configure.ac: Sort AC_CHECK_FUNCS() arguments alphabetically
[valgrind.git] / coregrind / m_libcbase.c
bloba5d004880254b25064fd2d97345cb1c994b4bc52
2 /*--------------------------------------------------------------------*/
3 /*--- Entirely standalone libc stuff. m_libcbase.c ---*/
4 /*--------------------------------------------------------------------*/
6 /*
7 This file is part of Valgrind, a dynamic binary instrumentation
8 framework.
10 Copyright (C) 2000-2017 Julian Seward
11 jseward@acm.org
13 This program is free software; you can redistribute it and/or
14 modify it under the terms of the GNU General Public License as
15 published by the Free Software Foundation; either version 2 of the
16 License, or (at your option) any later version.
18 This program is distributed in the hope that it will be useful, but
19 WITHOUT ANY WARRANTY; without even the implied warranty of
20 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
21 General Public License for more details.
23 You should have received a copy of the GNU General Public License
24 along with this program; if not, see <http://www.gnu.org/licenses/>.
26 The GNU General Public License is contained in the file COPYING.
29 #include "pub_core_basics.h"
30 #include "pub_core_libcassert.h" // VG_(exit_now)
31 #include "pub_core_debuglog.h" // VG_(debugLog)
32 #include "pub_core_libcbase.h"
35 /* ---------------------------------------------------------------------
36 Assert machinery for use in this file. vg_assert cannot be called
37 here due to cyclic dependencies.
38 ------------------------------------------------------------------ */
39 #if 0
40 #define libcbase_assert(expr) \
41 ((void) (LIKELY(expr) ? 0 : \
42 (ML_(libcbase_assert_fail)(#expr, \
43 __FILE__, __LINE__, \
44 __PRETTY_FUNCTION__))))
46 static void ML_(libcbase_assert_fail)( const HChar *expr,
47 const HChar *file,
48 Int line,
49 const HChar *fn )
51 VG_(debugLog)(0, "libcbase",
52 "Valgrind: FATAL: assertion failed:\n");
53 VG_(debugLog)(0, "libcbase", " %s\n", expr);
54 VG_(debugLog)(0, "libcbase", " at %s:%d (%s)\n", file, line, fn);
55 VG_(debugLog)(0, "libcbase", "Exiting now.\n");
56 VG_(exit_now)(1);
58 #endif
60 /* ---------------------------------------------------------------------
61 HChar functions.
62 ------------------------------------------------------------------ */
64 Bool VG_(isspace) ( HChar c )
66 return (c == ' ' || c == '\n' || c == '\t' ||
67 c == '\f' || c == '\v' || c == '\r');
70 Bool VG_(isdigit) ( HChar c )
72 return (c >= '0' && c <= '9');
75 /* ---------------------------------------------------------------------
76 Converting strings to numbers
77 ------------------------------------------------------------------ */
79 static Bool is_dec_digit(HChar c, Long* digit)
81 if (c >= '0' && c <= '9') { *digit = (Long)(c - '0'); return True; }
82 return False;
85 static Bool is_hex_digit(HChar c, Long* digit)
87 if (c >= '0' && c <= '9') { *digit = (Long)(c - '0'); return True; }
88 if (c >= 'A' && c <= 'F') { *digit = (Long)((c - 'A') + 10); return True; }
89 if (c >= 'a' && c <= 'f') { *digit = (Long)((c - 'a') + 10); return True; }
90 return False;
93 Long VG_(strtoll10) ( const HChar* str, HChar** endptr )
95 Bool neg = False, converted = False;
96 Long n = 0, digit = 0;
97 const HChar* str0 = str;
99 // Skip leading whitespace.
100 while (VG_(isspace)(*str)) str++;
102 // Allow a leading '-' or '+'.
103 if (*str == '-') { str++; neg = True; }
104 else if (*str == '+') { str++; }
106 while (is_dec_digit(*str, &digit)) {
107 converted = True; // Ok, we've actually converted a digit.
108 n = 10*n + digit;
109 str++;
112 if (!converted) str = str0; // If nothing converted, endptr points to
113 if (neg) n = -n; // the start of the string.
114 if (endptr)
115 *endptr = CONST_CAST(HChar *,str); // Record first failing character.
116 return n;
119 ULong VG_(strtoull10) ( const HChar* str, HChar** endptr )
121 Bool converted = False;
122 ULong n = 0;
123 Long digit = 0;
124 const HChar* str0 = str;
126 // Skip leading whitespace.
127 while (VG_(isspace)(*str)) str++;
129 // Allow a leading '+'.
130 if (*str == '+') { str++; }
132 while (is_dec_digit(*str, &digit)) {
133 converted = True; // Ok, we've actually converted a digit.
134 n = 10*n + digit;
135 str++;
138 if (!converted) str = str0; // If nothing converted, endptr points to
139 // the start of the string.
140 if (endptr)
141 *endptr = CONST_CAST(HChar *,str); // Record first failing character.
142 return n;
145 Long VG_(strtoll16) ( const HChar* str, HChar** endptr )
147 Bool neg = False, converted = False;
148 Long n = 0, digit = 0;
149 const HChar* str0 = str;
151 // Skip leading whitespace.
152 while (VG_(isspace)(*str)) str++;
154 // Allow a leading '-' or '+'.
155 if (*str == '-') { str++; neg = True; }
156 else if (*str == '+') { str++; }
158 // Allow leading "0x", but only if there's a hex digit
159 // following it.
160 if (*str == '0'
161 && (*(str+1) == 'x' || *(str+1) == 'X')
162 && is_hex_digit( *(str+2), &digit )) {
163 str += 2;
166 while (is_hex_digit(*str, &digit)) {
167 converted = True; // Ok, we've actually converted a digit.
168 n = 16*n + digit;
169 str++;
172 if (!converted) str = str0; // If nothing converted, endptr points to
173 if (neg) n = -n; // the start of the string.
174 if (endptr)
175 *endptr = CONST_CAST(HChar *,str); // Record first failing character.
176 return n;
179 ULong VG_(strtoull16) ( const HChar* str, HChar** endptr )
181 Bool converted = False;
182 ULong n = 0;
183 Long digit = 0;
184 const HChar* str0 = str;
186 // Skip leading whitespace.
187 while (VG_(isspace)(*str)) str++;
189 // Allow a leading '+'.
190 if (*str == '+') { str++; }
192 // Allow leading "0x", but only if there's a hex digit
193 // following it.
194 if (*str == '0'
195 && (*(str+1) == 'x' || *(str+1) == 'X')
196 && is_hex_digit( *(str+2), &digit )) {
197 str += 2;
200 while (is_hex_digit(*str, &digit)) {
201 converted = True; // Ok, we've actually converted a digit.
202 n = 16*n + digit;
203 str++;
206 if (!converted) str = str0; // If nothing converted, endptr points to
207 // the start of the string.
208 if (endptr)
209 *endptr = CONST_CAST(HChar *,str); // Record first failing character.
210 return n;
213 double VG_(strtod) ( const HChar* str, HChar** endptr )
215 Bool neg = False;
216 Long digit;
217 double n = 0, frac = 0, x = 0.1;
219 // Skip leading whitespace.
220 while (VG_(isspace)(*str)) str++;
222 // Allow a leading '-' or '+'.
223 if (*str == '-') { str++; neg = True; }
224 else if (*str == '+') { str++; }
226 while (is_dec_digit(*str, &digit)) {
227 n = 10*n + digit;
228 str++;
231 if (*str == '.') {
232 str++;
233 while (is_dec_digit(*str, &digit)) {
234 frac += x*digit;
235 x /= 10;
236 str++;
240 n += frac;
241 if (neg) n = -n;
242 if (endptr)
243 *endptr = CONST_CAST(HChar *,str); // Record first failing character.
244 return n;
247 HChar VG_(tolower) ( HChar c )
249 if ( c >= 'A' && c <= 'Z' ) {
250 return c - 'A' + 'a';
251 } else {
252 return c;
256 /* ---------------------------------------------------------------------
257 String functions
258 ------------------------------------------------------------------ */
260 SizeT VG_(strlen) ( const HChar* str )
262 SizeT i = 0;
263 while (str[i] != 0) i++;
264 return i;
267 SizeT VG_(strnlen)(const HChar* str, SizeT n)
269 SizeT i = 0;
270 while (i < n && str[i] != 0)
271 i++;
272 return i;
275 HChar* VG_(strcat) ( HChar* dest, const HChar* src )
277 HChar* dest_orig = dest;
278 while (*dest) dest++;
279 while (*src) *dest++ = *src++;
280 *dest = 0;
281 return dest_orig;
284 HChar* VG_(strncat) ( HChar* dest, const HChar* src, SizeT n )
286 HChar* dest_orig = dest;
287 while (*dest) dest++;
288 while (*src && n > 0) { *dest++ = *src++; n--; }
289 *dest = 0;
290 return dest_orig;
293 HChar* VG_(strpbrk) ( const HChar* s, const HChar* accpt )
295 const HChar* a;
296 while (*s) {
297 a = accpt;
298 while (*a)
299 if (*a++ == *s)
300 return CONST_CAST(HChar *,s);
301 s++;
303 return NULL;
306 HChar* VG_(strcpy) ( HChar* dest, const HChar* src )
308 HChar* dest_orig = dest;
309 while (*src) *dest++ = *src++;
310 *dest = 0;
311 return dest_orig;
314 HChar* VG_(strncpy) ( HChar* dest, const HChar* src, SizeT ndest )
316 SizeT i = 0;
317 while (True) {
318 if (i >= ndest) return dest; /* reached limit */
319 dest[i] = src[i];
320 if (src[i++] == 0) {
321 /* reached NUL; pad rest with zeroes as required */
322 while (i < ndest) dest[i++] = 0;
323 return dest;
328 /* Copies up to n-1 bytes from src to dst. Then nul-terminate dst if n > 0.
329 Returns strlen(src). Does not zero-fill the remainder of dst. */
330 SizeT VG_(strlcpy)(HChar *dst, const HChar *src, SizeT n)
332 const HChar *src_orig = src;
333 SizeT m = 0;
335 while (m < n - 1 && *src != '\0') {
336 m++;
337 *dst++ = *src++;
340 /* Nul-terminate dst. */ \
341 if (n > 0)
342 *dst = 0;
344 /* Finish counting strlen(src). */ \
345 while (*src != '\0')
346 src++;
348 return src - src_orig;
351 Int VG_(strcmp) ( const HChar* s1, const HChar* s2 )
353 while (True) {
354 if (*(const UChar*)s1 < *(const UChar*)s2) return -1;
355 if (*(const UChar*)s1 > *(const UChar*)s2) return 1;
357 /* *s1 == *s2 */
358 if (*s1 == 0) return 0;
360 s1++; s2++;
364 Int VG_(strcasecmp) ( const HChar* s1, const HChar* s2 )
366 while (True) {
367 UChar c1 = (UChar)VG_(tolower)(*s1);
368 UChar c2 = (UChar)VG_(tolower)(*s2);
369 if (c1 < c2) return -1;
370 if (c1 > c2) return 1;
372 /* c1 == c2 */
373 if (c1 == 0) return 0;
375 s1++; s2++;
379 Int VG_(strncmp) ( const HChar* s1, const HChar* s2, SizeT nmax )
381 SizeT n = 0;
382 while (True) {
383 if (n >= nmax) return 0;
384 if (*(const UChar*)s1 < *(const UChar*)s2) return -1;
385 if (*(const UChar*)s1 > *(const UChar*)s2) return 1;
387 /* *s1 == *s2 */
388 if (*s1 == 0) return 0;
390 s1++; s2++; n++;
394 Int VG_(strncasecmp) ( const HChar* s1, const HChar* s2, SizeT nmax )
396 Int n = 0;
397 while (True) {
398 UChar c1;
399 UChar c2;
400 if (n >= nmax) return 0;
401 c1 = (UChar)VG_(tolower)(*s1);
402 c2 = (UChar)VG_(tolower)(*s2);
403 if (c1 < c2) return -1;
404 if (c1 > c2) return 1;
406 /* c1 == c2 */
407 if (c1 == 0) return 0;
409 s1++; s2++; n++;
413 HChar* VG_(strstr) ( const HChar* haystack, const HChar* needle )
415 SizeT n;
416 if (haystack == NULL)
417 return NULL;
418 n = VG_(strlen)(needle);
419 while (True) {
420 if (haystack[0] == 0)
421 return NULL;
422 if (VG_(strncmp)(haystack, needle, n) == 0)
423 return CONST_CAST(HChar *,haystack);
424 haystack++;
428 HChar* VG_(strcasestr) ( const HChar* haystack, const HChar* needle )
430 Int n;
431 if (haystack == NULL)
432 return NULL;
433 n = VG_(strlen)(needle);
434 while (True) {
435 if (haystack[0] == 0)
436 return NULL;
437 if (VG_(strncasecmp)(haystack, needle, n) == 0)
438 return CONST_CAST(HChar *,haystack);
439 haystack++;
443 HChar* VG_(strchr) ( const HChar* s, HChar c )
445 while (True) {
446 if (*s == c) return CONST_CAST(HChar *,s);
447 if (*s == 0) return NULL;
448 s++;
452 HChar* VG_(strrchr) ( const HChar* s, HChar c )
454 Int n = VG_(strlen)(s);
455 while (--n > 0) {
456 if (s[n] == c) return CONST_CAST(HChar *,s) + n;
458 return NULL;
461 /* (code copied from glib then updated to valgrind types) */
462 static HChar *olds;
463 HChar *
464 VG_(strtok) (HChar *s, const HChar *delim)
466 return VG_(strtok_r) (s, delim, &olds);
469 HChar *
470 VG_(strtok_r) (HChar* s, const HChar* delim, HChar** saveptr)
472 HChar *token;
474 if (s == NULL)
475 s = *saveptr;
477 /* Scan leading delimiters. */
478 s += VG_(strspn) (s, delim);
479 if (*s == '\0')
481 *saveptr = s;
482 return NULL;
485 /* Find the end of the token. */
486 token = s;
487 s = VG_(strpbrk) (token, delim);
488 if (s == NULL)
489 /* This token finishes the string. */
490 *saveptr = token + VG_(strlen) (token);
491 else
493 /* Terminate the token and make OLDS point past it. */
494 *s = '\0';
495 *saveptr = s + 1;
497 return token;
500 static Bool isHex ( HChar c )
502 return ((c >= '0' && c <= '9') ||
503 (c >= 'a' && c <= 'f') ||
504 (c >= 'A' && c <= 'F'));
507 static UInt fromHex ( HChar c )
509 if (c >= '0' && c <= '9')
510 return (UInt)c - (UInt)'0';
511 if (c >= 'a' && c <= 'f')
512 return 10 + (UInt)c - (UInt)'a';
513 if (c >= 'A' && c <= 'F')
514 return 10 + (UInt)c - (UInt)'A';
515 /*NOTREACHED*/
516 // ??? need to vg_assert(0);
517 return 0;
520 Bool VG_(parse_Addr) ( const HChar** ppc, Addr* result )
522 Int used, limit = 2 * sizeof(Addr);
523 if (**ppc != '0')
524 return False;
525 (*ppc)++;
526 if (**ppc != 'x')
527 return False;
528 (*ppc)++;
529 *result = 0;
530 used = 0;
531 while (isHex(**ppc)) {
532 // ??? need to vg_assert(d < fromHex(**ppc));
533 *result = ((*result) << 4) | fromHex(**ppc);
534 (*ppc)++;
535 used++;
536 if (used > limit) return False;
538 if (used == 0)
539 return False;
540 return True;
543 Bool VG_(parse_UInt) ( const HChar** ppc, UInt* result )
545 ULong res64 = 0;
546 Int used, limit = 10;
547 used = 0;
548 while (VG_(isdigit)(**ppc)) {
549 res64 = res64 * 10 + ((ULong)(**ppc)) - (ULong)'0';
550 (*ppc)++;
551 used++;
552 if (used > limit) return False;
554 if (used == 0)
555 return False;
556 if ((res64 >> 32) != 0)
557 return False;
558 *result = (UInt)res64;
559 return True;
562 Bool VG_(parse_enum_set) ( const HChar *tokens,
563 Bool allow_all,
564 const HChar *input,
565 UInt *enum_set)
567 const SizeT tokens_len = VG_(strlen)(tokens);
568 if (tokens_len > 1000) return False; /* "obviously invalid" */
569 HChar tok_tokens[tokens_len+1];
570 HChar *tokens_saveptr;
571 HChar *token;
572 UInt token_nr = 0;
573 UInt all_set = 0;
575 const SizeT input_len = VG_(strlen)(input);
576 if (input_len > 1000) return False; /* "obviously invalid" */
577 HChar tok_input[input_len+1];
578 HChar *input_saveptr;
579 HChar *input_word;
580 UInt word_nr = 0;
581 UInt known_words = 0;
582 Bool seen_all_kw = False;
583 Bool seen_none_kw = False;
585 *enum_set = 0;
587 VG_(strcpy) (tok_input, input);
588 for (input_word = VG_(strtok_r)(tok_input, ",", &input_saveptr);
589 input_word;
590 input_word = VG_(strtok_r)(NULL, ",", &input_saveptr)) {
591 word_nr++;
592 if (allow_all && 0 == VG_(strcmp)(input_word, "all")) {
593 seen_all_kw = True;
594 known_words++;
595 } else if (0 == VG_(strcmp)(input_word, "none")) {
596 seen_none_kw = True;
597 known_words++;
600 // Scan tokens + compute all_set. Do that even if all or none was
601 // recognised to have a correct value for all_set when exiting
602 // of the 'input' loop.
603 all_set = 0;
604 token_nr = 0;
605 VG_(strcpy) (tok_tokens, tokens);
606 for (token = VG_(strtok_r)(tok_tokens, ",", &tokens_saveptr);
607 token;
608 token = VG_(strtok_r)(NULL, ",", &tokens_saveptr)) {
609 if (0 != VG_(strcmp)(token, "-")) {
610 if (0 == VG_(strcmp)(input_word, token)) {
611 *enum_set |= 1 << token_nr;
612 known_words++;
614 all_set |= 1 << token_nr;
616 token_nr++;
620 if (known_words != word_nr)
621 return False; // One or more input_words not recognised.
622 if (seen_all_kw) {
623 if (seen_none_kw || *enum_set)
624 return False; // mixing all with either none or a specific value.
625 *enum_set = all_set;
626 } else if (seen_none_kw) {
627 if (seen_all_kw || *enum_set)
628 return False; // mixing none with either all or a specific value.
629 *enum_set = 0;
630 } else {
631 // seen neither all or none, we must see at least one value
632 if (*enum_set == 0)
633 return False;
636 return True;
639 SizeT VG_(strspn) ( const HChar* s, const HChar* accpt )
641 const HChar *p, *a;
642 SizeT count = 0;
643 for (p = s; *p != '\0'; ++p) {
644 for (a = accpt; *a != '\0'; ++a)
645 if (*p == *a)
646 break;
647 if (*a == '\0')
648 return count;
649 else
650 ++count;
652 return count;
655 SizeT VG_(strcspn) ( const HChar* s, const HChar* reject )
657 SizeT count = 0;
658 while (*s != '\0') {
659 if (VG_(strchr) (reject, *s++) == NULL)
660 ++count;
661 else
662 return count;
664 return count;
668 /* ---------------------------------------------------------------------
669 mem* functions
670 ------------------------------------------------------------------ */
672 void* VG_(memcpy) ( void *dest, const void *src, SizeT sz )
674 const UChar* s = (const UChar*)src;
675 UChar* d = (UChar*)dest;
676 const UInt* sI = (const UInt*)src;
677 UInt* dI = (UInt*)dest;
679 if (VG_IS_4_ALIGNED(dI) && VG_IS_4_ALIGNED(sI)) {
680 while (sz >= 16) {
681 dI[0] = sI[0];
682 dI[1] = sI[1];
683 dI[2] = sI[2];
684 dI[3] = sI[3];
685 sz -= 16;
686 dI += 4;
687 sI += 4;
689 if (sz == 0)
690 return dest;
691 while (sz >= 4) {
692 dI[0] = sI[0];
693 sz -= 4;
694 dI += 1;
695 sI += 1;
697 if (sz == 0)
698 return dest;
699 s = (const UChar*)sI;
700 d = (UChar*)dI;
703 /* If we're unlucky, the alignment constraints for the fast case
704 above won't apply, and we'll have to do it all here. Hence the
705 unrolling. */
706 while (sz >= 4) {
707 d[0] = s[0];
708 d[1] = s[1];
709 d[2] = s[2];
710 d[3] = s[3];
711 d += 4;
712 s += 4;
713 sz -= 4;
715 while (sz >= 1) {
716 d[0] = s[0];
717 d += 1;
718 s += 1;
719 sz -= 1;
722 return dest;
725 void* VG_(memmove)(void *dest, const void *src, SizeT sz)
727 SizeT i;
728 if (sz == 0)
729 return dest;
730 if (dest < src) {
731 for (i = 0; i < sz; i++) {
732 ((UChar*)dest)[i] = ((const UChar*)src)[i];
735 else if (dest > src) {
736 for (i = 0; i < sz; i++) {
737 ((UChar*)dest)[sz-i-1] = ((const UChar*)src)[sz-i-1];
740 return dest;
743 void* VG_(memset) ( void *destV, Int c, SizeT sz )
745 UInt c4;
746 UChar* d = destV;
747 UChar uc = c;
749 while ((!VG_IS_4_ALIGNED(d)) && sz >= 1) {
750 d[0] = uc;
751 d++;
752 sz--;
754 UInt* d4 = ASSUME_ALIGNED(UInt*, d);
755 if (sz == 0)
756 return destV;
757 c4 = uc;
758 c4 |= (c4 << 8);
759 c4 |= (c4 << 16);
760 while (sz >= 16) {
761 d4[0] = c4;
762 d4[1] = c4;
763 d4[2] = c4;
764 d4[3] = c4;
765 d4 += 4;
766 sz -= 16;
768 while (sz >= 4) {
769 d4[0] = c4;
770 d4 += 1;
771 sz -= 4;
773 d = (UChar*) d4;
774 while (sz >= 1) {
775 d[0] = c;
776 d++;
777 sz--;
779 return destV;
782 Int VG_(memcmp) ( const void* s1, const void* s2, SizeT n )
784 Int res;
785 const UChar *p1 = s1;
786 const UChar *p2 = s2;
787 UChar a0;
788 UChar b0;
790 while (n != 0) {
791 a0 = p1[0];
792 b0 = p2[0];
793 p1 += 1;
794 p2 += 1;
795 res = a0 - b0;
796 if (res != 0)
797 return res;
798 n -= 1;
800 return 0;
803 /* ---------------------------------------------------------------------
804 Misc useful functions
805 ------------------------------------------------------------------ */
807 /////////////////////////////////////////////////////////////
808 /////////////////////////////////////////////////////////////
809 /// begin Bentley-McIlroy style quicksort
810 /// See "Engineering a Sort Function". Jon L Bentley, M. Douglas
811 /// McIlroy. Software Practice and Experience Vol 23(11), Nov 1993.
813 #define BM_MIN(a, b) \
814 (a) < (b) ? a : b
816 #define BM_SWAPINIT(a, es) \
817 swaptype = ((a-(Char*)0) | es) % sizeof(Word) ? 2 \
818 : es > (SizeT)sizeof(Word) ? 1 \
821 #define BM_EXCH(a, b, t) \
822 (t = a, a = b, b = t)
824 #define BM_SWAP(a, b) \
825 swaptype != 0 \
826 ? bm_swapfunc(a, b, es, swaptype) \
827 : (void)BM_EXCH(*ASSUME_ALIGNED(Word*, (a)), \
828 *ASSUME_ALIGNED(Word*, (b)), t)
830 #define BM_VECSWAP(a, b, n) \
831 if (n > 0) bm_swapfunc(a, b, n, swaptype)
833 #define BM_PVINIT(pv, pm) \
834 if (swaptype != 0) \
835 pv = a, BM_SWAP(pv, pm); \
836 else \
837 pv = (Char*)&v, v = *ASSUME_ALIGNED(Word*, pm)
839 static Char* bm_med3 ( Char* a, Char* b, Char* c,
840 Int (*cmp)(const void*, const void*) ) {
841 return cmp(a, b) < 0
842 ? (cmp(b, c) < 0 ? b : cmp(a, c) < 0 ? c : a)
843 : (cmp(b, c) > 0 ? b : cmp(a, c) > 0 ? c : a);
846 static void bm_swapfunc ( Char* a, Char* b, SizeT n, Int swaptype )
848 if (swaptype <= 1) {
849 Word t;
850 for ( ; n > 0; a += sizeof(Word), b += sizeof(Word),
851 n -= sizeof(Word))
852 BM_EXCH(*ASSUME_ALIGNED(Word*, a), *ASSUME_ALIGNED(Word*, b), t);
853 } else {
854 Char t;
855 for ( ; n > 0; a += 1, b += 1, n -= 1)
856 BM_EXCH(*a, *b, t);
860 static void bm_qsort ( Char* a, SizeT n, SizeT es,
861 Int (*cmp)(const void*, const void*) )
863 Char *pa, *pb, *pc, *pd, *pl, *pm, *pn, *pv;
864 Int r, swaptype;
865 Word t, v;
866 SizeT s, s1, s2;
867 tailcall:
868 BM_SWAPINIT(a, es);
869 if (n < 7) {
870 for (pm = a + es; pm < a + n*es; pm += es)
871 for (pl = pm; pl > a && cmp(pl-es, pl) > 0; pl -= es)
872 BM_SWAP(pl, pl-es);
873 return;
875 pm = a + (n/2)*es;
876 if (n > 7) {
877 pl = a;
878 pn = a + (n-1)*es;
879 if (n > 40) {
880 s = (n/8)*es;
881 pl = bm_med3(pl, pl+s, pl+2*s, cmp);
882 pm = bm_med3(pm-s, pm, pm+s, cmp);
883 pn = bm_med3(pn-2*s, pn-s, pn, cmp);
885 pm = bm_med3(pl, pm, pn, cmp);
887 BM_PVINIT(pv, pm);
888 pa = pb = a;
889 pc = pd = a + (n-1)*es;
890 for (;;) {
891 while (pb <= pc && (r = cmp(pb, pv)) <= 0) {
892 if (r == 0) { BM_SWAP(pa, pb); pa += es; }
893 pb += es;
895 while (pc >= pb && (r = cmp(pc, pv)) >= 0) {
896 if (r == 0) { BM_SWAP(pc, pd); pd -= es; }
897 pc -= es;
899 if (pb > pc) break;
900 BM_SWAP(pb, pc);
901 pb += es;
902 pc -= es;
904 pn = a + n*es;
905 s = BM_MIN(pa-a, pb-pa ); BM_VECSWAP(a, pb-s, s);
906 s = BM_MIN(pd-pc, pn-pd-es); BM_VECSWAP(pb, pn-s, s);
907 /* Now recurse. Do the smaller partition first with an explicit
908 recursion, then do the larger partition using a tail call.
909 Except we can't rely on gcc to implement a tail call in any sane
910 way, so simply jump back to the start. This guarantees stack
911 growth can never exceed O(log N) even in the worst case. */
912 s1 = pb-pa;
913 s2 = pd-pc;
914 if (s1 < s2) {
915 if (s1 > es) {
916 bm_qsort(a, s1/es, es, cmp);
918 if (s2 > es) {
919 /* bm_qsort(pn-s2, s2/es, es, cmp); */
920 a = pn-s2; n = s2/es; es = es; cmp = cmp;
921 goto tailcall;
923 } else {
924 if (s2 > es) {
925 bm_qsort(pn-s2, s2/es, es, cmp);
927 if (s1 > es) {
928 /* bm_qsort(a, s1/es, es, cmp); */
929 a = a; n = s1/es; es = es; cmp = cmp;
930 goto tailcall;
935 #undef BM_MIN
936 #undef BM_SWAPINIT
937 #undef BM_EXCH
938 #undef BM_SWAP
939 #undef BM_VECSWAP
940 #undef BM_PVINIT
942 /// end Bentley-McIlroy style quicksort
943 /////////////////////////////////////////////////////////////
944 /////////////////////////////////////////////////////////////
946 /* Returns the base-2 logarithm of x. Returns -1 if x is not a power
947 of two. */
948 Int VG_(log2) ( UInt x )
950 Int i;
951 /* Any more than 32 and we overflow anyway... */
952 for (i = 0; i < 32; i++) {
953 if ((1U << i) == x) return i;
955 return -1;
958 /* Ditto for 64 bit numbers. */
959 Int VG_(log2_64) ( ULong x )
961 Int i;
962 for (i = 0; i < 64; i++) {
963 if ((1ULL << i) == x) return i;
965 return -1;
968 // Generic quick sort.
969 void VG_(ssort)( void* base, SizeT nmemb, SizeT size,
970 Int (*compar)(const void*, const void*) )
972 bm_qsort(base,nmemb,size,compar);
976 // This random number generator is based on the one suggested in Kernighan
977 // and Ritchie's "The C Programming Language".
979 // A pseudo-random number generator returning a random UInt. If pSeed
980 // is NULL, it uses its own seed, which starts at zero. If pSeed is
981 // non-NULL, it uses and updates whatever pSeed points at.
983 UInt VG_(random)( /*MOD*/UInt* pSeed )
985 static UInt seed = 0;
987 if (pSeed == NULL)
988 pSeed = &seed;
990 *pSeed = (1103515245 * *pSeed + 12345);
991 return *pSeed;
995 /* The following Adler-32 checksum code is taken from zlib-1.2.3, which
996 has the following copyright notice. */
998 Copyright notice:
1000 (C) 1995-2004 Jean-loup Gailly and Mark Adler
1002 This software is provided 'as-is', without any express or implied
1003 warranty. In no event will the authors be held liable for any damages
1004 arising from the use of this software.
1006 Permission is granted to anyone to use this software for any purpose,
1007 including commercial applications, and to alter it and redistribute it
1008 freely, subject to the following restrictions:
1010 1. The origin of this software must not be misrepresented; you must not
1011 claim that you wrote the original software. If you use this software
1012 in a product, an acknowledgment in the product documentation would be
1013 appreciated but is not required.
1014 2. Altered source versions must be plainly marked as such, and must not be
1015 misrepresented as being the original software.
1016 3. This notice may not be removed or altered from any source distribution.
1018 Jean-loup Gailly Mark Adler
1019 jloup@gzip.org madler@alumni.caltech.edu
1021 If you use the zlib library in a product, we would appreciate *not*
1022 receiving lengthy legal documents to sign. The sources are provided
1023 for free but without warranty of any kind. The library has been
1024 entirely written by Jean-loup Gailly and Mark Adler; it does not
1025 include third-party code.
1027 If you redistribute modified sources, we would appreciate that you include
1028 in the file ChangeLog history information documenting your changes. Please
1029 read the FAQ for more information on the distribution of modified source
1030 versions.
1033 /* Update a running Adler-32 checksum with the bytes buf[0..len-1] and
1034 return the updated checksum. If buf is NULL, this function returns
1035 the required initial value for the checksum. An Adler-32 checksum is
1036 almost as reliable as a CRC32 but can be computed much faster. */
1037 UInt VG_(adler32)( UInt adler, const UChar* buf, UInt len )
1039 # define BASE 65521UL /* largest prime smaller than 65536 */
1040 # define NMAX 5552
1041 /* NMAX is the largest n such that
1042 255n(n+1)/2 + (n+1)(BASE-1) <= 2^32-1 */
1044 # define DO1(buf,i) {adler += (buf)[i]; sum2 += adler;}
1045 # define DO2(buf,i) DO1(buf,i); DO1(buf,i+1);
1046 # define DO4(buf,i) DO2(buf,i); DO2(buf,i+2);
1047 # define DO8(buf,i) DO4(buf,i); DO4(buf,i+4);
1048 # define DO16(buf) DO8(buf,0); DO8(buf,8);
1050 /* The zlib sources recommend this definition of MOD if the
1051 processor cannot do integer division in hardware. */
1052 # define MOD(a) \
1053 do { \
1054 if (a >= (BASE << 16)) a -= (BASE << 16); \
1055 if (a >= (BASE << 15)) a -= (BASE << 15); \
1056 if (a >= (BASE << 14)) a -= (BASE << 14); \
1057 if (a >= (BASE << 13)) a -= (BASE << 13); \
1058 if (a >= (BASE << 12)) a -= (BASE << 12); \
1059 if (a >= (BASE << 11)) a -= (BASE << 11); \
1060 if (a >= (BASE << 10)) a -= (BASE << 10); \
1061 if (a >= (BASE << 9)) a -= (BASE << 9); \
1062 if (a >= (BASE << 8)) a -= (BASE << 8); \
1063 if (a >= (BASE << 7)) a -= (BASE << 7); \
1064 if (a >= (BASE << 6)) a -= (BASE << 6); \
1065 if (a >= (BASE << 5)) a -= (BASE << 5); \
1066 if (a >= (BASE << 4)) a -= (BASE << 4); \
1067 if (a >= (BASE << 3)) a -= (BASE << 3); \
1068 if (a >= (BASE << 2)) a -= (BASE << 2); \
1069 if (a >= (BASE << 1)) a -= (BASE << 1); \
1070 if (a >= BASE) a -= BASE; \
1071 } while (0)
1072 # define MOD4(a) \
1073 do { \
1074 if (a >= (BASE << 4)) a -= (BASE << 4); \
1075 if (a >= (BASE << 3)) a -= (BASE << 3); \
1076 if (a >= (BASE << 2)) a -= (BASE << 2); \
1077 if (a >= (BASE << 1)) a -= (BASE << 1); \
1078 if (a >= BASE) a -= BASE; \
1079 } while (0)
1081 UInt sum2;
1082 UInt n;
1084 /* split Adler-32 into component sums */
1085 sum2 = (adler >> 16) & 0xffff;
1086 adler &= 0xffff;
1088 /* in case user likes doing a byte at a time, keep it fast */
1089 if (len == 1) {
1090 adler += buf[0];
1091 if (adler >= BASE)
1092 adler -= BASE;
1093 sum2 += adler;
1094 if (sum2 >= BASE)
1095 sum2 -= BASE;
1096 return adler | (sum2 << 16);
1099 /* initial Adler-32 value (deferred check for len == 1 speed) */
1100 if (buf == NULL)
1101 return 1L;
1103 /* in case short lengths are provided, keep it somewhat fast */
1104 if (len < 16) {
1105 while (len--) {
1106 adler += *buf++;
1107 sum2 += adler;
1109 if (adler >= BASE)
1110 adler -= BASE;
1111 MOD4(sum2); /* only added so many BASE's */
1112 return adler | (sum2 << 16);
1115 /* do length NMAX blocks -- requires just one modulo operation */
1116 while (len >= NMAX) {
1117 len -= NMAX;
1118 n = NMAX / 16; /* NMAX is divisible by 16 */
1119 do {
1120 DO16(buf); /* 16 sums unrolled */
1121 buf += 16;
1122 } while (--n);
1123 MOD(adler);
1124 MOD(sum2);
1127 /* do remaining bytes (less than NMAX, still just one modulo) */
1128 if (len) { /* avoid modulos if none remaining */
1129 while (len >= 16) {
1130 len -= 16;
1131 DO16(buf);
1132 buf += 16;
1134 while (len--) {
1135 adler += *buf++;
1136 sum2 += adler;
1138 MOD(adler);
1139 MOD(sum2);
1142 /* return recombined sums */
1143 return adler | (sum2 << 16);
1145 # undef MOD4
1146 # undef MOD
1147 # undef DO16
1148 # undef DO8
1149 # undef DO4
1150 # undef DO2
1151 # undef DO1
1152 # undef NMAX
1153 # undef BASE
1156 /*--------------------------------------------------------------------*/
1157 /*--- end ---*/
1158 /*--------------------------------------------------------------------*/