Address Resolution Protocol (ARP) is a protocol or procedure that connects an ever-changing Internet Protocol (IP) address to a fixed physical machine address, also known as a media access control (MAC) address, in a local-area network (LAN).
This mapping procedure is important because the lengths of the IP and MAC addresses differ, and a translation is needed so that the systems can recognize one another. The most used IP today is IP version 4 (IPv4). An IP address is 32 bits long. However, MAC addresses are 48 bits long. ARP translates the 32-bit address to 48 and vice versa.
There is a networking model known as the Open Systems Interconnection (OSI) model. First developed in the late 1970s, the OSI model uses layers to give IT teams a visualization of what is going on with a particular networking system. This can be helpful in determining which layer affects which application, device, or software installed on the network, and further, which IT or engineering professional is responsible for managing that layer.
The MAC address is also known as the data link layer, which establishes and terminates a connection between two physically connected devices so that data transfer can take place. The IP address is also referred to as the network layer or the layer responsible for forwarding packets of data through different routers. ARP works between these layers.
How Does ARP Work?
When a new computer joins a LAN, it is assigned a unique IP address to use for identification and communication.
Packets of data arrive at a gateway, destined for a particular host machine. The gateway, or the piece of hardware on a network that allows data to flow from one network to another, asks the ARP program to find a MAC address that matches the IP address. The ARP cache keeps a record of each IP address and its matching MAC address. The ARP cache is dynamic, but users on a network can also configure a static ARP table containing IP addresses and MAC addresses.
ARP caches are kept on all operating systems in an IPv4 Ethernet network. Every time a device requests a MAC address to send data to another device connected to the LAN, the device verifies its ARP cache to see if the IP-to-MAC-address connection has already been completed. If it exists, then a new request is unnecessary. However, if the translation has not yet been carried out, then the request for network addresses is sent, and ARP is performed.
An ARP cache size is limited by design, and addresses tend to stay in the cache for only a few minutes. It is purged regularly to free up space. This design is also intended for privacy and security to prevent IP addresses from being stolen or spoofed by cyberattackers. While MAC addresses are fixed, IP addresses are constantly changing.
In the purging process, unutilized addresses are deleted; so is any data related to unsuccessful tries to communicate with computers not connected to the network or that are not even powered on.
What is the Functional Difference Between ARP, DHCP, and DNS?
ARP is the process of connecting a dynamic IP address to a physical machine's MAC address. As such, it is important to have a look at a few technologies related to IP.
As mentioned previously, IP addresses, by design, are intended to change constantly for the simple reason that doing so gives users security and privacy. However, IP addresses should not be completely random. There should be rules that allocate an IP address from a defined range of numbers available in a specific network. This helps prevent issues, such as two computers receiving the same IP address. The rules are known as DHCP or Dynamic Host Configuration Protocol.
IP addresses as identities for computers are important because they are needed to perform an internet search. When users search for a domain name or Uniform Resource Locator (URL), they use an alphabetical name. Computers, on the other hand, use the numerical IP address to associate the domain name with a server. To connect the two, a Domain Name System (DNS) server is used to translate an IP address from a confusing string of numbers into a more readable, easily understandable domain name, and vice versa.
What Are the Types of ARP?
There are different versions and use cases of ARP. Let us take a look at a few.
Proxy ARP is a technique by which a proxy device on a given network answers the ARP request for an IP address that is not on that network. The proxy is aware of the location of the traffic's destination and offers its own MAC address as the destination.
Gratuitous ARP is almost like an administrative procedure, carried out as a way for a host on a network to simply announce or update its IP-to-MAC address. Gratuitous ARP is not prompted by an ARP request to translate an IP address to a MAC address.
Reverse ARP (RARP)
Host machines that do not know their own IP address can use the Reverse Address Resolution Protocol (RARP) for discovery.
Inverse ARP (IARP)
Whereas ARP uses an IP address to find a MAC address, IARP uses a MAC address to find an IP address.
Why is ARP Necessary?
ARP is necessary because the software address (IP address) of the host or computer connected to the network needs to be translated to a hardware address (MAC address). Without ARP, a host would not be able to figure out the hardware address of another host. The LAN keeps a table or directory that maps IP addresses to MAC addresses of the different devices, including both endpoints and routers on that network.
This table or directory is not maintained by users or even by IT administrators. Instead, the ARP protocol creates entries on the fly. If a user's device does not know the hardware address of the destination host, the device will send a message to every host on the network asking for this address. When the proper destination host learns of the request, it will reply back with its hardware address, which will then be stored in the ARP directory or table.
If ARP is not supported, manual entries can be made to this directory.
What Is ARP Spoofing/ARP Poisoning Attack?
ARP spoofing is also known as ARP poison routing or ARP cache poisoning. This is a type of attack in which a cyber criminal sends fake ARP messages to a LAN with the intention of linking their MAC address with the IP address of a legitimate device or server within the network. The link allows for data from the victim's computer to be sent to the attacker's computer instead of the original destination.
ARP spoofing attacks can prove dangerous, as sensitive information can be passed between computers without the victims' knowledge. ARP spoofing also enables other forms of cyberattacks, including the following:
Man-in-the-Middle (MTM) Attacks
A man-in-the-middle (MITM) attack is a type of eavesdropping in which the cyberattacker intercepts, relays, and alters messages between two parties—who have no idea that a third party is involved—to steal information. The attacker may try to control and manipulate the messages of one of the parties, or of both, to obtain sensitive information. Because these types of attacks use sophisticated software to mimic the style and tone of conversations—including those that are text- and voice-based—a MITM attack is difficult to intercept and thwart.
A MITM attack occurs when malware is distributed and takes control of a victim's web browser. The browser itself is not important to the attacker, but the data that the victim shares very much is because it can include usernames, passwords, account numbers, and other sensitive information shared in chats and online discussions.
Once they have control, the attacker creates a proxy between the victim and a legitimate site, usually with a fake lookalike site, to intercept any data between the victim and the legitimate site. Attackers do this with online banking and e-commerce sites to capture personal information and financial data.
A denial-of-service (DoS) attack is one in which a cyberattacker attempts to overwhelm systems, servers, and networks with traffic to prevent users from accessing them. A larger-scale DoS attack is known as a distributed denial-of-service (DDoS) attack, where a much larger number of sources are used to flood a system with traffic.
These types of attacks exploit known vulnerabilities in network protocols. When a large number of packets are transmitted to a vulnerable network, the service can easily become overwhelmed and then unavailable.
Session hijacking occurs when a cyberattacker steals a user's session ID, takes over that user's web session, and masquerades as that user. With the session ID in their possession, the attacker can perform any task or activity that user is authorized to do on that network.
Authentication occurs when a user tries to gain access to a system or sign in to a restricted website or web service. The session ID is stored in a cookie in the browser, and an attacker engaged in session hijacking will intercept the authentication process and intrude in real time.
How Fortinet Can Help
The Fortinet network access control (NAC) solution provides enhanced visibility across all devices in a network to keep up with the ever-evolving threat landscape. NAC is part of the zero-trust network access model for security, in which trust is not a given for users, applications, or devices, whether connected to the network or not, but has to be established.
Each device in a network maintains a copy of the ARP cache, and the cache is cleaned every few minutes. As such, all devices connected to that network must be kept secure so that important data, including IP addresses, are not compromised. To further protect your network devices and servers, Fortinet Ethernet LAN switches safeguard an organization's infrastructure and even include a selector tool to identify the best switch to meet network requirements.