npf/npfctl/npf_data.c

1.18.2.2       tls /*	$NetBSD: npf_data.c,v 1.18.2.2 2014/08/20 00:05:11 tls Exp $	*/
     1.1     rmind
     1.1     rmind /*-
1.18.2.2       tls  * Copyright (c) 2009-2014 The NetBSD Foundation, Inc.
     1.1     rmind  * All rights reserved.
     1.1     rmind  *
     1.1     rmind  * Redistribution and use in source and binary forms, with or without
     1.1     rmind  * modification, are permitted provided that the following conditions
     1.1     rmind  * are met:
     1.1     rmind  * 1. Redistributions of source code must retain the above copyright
     1.1     rmind  *    notice, this list of conditions and the following disclaimer.
     1.1     rmind  * 2. Redistributions in binary form must reproduce the above copyright
     1.1     rmind  *    notice, this list of conditions and the following disclaimer in the
     1.1     rmind  *    documentation and/or other materials provided with the distribution.
     1.1     rmind  *
     1.1     rmind  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
     1.1     rmind  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
     1.1     rmind  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
     1.1     rmind  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
     1.1     rmind  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
     1.1     rmind  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
     1.1     rmind  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
     1.1     rmind  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
     1.1     rmind  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
     1.1     rmind  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
     1.1     rmind  * POSSIBILITY OF SUCH DAMAGE.
     1.1     rmind  */
     1.1     rmind
     1.1     rmind /*
    1.10     rmind  * npfctl(8) data manipulation and helper routines.
     1.1     rmind  */
     1.1     rmind
     1.4     rmind #include <sys/cdefs.h>
1.18.2.2       tls __RCSID("$NetBSD: npf_data.c,v 1.18.2.2 2014/08/20 00:05:11 tls Exp $");
     1.4     rmind
     1.1     rmind #include <sys/types.h>
    1.10     rmind #include <sys/null.h>
    1.10     rmind
    1.10     rmind #include <netinet/in.h>
    1.10     rmind #include <netinet/in_systm.h>
    1.10     rmind #include <netinet/ip.h>
    1.10     rmind #define ICMP_STRINGS
    1.10     rmind #include <netinet/ip_icmp.h>
    1.16       spz #define ICMP6_STRINGS
    1.16       spz #include <netinet/icmp6.h>
    1.10     rmind #include <netinet/tcp.h>
     1.1     rmind #include <net/if.h>
     1.1     rmind
     1.1     rmind #include <stdlib.h>
1.18.2.2       tls #include <stddef.h>
     1.1     rmind #include <string.h>
1.18.2.2       tls #include <ctype.h>
     1.1     rmind #include <err.h>
    1.10     rmind #include <errno.h>
     1.1     rmind #include <ifaddrs.h>
     1.1     rmind #include <netdb.h>
     1.1     rmind
     1.1     rmind #include "npfctl.h"
     1.1     rmind
     1.1     rmind static struct ifaddrs *		ifs_list = NULL;
     1.1     rmind
1.18.2.2       tls void
1.18.2.2       tls npfctl_note_interface(const char *ifname)
1.18.2.2       tls {
1.18.2.2       tls 	unsigned long if_idx = if_nametoindex(ifname);
1.18.2.2       tls 	bool testif = npfctl_debug_addif(ifname);
1.18.2.2       tls 	const char *p = ifname;
1.18.2.2       tls
1.18.2.2       tls 	/* If such interface exists or if it is a test interface - done. */
1.18.2.2       tls 	if (if_idx || testif) {
1.18.2.2       tls 		return;
1.18.2.2       tls 	}
1.18.2.2       tls
1.18.2.2       tls 	/*
1.18.2.2       tls 	 * Minimum sanity check.  The interface name shall be non-empty
1.18.2.2       tls 	 * string shorter than IFNAMSIZ and alphanumeric only.
1.18.2.2       tls 	 */
1.18.2.2       tls 	if (*p == '\0') {
1.18.2.2       tls 		goto invalid;
1.18.2.2       tls 	}
1.18.2.2       tls 	while (*p) {
1.18.2.2       tls 		const size_t len = (ptrdiff_t)p - (ptrdiff_t)ifname;
1.18.2.2       tls
1.18.2.2       tls 		if (!isalnum((unsigned char)*p) || len > IFNAMSIZ) {
1.18.2.2       tls invalid:		yyerror("illegitimate interface name '%s'", ifname);
1.18.2.2       tls 		}
1.18.2.2       tls 		p++;
1.18.2.2       tls 	}
1.18.2.2       tls
1.18.2.2       tls 	/* Throw a warning, so that the user could double check. */
1.18.2.2       tls 	warnx("warning - unknown interface '%s'", ifname);
1.18.2.2       tls }
1.18.2.2       tls
1.18.2.2       tls static unsigned long
    1.10     rmind npfctl_find_ifindex(const char *ifname)
     1.1     rmind {
    1.18     rmind 	unsigned long if_idx = if_nametoindex(ifname);
1.18.2.2       tls 	bool testif = npfctl_debug_addif(ifname);
    1.18     rmind
    1.18     rmind 	if (!if_idx) {
1.18.2.2       tls 		if (testif) {
1.18.2.2       tls 			static u_int dummy_if_idx = (1 << 15);
1.18.2.2       tls 			return ++dummy_if_idx;
    1.18     rmind 		}
    1.18     rmind 		yyerror("unknown interface '%s'", ifname);
    1.18     rmind 	}
    1.18     rmind 	return if_idx;
     1.1     rmind }
     1.1     rmind
    1.10     rmind static bool
    1.10     rmind npfctl_copy_address(sa_family_t fam, npf_addr_t *addr, const void *ptr)
     1.1     rmind {
    1.14     rmind 	memset(addr, 0, sizeof(npf_addr_t));
    1.14     rmind
    1.10     rmind 	switch (fam) {
    1.10     rmind 	case AF_INET: {
    1.10     rmind 		const struct sockaddr_in *sin = ptr;
    1.10     rmind 		memcpy(addr, &sin->sin_addr, sizeof(sin->sin_addr));
    1.10     rmind 		return true;
    1.10     rmind 	}
    1.10     rmind 	case AF_INET6: {
    1.10     rmind 		const struct sockaddr_in6 *sin6 = ptr;
    1.10     rmind 		memcpy(addr, &sin6->sin6_addr, sizeof(sin6->sin6_addr));
    1.10     rmind 		return true;
    1.10     rmind 	}
    1.10     rmind 	default:
    1.10     rmind 		yyerror("unknown address family %u", fam);
    1.10     rmind 		return false;
    1.10     rmind 	}
     1.5     rmind }
     1.5     rmind
    1.10     rmind static bool
    1.10     rmind npfctl_parse_fam_addr(const char *name, sa_family_t *fam, npf_addr_t *addr)
     1.1     rmind {
    1.10     rmind 	static const struct addrinfo hint = {
    1.10     rmind 		.ai_family = AF_UNSPEC,
    1.10     rmind 		.ai_flags = AI_NUMERICHOST
    1.10     rmind 	};
    1.10     rmind 	struct addrinfo *ai;
    1.10     rmind 	int ret;
     1.1     rmind
    1.10     rmind 	ret = getaddrinfo(name, NULL, &hint, &ai);
    1.10     rmind 	if (ret) {
    1.10     rmind 		yyerror("cannot parse '%s' (%s)", name, gai_strerror(ret));
    1.10     rmind 		return false;
    1.10     rmind 	}
    1.10     rmind 	if (fam) {
    1.10     rmind 		*fam = ai->ai_family;
     1.1     rmind 	}
    1.10     rmind 	if (!npfctl_copy_address(*fam, addr, ai->ai_addr)) {
    1.10     rmind 		return false;
     1.1     rmind 	}
    1.10     rmind 	freeaddrinfo(ai);
    1.10     rmind 	return true;
     1.1     rmind }
     1.1     rmind
    1.10     rmind static bool
    1.10     rmind npfctl_parse_mask(const char *s, sa_family_t fam, npf_netmask_t *mask)
     1.3     rmind {
    1.10     rmind 	char *ep = NULL;
    1.10     rmind 	npf_addr_t addr;
    1.10     rmind 	uint8_t *ap;
    1.10     rmind
    1.10     rmind 	if (s) {
    1.10     rmind 		errno = 0;
    1.10     rmind 		*mask = (npf_netmask_t)strtol(s, &ep, 0);
    1.10     rmind 		if (*ep == '\0' && s != ep && errno != ERANGE)
    1.10     rmind 			return true;
    1.10     rmind 		if (!npfctl_parse_fam_addr(s, &fam, &addr))
    1.10     rmind 			return false;
    1.10     rmind 	}
     1.3     rmind
    1.15     rmind 	assert(fam == AF_INET || fam == AF_INET6);
    1.15     rmind 	*mask = NPF_NO_NETMASK;
    1.10     rmind 	if (ep == NULL) {
    1.10     rmind 		return true;
    1.10     rmind 	}
    1.15     rmind
    1.10     rmind 	ap = addr.s6_addr + (*mask / 8) - 1;
    1.10     rmind 	while (ap >= addr.s6_addr) {
    1.10     rmind 		for (int j = 8; j > 0; j--) {
    1.10     rmind 			if (*ap & 1)
    1.10     rmind 				return true;
    1.10     rmind 			*ap >>= 1;
    1.10     rmind 			(*mask)--;
    1.10     rmind 			if (*mask == 0)
    1.10     rmind 				return true;
     1.3     rmind 		}
    1.10     rmind 		ap--;
     1.3     rmind 	}
     1.3     rmind 	return true;
     1.1     rmind }
     1.1     rmind
    1.10     rmind /*
    1.10     rmind  * npfctl_parse_fam_addr_mask: return address family, address and mask.
    1.10     rmind  *
    1.10     rmind  * => Mask is optional and can be NULL.
    1.10     rmind  * => Returns true on success or false if unable to parse.
    1.10     rmind  */
    1.10     rmind npfvar_t *
    1.10     rmind npfctl_parse_fam_addr_mask(const char *addr, const char *mask,
    1.10     rmind     unsigned long *nummask)
     1.8    zoltan {
    1.10     rmind 	fam_addr_mask_t fam;
    1.10     rmind
    1.10     rmind 	memset(&fam, 0, sizeof(fam));
     1.8    zoltan
    1.10     rmind 	if (!npfctl_parse_fam_addr(addr, &fam.fam_family, &fam.fam_addr))
1.18.2.2       tls 		return NULL;
    1.10     rmind
    1.10     rmind 	/*
    1.10     rmind 	 * Note: both mask and nummask may be NULL.  In such case,
    1.10     rmind 	 * npfctl_parse_mask() will handle and will set full mask.
    1.10     rmind 	 */
    1.10     rmind 	if (nummask) {
    1.10     rmind 		fam.fam_mask = *nummask;
    1.10     rmind 	} else if (!npfctl_parse_mask(mask, fam.fam_family, &fam.fam_mask)) {
1.18.2.2       tls 		return NULL;
     1.8    zoltan 	}
1.18.2.2       tls 	return npfvar_create_element(NPFVAR_FAM, &fam, sizeof(fam));
     1.1     rmind }
     1.1     rmind
    1.10     rmind npfvar_t *
1.18.2.2       tls npfctl_parse_table_id(const char *name)
     1.3     rmind {
1.18.2.2       tls 	u_int tid;
     1.3     rmind
1.18.2.2       tls 	tid = npfctl_table_getid(name);
1.18.2.2       tls 	if (tid == (unsigned)-1) {
1.18.2.2       tls 		yyerror("table '%s' is not defined", name);
    1.10     rmind 		return NULL;
     1.3     rmind 	}
1.18.2.2       tls 	return npfvar_create_element(NPFVAR_TABLE, &tid, sizeof(u_int));
     1.3     rmind }
     1.3     rmind
    1.10     rmind /*
    1.10     rmind  * npfctl_parse_port_range: create a port-range variable.  Note that the
    1.12     rmind  * passed port numbers should be in host byte order.
    1.10     rmind  */
    1.10     rmind npfvar_t *
    1.10     rmind npfctl_parse_port_range(in_port_t s, in_port_t e)
     1.1     rmind {
    1.10     rmind 	port_range_t pr;
     1.1     rmind
    1.12     rmind 	pr.pr_start = htons(s);
    1.12     rmind 	pr.pr_end = htons(e);
     1.1     rmind
1.18.2.2       tls 	return npfvar_create_element(NPFVAR_PORT_RANGE, &pr, sizeof(pr));
     1.1     rmind }
     1.1     rmind
    1.10     rmind npfvar_t *
    1.11  christos npfctl_parse_port_range_variable(const char *v)
    1.11  christos {
    1.11  christos 	npfvar_t *vp = npfvar_lookup(v);
    1.11  christos 	size_t count = npfvar_get_count(vp);
1.18.2.2       tls 	npfvar_t *pvp = npfvar_create();
    1.12     rmind 	port_range_t *pr;
    1.12     rmind 	in_port_t p;
    1.11  christos
    1.11  christos 	for (size_t i = 0; i < count; i++) {
    1.11  christos 		int type = npfvar_get_type(vp, i);
    1.11  christos 		void *data = npfvar_get_data(vp, type, i);
    1.12     rmind
    1.11  christos 		switch (type) {
    1.11  christos 		case NPFVAR_IDENTIFIER:
    1.11  christos 		case NPFVAR_STRING:
    1.11  christos 			p = npfctl_portno(data);
    1.11  christos 			npfvar_add_elements(pvp, npfctl_parse_port_range(p, p));
    1.11  christos 			break;
    1.11  christos 		case NPFVAR_PORT_RANGE:
    1.11  christos 			pr = data;
    1.11  christos 			npfvar_add_element(pvp, NPFVAR_PORT_RANGE, pr,
    1.11  christos 			    sizeof(*pr));
    1.11  christos 			break;
    1.11  christos 		case NPFVAR_NUM:
    1.11  christos 			p = *(unsigned long *)data;
    1.11  christos 			npfvar_add_elements(pvp, npfctl_parse_port_range(p, p));
    1.11  christos 			break;
    1.11  christos 		default:
    1.11  christos 			yyerror("wrong variable '%s' type '%s' for port range",
    1.11  christos 			    v, npfvar_type(type));
    1.12     rmind 			npfvar_destroy(pvp);
    1.12     rmind 			return NULL;
    1.11  christos 		}
    1.11  christos 	}
    1.11  christos 	return pvp;
    1.11  christos }
    1.11  christos
    1.11  christos npfvar_t *
1.18.2.1       tls npfctl_parse_ifnet(const char *ifname, const int family)
    1.10     rmind {
    1.10     rmind 	struct ifaddrs *ifa;
1.18.2.1       tls 	ifnet_addr_t ifna;
1.18.2.2       tls 	npfvar_t *vpa;
     1.1     rmind
    1.10     rmind 	if (ifs_list == NULL && getifaddrs(&ifs_list) == -1) {
    1.10     rmind 		err(EXIT_FAILURE, "getifaddrs");
    1.10     rmind 	}
     1.1     rmind
1.18.2.2       tls 	vpa = npfvar_create();
1.18.2.2       tls 	ifna.ifna_name = estrdup(ifname);
1.18.2.1       tls 	ifna.ifna_addrs = vpa;
1.18.2.1       tls 	ifna.ifna_index = npfctl_find_ifindex(ifname);
1.18.2.1       tls 	assert(ifna.ifna_index != 0);
     1.1     rmind
    1.10     rmind 	for (ifa = ifs_list; ifa != NULL; ifa = ifa->ifa_next) {
1.18.2.1       tls 		fam_addr_mask_t fam;
    1.10     rmind 		struct sockaddr *sa;
     1.1     rmind
    1.10     rmind 		if (strcmp(ifa->ifa_name, ifname) != 0)
    1.10     rmind 			continue;
     1.1     rmind
    1.10     rmind 		if ((ifa->ifa_flags & IFF_UP) == 0)
    1.10     rmind 			warnx("interface '%s' is down", ifname);
    1.10     rmind
    1.10     rmind 		sa = ifa->ifa_addr;
1.18.2.1       tls 		if (sa->sa_family != AF_INET && sa->sa_family != AF_INET6)
1.18.2.1       tls 			continue;
1.18.2.1       tls 		if (family != AF_UNSPEC && sa->sa_family != family)
    1.10     rmind 			continue;
     1.1     rmind
1.18.2.1       tls 		memset(&fam, 0, sizeof(fam));
1.18.2.1       tls 		fam.fam_family = sa->sa_family;
1.18.2.1       tls 		fam.fam_ifindex = ifna.ifna_index;
     1.1     rmind
1.18.2.1       tls 		if (!npfctl_copy_address(sa->sa_family, &fam.fam_addr, sa))
    1.10     rmind 			goto out;
     1.1     rmind
    1.10     rmind 		if (!npfctl_parse_mask(NULL, fam.fam_family, &fam.fam_mask))
    1.10     rmind 			goto out;
     1.1     rmind
1.18.2.1       tls 		if (!npfvar_add_element(vpa, NPFVAR_FAM, &fam, sizeof(fam)))
    1.10     rmind 			goto out;
    1.10     rmind 	}
1.18.2.1       tls 	if (npfvar_get_count(vpa) == 0) {
    1.10     rmind 		yyerror("no addresses matched for interface '%s'", ifname);
    1.10     rmind 		goto out;
     1.1     rmind 	}
1.18.2.1       tls
1.18.2.2       tls 	return npfvar_create_element(NPFVAR_INTERFACE, &ifna, sizeof(ifna));
    1.10     rmind out:
1.18.2.1       tls 	npfvar_destroy(ifna.ifna_addrs);
    1.10     rmind 	return NULL;
     1.1     rmind }
     1.1     rmind
    1.15     rmind bool
    1.15     rmind npfctl_parse_cidr(char *cidr, fam_addr_mask_t *fam, int *alen)
     1.1     rmind {
    1.15     rmind 	char *mask, *p;
     1.1     rmind
    1.15     rmind 	p = strchr(cidr, '\n');
    1.10     rmind 	if (p) {
    1.15     rmind 		*p = '\0';
    1.15     rmind 	}
    1.15     rmind 	mask = strchr(cidr, '/');
    1.15     rmind 	if (mask) {
    1.15     rmind 		*mask++ = '\0';
     1.1     rmind 	}
    1.15     rmind
    1.15     rmind 	memset(fam, 0, sizeof(*fam));
    1.15     rmind 	if (!npfctl_parse_fam_addr(cidr, &fam->fam_family, &fam->fam_addr)) {
    1.15     rmind 		return false;
    1.15     rmind 	}
    1.15     rmind 	if (!npfctl_parse_mask(mask, fam->fam_family, &fam->fam_mask)) {
    1.15     rmind 		return false;
    1.15     rmind 	}
    1.15     rmind 	switch (fam->fam_family) {
    1.15     rmind 	case AF_INET:
    1.15     rmind 		*alen = sizeof(struct in_addr);
    1.15     rmind 		break;
    1.15     rmind 	case AF_INET6:
    1.15     rmind 		*alen = sizeof(struct in6_addr);
    1.15     rmind 		break;
    1.15     rmind 	default:
    1.15     rmind 		return false;
     1.1     rmind 	}
    1.15     rmind 	return true;
     1.1     rmind }
     1.1     rmind
    1.14     rmind int
    1.14     rmind npfctl_protono(const char *proto)
    1.14     rmind {
    1.14     rmind 	struct protoent *pe;
    1.14     rmind
    1.14     rmind 	pe = getprotobyname(proto);
    1.14     rmind 	if (pe == NULL) {
    1.14     rmind 		yyerror("unknown protocol '%s'", proto);
    1.14     rmind 		return -1;
    1.14     rmind 	}
    1.14     rmind 	return pe->p_proto;
    1.14     rmind }
    1.14     rmind
    1.10     rmind /*
    1.10     rmind  * npfctl_portno: convert port identifier (string) to a number.
    1.10     rmind  *
    1.12     rmind  * => Returns port number in host byte order.
    1.10     rmind  */
    1.10     rmind in_port_t
    1.10     rmind npfctl_portno(const char *port)
     1.1     rmind {
    1.10     rmind 	struct addrinfo *ai, *rai;
    1.10     rmind 	in_port_t p = 0;
    1.10     rmind 	int e;
    1.10     rmind
    1.10     rmind 	e = getaddrinfo(NULL, port, NULL, &rai);
    1.10     rmind 	if (e != 0) {
    1.14     rmind 		yyerror("invalid port name '%s' (%s)", port, gai_strerror(e));
    1.10     rmind 		return 0;
    1.10     rmind 	}
    1.10     rmind
    1.10     rmind 	for (ai = rai; ai; ai = ai->ai_next) {
    1.10     rmind 		switch (ai->ai_family) {
    1.10     rmind 		case AF_INET: {
    1.10     rmind 			struct sockaddr_in *sin = (void *)ai->ai_addr;
    1.10     rmind 			p = sin->sin_port;
    1.10     rmind 			goto out;
    1.10     rmind 		}
    1.10     rmind 		case AF_INET6: {
    1.10     rmind 			struct sockaddr_in6 *sin6 = (void *)ai->ai_addr;
    1.10     rmind 			p = sin6->sin6_port;
    1.10     rmind 			goto out;
     1.8    zoltan 		}
    1.10     rmind 		default:
    1.10     rmind 			break;
     1.8    zoltan 		}
     1.1     rmind 	}
    1.10     rmind out:
    1.10     rmind 	freeaddrinfo(rai);
    1.12     rmind 	return ntohs(p);
    1.10     rmind }
     1.1     rmind
    1.10     rmind npfvar_t *
    1.10     rmind npfctl_parse_tcpflag(const char *s)
    1.10     rmind {
    1.10     rmind 	uint8_t tfl = 0;
     1.3     rmind
    1.10     rmind 	while (*s) {
    1.10     rmind 		switch (*s) {
    1.10     rmind 		case 'F': tfl |= TH_FIN; break;
    1.10     rmind 		case 'S': tfl |= TH_SYN; break;
    1.10     rmind 		case 'R': tfl |= TH_RST; break;
    1.10     rmind 		case 'P': tfl |= TH_PUSH; break;
    1.10     rmind 		case 'A': tfl |= TH_ACK; break;
    1.10     rmind 		case 'U': tfl |= TH_URG; break;
    1.10     rmind 		case 'E': tfl |= TH_ECE; break;
    1.10     rmind 		case 'W': tfl |= TH_CWR; break;
    1.10     rmind 		default:
    1.10     rmind 			yyerror("invalid flag '%c'", *s);
    1.10     rmind 			return NULL;
     1.3     rmind 		}
    1.10     rmind 		s++;
     1.1     rmind 	}
1.18.2.2       tls 	return npfvar_create_element(NPFVAR_TCPFLAG, &tfl, sizeof(tfl));
    1.10     rmind }
    1.10     rmind
    1.10     rmind uint8_t
    1.16       spz npfctl_icmptype(int proto, const char *type)
    1.10     rmind {
    1.16       spz 	uint8_t ul;
    1.16       spz
    1.16       spz 	switch (proto) {
    1.16       spz 	case IPPROTO_ICMP:
    1.16       spz 		for (ul = 0; icmp_type[ul]; ul++)
    1.16       spz 			if (strcmp(icmp_type[ul], type) == 0)
    1.16       spz 				return ul;
    1.16       spz 		break;
    1.16       spz 	case IPPROTO_ICMPV6:
    1.16       spz 		for (ul = 0; icmp6_type_err[ul]; ul++)
    1.16       spz 			if (strcmp(icmp6_type_err[ul], type) == 0)
    1.16       spz 				return ul;
    1.16       spz 		for (ul = 0; icmp6_type_info[ul]; ul++)
    1.16       spz 			if (strcmp(icmp6_type_info[ul], type) == 0)
1.18.2.2       tls 				return ul + 128;
    1.16       spz 		break;
    1.16       spz 	default:
    1.16       spz 		assert(false);
    1.16       spz 	}
    1.16       spz
    1.16       spz 	yyerror("unknown icmp-type %s", type);
    1.10     rmind 	return ~0;
    1.10     rmind }
    1.10     rmind
    1.10     rmind uint8_t
    1.16       spz npfctl_icmpcode(int proto, uint8_t type, const char *code)
    1.10     rmind {
    1.17     rmind 	const char * const *arr;
    1.10     rmind
    1.16       spz 	switch (proto) {
    1.16       spz 	case IPPROTO_ICMP:
    1.16       spz 		switch (type) {
    1.16       spz 		case ICMP_ECHOREPLY:
    1.16       spz 		case ICMP_SOURCEQUENCH:
    1.16       spz 		case ICMP_ALTHOSTADDR:
    1.16       spz 		case ICMP_ECHO:
    1.16       spz 		case ICMP_ROUTERSOLICIT:
    1.16       spz 		case ICMP_TSTAMP:
    1.16       spz 		case ICMP_TSTAMPREPLY:
    1.16       spz 		case ICMP_IREQ:
    1.16       spz 		case ICMP_IREQREPLY:
    1.16       spz 		case ICMP_MASKREQ:
    1.16       spz 		case ICMP_MASKREPLY:
    1.16       spz 			arr = icmp_code_none;
    1.16       spz 			break;
    1.16       spz 		case ICMP_ROUTERADVERT:
    1.16       spz 			arr = icmp_code_routeradvert;
    1.16       spz 			break;
    1.16       spz 		case ICMP_UNREACH:
    1.16       spz 			arr = icmp_code_unreach;
    1.16       spz 			break;
    1.16       spz 		case ICMP_REDIRECT:
    1.16       spz 			arr = icmp_code_redirect;
    1.16       spz 			break;
    1.16       spz 		case ICMP_TIMXCEED:
    1.16       spz 			arr = icmp_code_timxceed;
    1.16       spz 			break;
    1.16       spz 		case ICMP_PARAMPROB:
    1.16       spz 			arr = icmp_code_paramprob;
    1.16       spz 			break;
    1.16       spz 		case ICMP_PHOTURIS:
    1.16       spz 			arr = icmp_code_photuris;
    1.16       spz 			break;
    1.16       spz 		default:
    1.16       spz 			yyerror("unknown icmp-type %d while parsing code %s",
    1.16       spz 				type, code);
    1.16       spz 			return ~0;
    1.16       spz 		}
    1.10     rmind 		break;
    1.16       spz 	case IPPROTO_ICMPV6:
    1.16       spz 		switch (type) {
    1.16       spz 		case ICMP6_DST_UNREACH:
    1.16       spz 			arr = icmp6_code_unreach;
    1.16       spz 			break;
    1.16       spz 		case ICMP6_TIME_EXCEEDED:
    1.16       spz 			arr = icmp6_code_timxceed;
    1.16       spz 			break;
    1.16       spz 		case ICMP6_PARAM_PROB:
    1.16       spz 			arr = icmp6_code_paramprob;
    1.16       spz 			break;
    1.16       spz 		case ICMP6_PACKET_TOO_BIG:
    1.16       spz 		/* code-less info ICMPs */
    1.16       spz 		case ICMP6_ECHO_REQUEST:
    1.16       spz 		case ICMP6_ECHO_REPLY:
    1.16       spz 		case MLD_LISTENER_QUERY:
    1.16       spz 		case MLD_LISTENER_REPORT:
    1.16       spz 		case MLD_LISTENER_DONE:
    1.16       spz 		case ND_ROUTER_SOLICIT:
    1.16       spz 		case ND_ROUTER_ADVERT:
    1.16       spz 		case ND_NEIGHBOR_SOLICIT:
    1.16       spz 		case ND_NEIGHBOR_ADVERT:
    1.16       spz 		case ND_REDIRECT:
    1.16       spz 			arr = icmp6_code_none;
    1.16       spz 			break;
    1.16       spz 		/* XXX TODO: info ICMPs with code values */
    1.16       spz 		default:
    1.16       spz 			yyerror("unknown icmp-type %d while parsing code %s",
    1.16       spz 				type, code);
    1.16       spz 			return ~0;
    1.16       spz 		}
    1.10     rmind 		break;
    1.10     rmind 	default:
    1.16       spz 		assert(false);
    1.10     rmind 	}
    1.10     rmind
    1.10     rmind 	for (uint8_t ul = 0; arr[ul]; ul++) {
    1.10     rmind 		if (strcmp(arr[ul], code) == 0)
    1.10     rmind 			return ul;
    1.10     rmind 	}
    1.16       spz 	yyerror("unknown code %s for icmp-type %d", code, type);
    1.10     rmind 	return ~0;
    1.10     rmind }
    1.10     rmind
    1.10     rmind npfvar_t *
    1.16       spz npfctl_parse_icmp(int proto, int type, int code)
    1.10     rmind {
1.18.2.2       tls 	npfvar_t *vp = npfvar_create();
    1.10     rmind
1.18.2.2       tls 	if (!npfvar_add_element(vp, NPFVAR_ICMP, &type, sizeof(type)))
    1.10     rmind 		goto out;
    1.10     rmind
1.18.2.2       tls 	if (!npfvar_add_element(vp, NPFVAR_ICMP, &code, sizeof(code)))
    1.10     rmind 		goto out;
    1.10     rmind
    1.10     rmind 	return vp;
    1.10     rmind out:
    1.10     rmind 	npfvar_destroy(vp);
    1.10     rmind 	return NULL;
     1.1     rmind }
1.18.2.2       tls
1.18.2.2       tls /*
1.18.2.2       tls  * npfctl_npt66_calcadj: calculate the adjustment for NPTv6 as per RFC 6296.
1.18.2.2       tls  */
1.18.2.2       tls uint16_t
1.18.2.2       tls npfctl_npt66_calcadj(npf_netmask_t len, const npf_addr_t *pref_in,
1.18.2.2       tls     const npf_addr_t *pref_out)
1.18.2.2       tls {
1.18.2.2       tls 	const uint16_t *addr6_in = (const uint16_t *)pref_in;
1.18.2.2       tls 	const uint16_t *addr6_out = (const uint16_t *)pref_out;
1.18.2.2       tls 	unsigned i, remnant, wordmask, preflen = len >> 4;
1.18.2.2       tls 	uint32_t adj, isum = 0, osum = 0;
1.18.2.2       tls
1.18.2.2       tls 	/*
1.18.2.2       tls 	 * Extract the bits within a 16-bit word (when prefix length is
1.18.2.2       tls 	 * not dividable by 16) and include them into the sum.
1.18.2.2       tls 	 */
1.18.2.2       tls 	remnant = len - (preflen << 4);
1.18.2.2       tls 	wordmask = (1U << remnant) - 1;
1.18.2.2       tls 	assert(wordmask == 0 || (len % 16) != 0);
1.18.2.2       tls
1.18.2.2       tls 	/* Inner prefix - sum and fold. */
1.18.2.2       tls 	for (i = 0; i < preflen; i++) {
1.18.2.2       tls 		isum += addr6_in[i];
1.18.2.2       tls 	}
1.18.2.2       tls 	isum += addr6_in[i] & wordmask;
1.18.2.2       tls 	while (isum >> 16) {
1.18.2.2       tls 		isum = (isum >> 16) + (isum & 0xffff);
1.18.2.2       tls 	}
1.18.2.2       tls
1.18.2.2       tls 	/* Outer prefix - sum and fold. */
1.18.2.2       tls 	for (i = 0; i < preflen; i++) {
1.18.2.2       tls 		osum += addr6_out[i];
1.18.2.2       tls 	}
1.18.2.2       tls 	osum += addr6_out[i] & wordmask;
1.18.2.2       tls 	while (osum >> 16) {
1.18.2.2       tls 		osum = (osum >> 16) + (osum & 0xffff);
1.18.2.2       tls 	}
1.18.2.2       tls
1.18.2.2       tls 	/* Calculate 1's complement difference. */
1.18.2.2       tls 	adj = isum + ~osum;
1.18.2.2       tls 	while (adj >> 16) {
1.18.2.2       tls 		adj = (adj >> 16) + (adj & 0xffff);
1.18.2.2       tls 	}
1.18.2.2       tls 	return (uint16_t)adj;
1.18.2.2       tls }