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/* source: xio-ip4.c */
/* Copyright Gerhard Rieger and contributors (see file CHANGES) */
/* Published under the GNU General Public License V.2, see file COPYING */
/* this file contains the source for IP4 related functions */
#include "xiosysincludes.h"
#if WITH_IP4
#include "xioopen.h"
#include "xio-socket.h"
#include "xio-ip.h"
#include "xio-ip4.h"
int xioparsenetwork_ip4(
const char *rangename,
struct xiorange *range,
const int ai_flags[2])
{
struct in_addr *netaddr_in = &range->netaddr.ip4.sin_addr;
struct in_addr *netmask_in = &range->netmask.ip4.sin_addr;
char *rangename1; /* a copy of rangename with writing allowed */
char *delimpos; /* absolute address of delimiter */
unsigned int bits; /* netmask bits */
union sockaddr_union sau;
socklen_t socklen = sizeof(sau);
int rc;
if ((rangename1 = strdup(rangename)) == NULL) {
Error1("strdup(\"%s\"): out of memory", rangename);
return STAT_RETRYLATER;
}
if (delimpos = strchr(rangename1, '/')) {
char *endptr;
bits = strtoul(delimpos+1, &endptr, 10);
if (! ((*(delimpos+1) != '\0') && (*endptr == '\0'))) {
Error1("not a valid IPv4 netmask in \"%s\"", rangename);
bits = 32; /* most secure selection */
} else if (bits > 32) {
Error1("IPv4 netmask \"%s\" is too large", rangename);
bits = 32;
}
if (bits <= 0) {
netmask_in->s_addr = 0;
} else {
netmask_in->s_addr = htonl((0xffffffff << (32-bits)));
}
} else if (delimpos = strchr(rangename1, ':')) {
if ((rc = xioresolve(delimpos+1, NULL, PF_INET, 0, 0,
&sau, &socklen, ai_flags))
!= STAT_OK) {
return rc;
}
netmask_in->s_addr = sau.ip4.sin_addr.s_addr;
} else {
Error1("xioparsenetwork_ip4(\"%s\",,): missing netmask delimiter", rangename);
free(rangename1);
return STAT_NORETRY;
}
{
*delimpos = 0;
if ((rc = xioresolve(rangename1, NULL, PF_INET, 0, 0,
&sau, &socklen, ai_flags))
!= STAT_OK) {
return rc;
}
netaddr_in->s_addr = sau.ip4.sin_addr.s_addr;
}
free(rangename1);
return STAT_OK;
}
/* check if peer address is within permitted range.
return >= 0 if so. */
int xiocheckrange_ip4(struct sockaddr_in *pa, struct xiorange *range) {
struct in_addr *netaddr_in = &range->netaddr.ip4.sin_addr;
struct in_addr *netmask_in = &range->netmask.ip4.sin_addr;
char addrbuf[256], maskbuf[256];
char peername[256];
/* is provided client address valid? */
if (pa->sin_addr.s_addr == 0) {
Warn("invalid client address 0.0.0.0");
return -1;
}
/* client address restriction */
Debug2("permitted client subnet: %s:%s",
inet4addr_info(ntohl(netaddr_in->s_addr), addrbuf, sizeof(addrbuf)),
inet4addr_info(ntohl(netmask_in->s_addr), maskbuf, sizeof(maskbuf)));
Debug1("client address is 0x%08x",
ntohl(pa->sin_addr.s_addr));
Debug1("masked address is 0x%08x",
ntohl(pa->sin_addr.s_addr & netmask_in->s_addr));
if ((pa->sin_addr.s_addr & netmask_in->s_addr)
!= netaddr_in->s_addr) {
Debug1("client address %s is not permitted",
sockaddr_inet4_info(pa, peername, sizeof(peername)));
return -1;
}
return 0;
}
/* returns information that can be used for constructing an environment
variable describing the socket address.
if idx is 0, this function writes "ADDR" into namebuff and the IP address
into valuebuff, and returns 1 (which means that one more info is there).
if idx is 1, it writes "PORT" into namebuff and the port number into
valuebuff, and returns 0 (no more info)
namelen and valuelen contain the max. allowed length of output chars in the
respective buffer.
on error this function returns -1.
*/
int
xiosetsockaddrenv_ip4(int idx, char *namebuff, size_t namelen,
char *valuebuff, size_t valuelen,
struct sockaddr_in *sa, int ipproto) {
switch (idx) {
case 0:
strcpy(namebuff, "ADDR");
inet4addr_info(ntohl(sa->sin_addr.s_addr), valuebuff, valuelen);
switch (ipproto) {
case IPPROTO_TCP:
case IPPROTO_UDP:
#ifdef IPPROTO_SCTP
case IPPROTO_SCTP:
#endif
return 1; /* there is port information to also be retrieved */
default:
return 0; /* no port info coming */
}
case 1:
strcpy(namebuff, "PORT");
snprintf(valuebuff, valuelen, "%u", ntohs(sa->sin_port));
return 0;
}
return -1;
}
#endif /* WITH_IP4 */