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A cross-platform binding for performing packet capturing with node.js.
node.js -- v0.10.0 or newer
For Windows: WinPcap
For *nix: libpcap and libpcap-dev/libpcap-devel packages
npm install cap
var Cap = require('cap').Cap,
decoders = require('cap').decoders,
PROTOCOL = decoders.PROTOCOL;
var c = new Cap(),
device = Cap.findDevice('192.168.0.10'),
filter = 'tcp and dst port 80',
bufSize = 10 * 1024 * 1024,
buffer = new Buffer(65535);
var linkType = c.open(device, filter, bufSize, buffer);
c.setMinBytes && c.setMinBytes(0);
c.on('packet', function(nbytes, trunc) {
console.log('packet: length ' + nbytes + ' bytes, truncated? '
+ (trunc ? 'yes' : 'no'));
// raw packet data === buffer.slice(0, nbytes)
if (linkType === 'ETHERNET') {
var ret = decoders.Ethernet(buffer);
if (ret.info.type === PROTOCOL.ETHERNET.IPV4) {
console.log('Decoding IPv4 ...');
ret = decoders.IPV4(buffer, ret.offset);
console.log('from: ' + ret.info.srcaddr + ' to ' + ret.info.dstaddr);
if (ret.info.protocol === PROTOCOL.IP.TCP) {
var datalen = ret.info.totallen - ret.hdrlen;
console.log('Decoding TCP ...');
ret = decoders.TCP(buffer, ret.offset);
console.log(' from port: ' + ret.info.srcport + ' to port: ' + ret.info.dstport);
datalen -= ret.hdrlen;
console.log(buffer.toString('binary', ret.offset, ret.offset + datalen));
} else if (ret.info.protocol === PROTOCOL.IP.UDP) {
console.log('Decoding UDP ...');
ret = decoders.UDP(buffer, ret.offset);
console.log(' from port: ' + ret.info.srcport + ' to port: ' + ret.info.dstport);
console.log(buffer.toString('binary', ret.offset, ret.offset + ret.info.length));
} else
console.log('Unsupported IPv4 protocol: ' + PROTOCOL.IP[ret.info.protocol]);
} else
console.log('Unsupported Ethertype: ' + PROTOCOL.ETHERNET[ret.info.type]);
}
});
var Cap = require('cap').Cap,
c = new Cap(),
device = Cap.findDevice('192.168.1.200'),
filter = 'arp',
bufSize = 10 * 1024 * 1024,
buffer = new Buffer(65535);
var linkType = c.open(device, filter, bufSize, buffer);
// To use this example, change Source Mac, Sender Hardware Address (MAC) and Target Protocol address
var buffer = new Buffer ([
// ETHERNET
0xff, 0xff, 0xff, 0xff, 0xff,0xff, // 0 = Destination MAC
0x84, 0x8F, 0x69, 0xB7, 0x3D, 0x92, // 6 = Source MAC
0x08, 0x06, // 12 = EtherType = ARP
// ARP
0x00, 0x01, // 14/0 = Hardware Type = Ethernet (or wifi)
0x08, 0x00, // 16/2 = Protocol type = ipv4 (request ipv4 route info)
0x06, 0x04, // 18/4 = Hardware Addr Len (Ether/MAC = 6), Protocol Addr Len (ipv4 = 4)
0x00, 0x01, // 20/6 = Operation (ARP, who-has)
0x84, 0x8f, 0x69, 0xb7, 0x3d, 0x92, // 22/8 = Sender Hardware Addr (MAC)
0xc0, 0xa8, 0x01, 0xc8, // 28/14 = Sender Protocol address (ipv4)
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 32/18 = Target Hardware Address (Blank/nulls for who-has)
0xc0, 0xa8, 0x01, 0xc9 // 38/24 = Target Protocol address (ipv4)
]);
try {
// send will not work if pcap_sendpacket is not supported by underlying `device`
c.send(buffer, buffer.length);
} catch (e) {
console.log("Error sending packet:", e);
}
// TCPDUMP. Note: Some values are changed by the network stack when the broadcast arp message is received.
//12:28:33.230319 ARP, Ethernet (len 6), IPv4 (len 4), Request who-has 192.168.1.200 tell 192.168.1.199, length 46
//0x0000: ffff ffff ffff 848f 69b7 3d92 0806 0001 ........i.=.....
//0x0010: 0800 0604 0001 848f 69b7 3d92 c0a8 01c7 ........i.=.....
//0x0020: 0000 0000 0000 c0a8 01c8 0000 0000 0000 ................
//0x0030: 0000 0000 0000 0000 0000 0000 ............
//12:28:33.230336 ARP, Ethernet (len 6), IPv4 (len 4), Reply 192.168.1.200 is-at 74:ea:3a:a3:e6:69, length 28
//0x0000: 848f 69b7 3d92 74ea 3aa3 e669 0806 0001 ..i.=.t.:..i....
//0x0010: 0800 0604 0002 74ea 3aa3 e669 c0a8 01c8 ......t.:..i....
//0x0020: 848f 69b7 3d92 c0a8 01c7 ..i.=.....
var Cap = require('cap').Cap;
console.dir(Cap.deviceList());
// example output on Linux:
// [ { name: 'eth0',
// addresses:
// [ { addr: '192.168.0.10',
// netmask: '255.255.255.0',
// broadaddr: '192.168.0.255' } ] },
// { name: 'nflog',
// description: 'Linux netfilter log (NFLOG) interface',
// addresses: [] },
// { name: 'any',
// description: 'Pseudo-device that captures on all interfaces',
// addresses: [] },
// { name: 'lo',
// addresses:
// [ { addr: '127.0.0.1', netmask: '255.0.0.0' },
// { addr: '::1',
// netmask: 'ffff:ffff:ffff:ffff:ffff:ffff:ffff:ffff' } ],
// flags: 'PCAP_IF_LOOPBACK' } ]
nbytes in size was captured. truncated indicates if the entire packet did not fit inside the Buffer supplied to open().(constructor)() - Creates and returns a new Cap instance.
open(< string >device, < string >filter, < integer >bufSize, < Buffer >buffer) - (void) - Opens device and starts capturing packets using filter. To see the syntax for filter check pcap-filter man page. bufSize is the size of the internal buffer that libpcap uses to temporarily store packets until they are emitted. buffer is a Buffer large enough to store one packet. If open() is called again without a previous call to close(), an implicit close() will occur first.
close() - (void) - Stops capturing.
setMinBytes(< integer >nBytes) - (void) - (Windows ONLY) This sets the minimum number of packet bytes that must be captured before the full packet data is made available. If this value is set too high, you may not receive any packets until WinPCap's internal buffer fills up. Therefore it's generally best to pass in 0 to this function after calling open(), despite it resulting in more syscalls.
send(< Buffer >buffer[, < integer >nBytes]) - (void) - Sends an arbitrary, raw packet on the opened device. nBytes is the number of bytes in buffer to send (starting from position 0) and defaults to buffer.length.
findDevice([< string >ip]) - mixed - If ip is given, the (first) device name associated with ip, or undefined is returned if not found. If ip is not given, the device name of the first non-loopback device is returned.
deviceList() - array - Returns a list of available devices and related information.
The following methods are available off of require('cap').decoders. They parse the relevant protocol header and return an object containing the parsed information:
Link Layer Protocols
Internet Layer Protocols
IPV4(< Buffer buf[, < integer >bufOffset=0])
IPV6(< Buffer buf[, < integer >bufOffset=0])
ICMPV4(< Buffer buf, < integer >nbytes[, < integer >bufOffset=0])
Transport Layer Protocols
TCP(< Buffer buf[, < integer >bufOffset=0])
UDP(< Buffer buf[, < integer >bufOffset=0])
SCTP(< Buffer buf, < integer >nbytes[, < integer >bufOffset=0])
FAQs
A cross-platform binding for performing packet capturing with node.js
The npm package cap2 receives a total of 3 weekly downloads. As such, cap2 popularity was classified as not popular.
We found that cap2 demonstrated a not healthy version release cadence and project activity because the last version was released a year ago. It has 1 open source maintainer collaborating on the project.
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