File Coverage

functions.c

Criterion	Covered	Total	%
statement	1047	1068	98.0
branch	629	670	93.8
condition			n/a
subroutine			n/a
pod			n/a
total	1676	1738	96.4

line	stmt	bran	code
1			/*
2			functions.c - Core functions for Net::IP::XS.
3
4			Copyright (C) 2010-2016 Tom Harrison
5			Original inet_pton4, inet_pton6 are Copyright (C) 2006 Free Software
6			Foundation.
7			Original interface, and the auth and ip_auth functions, are Copyright
8			(C) 1999-2002 RIPE NCC.
9
10			This program is free software; you can redistribute it and/or modify
11			it under the terms of the GNU General Public License as published by
12			the Free Software Foundation; either version 2 of the License, or
13			(at your option) any later version.
14
15			This program is distributed in the hope that it will be useful,
16			but WITHOUT ANY WARRANTY; without even the implied warranty of
17			MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
18			GNU General Public License for more details.
19
20			You should have received a copy of the GNU General Public License along
21			with this program; if not, write to the Free Software Foundation, Inc.,
22			51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
23			*/
24
25			#include "EXTERN.h"
26			#include "perl.h"
27			#include "XSUB.h"
28
29			#include "functions.h"
30			#include "inet_pton.h"
31
32			#ifdef __cplusplus
33			extern "C" {
34			#endif
35
36			/* Global error string and error number (tied to $Net::IP::XS::ERROR
37			* and $Net::IP::XS::ERRNO). */
38			static char netip_Error[512];
39			static int netip_Errno;
40
41			/**
42			* NI_hv_get_pv(): get string value from hashref.
43			* @object: reference to a hashref.
44			* @key: hashref key as a string.
45			* @keylen: the length of the hashref key.
46			*
47			* Returns a pointer to the beginning of the string to which @key is
48			* mapped in the hashref. If @key does not exist in the hashref,
49			* returns 0.
50			*/
51			const char*
52	2814		NI_hv_get_pv(SV object, const char key, int keylen)
53			{
54			SV **ref;
55
56	2814		ref = hv_fetch((HV*) SvRV(object), key, keylen, 0);
57	2814	100	if (!ref) {
58	87		return NULL;
59			}
60	2727	50	return SvPV(*ref, PL_na);
61			}
62
63			/**
64			* NI_hv_get_iv(): get integer value from hashref.
65			* @object: reference to a hashref.
66			* @key: hashref key as a string.
67			* @keylen: the length of the hashref key.
68			*
69			* Returns the integer to which @key is mapped in the hashref. If
70			* @key does not exist in the hashref, returns 0.
71			*/
72			int
73	1916		NI_hv_get_iv(SV object, const char key, int keylen)
74			{
75			SV **ref;
76
77	1916		ref = hv_fetch((HV*) SvRV(object), key, keylen, 0);
78	1916	100	if (!ref) {
79	20		return -1;
80			}
81	1896	100	return SvIV(*ref);
82			}
83
84			/**
85			* NI_hv_get_uv(): get unsigned integer value from hashref.
86			* @object: reference to a hashref.
87			* @key: hashref key as a string.
88			* @keylen: the length of the hashref key.
89			*
90			* Returns the unsigned integer to which @key is mapped in the
91			* hashref. If @key does not exist in the hashref, returns 0.
92			*/
93			unsigned int
94	928		NI_hv_get_uv(SV object, const char key, int keylen)
95			{
96			SV **ref;
97
98	928		ref = hv_fetch((HV*) SvRV(object), key, keylen, 0);
99	928	100	if (!ref) {
100	2		return -1;
101			}
102	926	50	return SvUV(*ref);
103			}
104
105			/**
106			* NI_set_Errno() - set the global error number.
107			* @Errno: the new error number.
108			*/
109			void
110	3		NI_set_Errno(int Errno)
111			{
112	3		netip_Errno = Errno;
113	3		}
114
115			/**
116			* NI_get_Errno() - get the global error number.
117			*/
118			int
119	76		NI_get_Errno(void)
120			{
121	76		return netip_Errno;
122			}
123
124			/**
125			* NI_set_Error() - set the global error string.
126			* @Error: the new error string.
127			*
128			* If the error string is more than 512 characters in length
129			* (including the ending null), only the first 511 characters will be
130			* used (with a null as the 512th character).
131			*/
132			void
133	3		NI_set_Error(const char *Error)
134			{
135			int len;
136
137	3		len = strlen(Error);
138	3	100	if (len > 511) {
139	1		len = 511;
140			}
141	3		memcpy(netip_Error, Error, len);
142	3		netip_Error[len] = '\0';
143	3		}
144
145			/**
146			* NI_get_Error() - get the global error string.
147			*/
148			const char*
149	73		NI_get_Error(void)
150			{
151	73		return (const char *) netip_Error;
152			}
153
154			/**
155			* NI_set_Error_Errno() - set the global error number and string.
156			* @Errno: the new error number.
157			* @Error: the new error string (can include printf modifiers).
158			* @...: format arguments to substitute into @Error.
159			*/
160			void
161	819		NI_set_Error_Errno(int Errno, const char *Error, ...)
162			{
163			va_list args;
164
165	819		va_start(args, Error);
166	819		vsnprintf(netip_Error, 512, Error, args);
167	819		netip_Error[511] = '\0';
168	819		netip_Errno = Errno;
169	819		va_end(args);
170	819		}
171
172			/**
173			* NI_ip_uchars_to_n128(): make N128 integer from array of chars.
174			* @uchars: array of at least 16 unsigned chars.
175			* @buf: N128 integer buffer.
176			*/
177			void
178	52		NI_ip_uchars_to_n128(unsigned char uchars[16], n128_t *num)
179			{
180			int i;
181			int j;
182			unsigned long k;
183
184	260	100	for (i = 0; i < 4; i++) {
185	208		j = i * 4;
186	416		k = ( (uchars[j + 3])
187	208		\| (uchars[j + 2] << 8)
188	208		\| (uchars[j + 1] << 16)
189	208		\| (uchars[j] << 24));
190	208		num->nums[i] = k;
191			}
192	52		}
193
194			/**
195			* NI_ip_uchars_to_ulong(): get whole integer from array of chars.
196			* @uchars: array of at least 4 unsigned chars.
197			*/
198			unsigned long
199	1043		NI_ip_uchars_to_ulong(unsigned char uchars[4])
200			{
201			return
202	1043		(uchars[3]
203	1043		\| (uchars[2] << 8)
204	1043		\| (uchars[1] << 16)
205	1043		\| (uchars[0] << 24));
206			}
207
208			/**
209			* NI_hdtoi(): convert hexadecimal character to integer.
210			* @c: hexadecimal character.
211			*
212			* Returns -1 when the character is not a valid hexadecimal character.
213			*/
214			int
215	27606		NI_hdtoi(char c)
216			{
217	27606		c = tolower(c);
218
219			return
220	55212		(isdigit(c)) ? c - '0'
221	58487	100	: ((c >= 'a') && (c <= 'f')) ? 10 + (c - 'a')
		50
222	30881	100	: -1;
223			}
224
225			/**
226			* NI_trailing_zeroes(): get trailing zeroes from number treated as binary.
227			* @n: the number.
228			*/
229			int
230	5561		NI_trailing_zeroes(unsigned long n)
231			{
232			int c;
233
234	5561	100	if (!n) {
235	53		return CHAR_BIT * sizeof(n);
236			}
237
238	5508		n = (n ^ (n - 1)) >> 1;
239	109846	100	for (c = 0; n; c++) {
240	104338		n >>= 1;
241			}
242
243	5508		return c;
244			}
245
246			/**
247			* NI_bintoint(): convert bitstring to integer.
248			* @bitstr: the bitstring.
249			* @len: the number of characters to use from the bitstring.
250			*/
251			unsigned long
252	66129		NI_bintoint(const char *bitstr, int len)
253			{
254			unsigned long res;
255			int i;
256			int help;
257
258	66129		res = 0;
259	66129		help = len - 1;
260
261	2182099	100	for (i = 0; i < len; i++) {
262	2115970		res += (((unsigned long) (bitstr[i] == '1')) << (help - i));
263			}
264
265	66129		return res;
266			}
267
268			/**
269			* NI_bintoint_nonzero(): convert bitstring to integer.
270			* @bitstr: the bitstring.
271			* @len: the number of characters to use from the bitstring.
272			*
273			* This function treats all non-zero characters in the bitstring as
274			* if they were '1', whereas NI_bintoint() treats all non-one
275			* characters as if they were '0'.
276			*/
277			unsigned long
278	7		NI_bintoint_nonzero(const char *bitstr, int len)
279			{
280			unsigned long res;
281			int i;
282			int help;
283
284	7		res = 0;
285	7		help = len - 1;
286
287	88	100	for (i = 0; i < len; i++) {
288	81		res += (((unsigned long) (bitstr[i] != '0')) << (help - i));
289			}
290
291	7		return res;
292			}
293
294			/**
295			* NI_iplengths() - return length in bits of the version of IP address.
296			* @version: IP version as integer (either 4 or 6).
297			*
298			* Returns 0 if @version is an invalid value.
299			*/
300			int
301	19329		NI_iplengths(int version)
302			{
303	19329		switch (version) {
304	1881		case 4: return 32;
305	17439		case 6: return 128;
306	9		default: return 0;
307			};
308			}
309
310			/**
311			* NI_ip_n128tobin(): make bitstring from N128 integer.
312			* @num: N128 integer.
313			* @len: the number of bits to write to the buffer.
314			* @buf: the bitstring buffer.
315			*
316			* This does not null-terminate the buffer.
317			*/
318			void
319	16008		NI_ip_n128tobin(n128_t num, int len, char buf)
320			{
321			int i;
322
323	16008	100	if (len == 0) {
324	3		return;
325			}
326
327	2063800	100	for (i = 0; i < len; i++) {
328	2047795	100	buf[len - 1 - i] = (n128_tstbit(num, i) ? '1' : '0');
329			}
330			}
331
332			/**
333			* NI_ip_inttobin_str() - make bitstring from IP address integer.
334			* @ip_int_str: the IP address integer as a string.
335			* @version: the IP address version.
336			* @buf: the bitstring buffer.
337			*
338			* Returns 1 if the buffer is able to be populated properly. Returns 0
339			* if the IP version is invalid. This function null-terminates the
340			* buffer. The buffer must have at least 129 characters' capacity.
341			*/
342			int
343	13		NI_ip_inttobin_str(const char ip_int_str, int version, char buf)
344			{
345			n128_t num;
346			int i;
347			int len;
348			int res;
349
350	13	100	if (!version) {
351	1		NI_set_Error_Errno(101, "Cannot determine IP "
352			"version for %s", ip_int_str);
353	1		return 0;
354			}
355
356	12		len = strlen(ip_int_str);
357	165	100	for (i = 0; i < len; i++) {
358	155	100	if (!isdigit(ip_int_str[i])) {
359	2	100	memset(buf, '0', (version == 4) ? 32 : 128);
360	2	100	buf[(version == 4) ? 32 : 128] = '\0';
361	2		return 1;
362			}
363			}
364
365	10		n128_set_ui(&num, 0);
366	10		res = n128_set_str_decimal(&num, ip_int_str, strlen(ip_int_str));
367	10	100	if (!res) {
368	1		return 0;
369			}
370
371	9		n128_print_bin(&num, buf, (version == 4));
372
373	13		return 1;
374			}
375
376			/**
377			* NI_ip_bintoint_str(): convert bitstring to integer string.
378			* @bitstr: the bitstring.
379			* @buf: the integer string buffer.
380			*/
381			int
382	10		NI_ip_bintoint_str(const char bitstr, char buf)
383			{
384			unsigned long num_ulong;
385			n128_t num_n128;
386			int len;
387
388	10		len = strlen(bitstr);
389
390	10	100	if (len <= 32) {
391	7		num_ulong = NI_bintoint_nonzero(bitstr, len);
392	7		sprintf(buf, "%lu", num_ulong);
393	7		return 1;
394			}
395
396	3		n128_set_ui(&num_n128, 0);
397
398	3		n128_set_str_binary(&num_n128, bitstr, len);
399	3		n128_print_dec(&num_n128, buf);
400
401	10		return 1;
402			}
403
404			/**
405			* NI_ip_is_ipv4(): check whether string is an IPv4 address.
406			* @str: IP address string (null-terminated).
407			*/
408			int
409	1918		NI_ip_is_ipv4(const char *str)
410			{
411			int i;
412			int len;
413	1918		int quads = 0;
414			int quadspots[3];
415			long current_quad;
416			int cq_index;
417			char *endptr;
418
419	1918		len = strlen(str);
420	1918	100	if (!len) {
421	2		NI_set_Error_Errno(107, "Invalid chars in IP ");
422	2		return 0;
423			}
424
425			/* Contains invalid characters. */
426
427	19912	100	for (i = 0; i < len; i++) {
428	18730	100	if (!isdigit(str[i]) && str[i] != '.') {
		100
429	734		NI_set_Error_Errno(107, "Invalid chars in IP %s", str);
430	734		return 0;
431			}
432			}
433
434			/* Starts or ends with '.'. */
435
436	1182	100	if (str[0] == '.') {
437	1		NI_set_Error_Errno(103, "Invalid IP %s - starts with a dot", str);
438	1		return 0;
439			}
440
441	1181	100	if (str[len - 1] == '.') {
442	1		NI_set_Error_Errno(104, "Invalid IP %s - ends with a dot", str);
443	1		return 0;
444			}
445
446			/* Contains more than four quads (octets). */
447
448	19155	100	for (i = 0; i < len; i++) {
449	17976	100	if (str[i] == '.') {
450	3321	100	if (quads == 3) {
451	1		NI_set_Error_Errno(105, "Invalid IP address %s", str);
452	1		return 0;
453			}
454	3320		quadspots[quads] = i + 1;
455	3320		quads++;
456			}
457			}
458
459			/* Contains an empty quad. */
460
461	17963	100	for (i = 0; i < (len - 1); i++) {
462	16785	100	if ((str[i] == '.') && (str[i + 1] == '.')) {
		100
463	1		NI_set_Error_Errno(106, "Empty quad in IP address %s", str);
464	1		return 0;
465			}
466			}
467
468			/* Contains an invalid quad value. */
469
470	5661	100	for (cq_index = 0; cq_index <= quads; cq_index++) {
471	4492	100	i = (cq_index > 0) ? (quadspots[cq_index - 1]) : 0;
472
473	4492		endptr = NULL;
474
475	4492		current_quad = strtol(str + i, &endptr, 10);
476	4492	100	if (STRTOL_FAILED(current_quad, str + i, endptr)
		50
		50
		100
		50
477	4489	50	\|\| (!(current_quad >= 0 && current_quad < 256))) {
		100
478	9		NI_set_Error_Errno(107, "Invalid quad in IP address "
479			"%s - %d", str, current_quad);
480	9		return 0;
481			}
482			}
483
484	1918		return 1;
485			}
486
487			/**
488			* NI_ip_is_ipv6(): check whether string is an IPv6 address.
489			* @str: the IP address string.
490			*/
491			int
492	861		NI_ip_is_ipv6(const char *str)
493			{
494			int i;
495			int len;
496	861		int octs = 0;
497			int octspots[8];
498			int oct_index;
499			const char *double_colon;
500			const char *next_oct;
501			const char *cc;
502			int count;
503			int is_hd;
504			int max_colons;
505
506	861		len = strlen(str);
507
508	861		double_colon = strstr(str, "::");
509	861	100	max_colons = (double_colon == NULL) ? 7 : 8;
510
511			/* Store a pointer to the next character after each ':' in
512			* octspots. */
513
514	33659	100	for (i = 0; i < len; i++) {
515	32800	100	if (str[i] == ':') {
516	5544	100	if (octs == max_colons) {
517	2		return 0;
518			}
519	5542		octspots[octs++] = i + 1;
520			}
521			}
522
523	859	100	if (!octs) {
524	12		return 0;
525			}
526
527	7216	100	for (oct_index = 0; oct_index <= octs; oct_index++) {
528	6372	100	i = (oct_index > 0) ? (octspots[oct_index - 1]) : 0;
529
530			/* Empty octet. */
531
532	6372	100	if (str[i] == ':') {
533	119		continue;
534			}
535	6253	100	if (strlen(str + i) == 0) {
536	68		continue;
537			}
538
539			/* Last octet can be an IPv4 address. */
540
541	6185		cc = str + i;
542	6185	100	if ((oct_index == octs) && NI_ip_is_ipv4(cc)) {
		100
543	53		continue;
544			}
545
546			/* 1-4 hex digits. */
547
548	6132		next_oct = strchr(str + i, ':');
549	6132	100	if (next_oct == NULL) {
550	724		next_oct = (str + len);
551			}
552
553	6132		count = next_oct - cc;
554	6132		is_hd = 1;
555
556	30568	100	while (cc != next_oct) {
557	24438	100	if (!isxdigit(*cc)) {
558	2		is_hd = 0;
559	2		break;
560			}
561	24436		cc++;
562			}
563
564	6132	100	if (is_hd && (count <= 4)) {
		100
565	6129		continue;
566			}
567
568	3		NI_set_Error_Errno(108, "Invalid IP address %s", str);
569	3		return 0;
570			}
571
572			/* Starts or ends with ':'. */
573
574	844	100	if ((str[0] == ':') && (str[1] != ':')) {
		100
575	1		NI_set_Error_Errno(109, "Invalid address %s "
576			"(starts with :)", str);
577	1		return 0;
578			}
579
580	843	100	if ((str[len - 1] == ':') && (str[len - 2] != ':')) {
		100
581	1		NI_set_Error_Errno(110, "Invalid address %s "
582			"(ends with :)", str);
583	1		return 0;
584			}
585
586			/* Contains more than one '::'. */
587
588	842	100	if ((double_colon != NULL) && (strstr(double_colon + 1, "::"))) {
		100
589	1		NI_set_Error_Errno(111, "Invalid address %s "
590			"(More than one :: pattern)", str);
591	1		return 0;
592			}
593
594			/* Doesn't contain '::', though it has fewer than eight segments. */
595
596	841	100	if ((octs != 7) && (double_colon == NULL)) {
		100
597	1		NI_set_Error_Errno(112, "Invalid number of octets %s", str);
598	1		return 0;
599			}
600
601	861		return 1;
602			}
603
604			/**
605			* NI_ip_get_version(): return the version of the IP address string.
606			* @str: the IP address string.
607			*
608			* Returns 0 if the string is neither an IPv4 nor an IPv6 address
609			* string.
610			*/
611			int
612	1952		NI_ip_get_version(const char *str)
613			{
614	1952	100	if ((!strchr(str, ':')) && NI_ip_is_ipv4(str)) {
		100
615	1104		return 4;
616	848	100	} else if (NI_ip_is_ipv6(str)) {
617	835		return 6;
618			} else {
619	13		return 0;
620			}
621			}
622
623			/**
624			* NI_ip_get_mask(): make bitstring network mask.
625			* @len: the mask's prefix length.
626			* @version: the mask's IP address version.
627			* @buf: the bitstring mask buffer.
628			*
629			* If @len is larger than the number of bits for an IP address of the
630			* specified version, then @len is set to equal that number of bits.
631			* So if 48 were specified for @len for an IPv4 address, it would be
632			* set to 32. This function does not null-terminate the buffer. The
633			* buffer must have 32 or 128 characters' capacity for IPv4 and IPv6
634			* respectively.
635			*/
636			int
637	144		NI_ip_get_mask(int len, int version, char *buf)
638			{
639			int size;
640
641	144	100	if (!version) {
642	1		NI_set_Error_Errno(101, "Cannot determine IP version");
643	1		return 0;
644			}
645
646	143		size = NI_iplengths(version);
647
648	143	100	if (len < 0) {
649	1		len = 0;
650	142	100	} else if (len > size) {
651	2		len = size;
652			}
653
654	143		memset(buf, '1', len);
655	143		memset(buf + len, '0', (size - len));
656
657	143		return 1;
658			}
659
660			/**
661			* NI_ip_last_address_ipv6(): get last address of prefix.
662			* @ip: the beginning IP address.
663			* @len: the prefix length.
664			* @buf: N128 integer buffer for the last address.
665			*/
666			int
667	47		NI_ip_last_address_ipv6(n128_t ip, int len, n128_t buf)
668			{
669			int i;
670
671	47		memcpy(buf, ip, sizeof(*ip));
672
673	47	100	len = (len == 0) ? 128 : (128 - len);
674
675	4529	100	for (i = 0; i < len; i++) {
676	4482		n128_setbit(buf, i);
677			}
678
679	47		return 1;
680			}
681
682			/**
683			* NI_ip_last_address_ipv4(): get last address of prefix.
684			* @ip: the beginning IP address.
685			* @len: the prefix length.
686			*/
687			unsigned long
688	61		NI_ip_last_address_ipv4(unsigned long ip, int len)
689			{
690			unsigned long mask;
691
692	61	100	mask = (len == 0) ? 0xFFFFFFFF : ((1 << (32 - len)) - 1);
693	61		return ip \| mask;
694			}
695
696			/**
697			* NI_ip_last_address_bin(): make last address of prefix as a bitstring.
698			* @bitstr: the beginning IP address as a bitstring.
699			* @len: the prefix length.
700			* @version: the IP address version.
701			* @buf: the last address bitstring buffer.
702			*
703			* This function does not null-terminate the buffer. The buffer must
704			* have 32 or 128 characters' capacity for IPv4 and IPv6 respectively.
705			*/
706			int
707	28		NI_ip_last_address_bin(const char bitstr, int len, int version, char buf)
708			{
709			int size;
710
711	28	100	if (!version) {
712	1		NI_set_Error_Errno(101, "Cannot determine IP version");
713	1		return 0;
714			}
715
716	27		size = NI_iplengths(version);
717
718	27	100	if ((len < 0) \|\| (len > size)) {
		100
719	3		len = size;
720			}
721
722	27		strncpy(buf, bitstr, len);
723	27		memset(buf + len, '1', (size - len));
724
725	27		return 1;
726			}
727
728			/**
729			* NI_ip_bincomp(): compare two bitstrings.
730			* @bitstr_1: first bitstring.
731			* @op_str: the comparator as a string.
732			* @bitstr_2: second bitstring.
733			* @result: a pointer to an integer.
734			*
735			* The bitstrings and the comparator must be null-terminated. The
736			* comparator must be one of 'gt', 'ge', 'lt', and 'le'. 'gt' means
737			* 'greater than', 'ge' means 'greater than or equal to', 'lt' means
738			* 'less than', 'le' means 'less than or equal to'. Returns 1 or 0
739			* depending on whether the strings were able to be compared
740			* successfully. If the comparison was able to be made, the result of
741			* the comparison is stored in @result. This function will not compare
742			* two bitstrings of different lengths.
743			*/
744			int
745	954		NI_ip_bincomp(const char bitstr_1, const char op_str,
746			const char bitstr_2, int result)
747			{
748			const char *b;
749			const char *e;
750			int op;
751			int res;
752
753	1908		op = (!strcmp(op_str, "gt")) ? GT
754	1903	100	: (!strcmp(op_str, "lt")) ? LT
755	1888	100	: (!strcmp(op_str, "le")) ? LE
756	948	100	: (!strcmp(op_str, "ge")) ? GE
757	9	100	: 0;
758
759	954	100	if (!op) {
760	2		NI_set_Error_Errno(131, "Invalid Operator %s", op_str);
761	2		return 0;
762			}
763
764	952	100	if ((op == GT) \|\| (op == GE)) {
		100
765	12		b = bitstr_1;
766	12		e = bitstr_2;
767			} else {
768	940		b = bitstr_2;
769	940		e = bitstr_1;
770			}
771
772	952	100	if (strlen(b) != (strlen(e))) {
773	2		NI_set_Error_Errno(130, "IP addresses of different length");
774	2		return 0;
775			}
776
777	950		res = strcmp(b, e);
778
779	950		*result =
780	20	100	(!res && ((op == GE) \|\| (op == LE)))
		100
781			? 1
782	970	100	: (res > 0);
		100
783
784	950		return 1;
785			}
786
787			/**
788			* NI_ip_is_overlap_ipv6(): get overlap status of two ranges.
789			* @begin_1: beginning address of first range.
790			* @end_1: ending address of first range.
791			* @begin_2: beginning address of second range.
792			* @end_2: ending address of second range.
793			* @result: a pointer to an integer.
794			*/
795			void
796	15		NI_ip_is_overlap_ipv6(n128_t begin_1, n128_t end_1,
797			n128_t begin_2, n128_t end_2, int *result)
798			{
799			int res;
800
801	15	100	if (!n128_cmp(begin_1, begin_2)) {
802	5	100	if (!n128_cmp(end_1, end_2)) {
803	2		*result = IP_IDENTICAL;
804	2		return;
805			}
806	3		res = n128_cmp(end_1, end_2);
807	3		*result = (res < 0) ? IP_A_IN_B_OVERLAP
808	3	100	: IP_B_IN_A_OVERLAP;
809	3		return;
810			}
811
812	10	100	if (!n128_cmp(end_1, end_2)) {
813	2		res = n128_cmp(begin_1, begin_2);
814	2		*result = (res < 0) ? IP_B_IN_A_OVERLAP
815	2	100	: IP_A_IN_B_OVERLAP;
816	2		return;
817			}
818
819	8		res = n128_cmp(begin_1, begin_2);
820	8	100	if (res < 0) {
821	5		res = n128_cmp(end_1, begin_2);
822	5	100	if (res < 0) {
823	2		*result = IP_NO_OVERLAP;
824	2		return;
825			}
826	3		res = n128_cmp(end_1, end_2);
827	3		*result = (res < 0) ? IP_PARTIAL_OVERLAP
828	3	100	: IP_B_IN_A_OVERLAP;
829	3		return;
830			}
831
832	3		res = n128_cmp(end_2, begin_1);
833	3	100	if (res < 0) {
834	1		*result = IP_NO_OVERLAP;
835	1		return;
836			}
837
838	2		res = n128_cmp(end_2, end_1);
839	2		*result = (res < 0) ? IP_PARTIAL_OVERLAP
840	2	100	: IP_A_IN_B_OVERLAP;
841
842	2		return;
843			}
844
845			/**
846			* NI_ip_is_overlap_ipv4(): get overlap status of two ranges.
847			* @begin_1: beginning address of first range.
848			* @end_1: ending address of first range.
849			* @begin_2: beginning address of second range.
850			* @end_2: ending address of second range.
851			* @result: a pointer to an integer.
852			*/
853			void
854	13		NI_ip_is_overlap_ipv4(unsigned long begin_1, unsigned long end_1,
855			unsigned long begin_2, unsigned long end_2,
856			int *result)
857			{
858	13	100	if (begin_1 == begin_2) {
859	4	100	if (end_1 == end_2) {
860	2		*result = IP_IDENTICAL;
861	2		return;
862			}
863	2		*result =
864			(end_1 < end_2)
865			? IP_A_IN_B_OVERLAP
866	2	100	: IP_B_IN_A_OVERLAP;
867	2		return;
868			}
869
870	9	100	if (end_1 == end_2) {
871	2		*result =
872			(begin_1 < begin_2)
873			? IP_B_IN_A_OVERLAP
874	2	100	: IP_A_IN_B_OVERLAP;
875	2		return;
876			}
877
878	7	100	if (begin_1 < begin_2) {
879	4	100	if (end_1 < begin_2) {
880	2		*result = IP_NO_OVERLAP;
881	2		return;
882			}
883	2		*result =
884			(end_1 < end_2)
885			? IP_PARTIAL_OVERLAP
886	2	100	: IP_B_IN_A_OVERLAP;
887	2		return;
888			}
889
890	3	100	if (end_2 < begin_1) {
891	1		*result = IP_NO_OVERLAP;
892	1		return;
893			}
894
895	2		*result =
896			(end_2 < end_1)
897			? IP_PARTIAL_OVERLAP
898	2	100	: IP_A_IN_B_OVERLAP;
899
900	2		return;
901			}
902
903			/**
904			* NI_ip_is_overlap(): get overlap status of two ranges.
905			* @begin_1: beginning bitstring IP address for first range.
906			* @end_1: ending bitstring IP address for first range.
907			* @begin_2: beginning bitstring IP address for second range.
908			* @end_2: ending bitstring IP address for second range.
909			* @result: a pointer to an integer.
910			*
911			* Each bitstring must be null-terminated. Returns 1 or 0 depending
912			* on whether the ranges are able to be compared successfully. If the
913			* overlap status is able to be determined, stores that status in
914			* @result. Returns 0 if the bitstrings are not all of equal length.
915			* The possible overlap statuses are NO_OVERLAP, IP_PARTIAL_OVERLAP,
916			* IP_A_IN_B_OVERLAP (first range completely contained within second
917			* range), IP_B_IN_A_OVERLAP (second range completely contained within
918			* first range) and IP_IDENTICAL.
919			*/
920			int
921	23		NI_ip_is_overlap(const char begin_1, const char end_1,
922			const char begin_2, const char end_2, int *result)
923			{
924			int b1_len;
925			int b2_len;
926	23		int res = 0;
927			n128_t begin_1_n128;
928			n128_t end_1_n128;
929			n128_t begin_2_n128;
930			n128_t end_2_n128;
931			unsigned long begin_1_ulong;
932			unsigned long begin_2_ulong;
933			unsigned long end_1_ulong;
934			unsigned long end_2_ulong;
935
936	23		b1_len = strlen(begin_1);
937	23		b2_len = strlen(begin_2);
938
939	44	100	if (!( (b1_len == (int) strlen(end_1))
		100
940	22	100	&& (b2_len == (int) strlen(end_2))
941			&& (b1_len == b2_len))) {
942	3		NI_set_Error_Errno(130, "IP addresses of different length");
943	3		return 0;
944			}
945
946	20		NI_ip_bincomp(begin_1, "le", end_1, &res);
947	20	100	if (!res) {
948	1		NI_set_Error_Errno(140, "Invalid range %s - %s", begin_1, end_1);
949	1		return 0;
950			}
951
952	19		NI_ip_bincomp(begin_2, "le", end_2, &res);
953	19	100	if (!res) {
954	1		NI_set_Error_Errno(140, "Invalid range %s - %s", begin_2, end_2);
955	1		return 0;
956			}
957
958			/* IPv4-specific version (avoids using N128). */
959
960	18	100	if (b1_len <= 32) {
961	8		begin_1_ulong = NI_bintoint(begin_1, b1_len);
962	8		begin_2_ulong = NI_bintoint(begin_2, b1_len);
963	8		end_1_ulong = NI_bintoint(end_1, b1_len);
964	8		end_2_ulong = NI_bintoint(end_2, b1_len);
965	8		NI_ip_is_overlap_ipv4(begin_1_ulong, end_1_ulong,
966			begin_2_ulong, end_2_ulong, result);
967	8		return 1;
968			}
969
970			/* IPv6 version (using N128). */
971
972	10		n128_set_str_binary(&begin_1_n128, begin_1, b1_len);
973	10		n128_set_str_binary(&begin_2_n128, begin_2, b1_len);
974	10		n128_set_str_binary(&end_1_n128, end_1, b1_len);
975	10		n128_set_str_binary(&end_2_n128, end_2, b1_len);
976
977	10		NI_ip_is_overlap_ipv6(&begin_1_n128, &end_1_n128,
978			&begin_2_n128, &end_2_n128, result);
979
980	23		return 1;
981			}
982
983			/**
984			* NI_ip_check_prefix_ipv6(): check whether prefix length is valid.
985			* @ip: IP address.
986			* @len: the prefix length.
987			*/
988			int
989	50		NI_ip_check_prefix_ipv6(n128_t *ip, int len)
990			{
991			n128_t mask;
992			char buf[IPV6_BITSTR_LEN];
993			int i;
994
995	50	100	if ((len < 0) \|\| (len > 128)) {
		100
996	2		NI_set_Error_Errno(172, "Invalid prefix length /%d", len);
997	2		return 0;
998			}
999
1000	48		n128_set_ui(&mask, 0);
1001	4657	100	for (i = 0; i < (128 - len); i++) {
1002	4609		n128_setbit(&mask, i);
1003			}
1004	48		n128_and(&mask, ip);
1005
1006	48	100	if (n128_cmp_ui(&mask, 0)) {
1007	1		NI_ip_n128tobin(ip, len, buf);
1008	1		buf[len] = '\0';
1009	1		NI_set_Error_Errno(171, "Invalid prefix %s/%d", buf, len);
1010	1		return 0;
1011			}
1012
1013	50		return 1;
1014			}
1015
1016			/**
1017			* NI_ip_check_prefix_ipv4(): check whether prefix length is valid.
1018			* @ip: IP address.
1019			* @len: the prefix length.
1020			*/
1021			int
1022	64		NI_ip_check_prefix_ipv4(unsigned long ip, int len)
1023			{
1024			unsigned long mask;
1025
1026	64	100	if ((len < 0) \|\| (len > 32)) {
		100
1027	2		NI_set_Error_Errno(172, "Invalid prefix length /%d", len);
1028	2		return 0;
1029			}
1030
1031	62	100	mask = (len == 0) ? 0xFFFFFFFF : ((1 << (32 - len)) - 1);
1032
1033	62	100	if ((ip & mask) != 0) {
1034	1		NI_set_Error_Errno(171, "Invalid prefix %u/%d", ip, len);
1035	1		return 0;
1036			}
1037
1038	61		return 1;
1039			}
1040
1041			/**
1042			* NI_ip_check_prefix(): check whether prefix length is valid for address.
1043			* @bitstr: the bitstring IP address.
1044			* @len: the prefix length.
1045			* @version: the IP address version.
1046			*
1047			* The bitstring must be null-terminated.
1048			*/
1049			int
1050	160		NI_ip_check_prefix(const char *bitstr, int len, int version)
1051			{
1052			int iplen;
1053			const char *c;
1054
1055	160	100	if (len < 0) {
1056	1		NI_set_Error_Errno(172, "Invalid prefix length /%d", len);
1057	1		return 0;
1058			}
1059
1060	159		iplen = strlen(bitstr);
1061
1062	159	100	if (len > iplen) {
1063	1		NI_set_Error_Errno(170, "Prefix length %d is longer than "
1064			"IP address (%d)", len, iplen);
1065	1		return 0;
1066			}
1067
1068	158		c = bitstr + len;
1069
1070	6218	100	while (*c != '\0') {
1071	6062	100	if (*c != '0') {
1072	2		NI_set_Error_Errno(171, "Invalid prefix %s/%d", bitstr, len);
1073	2		return 0;
1074			}
1075	6060		c++;
1076			}
1077
1078	156	100	if (iplen != NI_iplengths(version)) {
1079	1		NI_set_Error_Errno(172, "Invalid prefix length /%d", len);
1080	1		return 0;
1081			}
1082
1083	155		return 1;
1084			}
1085
1086			/**
1087			* NI_ip_get_prefix_length_ipv4(): get prefix length for a given range.
1088			* @begin: first IP address.
1089			* @end: second IP address.
1090			* @bits: number of bits to check.
1091			* @len: a pointer to an integer.
1092			*/
1093			void
1094	5561		NI_ip_get_prefix_length_ipv4(unsigned long begin, unsigned long end,
1095			int bits, int *len)
1096			{
1097			int i;
1098	5561		int res = 0;
1099
1100	110742	100	for (i = 0; i < bits; i++) {
1101	110732	100	if ((begin & 1) == (end & 1)) {
1102	5551		res = bits - i;
1103	5551		break;
1104			}
1105	105181		begin >>= 1;
1106	105181		end >>= 1;
1107			}
1108
1109	5561		*len = res;
1110	5561		}
1111
1112			/**
1113			* NI_ip_get_prefix_length_ipv6(): get prefix length for a given range.
1114			* @num1: first IP address as an N128 integer.
1115			* @num2: second IP address as an N128 integer.
1116			* @bits: number of bits to check
1117			* @len: a pointer to an integer.
1118			*
1119			* Returns 1 or 0 depending on whether the prefix length could be
1120			* calculated. Stores the prefix length in @len if it is able to be
1121			* calculated.
1122			*/
1123			void
1124	15995		NI_ip_get_prefix_length_ipv6(n128_t num1, n128_t num2, int bits, int *len)
1125			{
1126			int i;
1127	15995		int res = 0;
1128
1129	1316809	100	for (i = 0; i < bits; i++) {
1130	1316777	100	if (n128_tstbit(num1, i) == n128_tstbit(num2, i)) {
1131	15963		res = bits - i;
1132	15963		break;
1133			}
1134			}
1135
1136	15995		*len = res;
1137	15995		}
1138
1139			/**
1140			* NI_ip_get_prefix_length(): get prefix length for a given range.
1141			* @bitstr_1: first IP address as a bitstring.
1142			* @bitstr_2: second IP address as a bitstring.
1143			* @len: a pointer to an integer.
1144			*
1145			* Returns 1 or 0 depending on whether the prefix length could be
1146			* calculated. Stores the prefix length in @len if it is able to be
1147			* calculated.
1148			*/
1149			int
1150	15		NI_ip_get_prefix_length(const char bitstr_1, const char bitstr_2, int *len)
1151			{
1152			int bin1_len;
1153			int bin2_len;
1154			int i;
1155			int res;
1156
1157	15		bin1_len = strlen(bitstr_1);
1158	15		bin2_len = strlen(bitstr_2);
1159
1160	15	100	if (bin1_len != bin2_len) {
1161	1		NI_set_Error_Errno(130, "IP addresses of different length");
1162	1		return 0;
1163			}
1164
1165	14		res = bin1_len;
1166
1167	245	100	for (i = (bin1_len - 1); i >= 0; i--) {
1168	243	100	if (bitstr_1[i] == bitstr_2[i]) {
1169	12		res = (bin1_len - 1 - i);
1170	12		break;
1171			}
1172			}
1173
1174	14		*len = res;
1175	14		return 1;
1176			}
1177
1178			/**
1179			* NI_ip_inttoip_ipv4(): make IPv4 address from integer.
1180			* @n: the IP address as a number.
1181			* @buf: the IP address buffer.
1182			*/
1183			void
1184	7544		NI_ip_inttoip_ipv4(unsigned long n, char *buf)
1185			{
1186	22632		sprintf(buf, "%lu.%lu.%lu.%lu", (n >> 24) & 0xFF,
1187	7544		(n >> 16) & 0xFF,
1188	7544		(n >> 8) & 0xFF,
1189			(n >> 0) & 0xFF);
1190	7544		}
1191
1192			/**
1193			* NI_ip_inttoip_ipv6(): make IPv6 address from integers.
1194			* @n1: the most significant 32 bits of the address.
1195			* @n2: the next-most significant 32 bits of the address.
1196			* @n3: the next-most significant 32 bits of the address.
1197			* @n4: the least significant 32 bits of the address.
1198			* @buf: the IP address buffer.
1199			*/
1200			void
1201	17525		NI_ip_inttoip_ipv6(unsigned long n1, unsigned long n2,
1202			unsigned long n3, unsigned long n4, char *buf)
1203			{
1204	140200		sprintf(buf, "%04x:%04x:%04x:%04x:%04x:%04x:%04x:%04x",
1205	17525		(unsigned int) (n1 >> 16) & 0xFFFF,
1206	17525		(unsigned int) (n1 ) & 0xFFFF,
1207	17525		(unsigned int) (n2 >> 16) & 0xFFFF,
1208	17525		(unsigned int) (n2 ) & 0xFFFF,
1209	17525		(unsigned int) (n3 >> 16) & 0xFFFF,
1210	17525		(unsigned int) (n3 ) & 0xFFFF,
1211	17525		(unsigned int) (n4 >> 16) & 0xFFFF,
1212	17525		(unsigned int) (n4 ) & 0xFFFF);
1213	17525		}
1214
1215			/**
1216			* NI_ip_inttoip_n128(): make IPv6 address from N128 integer.
1217			* @ip: IP address.
1218			* @buf: the IP address buffer.
1219			*/
1220			void
1221	774		NI_ip_inttoip_n128(n128_t ip, char buf)
1222			{
1223	774		NI_ip_inttoip_ipv6(ip->nums[0], ip->nums[1],
1224	1548		ip->nums[2], ip->nums[3], buf);
1225	774		}
1226
1227			/**
1228			* NI_ip_bintoip(): make IP address from bitstring.
1229			* @bitstr: the IP address as a bitstring.
1230			* @version: IP address version as integer.
1231			* @buf: the IP address buffer.
1232			*
1233			* The bitstring must be null-terminated. This function null-terminates the
1234			* buffer, so it has to have between eight and sixteen characters' capacity
1235			* (inclusive) for IPv4 addresses, depending on the value of the address, and
1236			* 40 characters' capacity for IPv6 addresses. Bitstrings that have fewer
1237			* characters than there are bits in the relevant version of IP address will be
1238			* treated as if they were left-padded with '0' characters until that number of
1239			* bits is met: e.g., passing "1" and 4 as the first two arguments to this
1240			* function will yield "0.0.0.1" in @buf.
1241			*/
1242			int
1243	16037		NI_ip_bintoip(const char bitstr, int version, char buf)
1244			{
1245			int size;
1246			int iplen;
1247			int longs;
1248			int i;
1249			int j;
1250			int excess;
1251			int bits;
1252			unsigned long nums[4];
1253
1254	16037		iplen = NI_iplengths(version);
1255	16037		size = strlen(bitstr);
1256	16037	100	if (size > iplen) {
1257	4		NI_set_Error_Errno(189, "Invalid IP length for "
1258			"binary IP %s", bitstr);
1259	4		return 0;
1260			}
1261
1262	16033	100	if (version == 4) {
1263	24		nums[0] = NI_bintoint(bitstr, size);
1264	24		NI_ip_inttoip_ipv4(nums[0], buf);
1265	24		return 1;
1266			}
1267
1268	80045	100	for (i = 0; i < 4; i++) {
1269	64036		nums[i] = 0;
1270			}
1271
1272	16009		excess = size % 32;
1273	16009		longs = (size / 32) + (!excess ? 0 : 1);
1274
1275	80020	100	for (i = (4 - longs), j = 0; i < 4; i++, j++) {
1276	64011		bits =
1277	16005	100	(i == (4 - longs) && excess)
1278			? excess
1279	80016	100	: 32;
1280	64011		nums[i] = NI_bintoint(bitstr + (j * 32), bits);
1281			}
1282
1283	16009		NI_ip_inttoip_ipv6(nums[0], nums[1], nums[2], nums[3], buf);
1284	16037		return 1;
1285			}
1286
1287			/**
1288			* NI_ip_binadd(): add two bitstring IP addresses.
1289			* @ip1: first bitstring IP address.
1290			* @ip2: second bitstring IP address.
1291			* @buf: result buffer.
1292			* @maxlen: maximum capacity of buffer.
1293			*
1294			* Both bitstrings must be null-terminated and of the same length as
1295			* each other. The result is stored as a bitstring and
1296			* null-terminated. The result will be of the length of the
1297			* bitstrings, regardless of the result of the addition.
1298			*/
1299			int
1300	17		NI_ip_binadd(const char ip1, const char ip2, char *buf, int maxlen)
1301			{
1302			n128_t num1;
1303			n128_t num2;
1304			int len1;
1305			int len2;
1306
1307	17		len1 = strlen(ip1);
1308	17		len2 = strlen(ip2);
1309
1310	17	100	if (len1 != len2) {
1311	3		NI_set_Error_Errno(130, "IP addresses of different length");
1312	3		return 0;
1313			}
1314	14	100	if (len1 > (maxlen - 1)) {
1315	2		return 0;
1316			}
1317
1318	12		n128_set_str_binary(&num1, ip1, len1);
1319	12		n128_set_str_binary(&num2, ip2, len2);
1320	12		n128_add(&num1, &num2);
1321	12		NI_ip_n128tobin(&num1, len1, buf);
1322
1323	12		buf[len2] = '\0';
1324	17		return 1;
1325			}
1326
1327			/**
1328			* NI_ip_range_to_prefix_ipv4(): get prefixes contained within range.
1329			* @begin: beginning address.
1330			* @end: ending address.
1331			* @version: IP address version.
1332			* @prefixes: prefix strings buffer.
1333			* @pcount: prefix count buffer.
1334			*
1335			* Will write at most 32 prefix strings to @prefixes.
1336			*/
1337			int
1338	519		NI_ip_range_to_prefix_ipv4(unsigned long begin, unsigned long end,
1339			int version, char *prefixes, int pcount)
1340			{
1341			unsigned long current;
1342			unsigned long mask;
1343
1344			unsigned long zeroes;
1345			int iplen;
1346			int res;
1347			int i;
1348			int prefix_length;
1349			char *new_prefix;
1350			char range[4];
1351
1352	519		current = 0;
1353	519		mask = 0;
1354
1355	519		iplen = NI_iplengths(version);
1356
1357	519		*pcount = 0;
1358
1359	5638	100	while (begin <= end) {
1360			/* Calculate the number of zeroes that exist on the right of
1361			* 'begin', and create a mask for that number of bits. */
1362	5561		zeroes = NI_trailing_zeroes(begin);
1363	5561		mask = 0;
1364
1365	113291	100	for (i = 0; i < (int) zeroes; i++) {
1366	107730		mask \|= (1 << i);
1367			}
1368
1369			/* Find the largest range (from 'begin' to 'current') that
1370			* does not exceed 'end'. */
1371
1372			do {
1373	8110		current = begin;
1374	8110		current \|= mask;
1375	8110		mask >>= 1;
1376	8110	100	} while (current > end);
1377
1378			/* Get the prefix length for the range and add the stringified
1379			* range to @prefixes. */
1380
1381	5561		NI_ip_get_prefix_length_ipv4(begin, current,
1382			iplen, &prefix_length);
1383
1384	5561		new_prefix = (char *) malloc(MAX_IPV4_RANGE_STR_LEN);
1385	5561	50	if (!new_prefix) {
1386	0		printf("NI_ip_range_to_prefix: malloc failed!\n");
1387	0		return 0;
1388			}
1389
1390	5561		prefixes[(*pcount)++] = new_prefix;
1391	5561		NI_ip_inttoip_ipv4(begin, new_prefix);
1392	5561		strcat(new_prefix, "/");
1393	5561		res = snprintf(range, 4, "%d", prefix_length);
1394	5561		strncat(new_prefix, range, res);
1395
1396	5561		begin = current + 1;
1397
1398			/* Do not continue getting prefixes if 'current' completely
1399			* comprises set bits. */
1400
1401	5561	100	if (current == 0xFFFFFFFF) {
1402	442		break;
1403			}
1404			}
1405
1406	519		return 1;
1407			}
1408
1409			/**
1410			* NI_ip_range_to_prefix_ipv6(): get prefixes contained within range.
1411			* @begin: beginning address.
1412			* @end: ending address.
1413			* @version: IP address version.
1414			* @prefixes: prefix strings buffer.
1415			* @pcount: prefix count buffer.
1416			*
1417			* Will write at most 128 prefix strings to @prefixes.
1418			*/
1419			int
1420	411		NI_ip_range_to_prefix_ipv6(n128_t begin, n128_t end,
1421			int version, char *prefixes, int pcount)
1422			{
1423			n128_t current;
1424			n128_t mask;
1425			unsigned long zeroes;
1426			int iplen;
1427			unsigned long res;
1428			int i;
1429			int prefix_length;
1430			char *new_prefix;
1431			char tempip[IPV6_BITSTR_LEN];
1432			char range[4];
1433
1434	411		iplen = NI_iplengths(version);
1435
1436	411		tempip[iplen] = '\0';
1437	411		*pcount = 0;
1438
1439	16030	100	while (n128_cmp(begin, end) <= 0) {
1440	15995	50	if (*pcount == 128) {
1441	0		return 0;
1442			}
1443
1444			/* Calculate the number of zeroes that exist on the right of
1445			* 'begin', and create a mask for that number of bits. */
1446
1447	15995		zeroes = n128_scan1(begin);
1448	15995	100	zeroes = ((zeroes == INT_MAX) ? (unsigned) iplen : zeroes) - 1;
1449
1450	15995		n128_set_ui(&mask, 0);
1451	1319844	100	for (i = 0; i < ((int) zeroes + 1); i++) {
1452	1303849		n128_setbit(&mask, i);
1453			}
1454
1455			/* Find the largest range (from 'begin' to 'current') that
1456			* does not exceed 'end'. */
1457
1458			do {
1459	19030		n128_set(¤t, begin);
1460	19030		n128_ior(¤t, &mask);
1461	19030		n128_clrbit(&mask, zeroes);
1462	19030		zeroes--;
1463	19030	100	} while (n128_cmp(¤t, end) > 0);
1464
1465			/* Get the prefix length for the range and add the stringified
1466			* range to @prefixes. */
1467
1468	15995		NI_ip_get_prefix_length_ipv6(begin, ¤t,
1469			iplen, &prefix_length);
1470
1471	15995		new_prefix = (char *) malloc(MAX_IPV6_RANGE_STR_LEN);
1472	15995	50	if (!new_prefix) {
1473	0		printf("NI_ip_range_to_prefix: malloc failed!\n");
1474	0		return 0;
1475			}
1476
1477	15995		prefixes[(*pcount)++] = new_prefix;
1478	15995		NI_ip_n128tobin(begin, iplen, tempip);
1479	15995		NI_ip_bintoip(tempip, version, new_prefix);
1480	15995		strcat(new_prefix, "/");
1481	15995		res = snprintf(range, 4, "%d", prefix_length);
1482	15995		strncat(new_prefix, range, res);
1483
1484	15995		n128_set(begin, ¤t);
1485	15995		n128_add_ui(begin, 1);
1486
1487			/* Do not continue getting prefixes if 'current' completely
1488			* comprises set bits. */
1489
1490	15995		res = n128_scan0(¤t);
1491	15995	100	if (res == INT_MAX) {
1492	376		break;
1493			}
1494			}
1495
1496	411		return 1;
1497			}
1498
1499			/**
1500			* NI_ip_range_to_prefix(): get prefixes contained within range.
1501			* @begin: first IP address as a bitstring.
1502			* @end: second IP address as a bitstring.
1503			* @version: IP address version.
1504			* @prefixes: prefix strings buffer.
1505			* @pcount: prefix count buffer.
1506			*
1507			* Both bitstrings must be null-terminated. If unsure of the number of
1508			* prefixes that will be created, @prefixes must contain space for 128
1509			* character pointers. Returns 1/0 depending on whether it completed
1510			* successfully.
1511			*/
1512			int
1513	923		NI_ip_range_to_prefix(const char begin, const char end,
1514			int version, char *prefixes, int pcount)
1515			{
1516			n128_t begin_n128;
1517			n128_t end_n128;
1518			unsigned long begin_ulong;
1519			unsigned long end_ulong;
1520			int iplen;
1521			int res;
1522
1523	923	100	if (!version) {
1524	2		NI_set_Error_Errno(101, "Cannot determine IP version");
1525	2		return 0;
1526			}
1527
1528	921	100	if (strlen(begin) != strlen(end)) {
1529	1		NI_set_Error_Errno(130, "IP addresses of different length");
1530	1		return 0;
1531			}
1532
1533	920		iplen = NI_iplengths(version);
1534	920	100	if (!iplen) {
1535	1		return 0;
1536			}
1537
1538	919	100	if (version == 4) {
1539	513		begin_ulong = NI_bintoint(begin, 32);
1540	513		end_ulong = NI_bintoint(end, 32);
1541	513		return NI_ip_range_to_prefix_ipv4(begin_ulong, end_ulong,
1542			version, prefixes, pcount);
1543			}
1544
1545	406		n128_set_str_binary(&begin_n128, begin, strlen(begin));
1546	406		n128_set_str_binary(&end_n128, end, strlen(end));
1547
1548	406		res = NI_ip_range_to_prefix_ipv6(&begin_n128, &end_n128,
1549			version, prefixes, pcount);
1550
1551	923		return res;
1552			}
1553
1554			/**
1555			* NI_ip_aggregate_tail(): post-processing after version-specific aggregation.
1556			* @res: the result of the relevant ip_range_to_prefix function.
1557			* @prefixes: prefix strings buffer.
1558			* @pcount: prefix count.
1559			* @version: IP address version.
1560			* @buf: the buffer for the new range.
1561			*
1562			* If @res is false, then frees the prefixes and returns zero. If no
1563			* prefixes were returned, returns zero. If more than one prefix was
1564
1565			* returned, frees the prefixes and returns 161. Otherwise, populates
1566			* the buffer (null-terminated) with the first range from @prefixes
1567			* and returns 1.
1568			*/
1569			int
1570	11		NI_ip_aggregate_tail(int res, char **prefixes, int pcount,
1571			int version, char *buf)
1572			{
1573			int i;
1574			int len;
1575			int max;
1576
1577	11	50	if (!res) {
1578	0	0	for (i = 0; i < pcount; i++) {
1579	0		free(prefixes[i]);
1580			}
1581	0		return 0;
1582			}
1583
1584	11	100	if (pcount == 0) {
1585	1		return 0;
1586			}
1587
1588	10	100	if (pcount > 1) {
1589	33	100	for (i = 0; i < pcount; i++) {
1590	32		free(prefixes[i]);
1591			}
1592	1		return 161;
1593			}
1594
1595	9		len = strlen(*prefixes);
1596	9		max = (version == 4) ? MAX_IPV4_RANGE_STR_LEN - 1
1597	9	100	: MAX_IPV6_RANGE_STR_LEN - 1;
1598	9	50	if (len > max) {
1599	0		len = max;
1600			}
1601
1602	9		strncpy(buf, *prefixes, len);
1603	9		buf[len] = 0;
1604
1605	9		return 1;
1606			}
1607
1608			/**
1609			* NI_ip_aggregate_ipv6(): get the aggregate range of two ranges as a string.
1610			* @begin_1: beginning N128 integer IP address for first range.
1611			* @end_1: ending N128 integer IP address for first range.
1612			* @begin_2: beginning N128 integer IP address for second range.
1613			* @end_2: ending N128 integer IP address for second range.
1614			* @version: IP address version.
1615			* @buf: the buffer for the new range.
1616			*
1617			* See NI_ip_aggregate().
1618			*/
1619			int
1620	7		NI_ip_aggregate_ipv6(n128_t b1, n128_t e1, n128_t b2, n128_t e2,
1621			int version, char *buf)
1622			{
1623			char *prefixes[128];
1624			int pcount;
1625			int res;
1626
1627	7		n128_add_ui(e1, 1);
1628	7	100	if (n128_cmp(e1, b2)) {
1629	2		return 160;
1630			}
1631
1632	5		pcount = 0;
1633	5		res = NI_ip_range_to_prefix_ipv6(b1, e2, version, prefixes, &pcount);
1634	7		return NI_ip_aggregate_tail(res, prefixes, pcount, version, buf);
1635			}
1636
1637			/**
1638			* NI_ip_aggregate_ipv4(): get the aggregate range of two ranges as a string.
1639			* @begin_1: beginning integer IP address for first range.
1640			* @end_1: ending integer IP address for first range.
1641			* @begin_2: beginning integer IP address for second range.
1642			* @end_2: ending integer IP address for second range.
1643			* @version: IP address version.
1644			* @buf: the buffer for the new range.
1645			*
1646			* See NI_ip_aggregate().
1647			*/
1648			int
1649	7		NI_ip_aggregate_ipv4(unsigned long b1, unsigned long e1,
1650			unsigned long b2, unsigned long e2,
1651			int version, char *buf)
1652			{
1653			char *prefixes[128];
1654			int pcount;
1655			int res;
1656
1657	7	100	if (e1 + 1 != b2) {
1658	1		return 160;
1659			}
1660
1661	6		pcount = 0;
1662	6		res = NI_ip_range_to_prefix_ipv4(b1, e2, version, prefixes, &pcount);
1663	7		return NI_ip_aggregate_tail(res, prefixes, pcount, version, buf);
1664			}
1665
1666			/**
1667			* NI_ip_aggregate(): get the aggregate range of two ranges as a string.
1668			* @begin_1: beginning bitstring IP address for first range.
1669			* @end_1: ending bitstring IP address for first range.
1670			* @begin_2: beginning bitstring IP address for second range.
1671			* @end_2: ending bitstring IP address for second range.
1672			* @version: IP address version.
1673			* @buf: the buffer for the new range.
1674			*
1675			* Returns zero and sets error messages if the ranges are not
1676			* contiguous or the aggregate of the ranges cannot be represented as
1677			* a single prefix. Otherwise, populates the buffer with the aggregate
1678			* of the two ranges as a prefix range string (e.g. '1.0.0.0/8').
1679			*/
1680			int
1681	14		NI_ip_aggregate(const char b1, const char e1,
1682			const char b2, const char e2,
1683			int version, char *buf)
1684			{
1685			int res;
1686			int i;
1687			n128_t b1_n128;
1688			n128_t e1_n128;
1689			n128_t b2_n128;
1690			n128_t e2_n128;
1691			unsigned long b1_ulong;
1692			unsigned long e1_ulong;
1693			unsigned long b2_ulong;
1694			unsigned long e2_ulong;
1695			const char *addr_args[4];
1696	14		addr_args[0] = b1;
1697	14		addr_args[1] = b2;
1698	14		addr_args[2] = e1;
1699	14		addr_args[3] = e2;
1700
1701	14	100	if (!version) {
1702	1		NI_set_Error_Errno(101, "Cannot determine IP version for %s",
1703			b1);
1704	1		return 0;
1705	13	100	} else if (version == 4) {
1706	31	100	for (i = 0; i < 4; i++) {
1707	25	100	if (strlen(addr_args[i]) != 32) {
1708	1		NI_set_Error_Errno(107, "Invalid IP address %s",
1709			addr_args[i]);
1710	1		return 0;
1711			}
1712			}
1713	6		b1_ulong = NI_bintoint(b1, 32);
1714	6		e1_ulong = NI_bintoint(e1, 32);
1715	6		b2_ulong = NI_bintoint(b2, 32);
1716	6		e2_ulong = NI_bintoint(e2, 32);
1717	6		res = NI_ip_aggregate_ipv4(b1_ulong, e1_ulong,
1718			b2_ulong, e2_ulong, version, buf);
1719			} else {
1720	26	100	for (i = 0; i < 4; i++) {
1721	21	100	if (strlen(addr_args[i]) != 128) {
1722	1		NI_set_Error_Errno(108, "Invalid IP address %s",
1723			addr_args[i]);
1724	1		return 0;
1725			}
1726			}
1727	5		n128_set_str_binary(&b1_n128, b1, strlen(b1));
1728	5		n128_set_str_binary(&e1_n128, e1, strlen(e1));
1729	5		n128_set_str_binary(&b2_n128, b2, strlen(b2));
1730	5		n128_set_str_binary(&e2_n128, e2, strlen(e2));
1731	5		res = NI_ip_aggregate_ipv6(&b1_n128, &e1_n128,
1732			&b2_n128, &e2_n128, version, buf);
1733			}
1734
1735	11	100	if (res == 0) {
1736	1		return 0;
1737			}
1738	10	100	if (res == 160) {
1739	2		NI_set_Error_Errno(160, "Ranges not contiguous - %s - %s", e1, b2);
1740	2		return 0;
1741			}
1742	8	100	if (res == 161) {
1743	1		NI_set_Error_Errno(161, "%s - %s is not a single prefix", b1, e2);
1744	1		return 0;
1745			}
1746	14		return 1;
1747			}
1748
1749			/**
1750			* NI_ip_iptobin(): get bitstring from IP address.
1751			* @ip: single IP address as a string.
1752			* @version: IP address version.
1753			* @buf: bitstring buffer.
1754			*
1755			* Returns zero (and may also set Error/Errno) if the IP address is
1756			* invalid. If an IPv6 address is provided, it must be fully expanded
1757			* - IPv6 addresses like '0::0' or '0:0:0:0:0:0:0:0' will not be
1758			* handled correctly.
1759			*/
1760
1761			int
1762	2000		NI_ip_iptobin(const char ip, int ipversion, char buf)
1763			{
1764			int res;
1765			int j;
1766			int k;
1767			int y;
1768			int i;
1769			char c;
1770			int ncount;
1771			unsigned char ipv4[4];
1772
1773	2000	100	if (ipversion == 4) {
1774	1131		res = inet_pton4(ip, ipv4);
1775	1131	100	if (res == 0) {
1776	4		return 0;
1777			}
1778
1779	5635	100	for (j = 0; j < 4; j++) {
1780	40572	100	for (i = 0; i < 8; i++) {
1781	36064	100	buf[(j * 8) + i] =
1782	36064		((ipv4[j] & (1 << (8 - i - 1)))) ? '1' : '0';
1783			}
1784			}
1785	1127		return 1;
1786			} else {
1787	869		j = 0;
1788	869		ncount = 0;
1789	34618	100	while ((c = ip[j])) {
1790	33749	100	if (c != ':') {
1791	27701		ncount++;
1792			}
1793	33749		j++;
1794			}
1795	869	100	if (ncount != 32) {
1796	4		NI_set_Error_Errno(102, "Bad IP address %s", ip);
1797	4		return 0;
1798			}
1799
1800	865		i = -1;
1801	34499	100	for (j = 0; ip[j] != '\0'; j++) {
1802	33637	100	if (ip[j] == ':') {
1803	6031		continue;
1804			} else {
1805	27606		i++;
1806			}
1807
1808	27606		y = NI_hdtoi(ip[j]);
1809	27606	100	if (y == -1) {
1810	3		return 0;
1811			}
1812
1813	138015	100	for (k = 0; k < 4; k++) {
1814	110412	100	buf[ (i * 4) + k ] =
1815	110412		((y >> (3 - k)) & 1) ? '1' : '0';
1816			}
1817			}
1818	2000		return 1;
1819			}
1820			}
1821
1822			/**
1823			* NI_ip_expand_address_ipv4(): expand an IPv4 address.
1824			* @ip: the IPv4 address as a string.
1825			* @buf: the IP address buffer.
1826			*
1827			* The IPv4 address string must be null-terminated. The buffer will be
1828			* null-terminated on success.
1829			*/
1830			int
1831	969		NI_ip_expand_address_ipv4(const char ip, char buf)
1832			{
1833			int res;
1834			unsigned char ipv4[4];
1835
1836	969		res = inet_pton4(ip, ipv4);
1837	969	100	if (!res) {
1838	4		return 0;
1839			}
1840
1841	965		NI_ip_inttoip_ipv4(NI_ip_uchars_to_ulong(ipv4), buf);
1842
1843	969		return 1;
1844			}
1845
1846			/**
1847			* NI_ip_expand_address_ipv6(): expand an IPv6 address.
1848			* @ip: the IPv6 address as a string.
1849			* @buf: the IP address buffer.
1850			*
1851			* The IPv6 address string must be null-terminated. The buffer will be
1852			* null-terminated on success.
1853			*/
1854			int
1855	753		NI_ip_expand_address_ipv6(const char ip, char retbuf)
1856			{
1857			int res;
1858			int i;
1859			unsigned char ipv6[16];
1860			unsigned long n[4];
1861
1862	753		res = inet_pton6(ip, ipv6);
1863	753	100	if (!res) {
1864	11		return 0;
1865			}
1866
1867	3710	100	for (i = 0; i < 4; i++) {
1868	5936		n[i] = (ipv6[(i * 4) + 0] << 24)
1869	2968		\| (ipv6[(i * 4) + 1] << 16)
1870	2968		\| (ipv6[(i * 4) + 2] << 8)
1871	2968		\| (ipv6[(i * 4) + 3]);
1872			}
1873
1874	742		NI_ip_inttoip_ipv6(n[0], n[1], n[2], n[3], retbuf);
1875
1876	753		return 1;
1877			}
1878
1879			/**
1880			* NI_ip_expand_address(): expand an IP address.
1881			* @ip: the IP address as a string.
1882			* @version: the IP address version.
1883			* @buf: the IP address buffer.
1884			*
1885			* See NI_ip_expand_address_ipv4() and NI_ip_expand_address_ipv6(). This
1886			* function dispatches to one of those functions depending on the
1887			* value of the @version argument.
1888			*/
1889			int
1890	1722		NI_ip_expand_address(const char ip, int version, char buf)
1891			{
1892			return
1893	1722		(version == 4)
1894			? NI_ip_expand_address_ipv4(ip, buf)
1895	1722	100	: NI_ip_expand_address_ipv6(ip, buf);
1896			}
1897
1898			/**
1899			* NI_ip_reverse_ipv4(): get reverse domain for an IPv4 address.
1900			* @ip: the IP address as a string.
1901			* @len: the prefix length of the reverse domain.
1902			* @buf: the reverse domain buffer.
1903			*
1904			* If the length is not evenly divisible by eight, then it will be
1905			* treated as though it were the next number lower than it that is
1906			* evenly divisible by eight when determining how many octets to
1907			* print. So e.g. if the length is 31, three octets from the address
1908			* will be included in the domain. The buffer is null-terminated. The
1909			* longest possible IPv4 reverse domain name contains 25 characters
1910			* (including the null terminator).
1911			*/
1912			int
1913	14		NI_ip_reverse_ipv4(const char ip, int len, char buf)
1914			{
1915			int res;
1916			int quads;
1917			int i;
1918			char numbuf[5];
1919			unsigned char ipv4[4];
1920
1921	14	100	if ((len < 0) \|\| (len > 32)) {
		100
1922	2		return 0;
1923			}
1924	12		quads = len / 8;
1925
1926	12		res = inet_pton4(ip, ipv4);
1927	12	100	if (!res) {
1928	1		return 0;
1929			}
1930
1931	39	100	for (i = (quads - 1); i >= 0; i--) {
1932	28		sprintf(numbuf, "%u.", ipv4[i]);
1933	28		strcat(buf, numbuf);
1934			}
1935
1936	11		strcat(buf, "in-addr.arpa.");
1937	14		return 1;
1938			}
1939
1940			/**
1941			* NI_ip_reverse_ipv6(): get reverse domain for an IPv4 address.
1942			* @ip: the IP address as a string.
1943			* @len: the prefix length of the reverse domain.
1944			* @buf: the reverse domain buffer.
1945			*
1946			* If the length is not evenly divisible by four, then it will be
1947			* treated as though it were the next number lower than it that is
1948			* evenly divisible by four when determining how many nibbles to
1949			* print. So e.g. if the length is 10, two nibbles from the address
1950			* will be included in the domain. The buffer is null-terminated. The
1951			* longest possible IPv6 reverse domain name contains 74 characters
1952			* (including the null terminator).
1953			*/
1954			int
1955	19		NI_ip_reverse_ipv6(const char ip, int len, char buf)
1956			{
1957			int res;
1958			int i;
1959			int index;
1960			int shift;
1961			unsigned char ipv6[16];
1962
1963	19	100	if ((len < 0) \|\| (len > 128)) {
		100
1964	2		return 0;
1965			}
1966	17		len = (len / 4);
1967
1968	17		res = inet_pton6(ip, ipv6);
1969	17	100	if (!res) {
1970	1		return 0;
1971			}
1972
1973	126	100	for (i = (len - 1); i >= 0; i--) {
1974	110		index = i / 2;
1975	110	100	shift = !(i % 2) * 4;
1976	110		sprintf(buf, "%x.", ((ipv6[index] >> shift) & 0xF));
1977	110		buf += 2;
1978			}
1979	16		strcat(buf, "ip6.arpa.");
1980	19		return 1;
1981			}
1982
1983			/**
1984			* NI_ip_reverse(): get reverse domain for an IP address.
1985			* @ip: the IP address as a string.
1986			* @len: the prefix length of the reverse domain.
1987			* @buf: the reverse domain buffer.
1988			*
1989			* See NI_ip_reverse_ipv4() and NI_ip_reverse_ipv6().
1990			*/
1991			int
1992	35		NI_ip_reverse(const char ip, int len, int ipversion, char buf)
1993			{
1994	35	100	if (!ipversion) {
1995	1		ipversion = NI_ip_get_version(ip);
1996			}
1997	35	100	if (!ipversion) {
1998	1		NI_set_Error_Errno(101, "Cannot determine IP "
1999			"version for %s", ip);
2000	1		return 0;
2001			}
2002
2003	34	100	if (ipversion == 4) {
2004	14		return NI_ip_reverse_ipv4(ip, len, buf);
2005	20	100	} else if (ipversion == 6) {
2006	19		return NI_ip_reverse_ipv6(ip, len, buf);
2007			}
2008
2009	1		return 0;
2010			}
2011
2012			/**
2013			* NI_ip_normalize_prefix_ipv4(): get first and last address from prefix range.
2014			* @ip: IP address.
2015			* @slash: pointer to first '/' in original string.
2016			* @ip1buf: first IP address buffer.
2017			* @ip2buf: second IP address buffer.
2018			*
2019			* Both buffers are null-terminated on success.
2020			*/
2021			int
2022	63		NI_ip_normalize_prefix_ipv4(unsigned long ip, char *slash,
2023			char ip1buf, char ip2buf)
2024			{
2025			unsigned long current;
2026	63		char *endptr = NULL;
2027			int res;
2028	63		long clen = 0;
2029	63		int addcst = 0;
2030			char c;
2031
2032	63		current = ip;
2033
2034			for (;;) {
2035	124		c = *slash++;
2036	124	100	if (c != '/') {
2037	54		break;
2038			}
2039
2040	70		endptr = NULL;
2041
2042	70		clen = strtol(slash, &endptr, 10);
2043	70	50	if (STRTOL_FAILED(clen, slash, endptr)) {
		50
		0
		100
		100
2044	3		return 0;
2045			}
2046	67	100	if (*endptr == ',') {
2047	8		addcst = 1;
2048	59	100	} else if (endptr != (slash + strlen(slash))) {
2049	3		NI_set_Error_Errno(172, "Invalid prefix length /%s", slash);
2050	3		return 0;
2051			} else {
2052	56		addcst = 0;
2053			}
2054
2055	64		res = NI_ip_check_prefix_ipv4(current, clen);
2056	64	100	if (!res) {
2057	3		return 0;
2058			}
2059
2060	61		current = NI_ip_last_address_ipv4(current, clen);
2061
2062	61	100	if (addcst) {
2063	8		current += 1;
2064	8		slash = endptr + 1;
2065			}
2066	61		}
2067
2068	54		NI_ip_inttoip_ipv4(ip, ip1buf);
2069	54		NI_ip_inttoip_ipv4(current, ip2buf);
2070
2071	63		return 2;
2072			}
2073
2074			/**
2075			* NI_ip_normalize_prefix_ipv6(): get first and last address from prefix range.
2076			* @ip: IP address (N128 integer).
2077			* @slash: pointer to first '/' in original string.
2078			* @ip1buf: first IP address buffer.
2079			* @ip2buf: second IP address buffer.
2080			*
2081			* Both buffers are null-terminated on success.
2082			*/
2083			int
2084	48		NI_ip_normalize_prefix_ipv6(n128_t ip, char slash,
2085			char ip1buf, char ip2buf)
2086			{
2087			n128_t current;
2088	48		char *endptr = NULL;
2089			int res;
2090	48		long clen = 0;
2091	48		int addcst = 0;
2092			char c;
2093
2094	48		n128_set(¤t, ip);
2095
2096			for (;;) {
2097	95		c = *slash++;
2098	95	100	if (c != '/') {
2099	42		break;
2100			}
2101
2102	53		endptr = NULL;
2103
2104	53		clen = strtol(slash, &endptr, 10);
2105	53	50	if (STRTOL_FAILED(clen, slash, endptr)) {
		50
		0
		100
		100
2106	1		return 0;
2107			}
2108	52	100	if (*endptr == ',') {
2109	5		addcst = 1;
2110	47	100	} else if (endptr != (slash + strlen(slash))) {
2111	2		NI_set_Error_Errno(172, "Invalid prefix length /%s", slash);
2112	2		return 0;
2113			} else {
2114	45		addcst = 0;
2115			}
2116
2117	50		res = NI_ip_check_prefix_ipv6(¤t, clen);
2118	50	100	if (!res) {
2119	3		return 0;
2120			}
2121
2122	47		NI_ip_last_address_ipv6(¤t, clen, ¤t);
2123
2124	47	100	if (addcst) {
2125	5		n128_add_ui(¤t, 1);
2126	5		slash = endptr + 1;
2127			}
2128	47		}
2129
2130	42		NI_ip_inttoip_n128(ip, ip1buf);
2131	42		NI_ip_inttoip_n128(¤t, ip2buf);
2132
2133	48		return 2;
2134			}
2135
2136			/**
2137			* NI_ip_normalize_prefix(): get first and last address from prefix range.
2138			* @ip: IP address prefix range as a string.
2139			* @ip1buf: first IP address buffer.
2140			* @ip2buf: second IP address buffer.
2141			*
2142			* The range can include commas and additional prefixes, e.g.
2143			* '0.0.0.0/32,/32,/32' will yield '0.0.0.0' and '0.0.0.2'.
2144			*/
2145			int
2146	978		NI_ip_normalize_prefix(char ip, char ip1buf, char *ip2buf)
2147			{
2148			char c;
2149			int res;
2150			int i;
2151			char *slash;
2152			int islash;
2153			char *start;
2154			unsigned char ipnum[16];
2155			unsigned long ipv4;
2156			n128_t ipv6;
2157			int ipversion;
2158
2159	978		i = 0;
2160	978		slash = NULL;
2161	978		islash = -1;
2162	978		start = ip;
2163
2164	24087	100	while ((c = *ip)) {
2165	23930	100	if (isspace(c)) {
2166	821		return -1;
2167			}
2168	23109	100	if (i && (c == '/') && (!slash)) {
		100
		100
2169	112		slash = ip;
2170	112		islash = i;
2171			}
2172	23109		i++;
2173	23109		ip++;
2174			}
2175
2176	157	100	if (islash < 1) {
2177	45		return -1;
2178			}
2179
2180	112		*slash = '\0';
2181	112		ipversion = NI_ip_get_version(start);
2182
2183	112	100	if (ipversion == 4) {
2184	63		res = inet_pton4(start, ipnum);
2185	63	50	if (!res) {
2186	0		return 0;
2187			}
2188	63		*slash = '/';
2189	63		ipv4 = NI_ip_uchars_to_ulong(ipnum);
2190	63		return NI_ip_normalize_prefix_ipv4(ipv4,
2191			slash,
2192			ip1buf,
2193			ip2buf);
2194	49	100	} else if (ipversion == 6) {
2195	48		res = inet_pton6(start, ipnum);
2196	48	50	if (!res) {
2197	0		return 0;
2198			}
2199	48		*slash = '/';
2200	48		NI_ip_uchars_to_n128(ipnum, &ipv6);
2201	48		res = NI_ip_normalize_prefix_ipv6(&ipv6,
2202			slash,
2203			ip1buf,
2204			ip2buf);
2205	48		return res;
2206			} else {
2207	978		return 0;
2208			}
2209			}
2210
2211			/**
2212			* NI_ip_tokenize_on_char(): get parts of string before and after char.
2213			* @str: the string to tokenize.
2214			* @separator: the char that separates the two parts of the string.
2215			* @end_first: buffer for the end of the first string.
2216			* @second: buffer for the start of the second string.
2217			*
2218			* Tokenizes the string based on the @separator character. Ignores
2219			* whitespace occurring before and after @separator. For example, if
2220			* the string provided is '127.0.0.1 - 127.0.0.255', @end_first will
2221			* point to the space immediately after the first IP address, and
2222			* @second will point to the second IP address.
2223			*/
2224			int
2225	920		NI_ip_tokenize_on_char(char *str, char separator,
2226			char end_first, char second)
2227			{
2228			char c;
2229			char *break_char;
2230			int i;
2231			int hit_separator;
2232
2233	920		break_char = NULL;
2234	920		i = 0;
2235	920		hit_separator = 0;
2236
2237	26936	100	while ((c = *str)) {
2238	26852	100	if (c == separator) {
2239	836		hit_separator = 1;
2240	836	100	if (!break_char) {
2241	17	100	if (!i) {
2242	3		return 0;
2243			} else {
2244	14		break_char = str;
2245			}
2246			}
2247	833		break;
2248	26016	100	} else if (isspace(c)) {
2249	856	100	if (!break_char) {
2250	856		break_char = str;
2251			}
2252			} else {
2253	25160		break_char = NULL;
2254			}
2255	26016		str++;
2256	26016		i++;
2257			}
2258
2259	917	100	if (!hit_separator) {
2260	84		return 0;
2261			}
2262
2263	833		str++;
2264	833		c = *str;
2265	833	100	if (c == '\0') {
2266	1		return 0;
2267			}
2268
2269	1657	100	while ((c = *str) && (isspace(c))) {
		100
2270	825		str++;
2271			}
2272
2273	832	100	if (c == '\0') {
2274	1		return 0;
2275			}
2276
2277	831		*end_first = break_char;
2278	831		*second = str;
2279
2280	831		return 1;
2281			}
2282
2283			/**
2284			* NI_ip_normalize_range(): get first and last address from a range.
2285			* @ip: the IP address range to normalize.
2286			* @ipbuf1: first IP address buffer.
2287			* @ipbuf2: second IP address buffer.
2288			*
2289			* @ip must be a range containing a hyphen, e.g. '127.0.0.0 -
2290			* 127.0.0.255'. Whitespace before and after the hyphen is ignored.
2291			* The IP address buffers will be null-terminated on success.
2292			*/
2293			int
2294	866		NI_ip_normalize_range(char ip, char ipbuf1, char *ipbuf2)
2295			{
2296			char *break_char;
2297			char *start;
2298			int ipversion;
2299			int res;
2300			char old_char;
2301
2302	866		res = NI_ip_tokenize_on_char(ip, '-', &break_char, &start);
2303	866	100	if (!res) {
2304	54		return -1;
2305			}
2306
2307	812		old_char = *break_char;
2308	812		*break_char = '\0';
2309
2310	812		ipversion = NI_ip_get_version(start);
2311	812	100	if (!ipversion) {
2312	1		*break_char = old_char;
2313	1		return 0;
2314			}
2315
2316	811		res = NI_ip_expand_address(ip, ipversion, ipbuf1);
2317	811		*break_char = old_char;
2318
2319	811	100	if (!res) {
2320	1		return 0;
2321			}
2322
2323	810		res = NI_ip_expand_address(start, ipversion, ipbuf2);
2324	810	50	if (!res) {
2325	0		return 0;
2326			}
2327
2328	866		return 2;
2329			}
2330
2331			/**
2332			* NI_ip_normalize_plus_ipv4(): get first and last address from addition.
2333			* @ip: the IP address string.
2334			* @num: the number of addresses to add as a string.
2335			* @ipbuf1: first IP address buffer.
2336			* @ipbuf2: second IP address buffer.
2337			*
2338			* The IP address buffers will be null-terminated on success.
2339			*/
2340			int
2341	15		NI_ip_normalize_plus_ipv4(char ip, char num,
2342			char ipbuf1, char ipbuf2)
2343			{
2344			int res;
2345			char *endptr;
2346			unsigned char ipnum[4];
2347			unsigned long ipv4;
2348			unsigned long addnum;
2349
2350	15		res = inet_pton4(ip, ipnum);
2351	15	50	if (!res) {
2352	0		return 0;
2353			}
2354
2355	15		ipv4 = NI_ip_uchars_to_ulong(ipnum);
2356
2357	15		endptr = NULL;
2358
2359	15		addnum = strtoul(num, &endptr, 10);
2360	15	100	if (STRTOUL_FAILED(addnum, num, endptr)) {
		100
		50
		50
		0
2361	2		return 0;
2362			}
2363	13	100	if (addnum > 0xFFFFFFFF) {
2364	1		return 0;
2365			}
2366
2367	12		NI_ip_inttoip_ipv4(ipv4, ipbuf1);
2368	12		ipv4 += addnum;
2369	12		NI_ip_inttoip_ipv4(ipv4, ipbuf2);
2370
2371	15		return 2;
2372			}
2373
2374			/**
2375			* NI_ip_normalize_plus_ipv6(): get first and last address from addition.
2376			* @ip: the IP address string.
2377			* @num: the number of addresses to add as a string.
2378			* @ipbuf1: first IP address buffer.
2379			* @ipbuf2: second IP address buffer.
2380			*
2381			* The IP address buffers will be null-terminated on success.
2382			*/
2383			int
2384	4		NI_ip_normalize_plus_ipv6(char ip, char num,
2385			char ipbuf1, char ipbuf2)
2386			{
2387			unsigned char ipnum[16];
2388			n128_t ipv6;
2389			n128_t addnum;
2390			int res;
2391
2392	4		res = inet_pton6(ip, ipnum);
2393	4	50	if (!res) {
2394	0		return 0;
2395			}
2396
2397	4		NI_ip_uchars_to_n128(ipnum, &ipv6);
2398
2399	4		res = n128_set_str_decimal(&addnum, num, strlen(num));
2400	4	100	if (!res) {
2401	2		return 0;
2402			}
2403
2404	2		NI_ip_inttoip_n128(&ipv6, ipbuf1);
2405	2		n128_add(&ipv6, &addnum);
2406	2		NI_ip_inttoip_n128(&ipv6, ipbuf2);
2407
2408	4		return 2;
2409			}
2410
2411			/**
2412			* NI_ip_normalize_plus(): get first and last address from addition.
2413			* @ip: the IP address string.
2414			* @ipbuf1: first IP address buffer.
2415			* @ipbuf2: second IP address buffer.
2416			*
2417			* @ip must begin with an IP address, then contain a '+' and an
2418			* integer, e.g. '127.0.0.0 + 16777216', '2000::+1234849245892845'.
2419			* The IP address buffers will be null-terminated on success.
2420			*/
2421			int
2422	54		NI_ip_normalize_plus(char ip1, char ipbuf1, char *ipbuf2)
2423			{
2424			char *break_char;
2425			char *start;
2426			int ipversion;
2427			int res;
2428			char old_char;
2429
2430	54		res = NI_ip_tokenize_on_char(ip1, '+', &break_char, &start);
2431	54	100	if (!res) {
2432	35		return -1;
2433			}
2434
2435	19		old_char = *break_char;
2436	19		*break_char = '\0';
2437
2438	19		ipversion = NI_ip_get_version(ip1);
2439
2440	19		switch (ipversion) {
2441	15		case 4: res = NI_ip_normalize_plus_ipv4(ip1, start, ipbuf1, ipbuf2);
2442	15		break;
2443	4		case 6: res = NI_ip_normalize_plus_ipv6(ip1, start, ipbuf1, ipbuf2);
2444	4		break;
2445	0		default: res = 0;
2446			}
2447
2448	19		*break_char = old_char;
2449	54		return res;
2450			}
2451
2452			/**
2453			* NI_ip_normalize_bare(): normalize a single IP address.
2454			* @ip: the IP address string.
2455			* @ipbuf1: the IP address buffer.
2456			*
2457			* Checks the version of the IP address and then expands it. For a
2458			* valid IP address, this function has the same effect as calling
2459			* NI_ip_expand_address(). The IP address buffer will be
2460			* null-terminated on success.
2461			*/
2462			int
2463	35		NI_ip_normalize_bare(char ip, char ipbuf1)
2464			{
2465			int ipversion;
2466			int res;
2467
2468	35		ipversion = NI_ip_get_version(ip);
2469	35	100	if (!ipversion) {
2470	9		return 0;
2471			}
2472
2473	26		res = NI_ip_expand_address(ip, ipversion, ipbuf1);
2474	26	50	if (!res) {
2475	0		return 0;
2476			}
2477
2478	26		return 1;
2479			}
2480
2481			/**
2482			* NI_ip_normalize(): normalize an IP address string.
2483			* @ip: the IP address string.
2484			* @ipbuf1: the first IP address buffer.
2485			* @ipbuf2: the second IP address buffer.
2486			*
2487			* The various formats that @ip can take are described in
2488			* NI_ip_normalize_prefix(), NI_ip_normalize_range(),
2489			* NI_ip_normalize_plus() and NI_ip_normalize_bare(). Returns zero on
2490			* failure, otherwise returns the number of IP address buffers that
2491			* were populated. Those buffers will be null-terminated on success.
2492			*/
2493			int
2494	978		NI_ip_normalize(char ip, char ipbuf1, char *ipbuf2)
2495			{
2496			int res;
2497
2498	978		res = NI_ip_normalize_prefix(ip, ipbuf1, ipbuf2);
2499	978	100	if (res >= 0) {
2500	112		return res;
2501			}
2502
2503	866		res = NI_ip_normalize_range(ip, ipbuf1, ipbuf2);
2504	866	100	if (res >= 0) {
2505	812		return res;
2506			}
2507
2508	54		res = NI_ip_normalize_plus(ip, ipbuf1, ipbuf2);
2509	54	100	if (res >= 0) {
2510	19		return res;
2511			}
2512
2513	35		res = NI_ip_normalize_bare(ip, ipbuf1);
2514	35	50	if (res >= 0) {
2515	35		return res;
2516			}
2517
2518	0		return 0;
2519			}
2520
2521			/**
2522			* NI_ip_normal_range(): normalize an IP address string into a range.
2523			* @ip: the IP address string.
2524			* @buf: the IP address range buffer.
2525			*
2526			* Uses NI_ip_normalize() to get the first and last (if applicable)
2527			* addresses from the string. Sets the buffer so that it is always in
2528			* range format (i.e. first address, hyphen, second address), even
2529			* where the IP address string contains only one address, in which
2530			* case both of the addresses will be the same. @buf is
2531			* null-terminated on success.
2532			*/
2533			int
2534	9		NI_ip_normal_range(char ip, char buf)
2535			{
2536			char ip1buf[MAX_IPV6_STR_LEN];
2537			char ip2buf[MAX_IPV6_STR_LEN];
2538			int res;
2539
2540	9		res = NI_ip_normalize(ip, ip1buf, ip2buf);
2541	9	100	if (!res) {
2542	3		return 0;
2543			}
2544
2545	6	100	sprintf(buf, "%s - %s", ip1buf,
2546			(res == 1) ? ip1buf : ip2buf);
2547
2548	9		return 1;
2549			}
2550
2551			/**
2552			* NI_ip_compress_v4_prefix(): get smallest representation of IPv4 prefix range.
2553			* @ip: the IP address.
2554			* @len: the prefix length of the range.
2555			* @buf: buffer for the compressed representation.
2556			* @maxlen: maximum capacity of buffer.
2557			*/
2558			int
2559	52		NI_ip_compress_v4_prefix(const char ip, int len, char buf, int maxlen)
2560			{
2561			int dotcount;
2562			const char *c;
2563			int buflen;
2564
2565	52	100	if ((len < 0) \|\| (len > 32)) {
		100
2566	3		return 0;
2567			}
2568	49	100	if (strlen(ip) > (MAX_IPV4_RANGE_STR_LEN - 1)) {
2569	2		return 0;
2570			}
2571
2572	47		c = ip;
2573	47	100	dotcount = (len == 0) ? 1 : ((len / 8) + (!(len % 8) ? 0 : 1));
2574	141	100	while (dotcount--) {
2575	108		c = strchr(c, '.');
2576	108	100	if (c == NULL) {
2577	14		c = ip + (strlen(ip) + 1);
2578	14		break;
2579			}
2580	94	50	if (*(c + 1) != '\0') {
2581	94		c++;
2582			}
2583			}
2584
2585	47		buflen = c - ip - 1;
2586	47	50	if (buflen > maxlen) {
2587	0		buflen = maxlen;
2588			}
2589
2590	47		strncpy(buf, ip, buflen);
2591	47		buf[buflen] = '\0';
2592
2593	47		return 1;
2594			}
2595
2596			/**
2597			* NI_ip_compress_address(): get smallest representation of IPv6 prefix range.
2598			* @ip: the IP address.
2599			* @version: the IP address version.
2600			* @buf: buffer for the compressed representation.
2601			*
2602			* If @ip is an IPv4 address, it will simply be copied to @buf.
2603			*/
2604			int
2605	19		NI_ip_compress_address(const char ip, int version, char buf)
2606			{
2607			unsigned char ipv6[16];
2608			int i;
2609			char mybuf[5];
2610			int res;
2611	19		int in_ws = 0;
2612	19		int ws_index = -1;
2613			int ws_start[4];
2614			int ws_count[4];
2615			int largest_index;
2616			int largest;
2617
2618	19		memset(ws_start, 0, 4 * sizeof(int));
2619	19		memset(ws_count, 0, 4 * sizeof(int));
2620
2621	19	100	if (!version) {
2622	1		NI_set_Error_Errno(101, "Cannot determine IP version for %s",
2623			ip);
2624	1		return 0;
2625			}
2626
2627	18	100	if (version == 4) {
2628	1		strcpy(buf, ip);
2629	1		return 1;
2630			}
2631
2632	17		res = inet_pton6(ip, ipv6);
2633	17	100	if (!res) {
2634	1		return 0;
2635			}
2636
2637	144	100	for (i = 0; i < 16; i += 2) {
2638	128	100	if ((ipv6[i] == 0) && (ipv6[i + 1] == 0)) {
		100
2639	72	100	if (!in_ws) {
2640	26		in_ws = 1;
2641	26		ws_start[++ws_index] = i;
2642			}
2643	72		ws_count[ws_index] += 1;
2644			} else {
2645	56		in_ws = 0;
2646			}
2647			}
2648
2649	16		largest = 0;
2650	16		largest_index = -1;
2651
2652	80	100	for (i = 0; i < 4; i++) {
2653			/* "The symbol '::' MUST NOT be used to shorten just one 16-bit 0
2654			field. For example, the representation 2001:db8:0:1:1:1:1:1 is
2655			correct, but 2001:db8::1:1:1:1:1 is not correct"
2656			(RFC 5952, [4.2.2]). So make sure that ws_count is greater
2657			than 1. */
2658	64	100	if (ws_count[i] > largest && ws_count[i] > 1) {
		100
2659	14		largest = ws_count[i];
2660	14		largest_index = i;
2661			}
2662			}
2663
2664	101	100	for (i = 0; i < 16; i += 2) {
2665	85	100	if ((largest_index != -1) && (i == ws_start[largest_index])) {
		100
2666	12	100	if (i == 0) {
2667	2		strcat(buf, ":");
2668			}
2669	12		i += ((largest * 2) - 2);
2670	12		strcat(buf, ":");
2671			} else {
2672	73		sprintf(mybuf, "%x",
2673	73		(ipv6[i] << 8) + ipv6[i + 1]);
2674	73		strcat(buf, mybuf);
2675	73	100	if (i < 14) {
2676	59		strcat(buf, ":");
2677			}
2678			}
2679			}
2680
2681	19		return 1;
2682			}
2683
2684			/**
2685			* NI_ip_splitprefix(): split range into IP address and prefix length.
2686			* @prefix: the IP address prefix range.
2687			* @ipbuf: the IP address buffer.
2688			* @lenbuf: the prefix length buffer.
2689			*/
2690			int
2691	147		NI_ip_splitprefix(const char prefix, char ipbuf, int *lenbuf)
2692			{
2693			const char *c;
2694			const char *slash;
2695			char *endptr;
2696			long num;
2697			int len;
2698
2699	147		c = slash = strchr(prefix, '/');
2700	147	100	if (!slash) {
2701	2		return 0;
2702			}
2703
2704	145		len = slash - prefix;
2705	145	100	if ((len == 0) \|\| (len > (MAX_IPV6_STR_LEN - 1))) {
		100
2706	3		return 0;
2707			}
2708
2709	142		c++;
2710	142	100	if (*c == '\0') {
2711	1		return 0;
2712			}
2713
2714	141		endptr = NULL;
2715
2716	141		num = strtol(c, &endptr, 10);
2717	141	50	if (STRTOL_FAILED(num, c, endptr)) {
		100
		50
		100
		100
2718	2		return 0;
2719			}
2720	139	100	if (num < 0) {
2721	1		return 0;
2722			}
2723
2724	138		memcpy(ipbuf, prefix, len);
2725	138		ipbuf[len] = '\0';
2726	138		*lenbuf = num;
2727
2728	147		return 1;
2729			}
2730
2731			/**
2732			* NI_ip_iptype(): get type of IP address as a string.
2733			* @ip: the IP address.
2734			* @version: the IP address version.
2735			* @buf: the type buffer.
2736			*
2737			* The type buffer will be null-terminated on success. Relies on
2738			* IPv4ranges and IPv6ranges for determining types.
2739			*/
2740			int
2741	16		NI_ip_iptype(const char ip, int version, char buf)
2742			{
2743			HV *hash;
2744			HE *entry;
2745			char *key;
2746			I32 keylen;
2747			SV *value;
2748			STRLEN len;
2749			int current_keylen;
2750			char *typestr;
2751
2752	16	100	hash = get_hv(
2753			(version == 4 ? "Net::IP::XS::IPv4ranges"
2754			: "Net::IP::XS::IPv6ranges"), 0);
2755
2756	16	50	if (!hash) {
2757	0		return 0;
2758			}
2759
2760	16		hv_iterinit(hash);
2761	16		current_keylen = 0;
2762
2763	284	100	while ((entry = hv_iternext(hash))) {
2764	268		key = hv_iterkey(entry, &keylen);
2765	268	100	if (keylen > current_keylen) {
2766	175	100	if (!strncmp(key, ip, keylen)) {
2767	12		current_keylen = keylen;
2768	12		value = hv_iterval(hash, entry);
2769	12	50	typestr = SvPV(value, len);
2770	12	100	if (len > (MAX_TYPE_STR_LEN - 1)) {
2771	1		len = (MAX_TYPE_STR_LEN - 1);
2772			}
2773	12		memcpy(buf, typestr, len);
2774	12		buf[len] = '\0';
2775			}
2776			}
2777			}
2778
2779	16	100	if (current_keylen) {
2780	10		return 1;
2781			}
2782
2783	6	100	if (version == 4) {
2784	3		memcpy(buf, "PUBLIC", 6);
2785	3		buf[6] = '\0';
2786	3		return 1;
2787			}
2788
2789	3		NI_set_Error_Errno(180, "Cannot determine type for %s", ip);
2790
2791	16		return 0;
2792			}
2793
2794			/**
2795			* NI_ip_is_valid_mask(): determine the validity of a bitstring mask.
2796			* @mask: bitstring mask.
2797			* @version: mask's IP address version.
2798			*/
2799			int
2800	9		NI_ip_is_valid_mask(const char *mask, int version)
2801			{
2802			const char *c;
2803			int iplen;
2804			int mask_len;
2805			int state;
2806
2807	9	100	if (!version) {
2808	1		NI_set_Error_Errno(101, "Cannot determine IP version for %s",
2809			mask);
2810	1		return 0;
2811			}
2812
2813	8		iplen = NI_iplengths(version);
2814	8		mask_len = strlen(mask);
2815
2816	8	100	if (mask_len != iplen) {
2817	2		NI_set_Error_Errno(150, "Invalid mask length for %s", mask);
2818	2		return 0;
2819			}
2820
2821	6		state = 0;
2822	6		c = mask;
2823
2824	103	100	while (*c != '\0') {
2825	99	100	if ((*c == '1') && (state == 0)) {
		100
2826	33		c++;
2827	33		continue;
2828			}
2829	66	100	if (*c == '0') {
2830	64	100	if (state == 0) {
2831	3		state = 1;
2832			}
2833	64		c++;
2834	64		continue;
2835			}
2836	2		NI_set_Error_Errno(151, "Invalid mask %s", mask);
2837	2		return 0;
2838			}
2839
2840	4		return 1;
2841			}
2842
2843			/**
2844			* NI_ip_prefix_to_range(): get begin/end addresses from address and length.
2845			* @ip: IP address.
2846			* @len: prefix length of range.
2847			* @version: IP address version.
2848			* @buf: last IP address buffer.
2849			*/
2850			int
2851	22		NI_ip_prefix_to_range(const char ip, int len, int version, char buf)
2852			{
2853			char bitstr1[IPV6_BITSTR_LEN];
2854			char bitstr2[IPV6_BITSTR_LEN];
2855
2856	22	100	if (!version) {
2857	1		NI_set_Error_Errno(101, "Cannot determine IP version");
2858	1		return 0;
2859			}
2860
2861	21	100	if (!NI_ip_expand_address(ip, version, buf)) {
2862	1		return 0;
2863			}
2864
2865	20	50	if (!NI_ip_iptobin(ip, version, bitstr1)) {
2866	0		return 0;
2867			}
2868
2869	20	100	bitstr1[(version == 4) ? 32 : 128] = '\0';
2870
2871	20	100	if (!NI_ip_check_prefix(bitstr1, len, version)) {
2872	1		return 0;
2873			}
2874
2875	19		NI_ip_last_address_bin(bitstr1, len, version, bitstr2);
2876
2877	19	100	bitstr2[(version == 4) ? 32 : 128] = '\0';
2878
2879	19	50	if (!NI_ip_bintoip(bitstr2, version, buf)) {
2880	0		return 0;
2881			}
2882
2883	22		return 1;
2884			}
2885
2886			/**
2887			* NI_ip_get_embedded_ipv4(): get IPv4 address contained within IPv6 address.
2888			* @ipv6: IPv6 address as a string.
2889			* @buf: IPv4 address buffer.
2890			*/
2891			int
2892	8		NI_ip_get_embedded_ipv4(const char ipv6, char buf)
2893			{
2894			const char *c;
2895			int len;
2896
2897	8		c = strrchr(ipv6, ':');
2898	8	100	if (c == NULL) {
2899	3		c = ipv6;
2900			} else {
2901	5		c++;
2902			}
2903
2904	8		len = strlen(c);
2905	8	100	if (len > (MAX_IPV4_STR_LEN - 1)) {
2906	1		len = (MAX_IPV4_STR_LEN - 1);
2907			}
2908	8	100	if ((len > 0) && NI_ip_is_ipv4(c)) {
		100
2909	4		strncpy(buf, c, len);
2910	4		buf[len] = '\0';
2911	4		return 1;
2912			} else {
2913	4		return 0;
2914			}
2915			}
2916
2917			#ifdef __cplusplus
2918			}
2919			#endif