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1 /* nasmlib.h header file for nasmlib.c
2 *
3 * The Netwide Assembler is copyright (C) 1996 Simon Tatham and
4 * Julian Hall. All rights reserved. The software is
5 * redistributable under the license given in the file "LICENSE"
6 * distributed in the NASM archive.
7 */
9 #ifndef NASM_NASMLIB_H
10 #define NASM_NASMLIB_H
14 #include <inttypes.h>
15 #include <stdio.h>
16 #include <string.h>
17 #ifdef HAVE_STRINGS_H
18 #include <strings.h>
19 #endif
21 /*
22 * If this is defined, the wrappers around malloc et al will
23 * transform into logging variants, which will cause NASM to create
24 * a file called `malloc.log' when run, and spew details of all its
25 * memory management into that. That can then be analysed to detect
26 * memory leaks and potentially other problems too.
27 */
28 /* #define LOGALLOC */
30 /*
31 * -------------------------
32 * Error reporting functions
33 * -------------------------
34 */
36 /*
37 * An error reporting function should look like this.
38 */
41 /*
42 * These are the error severity codes which get passed as the first
43 * argument to an efunc.
44 */
51 * and dump core for reference */
57 /*
58 * These codes define specific types of suppressible warning.
59 */
64 #define WARN(x) ((x) << ERR_WARN_SHR)
69 * alone on line) */
78 /*
79 * Wrappers around malloc, realloc and free. nasm_malloc will
80 * fatal-error and die rather than return NULL; nasm_realloc will
81 * do likewise, and will also guarantee to work right on being
82 * passed a NULL pointer; nasm_free will do nothing if it is passed
83 * a NULL pointer.
84 */
86 #ifndef LOGALLOC
93 #else
100 #define nasm_malloc(x) nasm_malloc_log(__FILE__,__LINE__,x)
101 #define nasm_zalloc(x) nasm_zalloc_log(__FILE__,__LINE__,x)
102 #define nasm_realloc(x,y) nasm_realloc_log(__FILE__,__LINE__,x,y)
103 #define nasm_free(x) nasm_free_log(__FILE__,__LINE__,x)
104 #define nasm_strdup(x) nasm_strdup_log(__FILE__,__LINE__,x)
105 #define nasm_strndup(x,y) nasm_strndup_log(__FILE__,__LINE__,x,y)
106 #endif
108 /*
109 * ANSI doesn't guarantee the presence of `stricmp' or
110 * `strcasecmp'.
111 */
112 #if defined(HAVE_STRCASECMP)
113 #define nasm_stricmp strcasecmp
114 #elif defined(HAVE_STRICMP)
115 #define nasm_stricmp stricmp
116 #else
118 #endif
120 #if defined(HAVE_STRNCASECMP)
121 #define nasm_strnicmp strncasecmp
122 #elif defined(HAVE_STRNICMP)
123 #define nasm_strnicmp strnicmp
124 #else
126 #endif
130 #if defined(HAVE_STRSEP)
131 #define nasm_strsep strsep
132 #else
134 #endif
137 /*
138 * Convert a string into a number, using NASM number rules. Sets
139 * `*error' to true if an error occurs, and false otherwise.
140 */
143 /*
144 * Convert a character constant into a number. Sets
145 * `*warn' to true if an overflow occurs, and false otherwise.
146 * str points to and length covers the middle of the string,
147 * without the quotes.
148 */
151 /*
152 * seg_init: Initialise the segment-number allocator.
153 * seg_alloc: allocate a hitherto unused segment number.
154 */
158 /*
159 * many output formats will be able to make use of this: a standard
160 * function to add an extension to the name of the input file
161 */
162 #ifdef NASM_NASM_H
164 efunc error);
165 #endif
167 /*
168 * Utility macros...
169 *
170 * This is a useful #define which I keep meaning to use more often:
171 * the number of elements of a statically defined array.
172 */
174 #define elements(x) ( sizeof(x) / sizeof(*(x)) )
177 /*
178 * some handy macros that will probably be of use in more than one
179 * output format: convert integers into little-endian byte packed
180 * format in memory
181 */
183 #if X86_MEMORY
185 #define WRITECHAR(p,v) \
186 do { \
187 *(uint8_t *)(p) = (v); \
188 (p) += 1; \
189 } while (0)
191 #define WRITESHORT(p,v) \
192 do { \
193 *(uint16_t *)(p) = (v); \
194 (p) += 2; \
195 } while (0)
197 #define WRITELONG(p,v) \
198 do { \
199 *(uint32_t *)(p) = (v); \
200 (p) += 4; \
201 } while (0)
203 #define WRITEDLONG(p,v) \
204 do { \
205 *(uint64_t *)(p) = (v); \
206 (p) += 8; \
207 } while (0)
209 #define WRITEADDR(p,v,s) \
210 do { \
211 uint64_t _wa_v = (v); \
212 memcpy((p), &_wa_v, (s)); \
213 (p) += (s); \
214 } while (0)
218 #define WRITECHAR(p,v) \
219 do { \
220 uint8_t *_wc_p = (uint8_t *)(p); \
221 uint8_t _wc_v = (v); \
222 _wc_p[0] = _wc_v; \
223 (p) = (void *)(_wc_p + 1); \
224 } while (0)
226 #define WRITESHORT(p,v) \
227 do { \
228 uint8_t *_ws_p = (uint8_t *)(p); \
229 uint16_t _ws_v = (v); \
230 _ws_p[0] = _ws_v; \
231 _ws_p[1] = _ws_v >> 8; \
232 (p) = (void *)(_ws_p + 2); \
233 } while (0)
235 #define WRITELONG(p,v) \
236 do { \
237 uint8_t *_wl_p = (uint8_t *)(p); \
238 uint32_t _wl_v = (v); \
239 _wl_p[0] = _wl_v; \
240 _wl_p[1] = _wl_v >> 8; \
241 _wl_p[2] = _wl_v >> 16; \
242 _wl_p[3] = _wl_v >> 24; \
243 (p) = (void *)(_wl_p + 4); \
244 } while (0)
246 #define WRITEDLONG(p,v) \
247 do { \
248 uint8_t *_wq_p = (uint8_t *)(p); \
249 uint64_t _wq_v = (v); \
250 _wq_p[0] = _wq_v; \
251 _wq_p[1] = _wq_v >> 8; \
252 _wq_p[2] = _wq_v >> 16; \
253 _wq_p[3] = _wq_v >> 24; \
254 _wq_p[4] = _wq_v >> 32; \
255 _wq_p[5] = _wq_v >> 40; \
256 _wq_p[6] = _wq_v >> 48; \
257 _wq_p[7] = _wq_v >> 56; \
258 (p) = (void *)(_wq_p + 8); \
259 } while (0)
261 #define WRITEADDR(p,v,s) \
262 do { \
263 int _wa_s = (s); \
264 uint64_t _wa_v = (v); \
265 while (_wa_s--) { \
266 WRITECHAR(p,_wa_v); \
267 _wa_v >>= 8; \
268 } \
269 } while(0)
271 #endif
273 /*
274 * and routines to do the same thing to a file
275 */
276 #define fwriteint8_t(d,f) putc(d,f)
282 /*
283 * Routines to manage a dynamic random access array of int64_ts which
284 * may grow in size to be more than the largest single malloc'able
285 * chunk.
286 */
289 #define RAA_BLKSIZE (1 << RAA_BLKSHIFT)
291 #define RAA_LAYERSIZE (1 << RAA_LAYERSHIFT)
299 /*
300 * Number of layers below this one to get to the real data. 0
301 * means this structure is a leaf, holding RAA_BLKSIZE real
302 * data items; 1 and above mean it's a branch, holding
303 * RAA_LAYERSIZE pointers to the next level branch or leaf
304 * structures.
305 */
308 /*
309 * Number of real data items spanned by one position in the
310 * `data' array at this level. This number is 0 trivially, for
311 * a leaf (level 0): for a level 1 branch it should be
312 * RAA_BLKSHIFT, and for a level 2 branch it's
313 * RAA_LAYERSHIFT+RAA_BLKSHIFT.
314 */
325 };
332 /*
333 * Routines to manage a dynamic sequential-access array, under the
334 * same restriction on maximum mallocable block. This array may be
335 * written to in two ways: a contiguous chunk can be reserved of a
336 * given size with a pointer returned OR single-byte data may be
337 * written. The array can also be read back in the same two ways:
338 * as a series of big byte-data blocks or as a list of structures
339 * of a given size.
340 */
343 /*
344 * members `end' and `elem_len' are only valid in first link in
345 * list; `rptr' and `rpos' are used for reading
346 */
360 };
372 /* random access */
376 /* dump to file */
379 /*
380 * Binary search routine. Returns index into `array' of an entry
381 * matching `string', or <0 if no match. `array' is taken to
382 * contain `size' elements.
383 *
384 * bsi() is case sensitive, bsii() is case insensitive.
385 */
392 /*
393 * src_get may be used if you simply want to know the source file and line.
394 * It is also used if you maintain private status about the source location
395 * It return 0 if the information was the same as the last time you
396 * checked, -1 if the name changed and (new-old) if just the line changed.
397 */
408 #endif