;
1745 }
1746 
1747 /** Get the current token.
1748  *
1749  */
1750 
__ktrfmtget_text(void)1751 char *__ktrfmtget_text  (void)
1752 {
1753         return __ktrfmttext;
1754 }
1755 
1756 /** Set the current line number.
1757  * @param line_number
1758  *
1759  */
__ktrfmtset_lineno(int line_number)1760 void __ktrfmtset_lineno (int  line_number )
1761 {
1762 
1763     __ktrfmtlineno = line_number;
1764 }
1765 
1766 /** Set the input stream. This does not discard the current
1767  * input buffer.
1768  * @param in_str A readable stream.
1769  *
1770  * @see __ktrfmt_switch_to_buffer
1771  */
__ktrfmtset_in(FILE * in_str)1772 void __ktrfmtset_in (FILE *  in_str )
1773 {
1774         __ktrfmtin = in_str ;
1775 }
1776 
__ktrfmtset_out(FILE * out_str)1777 void __ktrfmtset_out (FILE *  out_str )
1778 {
1779         __ktrfmtout = out_str ;
1780 }
1781 
__ktrfmtget_debug(void)1782 int __ktrfmtget_debug  (void)
1783 {
1784         return __ktrfmt_flex_debug;
1785 }
1786 
__ktrfmtset_debug(int bdebug)1787 void __ktrfmtset_debug (int  bdebug )
1788 {
1789         __ktrfmt_flex_debug = bdebug ;
1790 }
1791 
yy_init_globals(void)1792 static int yy_init_globals (void)
1793 {
1794         /* Initialization is the same as for the non-reentrant scanner.
1795      * This function is called from __ktrfmtlex_destroy(), so don't allocate here.
1796      */
1797 
1798     (yy_buffer_stack) = 0;
1799     (yy_buffer_stack_top) = 0;
1800     (yy_buffer_stack_max) = 0;
1801     (yy_c_buf_p) = (char *) 0;
1802     (yy_init) = 0;
1803     (yy_start) = 0;
1804 
1805 /* Defined in main.c */
1806 #ifdef YY_STDINIT
1807     __ktrfmtin = stdin;
1808     __ktrfmtout = stdout;
1809 #else
1810     __ktrfmtin = (FILE *) 0;
1811     __ktrfmtout = (FILE *) 0;
1812 #endif
1813 
1814     /* For future reference: Set errno on error, since we are called by
1815      * __ktrfmtlex_init()
1816      */
1817     return 0;
1818 }
1819 
1820 /* __ktrfmtlex_destroy is for both reentrant and non-reentrant scanners. */
__ktrfmtlex_destroy(void)1821 int __ktrfmtlex_destroy  (void)
1822 {
1823 
1824     /* Pop the buffer stack, destroying each element. */
1825 	while(YY_CURRENT_BUFFER){
1826 		__ktrfmt_delete_buffer(YY_CURRENT_BUFFER  );
1827 		YY_CURRENT_BUFFER_LVALUE = NULL;
1828 		__ktrfmtpop_buffer_state();
1829 	}
1830 
1831 	/* Destroy the stack itself. */
1832 	__ktrfmtfree((yy_buffer_stack) );
1833 	(yy_buffer_stack) = NULL;
1834 
1835     /* Reset the globals. This is important in a non-reentrant scanner so the next time
1836      * __ktrfmtlex() is called, initialization will occur. */
1837     yy_init_globals( );
1838 
1839     return 0;
1840 }
1841 
1842 /*
1843  * Internal utility routines.
1844  */
1845 
1846 #ifndef yytext_ptr
yy_flex_strncpy(char * s1,yyconst char * s2,int n)1847 static void yy_flex_strncpy (char* s1, yyconst char * s2, int n )
1848 {
1849 	register int i;
1850 	for ( i = 0; i < n; ++i )
1851 		s1[i] = s2[i];
1852 }
1853 #endif
1854 
1855 #ifdef YY_NEED_STRLEN
yy_flex_strlen(yyconst char * s)1856 static int yy_flex_strlen (yyconst char * s )
1857 {
1858 	register int n;
1859 	for ( n = 0; s[n]; ++n )
1860 		;
1861 
1862 	return n;
1863 }
1864 #endif
1865 
__ktrfmtalloc(yy_size_t size)1866 void *__ktrfmtalloc (yy_size_t  size )
1867 {
1868 	return (void *) malloc( size );
1869 }
1870 
__ktrfmtrealloc(void * ptr,yy_size_t size)1871 void *__ktrfmtrealloc  (void * ptr, yy_size_t  size )
1872 {
1873 	/* The cast to (char *) in the following accommodates both
1874 	 * implementations that use char* generic pointers, and those
1875 	 * that use void* generic pointers.  It works with the latter
1876 	 * because both ANSI C and C++ allow castless assignment from
1877 	 * any pointer type to void*, and deal with argument conversions
1878 	 * as though doing an assignment.
1879 	 */
1880 	return (void *) realloc( (char *) ptr, size );
1881 }
1882 
__ktrfmtfree(void * ptr)1883 void __ktrfmtfree (void * ptr )
1884 {
1885 	free( (char *) ptr );	/* see __ktrfmtrealloc() for (char *) cast */
1886 }
1887 
1888 #define YYTABLES_NAME "yytables"
1889 
1890 #line 137 "ktrfmt.l"
1891 
1892 
1893 
1894