|This article needs additional citations for verification. (March 2013) (Learn how and when to remove this template message)|
A packet analyzer (also known as a network analyzer, protocol analyzer or packet sniffer—or, for particular types of networks, an Ethernet sniffer or wireless sniffer) is a computer program or piece of computer hardware that can intercept and log traffic that passes over a digital network or part of a network. As data streams flow across the network, the sniffer captures each packet and, if needed, decodes the packet's raw data, showing the values of various fields in the packet, and analyzes its content according to the appropriate RFC or other specifications.
Packet capture is the process of intercepting and logging traffic.
On wired broadcast LANs, such as Ethernet, Token Ring, and FDDI networks, depending on the network structure (hub or switch), one can capture traffic on all or parts of the network from a single machine on the network. However, some methods avoid traffic narrowing by switches to gain access to traffic from other systems on the network (e.g., ARP spoofing). For network monitoring purposes, it may also be desirable to monitor all data packets in a LAN by using a network switch with a so-called monitoring port that mirrors all packets that pass through all ports of the switch when systems are connected to a switch port. To use a network tap is an even more reliable solution than to use a monitoring port, since taps are less likely to drop packets during high traffic load.
On wireless LANs, one can capture traffic on a particular channel, or on several channels using multiple adapters.
On wired broadcast and wireless LANs, to capture traffic other than unicast traffic to the machine running the sniffer, multicast traffic to a multicast group that machine is monitoring, or broadcast traffic—the network adapter capturing the traffic must be in promiscuous mode. Some sniffers support this, but not all. On wireless LANs, even if the adapter is in promiscuous mode, packets not for the service set the adapter is configured for are usually ignored. To see those packets, the adapter must be in monitor mode.
When traffic is captured, either the entire contents of packets are recorded, or the headers are recorded without recording the total content of the packet. This can reduce storage requirements, and avoid legal problems, yet provide sufficient information to diagnose problems.
Captured information is decoded from raw digital form into a human-readable format that lets users easily review exchanged information. Protocol analyzers vary in their abilities to display data in multiple views, automatically detect errors, determine root causes of errors, generate timing diagrams, reconstruct TCP and UDP data streams, etc.
Some protocol analyzers can also generate traffic and thus act as the reference device. These can act as protocol testers. Such testers generate protocol-correct traffic for functional testing, and may also have the ability to deliberately introduce errors to test the DUT's ability to handle errors.
Protocol analyzers can also be hardware-based, either in probe format or, as is increasingly common, combined with a disk array. These devices record packets (or a slice of the packet) to a disk array. This allows historical forensic analysis of packets without users having to recreate any fault.
Packet sniffers can:
- Analyze network problems
- Detect network intrusion attempts
- Detect network misuse by internal and external users
- Documenting regulatory compliance through logging all perimeter and endpoint traffic
- Gain information for effecting a network intrusion
- Isolate exploited systems
- Monitor WAN bandwidth utilization
- Monitor network usage (including internal and external users and systems)
- Monitor data-in-motion
- Monitor WAN and endpoint security status
- Gather and report network statistics
- Filter suspect content from network traffic
- Serve as primary data source for day-to-day network monitoring and management
- Spy on other network users and collect sensitive information such as login details or users cookies (depending on any content encryption methods that may be in use)
- Reverse engineer proprietary protocols used over the network
- Debug client/server communications
- Debug network protocol implementations
- Verify adds, moves and changes
- Verify internal control system effectiveness (firewalls, access control, Web filter, spam filter, proxy)
Packet capture can be used to fulfill a warrant from a law enforcement agency (LEA) to produce all network traffic generated by an individual. Internet service providers and VoIP providers in the United States must comply with CALEA (Communications Assistance for Law Enforcement Act) regulations. Using packet capture and storage, telecommunications carriers can provide the legally required secure and separate access to targeted network traffic and are able to use the same device for internal security purposes. Collecting data from a carrier system without a warrant is illegal due to laws about interception. By using end-to-end encryption, communications can be kept confidential from telecommunication carriers and legal authorities.
Notable packet analyzers
- Capsa Network Analyzer
- Charles Web Debugging Proxy
- Carnivore (FBI)
- Microsoft Network Monitor
- NetScout Systems nGenius Infinistream
- ngrep, Network Grep
- Observer Analyzer
- Wireshark (formerly known as Ethereal)
- Xplico Open source Network Forensic Analysis Tool
- Bus analyzer
- Logic analyzer
- Network detector
- Network intrusion detection system
- Network tap
- Packet generation model
- Signals intelligence
- Kevin J. Connolly (2003). Law of Internet Security and Privacy. Aspen Publishers. p. 131. ISBN 978-0-7355-4273-0.
- "The greatest advantage of network segments is that they can increase network capacity.". www.linfo.org. Retrieved 2016-01-14.
|Wikimedia Commons has media related to Computer data network analyzers.|
|Wikiversity has learning resources about Packet analyzer|