File Coverage

ext/B/../../hv_func.h

Criterion	Covered	Total	%
statement	23	23	100.0
branch			n/a
condition			n/a
subroutine			n/a
total	23	23	100.0

line	stmt	code
1		/* hash a key
2		*--------------------------------------------------------------------------------------
3		* The "hash seed" feature was added in Perl 5.8.1 to perturb the results
4		* to avoid "algorithmic complexity attacks".
5		*
6		* If USE_HASH_SEED is defined, hash randomisation is done by default
7		* If USE_HASH_SEED_EXPLICIT is defined, hash randomisation is done
8		* only if the environment variable PERL_HASH_SEED is set.
9		* (see also perl.c:perl_parse() and S_init_tls_and_interp() and util.c:get_hash_seed())
10		*/
11
12		#ifndef PERL_SEEN_HV_FUNC_H /* compile once */
13		#define PERL_SEEN_HV_FUNC_H
14
15		#if !( 0 \
16		\|\| defined(PERL_HASH_FUNC_SIPHASH) \
17		\|\| defined(PERL_HASH_FUNC_SDBM) \
18		\|\| defined(PERL_HASH_FUNC_DJB2) \
19		\|\| defined(PERL_HASH_FUNC_SUPERFAST) \
20		\|\| defined(PERL_HASH_FUNC_MURMUR3) \
21		\|\| defined(PERL_HASH_FUNC_ONE_AT_A_TIME) \
22		\|\| defined(PERL_HASH_FUNC_ONE_AT_A_TIME_HARD) \
23		\|\| defined(PERL_HASH_FUNC_ONE_AT_A_TIME_OLD) \
24		)
25		#define PERL_HASH_FUNC_ONE_AT_A_TIME_HARD
26		#endif
27
28		#if defined(PERL_HASH_FUNC_SIPHASH)
29		# define PERL_HASH_FUNC "SIPHASH_2_4"
30		# define PERL_HASH_SEED_BYTES 16
31		# define PERL_HASH(hash,str,len) (hash)= S_perl_hash_siphash_2_4(PERL_HASH_SEED,(U8*)(str),(len))
32		#elif defined(PERL_HASH_FUNC_SUPERFAST)
33		# define PERL_HASH_FUNC "SUPERFAST"
34		# define PERL_HASH_SEED_BYTES 4
35		# define PERL_HASH(hash,str,len) (hash)= S_perl_hash_superfast(PERL_HASH_SEED,(U8*)(str),(len))
36		#elif defined(PERL_HASH_FUNC_MURMUR3)
37		# define PERL_HASH_FUNC "MURMUR3"
38		# define PERL_HASH_SEED_BYTES 4
39		# define PERL_HASH(hash,str,len) (hash)= S_perl_hash_murmur3(PERL_HASH_SEED,(U8*)(str),(len))
40		#elif defined(PERL_HASH_FUNC_DJB2)
41		# define PERL_HASH_FUNC "DJB2"
42		# define PERL_HASH_SEED_BYTES 4
43		# define PERL_HASH(hash,str,len) (hash)= S_perl_hash_djb2(PERL_HASH_SEED,(U8*)(str),(len))
44		#elif defined(PERL_HASH_FUNC_SDBM)
45		# define PERL_HASH_FUNC "SDBM"
46		# define PERL_HASH_SEED_BYTES 4
47		# define PERL_HASH(hash,str,len) (hash)= S_perl_hash_sdbm(PERL_HASH_SEED,(U8*)(str),(len))
48		#elif defined(PERL_HASH_FUNC_ONE_AT_A_TIME_HARD)
49		# define PERL_HASH_FUNC "ONE_AT_A_TIME_HARD"
50		# define PERL_HASH_SEED_BYTES 8
51		# define PERL_HASH(hash,str,len) (hash)= S_perl_hash_one_at_a_time_hard(PERL_HASH_SEED,(U8*)(str),(len))
52		#elif defined(PERL_HASH_FUNC_ONE_AT_A_TIME)
53		# define PERL_HASH_FUNC "ONE_AT_A_TIME"
54		# define PERL_HASH_SEED_BYTES 4
55		# define PERL_HASH(hash,str,len) (hash)= S_perl_hash_one_at_a_time(PERL_HASH_SEED,(U8*)(str),(len))
56		#elif defined(PERL_HASH_FUNC_ONE_AT_A_TIME_OLD)
57		# define PERL_HASH_FUNC "ONE_AT_A_TIME_OLD"
58		# define PERL_HASH_SEED_BYTES 4
59		# define PERL_HASH(hash,str,len) (hash)= S_perl_hash_old_one_at_a_time(PERL_HASH_SEED,(U8*)(str),(len))
60		#endif
61
62		#ifndef PERL_HASH
63		#error "No hash function defined!"
64		#endif
65		#ifndef PERL_HASH_SEED_BYTES
66		#error "PERL_HASH_SEED_BYTES not defined"
67		#endif
68		#ifndef PERL_HASH_FUNC
69		#error "PERL_HASH_FUNC not defined"
70		#endif
71
72		#ifndef PERL_HASH_SEED
73		# if defined(USE_HASH_SEED) \|\| defined(USE_HASH_SEED_EXPLICIT)
74		# define PERL_HASH_SEED PL_hash_seed
75		# elif PERL_HASH_SEED_BYTES == 4
76		# define PERL_HASH_SEED "PeRl"
77		# elif PERL_HASH_SEED_BYTES == 16
78		# define PERL_HASH_SEED "PeRlHaShhAcKpErl"
79		# else
80		# error "No PERL_HASH_SEED definition for " PERL_HASH_FUNC
81		# endif
82		#endif
83
84		/*-----------------------------------------------------------------------------
85		* Endianess, misalignment capabilities and util macros
86		*
87		* The following 3 macros are defined in this section. The other macros defined
88		* are only needed to help derive these 3.
89		*
90		* U8TO32_LE(x) Read a little endian unsigned 32-bit int
91		* UNALIGNED_SAFE Defined if READ_UINT32 works on non-word boundaries
92		* ROTL32(x,r) Rotate x left by r bits
93		*/
94
95		#if (defined(__GNUC__) && defined(__i386__)) \|\| defined(__WATCOMC__) \
96		\|\| defined(_MSC_VER) \|\| defined (__BORLANDC__) \|\| defined (__TURBOC__)
97		#define U8TO16_LE(d) (((const U16 ) (d)))
98		#endif
99
100		#if !defined (U8TO16_LE)
101		#define U8TO16_LE(d) ((((const U8 *)(d))[1] << 8)\
102		+((const U8 *)(d))[0])
103		#endif
104
105
106		/* Now find best way we can to READ_UINT32 */
107		#if (BYTEORDER == 0x1234 \|\| BYTEORDER == 0x12345678) && U32SIZE == 4
108		/* CPU endian matches murmurhash algorithm, so read 32-bit word directly */
109		#define U8TO32_LE(ptr) (((U32)(ptr)))
110		#elif BYTEORDER == 0x4321 \|\| BYTEORDER == 0x87654321
111		/* TODO: Add additional cases below where a compiler provided bswap32 is available */
112		#if defined(__GNUC__) && (__GNUC__>4 \|\| (__GNUC__==4 && __GNUC_MINOR__>=3))
113		#define U8TO32_LE(ptr) (__builtin_bswap32(((U32)(ptr))))
114		#else
115		/* Without a known fast bswap32 we're just as well off doing this */
116		#define U8TO32_LE(ptr) (ptr[0]\|ptr[1]<<8\|ptr[2]<<16\|ptr[3]<<24)
117		#define UNALIGNED_SAFE
118		#endif
119		#else
120		/* Unknown endianess so last resort is to read individual bytes */
121		#define U8TO32_LE(ptr) (ptr[0]\|ptr[1]<<8\|ptr[2]<<16\|ptr[3]<<24)
122		/* Since we're not doing word-reads we can skip the messing about with realignment */
123		#define UNALIGNED_SAFE
124		#endif
125
126		#ifdef HAS_QUAD
127		#ifndef U64TYPE
128		/* This probably isn't going to work, but failing with a compiler error due to
129		lack of uint64_t is no worse than failing right now with an #error. */
130		#define U64TYPE uint64_t
131		#endif
132		#endif
133
134		/* Find best way to ROTL32/ROTL64 */
135		#if defined(_MSC_VER)
136		#include /* Microsoft put _rotl declaration in here */
137		#define ROTL32(x,r) _rotl(x,r)
138		#ifdef HAS_QUAD
139		#define ROTL64(x,r) _rotl64(x,r)
140		#endif
141		#else
142		/* gcc recognises this code and generates a rotate instruction for CPUs with one */
143		#define ROTL32(x,r) (((U32)x << r) \| ((U32)x >> (32 - r)))
144		#ifdef HAS_QUAD
145		#define ROTL64(x,r) (((U64TYPE)x << r) \| ((U64TYPE)x >> (64 - r)))
146		#endif
147		#endif
148
149
150		#ifdef UV_IS_QUAD
151		#define ROTL_UV(x,r) ROTL64(x,r)
152		#else
153		#define ROTL_UV(x,r) ROTL32(x,r)
154		#endif
155
156		/* This is SipHash by Jean-Philippe Aumasson and Daniel J. Bernstein.
157		* The authors claim it is relatively secure compared to the alternatives
158		* and that performance wise it is a suitable hash for languages like Perl.
159		* See:
160		*
161		* https://www.131002.net/siphash/
162		*
163		* This implementation seems to perform slightly slower than one-at-a-time for
164		* short keys, but degrades slower for longer keys. Murmur Hash outperforms it
165		* regardless of keys size.
166		*
167		* It is 64 bit only.
168		*/
169
170		#ifdef HAS_QUAD
171
172		#define U8TO64_LE(p) \
173		(((U64TYPE)((p)[0]) ) \| \
174		((U64TYPE)((p)[1]) << 8) \| \
175		((U64TYPE)((p)[2]) << 16) \| \
176		((U64TYPE)((p)[3]) << 24) \| \
177		((U64TYPE)((p)[4]) << 32) \| \
178		((U64TYPE)((p)[5]) << 40) \| \
179		((U64TYPE)((p)[6]) << 48) \| \
180		((U64TYPE)((p)[7]) << 56))
181
182		#define SIPROUND \
183		do { \
184		v0 += v1; v1=ROTL64(v1,13); v1 ^= v0; v0=ROTL64(v0,32); \
185		v2 += v3; v3=ROTL64(v3,16); v3 ^= v2; \
186		v0 += v3; v3=ROTL64(v3,21); v3 ^= v0; \
187		v2 += v1; v1=ROTL64(v1,17); v1 ^= v2; v2=ROTL64(v2,32); \
188		} while(0)
189
190		/* SipHash-2-4 */
191
192		PERL_STATIC_INLINE U32
193		S_perl_hash_siphash_2_4(const unsigned char * const seed, const unsigned char *in, const STRLEN inlen) {
194		/* "somepseudorandomlygeneratedbytes" */
195		U64TYPE v0 = 0x736f6d6570736575ULL;
196		U64TYPE v1 = 0x646f72616e646f6dULL;
197		U64TYPE v2 = 0x6c7967656e657261ULL;
198		U64TYPE v3 = 0x7465646279746573ULL;
199
200		U64TYPE b;
201		U64TYPE k0 = ((U64TYPE*)seed)[0];
202		U64TYPE k1 = ((U64TYPE*)seed)[1];
203		U64TYPE m;
204		const int left = inlen & 7;
205		const U8 *end = in + inlen - left;
206
207		b = ( ( U64TYPE )(inlen) ) << 56;
208		v3 ^= k1;
209		v2 ^= k0;
210		v1 ^= k1;
211		v0 ^= k0;
212
213		for ( ; in != end; in += 8 )
214		{
215		m = U8TO64_LE( in );
216		v3 ^= m;
217		SIPROUND;
218		SIPROUND;
219		v0 ^= m;
220		}
221
222		switch( left )
223		{
224		case 7: b \|= ( ( U64TYPE )in[ 6] ) << 48;
225		case 6: b \|= ( ( U64TYPE )in[ 5] ) << 40;
226		case 5: b \|= ( ( U64TYPE )in[ 4] ) << 32;
227		case 4: b \|= ( ( U64TYPE )in[ 3] ) << 24;
228		case 3: b \|= ( ( U64TYPE )in[ 2] ) << 16;
229		case 2: b \|= ( ( U64TYPE )in[ 1] ) << 8;
230		case 1: b \|= ( ( U64TYPE )in[ 0] ); break;
231		case 0: break;
232		}
233
234		v3 ^= b;
235		SIPROUND;
236		SIPROUND;
237		v0 ^= b;
238
239		v2 ^= 0xff;
240		SIPROUND;
241		SIPROUND;
242		SIPROUND;
243		SIPROUND;
244		b = v0 ^ v1 ^ v2 ^ v3;
245		return (U32)(b & U32_MAX);
246		}
247		#endif /* defined(HAS_QUAD) */
248
249		/* FYI: This is the "Super-Fast" algorithm mentioned by Bob Jenkins in
250		* (http://burtleburtle.net/bob/hash/doobs.html)
251		* It is by Paul Hsieh (c) 2004 and is analysed here
252		* http://www.azillionmonkeys.com/qed/hash.html
253		* license terms are here:
254		* http://www.azillionmonkeys.com/qed/weblicense.html
255		*/
256
257
258		PERL_STATIC_INLINE U32
259		S_perl_hash_superfast(const unsigned char * const seed, const unsigned char *str, STRLEN len) {
260		U32 hash = ((U32)seed) + len;
261		U32 tmp;
262		int rem= len & 3;
263		len >>= 2;
264
265		for (;len > 0; len--) {
266		hash += U8TO16_LE (str);
267		tmp = (U8TO16_LE (str+2) << 11) ^ hash;
268		hash = (hash << 16) ^ tmp;
269		str += 2 * sizeof (U16);
270		hash += hash >> 11;
271		}
272
273		/* Handle end cases */
274		switch (rem) { \
275		case 3: hash += U8TO16_LE (str);
276		hash ^= hash << 16;
277		hash ^= str[sizeof (U16)] << 18;
278		hash += hash >> 11;
279		break;
280		case 2: hash += U8TO16_LE (str);
281		hash ^= hash << 11;
282		hash += hash >> 17;
283		break;
284		case 1: hash += *str;
285		hash ^= hash << 10;
286		hash += hash >> 1;
287		}
288		/* Force "avalanching" of final 127 bits */
289		hash ^= hash << 3;
290		hash += hash >> 5;
291		hash ^= hash << 4;
292		hash += hash >> 17;
293		hash ^= hash << 25;
294		return (hash + (hash >> 6));
295		}
296
297
298		/*-----------------------------------------------------------------------------
299		* MurmurHash3 was written by Austin Appleby, and is placed in the public
300		* domain.
301		*
302		* This implementation was originally written by Shane Day, and is also public domain,
303		* and was modified to function as a macro similar to other perl hash functions by
304		* Yves Orton.
305		*
306		* This is a portable ANSI C implementation of MurmurHash3_x86_32 (Murmur3A)
307		* with support for progressive processing.
308		*
309		* If you want to understand the MurmurHash algorithm you would be much better
310		* off reading the original source. Just point your browser at:
311		* http://code.google.com/p/smhasher/source/browse/trunk/MurmurHash3.cpp
312		*
313		* How does it work?
314		*
315		* We can only process entire 32 bit chunks of input, except for the very end
316		* that may be shorter.
317		*
318		* To handle endianess I simply use a macro that reads a U32 and define
319		* that macro to be a direct read on little endian machines, a read and swap
320		* on big endian machines, or a byte-by-byte read if the endianess is unknown.
321		*/
322
323
324		/*-----------------------------------------------------------------------------
325		* Core murmurhash algorithm macros */
326
327		#define MURMUR_C1 (0xcc9e2d51)
328		#define MURMUR_C2 (0x1b873593)
329		#define MURMUR_C3 (0xe6546b64)
330		#define MURMUR_C4 (0x85ebca6b)
331		#define MURMUR_C5 (0xc2b2ae35)
332
333		/* This is the main processing body of the algorithm. It operates
334		* on each full 32-bits of input. */
335		#define MURMUR_DOBLOCK(h1, k1) STMT_START { \
336		k1 *= MURMUR_C1; \
337		k1 = ROTL32(k1,15); \
338		k1 *= MURMUR_C2; \
339		\
340		h1 ^= k1; \
341		h1 = ROTL32(h1,13); \
342		h1 = h1 * 5 + MURMUR_C3; \
343		} STMT_END
344
345
346		/* Append unaligned bytes to carry, forcing hash churn if we have 4 bytes */
347		/* cnt=bytes to process, h1=name of h1 var, c=carry, n=bytes in c, ptr/len=payload */
348		#define MURMUR_DOBYTES(cnt, h1, c, n, ptr, len) STMT_START { \
349		int MURMUR_DOBYTES_i = cnt; \
350		while(MURMUR_DOBYTES_i--) { \
351		c = c>>8 \| *ptr++<<24; \
352		n++; len--; \
353		if(n==4) { \
354		MURMUR_DOBLOCK(h1, c); \
355		n = 0; \
356		} \
357		} \
358		} STMT_END
359
360
361		/* now we create the hash function */
362		PERL_STATIC_INLINE U32
363		S_perl_hash_murmur3(const unsigned char * const seed, const unsigned char *ptr, STRLEN len) {
364		U32 h1 = ((U32)seed);
365		U32 k1;
366		U32 carry = 0;
367
368		const unsigned char *end;
369		int bytes_in_carry = 0; /* bytes in carry */
370		I32 total_length= len;
371
372		#if defined(UNALIGNED_SAFE)
373		/* Handle carry: commented out as its only used in incremental mode - it never fires for us
374		int i = (4-n) & 3;
375		if(i && i <= len) {
376		MURMUR_DOBYTES(i, h1, carry, bytes_in_carry, ptr, len);
377		}
378		*/
379
380		/* This CPU handles unaligned word access */
381		/* Process 32-bit chunks */
382		end = ptr + len/4*4;
383		for( ; ptr < end ; ptr+=4) {
384		k1 = U8TO32_LE(ptr);
385		MURMUR_DOBLOCK(h1, k1);
386		}
387		#else
388		/* This CPU does not handle unaligned word access */
389
390		/* Consume enough so that the next data byte is word aligned */
391		STRLEN i = -PTR2IV(ptr) & 3;
392		if(i && i <= len) {
393		MURMUR_DOBYTES(i, h1, carry, bytes_in_carry, ptr, len);
394		}
395
396		/* We're now aligned. Process in aligned blocks. Specialise for each possible carry count */
397		end = ptr + len/4*4;
398		switch(bytes_in_carry) { /* how many bytes in carry */
399		case 0: /* c=[----] w=[3210] b=[3210]=w c'=[----] */
400		for( ; ptr < end ; ptr+=4) {
401		k1 = U8TO32_LE(ptr);
402		MURMUR_DOBLOCK(h1, k1);
403		}
404		break;
405		case 1: /* c=[0---] w=[4321] b=[3210]=c>>24\|w<<8 c'=[4---] */
406		for( ; ptr < end ; ptr+=4) {
407		k1 = carry>>24;
408		carry = U8TO32_LE(ptr);
409		k1 \|= carry<<8;
410		MURMUR_DOBLOCK(h1, k1);
411		}
412		break;
413		case 2: /* c=[10--] w=[5432] b=[3210]=c>>16\|w<<16 c'=[54--] */
414		for( ; ptr < end ; ptr+=4) {
415		k1 = carry>>16;
416		carry = U8TO32_LE(ptr);
417		k1 \|= carry<<16;
418		MURMUR_DOBLOCK(h1, k1);
419		}
420		break;
421		case 3: /* c=[210-] w=[6543] b=[3210]=c>>8\|w<<24 c'=[654-] */
422		for( ; ptr < end ; ptr+=4) {
423		k1 = carry>>8;
424		carry = U8TO32_LE(ptr);
425		k1 \|= carry<<24;
426		MURMUR_DOBLOCK(h1, k1);
427		}
428		}
429		#endif
430		/* Advance over whole 32-bit chunks, possibly leaving 1..3 bytes */
431		len -= len/4*4;
432
433		/* Append any remaining bytes into carry */
434		MURMUR_DOBYTES(len, h1, carry, bytes_in_carry, ptr, len);
435
436		if (bytes_in_carry) {
437		k1 = carry >> ( 4 - bytes_in_carry ) * 8;
438		k1 *= MURMUR_C1;
439		k1 = ROTL32(k1,15);
440		k1 *= MURMUR_C2;
441		h1 ^= k1;
442		}
443		h1 ^= total_length;
444
445		/* fmix */
446		h1 ^= h1 >> 16;
447		h1 *= MURMUR_C4;
448		h1 ^= h1 >> 13;
449		h1 *= MURMUR_C5;
450		h1 ^= h1 >> 16;
451		return h1;
452		}
453
454
455		PERL_STATIC_INLINE U32
456		S_perl_hash_djb2(const unsigned char * const seed, const unsigned char *str, const STRLEN len) {
457		const unsigned char * const end = (const unsigned char *)str + len;
458		U32 hash = ((U32)seed + len);
459		while (str < end) {
460		hash = ((hash << 5) + hash) + *str++;
461		}
462		return hash;
463		}
464
465		PERL_STATIC_INLINE U32
466		S_perl_hash_sdbm(const unsigned char * const seed, const unsigned char *str, const STRLEN len) {
467		const unsigned char * const end = (const unsigned char *)str + len;
468		U32 hash = ((U32)seed + len);
469		while (str < end) {
470		hash = (hash << 6) + (hash << 16) - hash + *str++;
471		}
472		return hash;
473		}
474
475		/* - ONE_AT_A_TIME_HARD is the 5.17+ recommend ONE_AT_A_TIME algorithm
476		* - ONE_AT_A_TIME_OLD is the unmodified 5.16 and older algorithm
477		* - ONE_AT_A_TIME is a 5.17+ tweak of ONE_AT_A_TIME_OLD to
478		* prevent strings of only \0 but different lengths from colliding
479		*
480		* Security-wise, from best to worst,
481		* ONE_AT_A_TIME_HARD > ONE_AT_A_TIME > ONE_AT_A_TIME_OLD
482		* There is a big drop-off in security between ONE_AT_A_TIME_HARD and
483		* ONE_AT_A_TIME
484		* */
485
486		/* This is the "One-at-a-Time" algorithm by Bob Jenkins
487		* from requirements by Colin Plumb.
488		* (http://burtleburtle.net/bob/hash/doobs.html)
489		* With seed/len tweak.
490		* */
491		PERL_STATIC_INLINE U32
492		S_perl_hash_one_at_a_time(const unsigned char * const seed, const unsigned char *str, const STRLEN len) {
493		const unsigned char * const end = (const unsigned char *)str + len;
494		U32 hash = ((U32)seed) + len;
495		while (str < end) {
496		hash += *str++;
497		hash += (hash << 10);
498		hash ^= (hash >> 6);
499		}
500		hash += (hash << 3);
501		hash ^= (hash >> 11);
502		return (hash + (hash << 15));
503		}
504
505		/* Derived from "One-at-a-Time" algorithm by Bob Jenkins */
506		PERL_STATIC_INLINE U32
507		S_perl_hash_one_at_a_time_hard(const unsigned char * const seed, const unsigned char *str, const STRLEN len) {
508	15544377	const unsigned char * const end = (const unsigned char *)str + len;
509	15544377	U32 hash = ((U32)seed) + len;
510
511	117690585	while (str < end) {
512	102146244	hash += (hash << 10);
513	102146232	hash ^= (hash >> 6);
514	102146232	hash += *str++;
515		}
516
517	15544395	hash += (hash << 10);
518	15544377	hash ^= (hash >> 6);
519	15544377	hash += seed[4];
520
521	15544377	hash += (hash << 10);
522	15544377	hash ^= (hash >> 6);
523	15544377	hash += seed[5];
524
525	15544377	hash += (hash << 10);
526	15544377	hash ^= (hash >> 6);
527	15544377	hash += seed[6];
528
529	15544377	hash += (hash << 10);
530	15544377	hash ^= (hash >> 6);
531	15544377	hash += seed[7];
532
533	15544377	hash += (hash << 10);
534	15544377	hash ^= (hash >> 6);
535
536	15544377	hash += (hash << 3);
537	15544377	hash ^= (hash >> 11);
538	15544377	return (hash + (hash << 15));
539		}
540
541		PERL_STATIC_INLINE U32
542		S_perl_hash_old_one_at_a_time(const unsigned char * const seed, const unsigned char *str, const STRLEN len) {
543		const unsigned char * const end = (const unsigned char *)str + len;
544		U32 hash = ((U32)seed);
545		while (str < end) {
546		hash += *str++;
547		hash += (hash << 10);
548		hash ^= (hash >> 6);
549		}
550		hash += (hash << 3);
551		hash ^= (hash >> 11);
552		return (hash + (hash << 15));
553		}
554
555		/* legacy - only mod_perl should be doing this. */
556		#ifdef PERL_HASH_INTERNAL_ACCESS
557		#define PERL_HASH_INTERNAL(hash,str,len) PERL_HASH(hash,str,len)
558		#endif
559
560		#endif /compile once/
561
562		/*
563		* Local variables:
564		* c-indentation-style: bsd
565		* c-basic-offset: 4
566		* indent-tabs-mode: nil
567		* End:
568		*
569		* ex: set ts=8 sts=4 sw=4 et:
570		*/