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packETH 1.4
packETH is a Linux GUI packet generator tool for ethernet. more>>
packETH is a Linux GUI packet generator tool for ethernet. The project allows you to create and send any possible packet or sequence of packets on the ethernet.
Main features:
you can create and send any ethernet packet. Supported protocols:
- ethernet II, ethernet 802.3, 802.1q, QinQ
- ARP, IPv4, user defined network layer payload
- UDP, TCP, ICMP, IGMP, user defined transport layer payload
- RTP (payload with options to send sin wave of any frequency for G.711)
sending sequence of packets
- delay between packets, number of packets to send
- sending with max speed, approaching the teoretical boundary
- change parameters while sending (change IP & mac address, UDP payload, 2 user defined bytes, etc.)
saving configuration to a text file and load from it.
Enhancements:
- new features
<<lessMain features:
you can create and send any ethernet packet. Supported protocols:
- ethernet II, ethernet 802.3, 802.1q, QinQ
- ARP, IPv4, user defined network layer payload
- UDP, TCP, ICMP, IGMP, user defined transport layer payload
- RTP (payload with options to send sin wave of any frequency for G.711)
sending sequence of packets
- delay between packets, number of packets to send
- sending with max speed, approaching the teoretical boundary
- change parameters while sending (change IP & mac address, UDP payload, 2 user defined bytes, etc.)
saving configuration to a text file and load from it.
Enhancements:
- new features
Download (0.13MB)
Added: 2007-02-19 License: GPL (GNU General Public License) Price:
980 downloads
RADIUS::Packet 1.0
RADIUS::Packet is an object-oriented Perl interface to RADIUS packets. more>>
RADIUS::Packet is an object-oriented Perl interface to RADIUS packets.
SYNOPSIS
use RADIUS::Packet;
use RADIUS::Dictionary;
my $d = new RADIUS::Dictionary "/etc/radius/dictionary";
my $p = new RADIUS::Packet $d, $data;
$p->dump;
if ($p->attr(User-Name eq "lwall") {
my $resp = new RADIUS::Packet $d;
$resp->set_code(Access-Accept);
$resp->set_identifier($p->identifier);
$resp->set_authenticator($p->authenticator);
$resp->set_attr(Reply-Message) = "Welcome, Larry!rn";
my $respdat = auth_resp($resp->pack, "mysecret");
...
RADIUS (RFC2138) specifies a binary packet format which contains various values and attributes. RADIUS::Packet provides an interface to turn RADIUS packets into Perl data structures and vice-versa.
RADIUS::Packet does not provide functions for obtaining RADIUS packets from the network. A simple network RADIUS server is provided as an example at the end of this document. Also, a RADIUS::Server module is under development which will simplify the interface.
<<lessSYNOPSIS
use RADIUS::Packet;
use RADIUS::Dictionary;
my $d = new RADIUS::Dictionary "/etc/radius/dictionary";
my $p = new RADIUS::Packet $d, $data;
$p->dump;
if ($p->attr(User-Name eq "lwall") {
my $resp = new RADIUS::Packet $d;
$resp->set_code(Access-Accept);
$resp->set_identifier($p->identifier);
$resp->set_authenticator($p->authenticator);
$resp->set_attr(Reply-Message) = "Welcome, Larry!rn";
my $respdat = auth_resp($resp->pack, "mysecret");
...
RADIUS (RFC2138) specifies a binary packet format which contains various values and attributes. RADIUS::Packet provides an interface to turn RADIUS packets into Perl data structures and vice-versa.
RADIUS::Packet does not provide functions for obtaining RADIUS packets from the network. A simple network RADIUS server is provided as an example at the end of this document. Also, a RADIUS::Server module is under development which will simplify the interface.
Download (0.042MB)
Added: 2007-04-11 License: Perl Artistic License Price:
931 downloads
Advanced Packet Sniffer 0.19
Aps is a small tool for analyzing network traffic. more>>
Aps is a small tool for analyzing network traffic. It prints out a great deal of information about the relevant protocols including TCP, UDP, ARP, and ICMP.
It allows you to filter IP addresses, hardware addresses, ports, and specific protocols. It comes with a little GTK-GUI displaying packet counters for each protocol.
APS tries to print detailed info about network frames that are received from the SOCK_RAW (ETH_P_ALL) socket. I am not sure if this is the clean way, but it works fine. APS prints info about the hardware layer and the IP and TCP/UDP/ICMP header.
The tail of the packet (mostly the data) wich could not be interpreted is written on the screen as ascii/hex-dump or both (your choice).
Example
HW-ADDR: 00:60:8c:f6:40:96 -----> 00:80:ad:30:8f:3b
IP-ADDR: 192.168.17.52 -----> 192.168.17.50
IP-Ver4 || Head:0x0a (bytes) || Service(TOS):16 || Length over all:0061
Fragmentation: ID:0x4079 - Flags: 0 1 0 - Offset:00000
TTL:064 || Protokoll:006 (TCP) || HeaderCRC:0x567b
TCP-HEADER:
Ports: 0023-->1034 (telnet) Seq./Ack. Nr.:0x70843468 / 0xeae29434
Data-Offset:0x05 Reserved-6Bit:00 Flags:-urg-ACK-PSH-rst-syn-fin-
Window:0x7fe0 CRC:0x9420 Urgent-Pointer:0x0000
73 61 74 75 72 6e 32 3a 2f 73 72 76 2f 70 72 69 6e 74 71 23 20
HW-ADDR: 52:54:40:25:8d:88 -----> ff:ff:ff:ff:ff:ff
SAMBA/NetBios
e0 e0 03 ff ff 00 22 00 11 00 00 00 00 ff ff ff ff ff ff 04 52 00 00 00 00 52
40 25 8d 88 40 08 00 03 00 04 20 20 20 20 20 20 20 20 20
HW-ADDR: 00:80:ad:30:8f:3b -----> 00:60:8c:f6:40:96
IP-ADDR: 192.168.17.50 -----> 194.112.123.200
IP-Ver4 || Head:0x0a (bytes) || Service(TOS):0 || Length over all:0029
Fragmentation: ID:0x29ae - Flags: 0 0 0 - Offset:00000
TTL:064 || Protokoll:001 (ICMP) || HeaderCRC:0x411f
echo request CODE:0x0 CRC:0xf9f5 SIG:0x602 NUM:0x0
00 ea
Enhancements:
- added break for Packet-counter and fixed some minor bugs
<<lessIt allows you to filter IP addresses, hardware addresses, ports, and specific protocols. It comes with a little GTK-GUI displaying packet counters for each protocol.
APS tries to print detailed info about network frames that are received from the SOCK_RAW (ETH_P_ALL) socket. I am not sure if this is the clean way, but it works fine. APS prints info about the hardware layer and the IP and TCP/UDP/ICMP header.
The tail of the packet (mostly the data) wich could not be interpreted is written on the screen as ascii/hex-dump or both (your choice).
Example
HW-ADDR: 00:60:8c:f6:40:96 -----> 00:80:ad:30:8f:3b
IP-ADDR: 192.168.17.52 -----> 192.168.17.50
IP-Ver4 || Head:0x0a (bytes) || Service(TOS):16 || Length over all:0061
Fragmentation: ID:0x4079 - Flags: 0 1 0 - Offset:00000
TTL:064 || Protokoll:006 (TCP) || HeaderCRC:0x567b
TCP-HEADER:
Ports: 0023-->1034 (telnet) Seq./Ack. Nr.:0x70843468 / 0xeae29434
Data-Offset:0x05 Reserved-6Bit:00 Flags:-urg-ACK-PSH-rst-syn-fin-
Window:0x7fe0 CRC:0x9420 Urgent-Pointer:0x0000
73 61 74 75 72 6e 32 3a 2f 73 72 76 2f 70 72 69 6e 74 71 23 20
HW-ADDR: 52:54:40:25:8d:88 -----> ff:ff:ff:ff:ff:ff
SAMBA/NetBios
e0 e0 03 ff ff 00 22 00 11 00 00 00 00 ff ff ff ff ff ff 04 52 00 00 00 00 52
40 25 8d 88 40 08 00 03 00 04 20 20 20 20 20 20 20 20 20
HW-ADDR: 00:80:ad:30:8f:3b -----> 00:60:8c:f6:40:96
IP-ADDR: 192.168.17.50 -----> 194.112.123.200
IP-Ver4 || Head:0x0a (bytes) || Service(TOS):0 || Length over all:0029
Fragmentation: ID:0x29ae - Flags: 0 0 0 - Offset:00000
TTL:064 || Protokoll:001 (ICMP) || HeaderCRC:0x411f
echo request CODE:0x0 CRC:0xf9f5 SIG:0x602 NUM:0x0
00 ea
Enhancements:
- added break for Packet-counter and fixed some minor bugs
Download (0.088MB)
Added: 2005-09-21 License: GPL (GNU General Public License) Price:
1512 downloads
deja-packet 1.0
deja-packet transmits raw packets through a specified interface. more>>
deja-packet transmits raw packets through a specified interface.
Usage: ./deja-packet -pcap < libpcap capture file > < interface name >
or: ./deja-packet -raw < raw packet file > < interface name >
Note: you must be root to successfully transmit packets with deja-packet due to the Linux security restrictions with raw sockets.
In the [-p]cap mode, deja-packet transmits selected packets from a libpcap capture file (such as one created by Ethereal/Wireshark, or tcpdump). In the [-r]aw mode, deja-packet transmits the raw contents of a file as one whole packet.
The [-p]cap mode is interactive: the user will be continuously prompted to select which packet from the libpcap capture file to transmit, until the “q” character is encountered, where the program will quit.
Example pcap mode:
$ sudo ./deja-packet -p icmp_ping.pcap eth0
Select packet number (1 to 6) for transmission or q for quit: 1
Successfully transmitted packet!
Select packet number (1 to 6) for transmission or q for quit: 2
Successfully transmitted packet!
Select packet number (1 to 6) for transmission or q for quit: 5
Successfully transmitted packet!
Select packet number (1 to 6) for transmission or q for quit: 6
Successfully transmitted packet!
Select packet number (1 to 6) for transmission or q for quit: q
$
In the [-r]aw mode, deja-packet exits immediately after the attempted transmission is complete (allows deja-packet to be easily used with a script).
Example raw mode:
$ sudo ./deja-packet -r samplepacket eth0
Successfully transmitted packet!
$
icmp_ping.pcap is included as a sample libpcap capture file.
To compile deja-packet, simply use the command “make”.
deja-packet remains Linux-only because it requires PF_PACKET sockets.
This project is released under the GNU General Public License version 2.
<<lessUsage: ./deja-packet -pcap < libpcap capture file > < interface name >
or: ./deja-packet -raw < raw packet file > < interface name >
Note: you must be root to successfully transmit packets with deja-packet due to the Linux security restrictions with raw sockets.
In the [-p]cap mode, deja-packet transmits selected packets from a libpcap capture file (such as one created by Ethereal/Wireshark, or tcpdump). In the [-r]aw mode, deja-packet transmits the raw contents of a file as one whole packet.
The [-p]cap mode is interactive: the user will be continuously prompted to select which packet from the libpcap capture file to transmit, until the “q” character is encountered, where the program will quit.
Example pcap mode:
$ sudo ./deja-packet -p icmp_ping.pcap eth0
Select packet number (1 to 6) for transmission or q for quit: 1
Successfully transmitted packet!
Select packet number (1 to 6) for transmission or q for quit: 2
Successfully transmitted packet!
Select packet number (1 to 6) for transmission or q for quit: 5
Successfully transmitted packet!
Select packet number (1 to 6) for transmission or q for quit: 6
Successfully transmitted packet!
Select packet number (1 to 6) for transmission or q for quit: q
$
In the [-r]aw mode, deja-packet exits immediately after the attempted transmission is complete (allows deja-packet to be easily used with a script).
Example raw mode:
$ sudo ./deja-packet -r samplepacket eth0
Successfully transmitted packet!
$
icmp_ping.pcap is included as a sample libpcap capture file.
To compile deja-packet, simply use the command “make”.
deja-packet remains Linux-only because it requires PF_PACKET sockets.
This project is released under the GNU General Public License version 2.
Download (0.004MB)
Added: 2007-07-04 License: GPL (GNU General Public License) Price:
847 downloads
Stone TCP/IP packet repeater 2.3c
Stone is an application layer TCP/IP packet repeater. more>>
Stone is an application layer TCP/IP packet repeater. It repeats TCP and UDP packets from the inside of a firewall to the outside or vice versa.
It is simple, supports OpenSSL for encrypting and decrypting packets, performing client and server verifications, and sending a substring of the subject of the certificate to the destination, can operate as an HTTP proxy, and performs POP to APOP conversion. It also supports IPv6 and can convert between IPv4 and IPv6 each other.
<<lessIt is simple, supports OpenSSL for encrypting and decrypting packets, performing client and server verifications, and sending a substring of the subject of the certificate to the destination, can operate as an HTTP proxy, and performs POP to APOP conversion. It also supports IPv6 and can convert between IPv4 and IPv6 each other.
Download (0.082MB)
Added: 2006-09-30 License: GPL (GNU General Public License) Price:
1125 downloads
Packet filtering setup script
Packet filtering setup script by Anthony C. Zboralski. more>>
Packet filtering setup script by Anthony C. Zboralski. Adapted by Didi Damian for iptables version 1.0.0
Sample:
PATH=/usr/local/sbin:/usr/local/bin:/sbin:/bin:/usr/sbin:/usr/bin
# Set up variables
EXT_IF="eth0"
INT_IF="eth1"
EXT_IP=24.x.x.x/32
INT_IP=192.168.0.1/32
EXT_NET=24.x.x.0/24
INT_NET=192.168.0.0/24
MASQ_NETS="192.168.0.0/24"
LOCAL_ADDRS="127.0.0.0/8 192.168.0.1/32 24.x.x.x/32"
MAIL_RELAY=24.x.x.x/32
SMB_ACCESS="192.168.0.2/32"
SMB_BCAST="192.168.0.255/32"
# Turn on IP forwarding
echo Turning on IP forwarding.
echo 1 > /proc/sys/net/ipv4/ip_forward
# Load the ip_tables module
echo Loading ip_tables module.
/sbin/modprobe ip_tables || exit 1
# I let the kernel dynamically load the other modules
echo Flush standard tables.
iptables --flush INPUT
iptables --flush OUTPUT
iptables --flush FORWARD
echo Deny everything until firewall setup is completed.
iptables --policy INPUT DROP
iptables --policy OUTPUT DROP
iptables --policy FORWARD DROP
CHAINS=`iptables -n -L |perl -n -e /Chains+(S+)/ && !($1 =~ /^(INPUT|FORWARD|OUTPUT)$/) && print "$1 "`
echo Remove remaining chains:
echo $CHAINS
for chain in $CHAINS; do
iptables --flush $chain
done
# 2nd step cause of dependencies
for chain in $CHAINS; do
iptables --delete-chain $chain
done
for net in $MASQ_NETS; do
# I delete all the rules so you can rerun the scripts without bloating
# your nat entries.
iptables -D POSTROUTING -t nat -s $MASQ_NETS -j MASQUERADE 2>/dev/null
iptables -A POSTROUTING -t nat -s $MASQ_NETS -j MASQUERADE || exit 1
done
iptables --policy FORWARD ACCEPT
# Create a target for logging and dropping packets
iptables --new LDROP 2>/dev/null
iptables -A LDROP --proto tcp -j LOG --log-level info
--log-prefix "TCP Drop "
iptables -A LDROP --proto udp -j LOG --log-level info
--log-prefix "UDP Drop "
iptables -A LDROP --proto icmp -j LOG --log-level info
--log-prefix "ICMP Drop "
iptables -A LDROP --proto gre -j LOG --log-level info
--log-prefix "GRE Drop "
iptables -A LDROP -f -j LOG --log-level emerg
--log-prefix "FRAG Drop "
iptables -A LDROP -j DROP
# Create a table for watching some accepting rules
iptables --new WATCH 2>/dev/null
iptables -A WATCH -m limit -j LOG --log-level warn --log-prefix "ACCEPT "
iptables -A WATCH -j ACCEPT
echo Special target for local addresses:
iptables --new LOCAL 2>/dev/null
echo $LOCAL_ADDRS
for ip in $LOCAL_ADDRS; do
iptables -A INPUT --dst $ip -j LOCAL
# iptables -A INPUT --src $ip -i ! lo -j LDROP # lame spoof protect
done
echo Authorize mail from mail relay.
iptables -A LOCAL --proto tcp --syn --src $MAIL_RELAY --dst $EXT_IP --dport 25 -j ACCEPT
echo Authorizing samba access to:
echo $SMB_ACCESS
iptables --new SMB 2>/dev/null
for ip in $SMB_ACCESS; do
iptables -A SMB -s $ip -j ACCEPT
done
iptables -A LOCAL --proto udp -i ! $EXT_IF --dport 135:139 -j SMB
iptables -A LOCAL --proto tcp -i ! $EXT_IF --dport 135:139 -j SMB
iptables -A LOCAL --proto tcp -i ! $EXT_IF --dport 445 -j SMB
iptables -A INPUT -i ! $EXT_IF --dst $SMB_BCAST -j ACCEPT #lame samba broadcast
echo Drop and log every other incoming tcp connection attempts.
iptables -A LOCAL -i ! lo --proto tcp --syn --j LDROP
echo Authorize dns access for local nets.
for net in $MASQ_NETS 127.0.0.0/8; do
iptables -A INPUT --proto udp --src $net --dport 53 -j ACCEPT
done
echo Enforcing up ICMP policies, use iptables -L ICMP to check.
# If you deny all ICMP messages you head for trouble since it would
# break lots of tcp/ip algorythm (acz)
iptables --new ICMP 2>/dev/null
iptables -A INPUT --proto icmp -j ICMP
iptables -A ICMP -p icmp --icmp-type echo-reply -j ACCEPT
iptables -A ICMP -p icmp --icmp-type destination-unreachable -j WATCH
iptables -A ICMP -p icmp --icmp-type network-unreachable -j WATCH
iptables -A ICMP -p icmp --icmp-type host-unreachable -j WATCH
iptables -A ICMP -p icmp --icmp-type protocol-unreachable -j WATCH
iptables -A ICMP -p icmp --icmp-type port-unreachable -j ACCEPT
iptables -A ICMP -p icmp --icmp-type fragmentation-needed -j LDROP
iptables -A ICMP -p icmp --icmp-type source-route-failed -j WATCH
iptables -A ICMP -p icmp --icmp-type network-unknown -j WATCH
iptables -A ICMP -p icmp --icmp-type host-unknown -j WATCH
iptables -A ICMP -p icmp --icmp-type network-prohibited -j WATCH
iptables -A ICMP -p icmp --icmp-type host-prohibited -j WATCH
iptables -A ICMP -p icmp --icmp-type TOS-network-unreachable -j WATCH
iptables -A ICMP -p icmp --icmp-type TOS-host-unreachable -j WATCH
iptables -A ICMP -p icmp --icmp-type communication-prohibited -j WATCH
iptables -A ICMP -p icmp --icmp-type host-precedence-violation -j LDROP
iptables -A ICMP -p icmp --icmp-type precedence-cutoff -j LDROP
iptables -A ICMP -p icmp --icmp-type source-quench -j LDROP
iptables -A ICMP -p icmp --icmp-type redirect -j LDROP
iptables -A ICMP -p icmp --icmp-type network-redirect -j LDROP
iptables -A ICMP -p icmp --icmp-type host-redirect -j LDROP
iptables -A ICMP -p icmp --icmp-type TOS-network-redirect -j LDROP
iptables -A ICMP -p icmp --icmp-type TOS-host-redirect -j LDROP
iptables -A ICMP -p icmp --icmp-type echo-request -j WATCH
iptables -A ICMP -p icmp --icmp-type router-advertisement -j LDROP
iptables -A ICMP -p icmp --icmp-type router-solicitation -j LDROP
iptables -A ICMP -p icmp --icmp-type time-exceeded -j WATCH
iptables -A ICMP -p icmp --icmp-type ttl-zero-during-transit -j WATCH
iptables -A ICMP -p icmp --icmp-type ttl-zero-during-reassembly -j WATCH
iptables -A ICMP -p icmp --icmp-type parameter-problem -j WATCH
iptables -A ICMP -p icmp --icmp-type ip-header-bad -j WATCH
iptables -A ICMP -p icmp --icmp-type required-option-missing -j WATCH
iptables -A ICMP -p icmp --icmp-type timestamp-request -j LDROP
iptables -A ICMP -p icmp --icmp-type timestamp-reply -j LDROP
iptables -A ICMP -p icmp --icmp-type address-mask-request -j LDROP
iptables -A ICMP -p icmp --icmp-type address-mask-reply -j LDROP
iptables -A ICMP -p icmp -j LDROP
echo Authorize tcp traffic.
iptables -A INPUT --proto tcp -j ACCEPT
echo Authorize packet output.
iptables --policy OUTPUT ACCEPT
#echo reject ident if you drop em you gotta wait for timeout
#iptables -I LOCAL --proto tcp --syn --dst $EXT_IP --dport 113 -j REJECT
echo Drop and log all udp below 1024.
iptables -A INPUT -i ! lo --proto udp --dport :1023 -j LDROP
echo Drop rpc dynamic udp port:
RPC_UDP=`rpcinfo -p localhost|perl -n -e /.*udps+(d+)s+/ && print $1,"n"|sort -u`
echo $RPC_UDP
for port in $RPC_UDP; do
iptables -A LOCAL -i ! lo --proto udp --dport $port -j LDROP
done
echo Authorize udp above 1024.
iptables -A INPUT --proto udp --dport 1024: -j ACCEPT
<<lessSample:
PATH=/usr/local/sbin:/usr/local/bin:/sbin:/bin:/usr/sbin:/usr/bin
# Set up variables
EXT_IF="eth0"
INT_IF="eth1"
EXT_IP=24.x.x.x/32
INT_IP=192.168.0.1/32
EXT_NET=24.x.x.0/24
INT_NET=192.168.0.0/24
MASQ_NETS="192.168.0.0/24"
LOCAL_ADDRS="127.0.0.0/8 192.168.0.1/32 24.x.x.x/32"
MAIL_RELAY=24.x.x.x/32
SMB_ACCESS="192.168.0.2/32"
SMB_BCAST="192.168.0.255/32"
# Turn on IP forwarding
echo Turning on IP forwarding.
echo 1 > /proc/sys/net/ipv4/ip_forward
# Load the ip_tables module
echo Loading ip_tables module.
/sbin/modprobe ip_tables || exit 1
# I let the kernel dynamically load the other modules
echo Flush standard tables.
iptables --flush INPUT
iptables --flush OUTPUT
iptables --flush FORWARD
echo Deny everything until firewall setup is completed.
iptables --policy INPUT DROP
iptables --policy OUTPUT DROP
iptables --policy FORWARD DROP
CHAINS=`iptables -n -L |perl -n -e /Chains+(S+)/ && !($1 =~ /^(INPUT|FORWARD|OUTPUT)$/) && print "$1 "`
echo Remove remaining chains:
echo $CHAINS
for chain in $CHAINS; do
iptables --flush $chain
done
# 2nd step cause of dependencies
for chain in $CHAINS; do
iptables --delete-chain $chain
done
for net in $MASQ_NETS; do
# I delete all the rules so you can rerun the scripts without bloating
# your nat entries.
iptables -D POSTROUTING -t nat -s $MASQ_NETS -j MASQUERADE 2>/dev/null
iptables -A POSTROUTING -t nat -s $MASQ_NETS -j MASQUERADE || exit 1
done
iptables --policy FORWARD ACCEPT
# Create a target for logging and dropping packets
iptables --new LDROP 2>/dev/null
iptables -A LDROP --proto tcp -j LOG --log-level info
--log-prefix "TCP Drop "
iptables -A LDROP --proto udp -j LOG --log-level info
--log-prefix "UDP Drop "
iptables -A LDROP --proto icmp -j LOG --log-level info
--log-prefix "ICMP Drop "
iptables -A LDROP --proto gre -j LOG --log-level info
--log-prefix "GRE Drop "
iptables -A LDROP -f -j LOG --log-level emerg
--log-prefix "FRAG Drop "
iptables -A LDROP -j DROP
# Create a table for watching some accepting rules
iptables --new WATCH 2>/dev/null
iptables -A WATCH -m limit -j LOG --log-level warn --log-prefix "ACCEPT "
iptables -A WATCH -j ACCEPT
echo Special target for local addresses:
iptables --new LOCAL 2>/dev/null
echo $LOCAL_ADDRS
for ip in $LOCAL_ADDRS; do
iptables -A INPUT --dst $ip -j LOCAL
# iptables -A INPUT --src $ip -i ! lo -j LDROP # lame spoof protect
done
echo Authorize mail from mail relay.
iptables -A LOCAL --proto tcp --syn --src $MAIL_RELAY --dst $EXT_IP --dport 25 -j ACCEPT
echo Authorizing samba access to:
echo $SMB_ACCESS
iptables --new SMB 2>/dev/null
for ip in $SMB_ACCESS; do
iptables -A SMB -s $ip -j ACCEPT
done
iptables -A LOCAL --proto udp -i ! $EXT_IF --dport 135:139 -j SMB
iptables -A LOCAL --proto tcp -i ! $EXT_IF --dport 135:139 -j SMB
iptables -A LOCAL --proto tcp -i ! $EXT_IF --dport 445 -j SMB
iptables -A INPUT -i ! $EXT_IF --dst $SMB_BCAST -j ACCEPT #lame samba broadcast
echo Drop and log every other incoming tcp connection attempts.
iptables -A LOCAL -i ! lo --proto tcp --syn --j LDROP
echo Authorize dns access for local nets.
for net in $MASQ_NETS 127.0.0.0/8; do
iptables -A INPUT --proto udp --src $net --dport 53 -j ACCEPT
done
echo Enforcing up ICMP policies, use iptables -L ICMP to check.
# If you deny all ICMP messages you head for trouble since it would
# break lots of tcp/ip algorythm (acz)
iptables --new ICMP 2>/dev/null
iptables -A INPUT --proto icmp -j ICMP
iptables -A ICMP -p icmp --icmp-type echo-reply -j ACCEPT
iptables -A ICMP -p icmp --icmp-type destination-unreachable -j WATCH
iptables -A ICMP -p icmp --icmp-type network-unreachable -j WATCH
iptables -A ICMP -p icmp --icmp-type host-unreachable -j WATCH
iptables -A ICMP -p icmp --icmp-type protocol-unreachable -j WATCH
iptables -A ICMP -p icmp --icmp-type port-unreachable -j ACCEPT
iptables -A ICMP -p icmp --icmp-type fragmentation-needed -j LDROP
iptables -A ICMP -p icmp --icmp-type source-route-failed -j WATCH
iptables -A ICMP -p icmp --icmp-type network-unknown -j WATCH
iptables -A ICMP -p icmp --icmp-type host-unknown -j WATCH
iptables -A ICMP -p icmp --icmp-type network-prohibited -j WATCH
iptables -A ICMP -p icmp --icmp-type host-prohibited -j WATCH
iptables -A ICMP -p icmp --icmp-type TOS-network-unreachable -j WATCH
iptables -A ICMP -p icmp --icmp-type TOS-host-unreachable -j WATCH
iptables -A ICMP -p icmp --icmp-type communication-prohibited -j WATCH
iptables -A ICMP -p icmp --icmp-type host-precedence-violation -j LDROP
iptables -A ICMP -p icmp --icmp-type precedence-cutoff -j LDROP
iptables -A ICMP -p icmp --icmp-type source-quench -j LDROP
iptables -A ICMP -p icmp --icmp-type redirect -j LDROP
iptables -A ICMP -p icmp --icmp-type network-redirect -j LDROP
iptables -A ICMP -p icmp --icmp-type host-redirect -j LDROP
iptables -A ICMP -p icmp --icmp-type TOS-network-redirect -j LDROP
iptables -A ICMP -p icmp --icmp-type TOS-host-redirect -j LDROP
iptables -A ICMP -p icmp --icmp-type echo-request -j WATCH
iptables -A ICMP -p icmp --icmp-type router-advertisement -j LDROP
iptables -A ICMP -p icmp --icmp-type router-solicitation -j LDROP
iptables -A ICMP -p icmp --icmp-type time-exceeded -j WATCH
iptables -A ICMP -p icmp --icmp-type ttl-zero-during-transit -j WATCH
iptables -A ICMP -p icmp --icmp-type ttl-zero-during-reassembly -j WATCH
iptables -A ICMP -p icmp --icmp-type parameter-problem -j WATCH
iptables -A ICMP -p icmp --icmp-type ip-header-bad -j WATCH
iptables -A ICMP -p icmp --icmp-type required-option-missing -j WATCH
iptables -A ICMP -p icmp --icmp-type timestamp-request -j LDROP
iptables -A ICMP -p icmp --icmp-type timestamp-reply -j LDROP
iptables -A ICMP -p icmp --icmp-type address-mask-request -j LDROP
iptables -A ICMP -p icmp --icmp-type address-mask-reply -j LDROP
iptables -A ICMP -p icmp -j LDROP
echo Authorize tcp traffic.
iptables -A INPUT --proto tcp -j ACCEPT
echo Authorize packet output.
iptables --policy OUTPUT ACCEPT
#echo reject ident if you drop em you gotta wait for timeout
#iptables -I LOCAL --proto tcp --syn --dst $EXT_IP --dport 113 -j REJECT
echo Drop and log all udp below 1024.
iptables -A INPUT -i ! lo --proto udp --dport :1023 -j LDROP
echo Drop rpc dynamic udp port:
RPC_UDP=`rpcinfo -p localhost|perl -n -e /.*udps+(d+)s+/ && print $1,"n"|sort -u`
echo $RPC_UDP
for port in $RPC_UDP; do
iptables -A LOCAL -i ! lo --proto udp --dport $port -j LDROP
done
echo Authorize udp above 1024.
iptables -A INPUT --proto udp --dport 1024: -j ACCEPT
Download (MB)
Added: 2007-02-14 License: GPL (GNU General Public License) Price:
984 downloads
fairly fast packet filter 1.5.0
The fairly fast packet filter (FFPF) is an approach to network packet processing. more>>
The fairly fast packet filter (FFPF) is an approach to network packet processing that adds many new features to existing filtering solutions like BPF.
fairly fast packet filter is designed for high speed by pushing computationally intensive tasks to the kernel or even network processors and by minimising packet copying.
By providing both access to richer programming languages and explicit extensibility, it is also considerably more flexible than existing approaches.
FFPF provides a complete solution for network monitoring that caters to all applications available today. Exploiting its extensibility, the language can even be used as a meta-filter to `script together filters from other approaches, such as BPF.
Main features:
- fast: processes significantly more packets per second than LSF (reference)
- scalable: transparently supports hardware assist, like that given by the Intel IXP2x00 network processors
- backward compatible: supports all existing libpcap based applications
- extensible: separates functionality from the framework. FFPF currently ships with implementations of BPF, Aho Corasick, Boyer Moore Horspool, and many more
- modular: new functions can be written in as little as 3 lines of code
- secure: relies on Keynote for authentication and resource control
- open and standard adherent: licensed under the GNU General Public License (GPL). It implements the Monitoring API (MAPI) draft as designed by the EU-SCAMPI consortium
Enhancements:
- enabled kernelspace processing
- enabled all 5 buffer implementations (Continuous, Fixed-size slot, Variable sized slot, Double ring and Index)
- added TCP stream reassembly and early implementation of zero-copy reassembly
- added PCAP input and output support, for userspace testing and offline use
- added additional minor functions: TCP Synprotect, output to files, ...
- added support for UDEV
- extended controlplane: flowspaces can now be queried for live state
- fixed up many bugs, hacks and irregularities.
<<lessfairly fast packet filter is designed for high speed by pushing computationally intensive tasks to the kernel or even network processors and by minimising packet copying.
By providing both access to richer programming languages and explicit extensibility, it is also considerably more flexible than existing approaches.
FFPF provides a complete solution for network monitoring that caters to all applications available today. Exploiting its extensibility, the language can even be used as a meta-filter to `script together filters from other approaches, such as BPF.
Main features:
- fast: processes significantly more packets per second than LSF (reference)
- scalable: transparently supports hardware assist, like that given by the Intel IXP2x00 network processors
- backward compatible: supports all existing libpcap based applications
- extensible: separates functionality from the framework. FFPF currently ships with implementations of BPF, Aho Corasick, Boyer Moore Horspool, and many more
- modular: new functions can be written in as little as 3 lines of code
- secure: relies on Keynote for authentication and resource control
- open and standard adherent: licensed under the GNU General Public License (GPL). It implements the Monitoring API (MAPI) draft as designed by the EU-SCAMPI consortium
Enhancements:
- enabled kernelspace processing
- enabled all 5 buffer implementations (Continuous, Fixed-size slot, Variable sized slot, Double ring and Index)
- added TCP stream reassembly and early implementation of zero-copy reassembly
- added PCAP input and output support, for userspace testing and offline use
- added additional minor functions: TCP Synprotect, output to files, ...
- added support for UDEV
- extended controlplane: flowspaces can now be queried for live state
- fixed up many bugs, hacks and irregularities.
Download (0.60MB)
Added: 2006-02-20 License: GPL (GNU General Public License) Price:
1342 downloads
Packet Excalibur 1.0.2
Packet Excalibur is a multi-platform graphical and scriptable network packet engine with extensible text-based protocol descript more>>
Packet Excalibur is a multi-platform graphical and scriptable network packet engine with extensible text-based protocol descriptions. It is a network tool designed to build and receive custom packets from network.
Pen testing firewalls, routers, or any network enable equipment. Validating your custom built protocols without the burden of writting lines of code. Teaching yourself how protocols works and articulates around each other.
Download the install package (PacketExcalibur_*.*_linux_tgz)
Unzip and untar the archive, run "make" in the "PacketExcalibur_*/main" directory,
- binaries are installed in /usr/sbin
- support packages are installed in /var/cache/excalibur
- preference file is created in the user home directory
<<lessPen testing firewalls, routers, or any network enable equipment. Validating your custom built protocols without the burden of writting lines of code. Teaching yourself how protocols works and articulates around each other.
Download the install package (PacketExcalibur_*.*_linux_tgz)
Unzip and untar the archive, run "make" in the "PacketExcalibur_*/main" directory,
- binaries are installed in /usr/sbin
- support packages are installed in /var/cache/excalibur
- preference file is created in the user home directory
Download (1.8MB)
Added: 2006-07-04 License: GPL (GNU General Public License) Price:
1259 downloads
Net::DHCP::Packet 0.66
Net::DHCP::Packet is a Perl module with object methods to create a DHCP packet. more>>
Net::DHCP::Packet is a Perl module with object methods to create a DHCP packet.
SYNOPSIS
use Net::DHCP::Packet;
my $p = new Net::DHCP::Packet->new(
Chaddr => 000BCDEF,
Xid => 0x9F0FD,
Ciaddr => 0.0.0.0,
Siaddr => 0.0.0.0,
Hops => 0);
Represents a DHCP packet as specified in RFC 1533, RFC 2132.
CONSTRUCTOR
This module only provides basic constructor. For "easy" constructors, you can use the Net::DHCP::Session module.
new( )
new( BUFFER )
new( ARG => VALUE, ARG => VALUE... )
Creates an Net::DHCP::Packet object, which can be used to send or receive DHCP network packets. BOOTP is not supported.
Without argument, a default empty packet is created.
$packet = Net::DHCP::Packet();
A BUFFER argument is interpreted as a binary buffer like one provided by the socket recv() function. if the packet is malformed, a fatal error is issued.
use IO::Socket::INET;
use Net::DHCP::Packet;
$sock = IO::Socket::INET->new(LocalPort => 67, Proto => "udp", Broadcast => 1)
or die "socket: $@";
while ($sock->recv($newmsg, 1024)) {
$packet = Net::DHCP::Packet->new($newmsg);
print $packet->toString();
}
To create a fresh new packet new() takes arguments as a key-value pairs :
ARGUMENT FIELD OCTETS DESCRIPTION
-------- ----- ------ -----------
Op op 1 Message op code / message type.
1 = BOOTREQUEST, 2 = BOOTREPLY
Htype htype 1 Hardware address type, see ARP section in "Assigned
Numbers" RFC; e.g., 1 = 10mb ethernet.
Hlen hlen 1 Hardware address length (e.g. 6 for 10mb
ethernet).
Hops hops 1 Client sets to zero, optionally used by relay agents
when booting via a relay agent.
Xid xid 4 Transaction ID, a random number chosen by the
client, used by the client and server to associate
messages and responses between a client and a
server.
Secs secs 2 Filled in by client, seconds elapsed since client
began address acquisition or renewal process.
Flags flags 2 Flags (see figure 2).
Ciaddr ciaddr 4 Client IP address; only filled in if client is in
BOUND, RENEW or REBINDING state and can respond
to ARP requests.
Yiaddr yiaddr 4 your (client) IP address.
Siaddr siaddr 4 IP address of next server to use in bootstrap;
returned in DHCPOFFER, DHCPACK by server.
Giaddr giaddr 4 Relay agent IP address, used in booting via a
relay agent.
Chaddr chaddr 16 Client hardware address.
Sname sname 64 Optional server host name, null terminated string.
File file 128 Boot file name, null terminated string; "generic"
name or null in DHCPDISCOVER, fully qualified
directory-path name in DHCPOFFER.
IsDhcp isDhcp 4 Controls whether the packet is BOOTP or DHCP.
DHCP conatains the "magic cookie" of 4 bytes.
0x63 0x82 0x53 0x63.
DHO_*code Optional parameters field. See the options
documents for a list of defined options.
See Net::DHCP::Constants.
Padding padding * Optional padding at the end of the packet
See below methods for values and syntax descrption.
Note: DHCP options are created in the same order as key-value pairs.
<<lessSYNOPSIS
use Net::DHCP::Packet;
my $p = new Net::DHCP::Packet->new(
Chaddr => 000BCDEF,
Xid => 0x9F0FD,
Ciaddr => 0.0.0.0,
Siaddr => 0.0.0.0,
Hops => 0);
Represents a DHCP packet as specified in RFC 1533, RFC 2132.
CONSTRUCTOR
This module only provides basic constructor. For "easy" constructors, you can use the Net::DHCP::Session module.
new( )
new( BUFFER )
new( ARG => VALUE, ARG => VALUE... )
Creates an Net::DHCP::Packet object, which can be used to send or receive DHCP network packets. BOOTP is not supported.
Without argument, a default empty packet is created.
$packet = Net::DHCP::Packet();
A BUFFER argument is interpreted as a binary buffer like one provided by the socket recv() function. if the packet is malformed, a fatal error is issued.
use IO::Socket::INET;
use Net::DHCP::Packet;
$sock = IO::Socket::INET->new(LocalPort => 67, Proto => "udp", Broadcast => 1)
or die "socket: $@";
while ($sock->recv($newmsg, 1024)) {
$packet = Net::DHCP::Packet->new($newmsg);
print $packet->toString();
}
To create a fresh new packet new() takes arguments as a key-value pairs :
ARGUMENT FIELD OCTETS DESCRIPTION
-------- ----- ------ -----------
Op op 1 Message op code / message type.
1 = BOOTREQUEST, 2 = BOOTREPLY
Htype htype 1 Hardware address type, see ARP section in "Assigned
Numbers" RFC; e.g., 1 = 10mb ethernet.
Hlen hlen 1 Hardware address length (e.g. 6 for 10mb
ethernet).
Hops hops 1 Client sets to zero, optionally used by relay agents
when booting via a relay agent.
Xid xid 4 Transaction ID, a random number chosen by the
client, used by the client and server to associate
messages and responses between a client and a
server.
Secs secs 2 Filled in by client, seconds elapsed since client
began address acquisition or renewal process.
Flags flags 2 Flags (see figure 2).
Ciaddr ciaddr 4 Client IP address; only filled in if client is in
BOUND, RENEW or REBINDING state and can respond
to ARP requests.
Yiaddr yiaddr 4 your (client) IP address.
Siaddr siaddr 4 IP address of next server to use in bootstrap;
returned in DHCPOFFER, DHCPACK by server.
Giaddr giaddr 4 Relay agent IP address, used in booting via a
relay agent.
Chaddr chaddr 16 Client hardware address.
Sname sname 64 Optional server host name, null terminated string.
File file 128 Boot file name, null terminated string; "generic"
name or null in DHCPDISCOVER, fully qualified
directory-path name in DHCPOFFER.
IsDhcp isDhcp 4 Controls whether the packet is BOOTP or DHCP.
DHCP conatains the "magic cookie" of 4 bytes.
0x63 0x82 0x53 0x63.
DHO_*code Optional parameters field. See the options
documents for a list of defined options.
See Net::DHCP::Constants.
Padding padding * Optional padding at the end of the packet
See below methods for values and syntax descrption.
Note: DHCP options are created in the same order as key-value pairs.
Download (0.021MB)
Added: 2007-06-23 License: Perl Artistic License Price:
859 downloads
Packet Construction Set 0.5 Beta
Packet Construction Set is a set of Python modules and objects that make building network protocol code easier. more>>
Packet Construction Set is a set of Python modules and objects that make building network protocol code easier for the protocol developer.
The core of the system is the pcs module itself which provides the necessary functionality to create classes that implement packets.
Installation Instructions for Packet Construction Set (PCS)
PCS follows the normal Python conventions for building and installing and there is very little, if any, magic. To install the library and the associated packet classes into your system do:
> python setup.py install < return >
To test your installation do:
> cd tests/ < return >
> python *.py
Some tests fail if you do not have enough privileges to work with the Berkeley Packet Filter. If you wish to run those tests run them using sudo.
To build the documentation you will need pdflatex and a BSD version of make installed. Go into the docs directory and build the documentation:
> cd docs/ < return >
> bsdmake all
you will see PDF versions of the docs.
Enhancements:
- Move my version of Doug Songs Python pcap library into the package.
- Update the Makefile to make sure that we install correctly no matter what target is selected.
<<lessThe core of the system is the pcs module itself which provides the necessary functionality to create classes that implement packets.
Installation Instructions for Packet Construction Set (PCS)
PCS follows the normal Python conventions for building and installing and there is very little, if any, magic. To install the library and the associated packet classes into your system do:
> python setup.py install < return >
To test your installation do:
> cd tests/ < return >
> python *.py
Some tests fail if you do not have enough privileges to work with the Berkeley Packet Filter. If you wish to run those tests run them using sudo.
To build the documentation you will need pdflatex and a BSD version of make installed. Go into the docs directory and build the documentation:
> cd docs/ < return >
> bsdmake all
you will see PDF versions of the docs.
Enhancements:
- Move my version of Doug Songs Python pcap library into the package.
- Update the Makefile to make sure that we install correctly no matter what target is selected.
Download (0.36MB)
Added: 2007-03-22 License: BSD License Price:
947 downloads
NetPacket::IP 0.04
NetPacket::IP is a Perl module to assemble and disassemble IP (Internet Protocol) packets. more>>
SYNOPSIS
use NetPacket::IP;
$ip_obj = NetPacket::IP->decode($raw_pkt);
$ip_pkt = NetPacket::IP->encode($ip_obj);
$ip_data = NetPacket::IP::strip($raw_pkt);
NetPacket::IP provides a set of routines for assembling and disassembling packets using IP (Internet Protocol).
Methods
NetPacket::IP->decode([RAW PACKET])
Decode the raw packet data given and return an object containing instance data. This method will quite happily decode garbage input. It is the responsibility of the programmer to ensure valid packet data is passed to this method.
NetPacket::IP->encode()
Return an IP packet encoded with the instance data specified. This will infer the total length of the packet automatically from the payload lenth and also adjust the checksum.
Functions
NetPacket::IP::strip([RAW PACKET])
Return the encapsulated data (or payload) contained in the IP packet. This data is suitable to be used as input for other NetPacket::* modules.
This function is equivalent to creating an object using the decode() constructor and returning the data field of that object.
Instance data
The instance data for the NetPacket::IP object consists of the following fields.
ver
The IP version number of this packet.
hlen
The IP header length of this packet.
flags
The IP header flags for this packet.
foffset
The IP fragment offset for this packet.
tos
The type-of-service for this IP packet.
len
The length (including length of header) in bytes for this packet.
id
The identification (sequence) number for this IP packet.
ttl
The time-to-live value for this packet.
proto
The IP protocol number for this packet.
cksum
The IP checksum value for this packet.
src_ip
The source IP address for this packet in dotted-quad notation.
dest_ip
The destination IP address for this packet in dotted-quad notation.
options
Any IP options for this packet.
data
The encapsulated data (payload) for this IP packet.
Download (0.011MB)
Added: 2007-02-28 License: Perl Artistic License Price:
968 downloads
NetPacket::TCP 0.04
NetPacket::TCP is a Perl module to assemble and disassemble TCP (Transmission Control Protocol) packets. more>>
NetPacket::TCP is a Perl module to assemble and disassemble TCP (Transmission Control Protocol) packets.
SYNOPSIS
use NetPacket::TCP;
$tcp_obj = NetPacket::TCP->decode($raw_pkt);
$tcp_pkt = NetPacket::TCP->encode($ip_pkt);
$tcp_data = NetPacket::TCP::strip($raw_pkt);
NetPacket::TCP provides a set of routines for assembling and disassembling packets using TCP (Transmission Control Protocol).
Methods
NetPacket::TCP->decode([RAW PACKET])
Decode the raw packet data given and return an object containing instance data. This method will quite happily decode garbage input. It is the responsibility of the programmer to ensure valid packet data is passed to this method.
NetPacket::TCP->encode($ip_obj)
Return a TCP packet encoded with the instance data specified. Needs parts of the ip header contained in $ip_obj in order to calculate the TCP checksum.
Functions
NetPacket::TCP::strip([RAW PACKET])
Return the encapsulated data (or payload) contained in the TCP packet. This data is suitable to be used as input for other NetPacket::* modules.
This function is equivalent to creating an object using the decode() constructor and returning the data field of that object.
Instance data
The instance data for the NetPacket::TCP object consists of the following fields.
src_port
The source TCP port for the packet.
dest_port
The destination TCP port for the packet.
seqnum
The TCP sequence number for this packet.
acknum
The TCP acknowledgement number for this packet.
hlen
The header length for this packet.
reserved
The 6-bit "reserved" space in the TCP header.
flags
Contains the urg, ack, psh, rst, syn, fin, ece and cwr flags for this packet.
winsize
The TCP window size for this packet.
cksum
The TCP checksum.
urg
The TCP urgent pointer.
options
Any TCP options for this packet in binary form.
data
The encapsulated data (payload) for this packet.
<<lessSYNOPSIS
use NetPacket::TCP;
$tcp_obj = NetPacket::TCP->decode($raw_pkt);
$tcp_pkt = NetPacket::TCP->encode($ip_pkt);
$tcp_data = NetPacket::TCP::strip($raw_pkt);
NetPacket::TCP provides a set of routines for assembling and disassembling packets using TCP (Transmission Control Protocol).
Methods
NetPacket::TCP->decode([RAW PACKET])
Decode the raw packet data given and return an object containing instance data. This method will quite happily decode garbage input. It is the responsibility of the programmer to ensure valid packet data is passed to this method.
NetPacket::TCP->encode($ip_obj)
Return a TCP packet encoded with the instance data specified. Needs parts of the ip header contained in $ip_obj in order to calculate the TCP checksum.
Functions
NetPacket::TCP::strip([RAW PACKET])
Return the encapsulated data (or payload) contained in the TCP packet. This data is suitable to be used as input for other NetPacket::* modules.
This function is equivalent to creating an object using the decode() constructor and returning the data field of that object.
Instance data
The instance data for the NetPacket::TCP object consists of the following fields.
src_port
The source TCP port for the packet.
dest_port
The destination TCP port for the packet.
seqnum
The TCP sequence number for this packet.
acknum
The TCP acknowledgement number for this packet.
hlen
The header length for this packet.
reserved
The 6-bit "reserved" space in the TCP header.
flags
Contains the urg, ack, psh, rst, syn, fin, ece and cwr flags for this packet.
winsize
The TCP window size for this packet.
cksum
The TCP checksum.
urg
The TCP urgent pointer.
options
Any TCP options for this packet in binary form.
data
The encapsulated data (payload) for this packet.
Download (0.011MB)
Added: 2007-02-28 License: Perl Artistic License Price:
971 downloads
NetPacket::UDP 0.04
NetPacket::UDP is a Perl module to assemble and disassemble UDP (User Datagram Protocol) packets. more>>
NetPacket::UDP is a Perl module to assemble and disassemble UDP (User Datagram Protocol) packets.
SYNOPSIS
use NetPacket::UDP;
$udp_obj = NetPacket::UDP->decode($raw_pkt);
$udp_pkt = NetPacket::UDP->encode($ip_obj);
$udp_data = NetPacket::UDP::strip($raw_pkt);
NetPacket::UDP provides a set of routines for assembling and disassembling packets using UDP (User Datagram Protocol).
Methods
NetPacket::UDP->decode([RAW PACKET])
Decode the raw packet data given and return an object containing instance data. This method will quite happily decode garbage input. It is the responsibility of the programmer to ensure valid packet data is passed to this method.
NetPacket::UDP->encode(param => value)
Return a UDP packet encoded with the instance data specified. Needs parts of the ip header contained in $ip_obj, the IP object, in order to calculate the UDP checksum. The length field will also be set automatically.
Functions
NetPacket::UDP::strip([RAW PACKET])
Return the encapsulated data (or payload) contained in the UDP packet. This data is suitable to be used as input for other NetPacket::* modules.
This function is equivalent to creating an object using the decode() constructor and returning the data field of that object.
Instance data
The instance data for the NetPacket::UDP object consists of the following fields.
src_port
The source UDP port for the datagram.
dest_port
The destination UDP port for the datagram.
len
The length (including length of header) in bytes for this packet.
cksum
The checksum value for this packet.
data
The encapsulated data (payload) for this packet.
<<lessSYNOPSIS
use NetPacket::UDP;
$udp_obj = NetPacket::UDP->decode($raw_pkt);
$udp_pkt = NetPacket::UDP->encode($ip_obj);
$udp_data = NetPacket::UDP::strip($raw_pkt);
NetPacket::UDP provides a set of routines for assembling and disassembling packets using UDP (User Datagram Protocol).
Methods
NetPacket::UDP->decode([RAW PACKET])
Decode the raw packet data given and return an object containing instance data. This method will quite happily decode garbage input. It is the responsibility of the programmer to ensure valid packet data is passed to this method.
NetPacket::UDP->encode(param => value)
Return a UDP packet encoded with the instance data specified. Needs parts of the ip header contained in $ip_obj, the IP object, in order to calculate the UDP checksum. The length field will also be set automatically.
Functions
NetPacket::UDP::strip([RAW PACKET])
Return the encapsulated data (or payload) contained in the UDP packet. This data is suitable to be used as input for other NetPacket::* modules.
This function is equivalent to creating an object using the decode() constructor and returning the data field of that object.
Instance data
The instance data for the NetPacket::UDP object consists of the following fields.
src_port
The source UDP port for the datagram.
dest_port
The destination UDP port for the datagram.
len
The length (including length of header) in bytes for this packet.
cksum
The checksum value for this packet.
data
The encapsulated data (payload) for this packet.
Download (0.011MB)
Added: 2007-02-28 License: Perl Artistic License Price:
972 downloads
NetPacket::ICMP 0.04
NetPacket::ICMP is a Perl module to assemble and disassemble ICMP (Internet Control Message Protocol) packets. more>>
NetPacket::ICMP is a Perl module to assemble and disassemble ICMP (Internet Control Message Protocol) packets.
SYNOPSIS
use NetPacket::ICMP;
$icmp_obj = NetPacket::ICMP->decode($raw_pkt);
$icmp_pkt = NetPacket::ICMP->encode();
$icmp_data = NetPacket::ICMP::strip($raw_pkt);
NetPacket::ICMP provides a set of routines for assembling and disassembling packets using ICMP (Internet Control Message Protocol).
Methods
NetPacket::ICMP->decode([RAW PACKET])
Decode the raw packet data given and return an object containing instance data. This method will quite happily decode garbage input. It is the responsibility of the programmer to ensure valid packet data is passed to this method.
NetPacket::ICMP->encode()
Return an ICMP packet encoded with the instance data specified.
<<lessSYNOPSIS
use NetPacket::ICMP;
$icmp_obj = NetPacket::ICMP->decode($raw_pkt);
$icmp_pkt = NetPacket::ICMP->encode();
$icmp_data = NetPacket::ICMP::strip($raw_pkt);
NetPacket::ICMP provides a set of routines for assembling and disassembling packets using ICMP (Internet Control Message Protocol).
Methods
NetPacket::ICMP->decode([RAW PACKET])
Decode the raw packet data given and return an object containing instance data. This method will quite happily decode garbage input. It is the responsibility of the programmer to ensure valid packet data is passed to this method.
NetPacket::ICMP->encode()
Return an ICMP packet encoded with the instance data specified.
Download (0.011MB)
Added: 2007-02-27 License: Perl Artistic License Price:
970 downloads
NetPacket::IGMP 0.04
etPacket::IGMP is a Perl module to assemble and disassemble IGMP (Internet Group Mangement Protocol) packets. more>>
etPacket::IGMP is a Perl module to assemble and disassemble IGMP (Internet Group Mangement Protocol) packets.
SYNOPSIS
use NetPacket::IGMP;
$igmp_obj = NetPacket::IGMP->decode($raw_pkt);
$igmp_pkt = NetPacket::IGMP->encode(params...); # Not implemented
$igmp_data = NetPacket::IGMP::strip($raw_pkt);
NetPacket::IGMP provides a set of routines for assembling and disassembling packets using IGMP (Internet Group Mangement Protocol).
Methods
NetPacket::IGMP->decode([RAW PACKET])
Decode the raw packet data given and return an object containing instance data. This method will quite happily decode garbage input. It is the responsibility of the programmer to ensure valid packet data is passed to this method.
NetPacket::IGMP->encode(param => value)
Return an IGMP packet encoded with the instance data specified. Not implemented.
<<lessSYNOPSIS
use NetPacket::IGMP;
$igmp_obj = NetPacket::IGMP->decode($raw_pkt);
$igmp_pkt = NetPacket::IGMP->encode(params...); # Not implemented
$igmp_data = NetPacket::IGMP::strip($raw_pkt);
NetPacket::IGMP provides a set of routines for assembling and disassembling packets using IGMP (Internet Group Mangement Protocol).
Methods
NetPacket::IGMP->decode([RAW PACKET])
Decode the raw packet data given and return an object containing instance data. This method will quite happily decode garbage input. It is the responsibility of the programmer to ensure valid packet data is passed to this method.
NetPacket::IGMP->encode(param => value)
Return an IGMP packet encoded with the instance data specified. Not implemented.
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Added: 2007-02-27 License: Perl Artistic License Price:
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