freebsd-nq/lib/libalias/alias.c

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/* -*- mode: c; tab-width: 8; c-basic-indent: 4; -*- */
/*
Alias.c provides supervisory control for the functions of the
packet aliasing software. It consists of routines to monitor
TCP connection state, protocol-specific aliasing routines,
fragment handling and the following outside world functional
interfaces: SaveFragmentPtr, GetFragmentPtr, FragmentAliasIn,
PacketAliasIn and PacketAliasOut.
The other C program files are briefly described. The data
structure framework which holds information needed to translate
packets is encapsulated in alias_db.c. Data is accessed by
function calls, so other segments of the program need not know
about the underlying data structures. Alias_ftp.c contains
special code for modifying the ftp PORT command used to establish
data connections, while alias_irc.c do the same for IRC
DCC. Alias_util.c contains a few utility routines.
This software is placed into the public domain with no restrictions
on its distribution.
Version 1.0 August, 1996 (cjm)
Version 1.1 August 20, 1996 (cjm)
PPP host accepts incoming connections for ports 0 to 1023.
(Gary Roberts pointed out the need to handle incoming
connections.)
Version 1.2 September 7, 1996 (cjm)
Fragment handling error in alias_db.c corrected.
(Tom Torrance helped fix this problem.)
Version 1.4 September 16, 1996 (cjm)
- A more generalized method for handling incoming
connections, without the 0-1023 restriction, is
implemented in alias_db.c
- Improved ICMP support in alias.c. Traceroute
packet streams can now be correctly aliased.
- TCP connection closing logic simplified in
alias.c and now allows for additional 1 minute
"grace period" after FIN or RST is observed.
Version 1.5 September 17, 1996 (cjm)
Corrected error in handling incoming UDP packets with 0 checksum.
(Tom Torrance helped fix this problem.)
Version 1.6 September 18, 1996 (cjm)
Simplified ICMP aliasing scheme. Should now support
traceroute from Win95 as well as FreeBSD.
Version 1.7 January 9, 1997 (cjm)
- Out-of-order fragment handling.
- IP checksum error fixed for ftp transfers
from aliasing host.
- Integer return codes added to all
aliasing/de-aliasing functions.
- Some obsolete comments cleaned up.
- Differential checksum computations for
IP header (TCP, UDP and ICMP were already
differential).
Version 2.1 May 1997 (cjm)
- Added support for outgoing ICMP error
messages.
- Added two functions PacketAliasIn2()
and PacketAliasOut2() for dynamic address
control (e.g. round-robin allocation of
incoming packets).
*/
#include <stdio.h>
#include <unistd.h>
#include <sys/param.h>
#include <sys/types.h>
#include <netinet/in_systm.h>
#include <netinet/in.h>
#include <netinet/ip.h>
#include <netinet/ip_icmp.h>
#include <netinet/tcp.h>
#include <netinet/udp.h>
#include "alias_local.h"
#include "alias.h"
#define FTP_CONTROL_PORT_NUMBER 21
#define IRC_CONTROL_PORT_NUMBER_1 6667
#define IRC_CONTROL_PORT_NUMBER_2 6668
/*
The following macro is used to update an
internet checksum. "delta" is a 32-bit
accumulation of all the changes to the
checksum (adding in new 16-bit words and
subtracting out old words), and "cksum"
is the checksum value to be updated.
*/
#define ADJUST_CHECKSUM(acc, cksum) { \
acc += cksum; \
if (acc < 0) \
{ \
acc = -acc; \
acc = (acc >> 16) + (acc & 0xffff); \
acc += acc >> 16; \
cksum = (u_short) ~acc; \
} \
else \
{ \
acc = (acc >> 16) + (acc & 0xffff); \
acc += acc >> 16; \
cksum = (u_short) acc; \
} \
}
/* TCP Handling Routines
TcpMonitorIn() -- These routines monitor TCP connections, and
TcpMonitorOut() -- delete a link node when a connection is closed.
These routines look for SYN, ACK and RST flags to determine when TCP
connections open and close. When a TCP connection closes, the data
structure containing packet aliasing information is deleted after
a timeout period.
*/
/* Local prototypes */
static void TcpMonitorIn(struct ip *, struct alias_link *);
static void TcpMonitorOut(struct ip *, struct alias_link *);
static void
TcpMonitorIn(struct ip *pip, struct alias_link *link)
{
struct tcphdr *tc;
tc = (struct tcphdr *) ((char *) pip + (pip->ip_hl << 2));
switch (GetStateIn(link))
{
case 0:
if (tc->th_flags & TH_SYN) SetStateIn(link, 1);
break;
case 1:
if (tc->th_flags & TH_FIN
|| tc->th_flags & TH_RST) SetStateIn(link, 2);
}
}
static void
TcpMonitorOut(struct ip *pip, struct alias_link *link)
{
struct tcphdr *tc;
tc = (struct tcphdr *) ((char *) pip + (pip->ip_hl << 2));
switch (GetStateOut(link))
{
case 0:
if (tc->th_flags & TH_SYN) SetStateOut(link, 1);
break;
case 1:
if (tc->th_flags & TH_FIN
|| tc->th_flags & TH_RST) SetStateOut(link, 2);
}
}
/* Protocol Specific Packet Aliasing Routines
IcmpAliasIn(), IcmpAliasIn1(), IcmpAliasIn2(), IcmpAliasIn3()
IcmpAliasOut(), IcmpAliasOut1(), IcmpAliasOut2(), IcmpAliasOut3()
UdpAliasIn(), UdpAliasOut()
TcpAliasIn(), TcpAliasOut()
These routines handle protocol specific details of packet aliasing.
One may observe a certain amount of repetitive arithmetic in these
functions, the purpose of which is to compute a revised checksum
without actually summing over the entire data packet, which could be
unnecessarily time consuming.
The purpose of the packet aliasing routines is to replace the source
address of the outgoing packet and then correctly put it back for
any incoming packets. For TCP and UDP, ports are also re-mapped.
For ICMP echo/timestamp requests and replies, the following scheme
is used: the id number is replaced by an alias for the outgoing
packet.
ICMP error messages are handled by looking at the IP fragment
in the data section of the message.
For TCP and UDP protocols, a port number is chosen for an outgoing
packet, and then incoming packets are identified by IP address and
port numbers. For TCP packets, there is additional logic in the event
that sequence and ack numbers have been altered (as is the case for
FTP data port commands).
The port numbers used by the packet aliasing module are not true
ports in the Unix sense. No sockets are actually bound to ports.
They are more correctly thought of as placeholders.
All packets go through the aliasing mechanism, whether they come from
the gateway machine or other machines on a local area network.
*/
/* Local prototypes */
static int IcmpAliasIn1(struct ip *);
static int IcmpAliasIn2(struct ip *);
static int IcmpAliasIn3(struct ip *);
static int IcmpAliasIn (struct ip *);
static int IcmpAliasOut1(struct ip *);
static int IcmpAliasOut2(struct ip *);
static int IcmpAliasOut3(struct ip *);
static int IcmpAliasOut (struct ip *);
static int UdpAliasOut(struct ip *);
static int UdpAliasIn (struct ip *);
static int TcpAliasOut(struct ip *, int);
static int TcpAliasIn (struct ip *);
static int
IcmpAliasIn1(struct ip *pip)
{
/*
De-alias incoming echo and timestamp replies
*/
struct alias_link *link;
struct icmp *ic;
ic = (struct icmp *) ((char *) pip + (pip->ip_hl << 2));
/* Get source address from ICMP data field and restore original data */
link = FindIcmpIn(pip->ip_src, pip->ip_dst, ic->icmp_id);
if (link != NULL)
{
u_short original_id;
int accumulate;
original_id = GetOriginalPort(link);
/* Adjust ICMP checksum */
accumulate = ic->icmp_id;
accumulate -= original_id;
ADJUST_CHECKSUM(accumulate, ic->icmp_cksum)
/* Put original sequence number back in */
ic->icmp_id = original_id;
/* Put original address back into IP header */
{
struct in_addr original_address;
original_address = GetOriginalAddress(link);
DifferentialChecksum(&pip->ip_sum,
(u_short *) &original_address,
(u_short *) &pip->ip_dst,
2);
pip->ip_dst = original_address;
}
return(PKT_ALIAS_OK);
}
return(PKT_ALIAS_IGNORED);
}
static int
IcmpAliasIn2(struct ip *pip)
{
/*
Alias incoming ICMP error messages containing
IP header and first 64 bits of datagram.
*/
struct ip *ip;
struct icmp *ic, *ic2;
struct udphdr *ud;
struct tcphdr *tc;
struct alias_link *link;
ic = (struct icmp *) ((char *) pip + (pip->ip_hl << 2));
ip = (struct ip *) ic->icmp_data;
ud = (struct udphdr *) ((char *) ip + (ip->ip_hl <<2));
tc = (struct tcphdr *) ud;
ic2 = (struct icmp *) ud;
if (ip->ip_p == IPPROTO_UDP)
link = FindUdpTcpIn(ip->ip_dst, ip->ip_src,
ud->uh_dport, ud->uh_sport,
IPPROTO_UDP);
else if (ip->ip_p == IPPROTO_TCP)
link = FindUdpTcpIn(ip->ip_dst, ip->ip_src,
tc->th_dport, tc->th_sport,
IPPROTO_TCP);
else if (ip->ip_p == IPPROTO_ICMP)
if (ic2->icmp_type == ICMP_ECHO || ic2->icmp_type == ICMP_TSTAMP)
link = FindIcmpIn(ip->ip_dst, ip->ip_src, ic2->icmp_id);
else
link = NULL;
else
link = NULL;
if (link != NULL)
{
if (ip->ip_p == IPPROTO_UDP || ip->ip_p == IPPROTO_TCP)
{
u_short *sptr;
int accumulate;
struct in_addr original_address;
u_short original_port;
original_address = GetOriginalAddress(link);
original_port = GetOriginalPort(link);
/* Adjust ICMP checksum */
sptr = (u_short *) &(ip->ip_src);
accumulate = *sptr++;
accumulate += *sptr;
sptr = (u_short *) &original_address;
accumulate -= *sptr++;
accumulate -= *sptr;
accumulate += ud->uh_sport;
accumulate -= original_port;
ADJUST_CHECKSUM(accumulate, ic->icmp_cksum)
/* Un-alias address in IP header */
DifferentialChecksum(&pip->ip_sum,
(u_short *) &original_address,
(u_short *) &pip->ip_dst,
2);
pip->ip_dst = original_address;
/* Un-alias address and port number of original IP packet
fragment contained in ICMP data section */
ip->ip_src = original_address;
ud->uh_sport = original_port;
}
else if (pip->ip_p == IPPROTO_ICMP)
{
u_short *sptr;
int accumulate;
struct in_addr original_address;
u_short original_id;
original_address = GetOriginalAddress(link);
original_id = GetOriginalPort(link);
/* Adjust ICMP checksum */
sptr = (u_short *) &(ip->ip_src);
accumulate = *sptr++;
accumulate += *sptr;
sptr = (u_short *) &original_address;
accumulate -= *sptr++;
accumulate -= *sptr;
accumulate += ic2->icmp_id;
accumulate -= original_id;
ADJUST_CHECKSUM(accumulate, ic->icmp_cksum)
/* Un-alias address in IP header */
DifferentialChecksum(&pip->ip_sum,
(u_short *) &original_address,
(u_short *) &pip->ip_dst,
2);
pip->ip_dst = original_address;
/* Un-alias address of original IP packet and seqence number of
embedded icmp datagram */
ip->ip_src = original_address;
ic2->icmp_id = original_id;
}
return(PKT_ALIAS_OK);
}
return(PKT_ALIAS_IGNORED);
}
static int
IcmpAliasIn3(struct ip *pip)
{
struct in_addr original_address;
original_address = FindOriginalAddress(pip->ip_dst);
DifferentialChecksum(&pip->ip_sum,
(u_short *) &original_address,
(u_short *) &pip->ip_dst,
2);
pip->ip_dst = original_address;
return PKT_ALIAS_OK;
}
static int
IcmpAliasIn(struct ip *pip)
{
int iresult;
struct icmp *ic;
ic = (struct icmp *) ((char *) pip + (pip->ip_hl << 2));
iresult = PKT_ALIAS_IGNORED;
switch (ic->icmp_type)
{
case ICMP_ECHOREPLY:
case ICMP_TSTAMPREPLY:
if (ic->icmp_code == 0)
{
iresult = IcmpAliasIn1(pip);
}
break;
case ICMP_UNREACH:
case ICMP_SOURCEQUENCH:
case ICMP_TIMXCEED:
case ICMP_PARAMPROB:
iresult = IcmpAliasIn2(pip);
break;
case ICMP_ECHO:
case ICMP_TSTAMP:
iresult = IcmpAliasIn3(pip);
break;
}
return(iresult);
}
static int
IcmpAliasOut1(struct ip *pip)
{
/*
Alias ICMP echo and timestamp packets
*/
struct alias_link *link;
struct icmp *ic;
ic = (struct icmp *) ((char *) pip + (pip->ip_hl << 2));
/* Save overwritten data for when echo packet returns */
link = FindIcmpOut(pip->ip_src, pip->ip_dst, ic->icmp_id);
if (link != NULL)
{
u_short alias_id;
int accumulate;
alias_id = GetAliasPort(link);
/* Since data field is being modified, adjust ICMP checksum */
accumulate = ic->icmp_id;
accumulate -= alias_id;
ADJUST_CHECKSUM(accumulate, ic->icmp_cksum)
/* Alias sequence number */
ic->icmp_id = alias_id;
/* Change source address */
{
struct in_addr alias_address;
alias_address = GetAliasAddress(link);
DifferentialChecksum(&pip->ip_sum,
(u_short *) &alias_address,
(u_short *) &pip->ip_src,
2);
pip->ip_src = alias_address;
}
return(PKT_ALIAS_OK);
}
return(PKT_ALIAS_IGNORED);
}
static int
IcmpAliasOut2(struct ip *pip)
{
/*
Alias outgoing ICMP error messages containing
IP header and first 64 bits of datagram.
*/
struct in_addr alias_addr;
struct ip *ip;
struct icmp *ic;
ic = (struct icmp *) ((char *) pip + (pip->ip_hl << 2));
ip = (struct ip *) ic->icmp_data;
alias_addr = FindAliasAddress(ip->ip_src);
/* Alias destination address in IP fragment */
DifferentialChecksum(&ic->icmp_cksum,
(u_short *) &alias_addr,
(u_short *) &ip->ip_dst,
2);
ip->ip_dst = alias_addr;
/* alias source address in IP header */
DifferentialChecksum(&pip->ip_sum,
(u_short *) &alias_addr,
(u_short *) &pip->ip_src,
2);
pip->ip_src = alias_addr;
return PKT_ALIAS_OK;
}
static int
IcmpAliasOut3(struct ip *pip)
{
/*
Handle outgoing echo and timestamp replies. The
only thing which is done in this case is to alias
the source IP address of the packet.
*/
struct in_addr alias_addr;
alias_addr = FindAliasAddress(pip->ip_src);
DifferentialChecksum(&pip->ip_sum,
(u_short *) &alias_addr,
(u_short *) &pip->ip_src,
2);
pip->ip_src = alias_addr;
return PKT_ALIAS_OK;
}
static int
IcmpAliasOut(struct ip *pip)
{
int iresult;
struct icmp *ic;
ic = (struct icmp *) ((char *) pip + (pip->ip_hl << 2));
iresult = PKT_ALIAS_IGNORED;
switch (ic->icmp_type)
{
case ICMP_ECHO:
case ICMP_TSTAMP:
if (ic->icmp_code == 0)
{
iresult = IcmpAliasOut1(pip);
}
break;
case ICMP_UNREACH:
case ICMP_SOURCEQUENCH:
case ICMP_TIMXCEED:
case ICMP_PARAMPROB:
iresult = IcmpAliasOut2(pip);
break;
case ICMP_ECHOREPLY:
case ICMP_TSTAMPREPLY:
iresult = IcmpAliasOut3(pip);
}
return(iresult);
}
static int
UdpAliasIn(struct ip *pip)
{
struct udphdr *ud;
struct alias_link *link;
ud = (struct udphdr *) ((char *) pip + (pip->ip_hl << 2));
link = FindUdpTcpIn(pip->ip_src, pip->ip_dst,
ud->uh_sport, ud->uh_dport,
IPPROTO_UDP);
if (link != NULL)
{
struct in_addr alias_address;
struct in_addr original_address;
u_short alias_port;
int accumulate;
u_short *sptr;
alias_address = GetAliasAddress(link);
original_address = GetOriginalAddress(link);
alias_port = ud->uh_dport;
ud->uh_dport = GetOriginalPort(link);
/* If UDP checksum is not zero, then adjust since destination port */
/* is being unaliased and destination port is being altered. */
if (ud->uh_sum != 0)
{
accumulate = alias_port;
accumulate -= ud->uh_dport;
sptr = (u_short *) &alias_address;
accumulate += *sptr++;
accumulate += *sptr;
sptr = (u_short *) &original_address;
accumulate -= *sptr++;
accumulate -= *sptr;
ADJUST_CHECKSUM(accumulate, ud->uh_sum)
}
/* Restore original IP address */
DifferentialChecksum(&pip->ip_sum,
(u_short *) &original_address,
(u_short *) &pip->ip_dst,
2);
pip->ip_dst = original_address;
return(PKT_ALIAS_OK);
}
return(PKT_ALIAS_IGNORED);
}
static int
UdpAliasOut(struct ip *pip)
{
struct udphdr *ud;
struct alias_link *link;
ud = (struct udphdr *) ((char *) pip + (pip->ip_hl << 2));
link = FindUdpTcpOut(pip->ip_src, pip->ip_dst,
ud->uh_sport, ud->uh_dport,
IPPROTO_UDP);
if (link != NULL)
{
u_short alias_port;
struct in_addr alias_address;
alias_address = GetAliasAddress(link);
alias_port = GetAliasPort(link);
/* If UDP checksum is not zero, adjust since source port is */
/* being aliased and source address is being altered */
if (ud->uh_sum != 0)
{
int accumulate;
u_short *sptr;
accumulate = ud->uh_sport;
accumulate -= alias_port;
sptr = (u_short *) &(pip->ip_src);
accumulate += *sptr++;
accumulate += *sptr;
sptr = (u_short *) &alias_address;
accumulate -= *sptr++;
accumulate -= *sptr;
ADJUST_CHECKSUM(accumulate, ud->uh_sum)
}
/* Put alias port in TCP header */
ud->uh_sport = alias_port;
/* Change source address */
DifferentialChecksum(&pip->ip_sum,
(u_short *) &alias_address,
(u_short *) &pip->ip_src,
2);
pip->ip_src = alias_address;
return(PKT_ALIAS_OK);
}
return(PKT_ALIAS_IGNORED);
}
static int
TcpAliasIn(struct ip *pip)
{
struct tcphdr *tc;
struct alias_link *link;
tc = (struct tcphdr *) ((char *) pip + (pip->ip_hl << 2));
link = FindUdpTcpIn(pip->ip_src, pip->ip_dst,
tc->th_sport, tc->th_dport,
IPPROTO_TCP);
if (link != NULL)
{
struct in_addr alias_address;
struct in_addr original_address;
u_short alias_port;
int accumulate;
u_short *sptr;
alias_address = GetAliasAddress(link);
original_address = GetOriginalAddress(link);
alias_port = tc->th_dport;
tc->th_dport = GetOriginalPort(link);
/* Adjust TCP checksum since destination port is being unaliased */
/* and destination port is being altered. */
accumulate = alias_port;
accumulate -= tc->th_dport;
sptr = (u_short *) &alias_address;
accumulate += *sptr++;
accumulate += *sptr;
sptr = (u_short *) &original_address;
accumulate -= *sptr++;
accumulate -= *sptr;
/* See if ack number needs to be modified */
if (GetAckModified(link) == 1)
{
int delta;
delta = GetDeltaAckIn(pip, link);
if (delta != 0)
{
sptr = (u_short *) &tc->th_ack;
accumulate += *sptr++;
accumulate += *sptr;
tc->th_ack = htonl(ntohl(tc->th_ack) - delta);
sptr = (u_short *) &tc->th_ack;
accumulate -= *sptr++;
accumulate -= *sptr;
}
}
ADJUST_CHECKSUM(accumulate, tc->th_sum);
/* Restore original IP address */
DifferentialChecksum(&pip->ip_sum,
(u_short *) &original_address,
(u_short *) &pip->ip_dst,
2);
pip->ip_dst = original_address;
/* Monitor TCP connection state */
TcpMonitorIn(pip, link);
return(PKT_ALIAS_OK);
}
return(PKT_ALIAS_IGNORED);
}
static int
TcpAliasOut(struct ip *pip, int maxpacketsize)
{
struct tcphdr *tc;
struct alias_link *link;
tc = (struct tcphdr *) ((char *) pip + (pip->ip_hl << 2));
link = FindUdpTcpOut(pip->ip_src, pip->ip_dst,
tc->th_sport, tc->th_dport,
IPPROTO_TCP);
if (link !=NULL)
{
struct in_addr alias_address;
u_short alias_port;
int accumulate;
u_short *sptr;
alias_port = GetAliasPort(link);
alias_address = GetAliasAddress(link);
/* Monitor tcp connection state */
TcpMonitorOut(pip, link);
/* Special processing for ftp connection */
if (ntohs(tc->th_dport) == FTP_CONTROL_PORT_NUMBER
|| ntohs(tc->th_sport) == FTP_CONTROL_PORT_NUMBER)
AliasHandleFtpOut(pip, link, maxpacketsize);
if (ntohs(tc->th_dport) == IRC_CONTROL_PORT_NUMBER_1
|| ntohs(tc->th_dport) == IRC_CONTROL_PORT_NUMBER_2)
AliasHandleIrcOut(pip, link, maxpacketsize);
/* Adjust TCP checksum since source port is being aliased */
/* and source address is being altered */
accumulate = tc->th_sport;
accumulate -= alias_port;
sptr = (u_short *) &(pip->ip_src);
accumulate += *sptr++;
accumulate += *sptr;
sptr = (u_short *) &alias_address;
accumulate -= *sptr++;
accumulate -= *sptr;
/* Modify sequence number if necessary */
if (GetAckModified(link) == 1)
{
int delta;
delta = GetDeltaSeqOut(pip, link);
if (delta != 0)
{
sptr = (u_short *) &tc->th_seq;
accumulate += *sptr++;
accumulate += *sptr;
tc->th_seq = htonl(ntohl(tc->th_seq) + delta);
sptr = (u_short *) &tc->th_seq;
accumulate -= *sptr++;
accumulate -= *sptr;
}
}
ADJUST_CHECKSUM(accumulate, tc->th_sum)
/* Put alias address in TCP header */
tc->th_sport = alias_port;
/* Change source address */
DifferentialChecksum(&pip->ip_sum,
(u_short *) &alias_address,
(u_short *) &pip->ip_src,
2);
pip->ip_src = alias_address;
return(PKT_ALIAS_OK);
}
return(PKT_ALIAS_IGNORED);
}
/* Fragment Handling
FragmentIn()
FragmentOut()
The packet aliasing module has a limited ability for handling IP
fragments. If the ICMP, TCP or UDP header is in the first fragment
received, then the id number of the IP packet is saved, and other
fragments are identified according to their ID number and IP address
they were sent from. Pointers to unresolved fragments can also be
saved and recalled when a header fragment is seen.
*/
/* Local prototypes */
static int FragmentIn(struct ip *);
static int FragmentOut(struct ip *);
static int
FragmentIn(struct ip *pip)
{
struct alias_link *link;
link = FindFragmentIn2(pip->ip_src, pip->ip_dst, pip->ip_id);
if (link != NULL)
{
struct in_addr original_address;
GetFragmentAddr(link, &original_address);
DifferentialChecksum(&pip->ip_sum,
(u_short *) &original_address,
(u_short *) &pip->ip_dst,
2);
pip->ip_dst = original_address;
return(PKT_ALIAS_OK);
}
return(PKT_ALIAS_UNRESOLVED_FRAGMENT);
}
static int
FragmentOut(struct ip *pip)
{
struct in_addr alias_address;
alias_address = FindAliasAddress(pip->ip_src);
DifferentialChecksum(&pip->ip_sum,
(u_short *) &alias_address,
(u_short *) &pip->ip_src,
2);
pip->ip_src = alias_address;
return(PKT_ALIAS_OK);
}
/* Outside World Access
SaveFragmentPtr()
GetNextFragmentPtr()
FragmentAliasIn()
PacketAliasIn()
PacketAliasOut()
PacketAliasIn2()
PacketAliasOut2()
(prototypes in alias.h)
*/
int
SaveFragmentPtr(char *ptr)
{
int iresult;
struct alias_link *link;
struct ip *pip;
pip = (struct ip *) ptr;
link = AddFragmentPtrLink(pip->ip_src, pip->ip_id);
iresult = PKT_ALIAS_ERROR;
if (link != NULL)
{
SetFragmentPtr(link, ptr);
iresult = PKT_ALIAS_OK;
}
return(iresult);
}
char *
GetNextFragmentPtr(char *ptr)
{
struct alias_link *link;
char *fptr;
struct ip *pip;
pip = (struct ip *) ptr;
link = FindFragmentPtr(pip->ip_src, pip->ip_id);
if (link != NULL)
{
GetFragmentPtr(link, &fptr);
SetExpire(link, 0); /* Deletes link */
return(fptr);
}
else
{
return(NULL);
}
}
void
FragmentAliasIn(char *ptr, /* Points to correctly de-aliased
header fragment */
char *ptr_fragment /* Points to fragment which must
be de-aliased */
)
{
struct ip *pip;
struct ip *fpip;
pip = (struct ip *) ptr;
fpip = (struct ip *) ptr_fragment;
DifferentialChecksum(&fpip->ip_sum,
(u_short *) &pip->ip_dst,
(u_short *) &fpip->ip_dst,
2);
fpip->ip_dst = pip->ip_dst;
}
int
PacketAliasIn(char *ptr, int maxpacketsize)
{
struct in_addr alias_addr;
struct ip *pip;
int iresult;
HouseKeeping();
pip = (struct ip *) ptr;
alias_addr = pip->ip_dst;
iresult = PKT_ALIAS_IGNORED;
if ( (ntohs(pip->ip_off) & IP_OFFMASK) == 0 )
{
switch (pip->ip_p)
{
case IPPROTO_ICMP:
iresult = IcmpAliasIn(pip);
break;
case IPPROTO_UDP:
iresult = UdpAliasIn(pip);
break;
case IPPROTO_TCP:
iresult = TcpAliasIn(pip);
break;
}
if (ntohs(pip->ip_off) & IP_MF)
{
struct alias_link *link;
link = FindFragmentIn1(pip->ip_src, alias_addr, pip->ip_id);
if (link != NULL)
{
iresult = PKT_ALIAS_FOUND_HEADER_FRAGMENT;
SetFragmentAddr(link, pip->ip_dst);
}
else
{
iresult = PKT_ALIAS_ERROR;
}
}
}
else
{
iresult = FragmentIn(pip);
}
return(iresult);
}
/* Unregistered address ranges */
/* 10.0.0.0 -> 10.255.255.255 */
#define UNREG_ADDR_A_LOWER 0x0a000000
#define UNREG_ADDR_A_UPPER 0x0affffff
/* 172.16.0.0 -> 172.31.255.255 */
#define UNREG_ADDR_B_LOWER 0xac100000
#define UNREG_ADDR_B_UPPER 0xac1fffff
/* 192.168.0.0 -> 192.168.255.255 */
#define UNREG_ADDR_C_LOWER 0xc0a80000
#define UNREG_ADDR_C_UPPER 0xc0a8ffff
int
PacketAliasOut(char *ptr, /* valid IP packet */
int maxpacketsize /* How much the packet data may grow
(FTP and IRC inline changes) */
)
{
int iresult;
struct in_addr addr_save;
struct ip *pip;
HouseKeeping();
pip = (struct ip *) ptr;
addr_save = GetDefaultAliasAddress();
if (packetAliasMode & PKT_ALIAS_UNREGISTERED_ONLY)
{
unsigned int addr;
int iclass;
iclass = 0;
addr = ntohl(pip->ip_src.s_addr);
if (addr >= UNREG_ADDR_C_LOWER && addr <= UNREG_ADDR_C_UPPER)
iclass = 3;
else if (addr >= UNREG_ADDR_B_LOWER && addr <= UNREG_ADDR_B_UPPER)
iclass = 2;
else if (addr >= UNREG_ADDR_A_LOWER && addr <= UNREG_ADDR_A_UPPER)
iclass = 1;
if (iclass == 0)
{
SetDefaultAliasAddress(pip->ip_src);
}
}
iresult = PKT_ALIAS_IGNORED;
if ((ntohs(pip->ip_off) & IP_OFFMASK) == 0)
{
switch (pip->ip_p)
{
case IPPROTO_ICMP:
iresult = IcmpAliasOut(pip);
break;
case IPPROTO_UDP:
iresult = UdpAliasOut(pip);
break;
case IPPROTO_TCP:
iresult = TcpAliasOut(pip, maxpacketsize);
break;
}
}
else
{
iresult = FragmentOut(pip);
}
SetDefaultAliasAddress(addr_save);
return(iresult);
}
int
PacketAliasIn2(char *ptr, /* valid IP packet */
struct in_addr addr, /* Default aliasing address */
int maxpacketsize /* How much the packet data may grow
(FTP and IRC inline changes) */
)
{
int result_code;
struct in_addr addr_save;
ClearNewDefaultLink();
addr_save = GetDefaultAliasAddress();
SetDefaultTargetAddress(addr);
result_code = PacketAliasIn(ptr, maxpacketsize);
ClearDefaultTargetAddress();
if (result_code == PKT_ALIAS_OK)
{
if (CheckNewDefaultLink())
return PKT_ALIAS_NEW_LINK;
}
return result_code;
}
int
PacketAliasOut2(char *ptr, /* valid IP packet */
struct in_addr addr, /* Default aliasing address */
int maxpacketsize /* How much the packet data may grow
(FTP and IRC inline changes) */
)
{
int result_code;
struct in_addr addr_save;
ClearNewDefaultLink();
addr_save = GetDefaultAliasAddress();
SetDefaultAliasAddress(addr);
result_code = PacketAliasOut(ptr, maxpacketsize);
SetDefaultAliasAddress(addr_save);
if (result_code == PKT_ALIAS_OK)
{
if (CheckNewDefaultLink())
return PKT_ALIAS_NEW_LINK;
}
return result_code;
}