(Answers) 126.96.36.199 Lab – Using Wireshark to Examine a UDP DNS Capture (Instructor Version)
- Part 1: Record a PC’s IP Configuration Information
- Part 2: Use Wireshark to Capture DNS Queries and Responses
- Part 3: Analyze Captured DNS or UDP Packets
Background / Scenario
When you use the Internet, you use the Domain Name System (DNS). DNS is a distributed network of servers that translates user-friendly domain names like www.google.com to an IP address. When you type a website URL into your browser, your PC performs a DNS query to the DNS server’s IP address. Your PC’s DNS query and the DNS server’s response make use of the User Datagram Protocol (UDP) as the transport layer protocol. UDP is connectionless and does not require a session setup as does TCP. DNS queries and responses are very small and do not require the overhead of TCP.
In this lab, you will communicate with a DNS server by sending a DNS query using the UDP transport protocol. You will use Wireshark to examine the DNS query and response exchanges with the same server.
- CyberOps Workstation Virtual Machine
- Internet access
Part 1: Record VM’s IP Configuration Information
In Part 1, you will use commands on your CyberOps Workstation VM to find and record the MAC and IP addresses of your VM’s virtual network interface card (NIC), the IP address of the specified default gateway, and the DNS server IP address specified for the PC. Record this information in the table provided. The information will be used in parts of this lab with packet analysis.
|IP address||Answers will vary. 192.168.1.11|
|MAC address||Answers will vary. 08:00:27:C9:FA:A1|
|Default gateway IP address||Answers will vary. 192.168.1.1|
|DNS server IP address||Answers will vary. 192.168.1.1|
a. Open a terminal in the VM. Enter ifconfig at the prompt to display interface information.
[[email protected] ~]$ ifconfig enp0s3: flags=4163<UP,BROADCAST,RUNNING,MULTICAST> mtu 1500 inet 192.168.1.19 netmask 255.255.255.0 broadcast 192.168.1.255 inet6 fe80::997f:9b16:5aae:1868 prefixlen 64 scopeid 0x20<link> ether 08:00:27:c9:fa:a1 txqueuelen 1000 (Ethernet) RX packets 1381 bytes 87320 (85.2 KiB) RX errors 0 dropped 0 overruns 0 frame 0 TX packets 24 bytes 1857 (1.8 KiB) TX errors 0 dropped 0 overruns 0 carrier 0 collisions 0 device interrupt 19 base 0xd000 <some output omitted>
b. At the terminal prompt, enter cat /etc/resolv.conf to determine the DNS server.
[[email protected] ~]$ cat /etc/resolv.conf # Generated by resolvconf nameserver 192.168.1.1
c. At the terminal prompt, enter netstat -r to display the IP routing table to the default gateway IP address.
[[email protected] ~]$ netstat -r Kernel IP routing table Destination Gateway Genmask Flags MSS Window irtt Iface default 192.168.1.1 0.0.0.0 UG 0 0 0 enp0s3 192.168.1.0 0.0.0.0 255.255.255.0 U 0 0 0 enp0s3
Note: The DNS IP address and default gateway IP address are often the same, especially in small networks. However, in a business or school network, the addresses would most likely be different.
Part 2: Use Wireshark to Capture DNS Queries and Responses
In Part 2, you will set up Wireshark to capture DNS query and response packets. This will demonstrate the use of the UDP transport protocol while communicating with a DNS server.
a. In the terminal window, start Wireshark and click OK when prompted.
[[email protected] ~]$ sudo wireshark-gtk [sudo] password for analyst: ** (wireshark-gtk:950): WARNING **: Couldn't connect to accessibility bus: Failed to connect to socket /tmp/dbus-REDRWOHelr: Connection refused Gtk-Message: GtkDialog mapped without a transient parent. This is discouraged.
b. In the Wireshark window, select enp0s3 from the interface list and click Start.
c. After selecting the desired interface, click Start to capture the packets.
d. Open a web browser and type www.google.com. Press Enter to continue.
e. Click Stop to stop the Wireshark capture when you see Google’s home page.
Part 3: Analyze Captured DNS or UDP Packets
In Part 3, you will examine the UDP packets that were generated when communicating with a DNS server for the IP addresses for www.google.com.
Step 1: Filter DNS packets.
a. In the Wireshark main window, type dns in the Filter field. Click Apply.
Note: If you do not see any results after the DNS filter was applied, close the web browser. In the terminal window, type ping www.google.com as an alternative to the web browser.
b. In the packet list pane (top section) of the main window, locate the packet that includes Standard query and A www.google.com. See frame 22 above as an example.
Step 2: Examine the fields in a DNS query packet.
The protocol fields, highlighted in gray, are displayed in the packet details pane (middle section) of the main window.
a. In the first line in the packet details pane, frame 22 had 74 bytes of data on the wire. This is the number of bytes it took to send a DNS query to a named server requesting the IP addresses of www.google.com. If you used a different web address, such as www.cisco.com, the byte count might be different.
b. The Ethernet II line displays the source and destination MAC addresses. The source MAC address is from your VM because your VM originated the DNS query. The destination MAC address is from the default gateway because this is the last stop before this query exits the local network.
Is the source MAC address the same as the one recorded from Part 1 for the VM?
The answer should be yes.
c. In the Internet Protocol Version 4 line, the IP packet Wireshark capture indicates that the source IP address of this DNS query is 192.168.1.19 and the destination IP address is 192.168.1.1. In this example, the destination address is the default gateway. The router is the default gateway in this network.
Can you identify the IP and MAC addresses for the source and destination devices?
|Device||IP Address||MAC Address|
|VM||Answers will vary. 192.168.1.19||Answers will vary. 08:00:27:C9:FA:A1|
|Default Gateway||Answers will vary. 192.168.1.1||Answers will vary. 08:00:27:C9:FA:A1|
The IP packet and header encapsulates the UDP segment. The UDP segment contains the DNS query as the data.
d. Click the arrow next to User Datagram Protocol to view the details. A UDP header only has four fields: source port, destination port, length, and checksum. Each field in a UDP header is only 16 bits as depicted below.
e. Click the arrow next to User Datagram Protocol to view the details. Notice that there are only four fields. The source port number in this example is 39964. The source port was randomly generated by the VM using port numbers that are not reserved. The destination port is 53. Port 53 is a well-known port reserved for use with DNS. DNS servers listen on port 53 for DNS queries from clients.
In this example, the length of the UDP segment is 40 bytes. The length of the UDP segment in your example may be different. Out of 40 bytes, 8 bytes are used as the header. The other 32 bytes are used by DNS query data. The 32 bytes of DNS query data is in the following illustration in the packet bytes pane (lower section) of the Wireshark main window.
The checksum is used to determine the integrity of the UDP header after it has traversed the Internet.
The UDP header has low overhead because UDP does not have fields that are associated with the three-way handshake in TCP. Any data transfer reliability issues that occur must be handled by the application layer.
Record your Wireshark results in the table below:
|Source MAC address|
|Destination MAC address|
|Source IP address|
|Destination IP address|
Is the source IP address the same as the local PC’s IP address you recorded in Part 1?
Is the destination IP address the same as the default gateway noted in Part 1?
Yes, if the default gateway is also performing DNS.
Step 3: Examine the fields in a DNS response packet.
In this step, you will examine the DNS response packet and verify that the DNS response packet also uses the UDP.
a. In this example, frame 24 is the corresponding DNS response packet. Notice the number of bytes on the wire is 90. It is a larger packet compared to the DNS query packet. This is because the DNS response packet will include a variety of information about the domain.
b. In the Ethernet II frame for the DNS response, what device is the source MAC address and what device is the destination MAC address?
The source MAC address is the default gateway and the destination MAC address is the VM.
c. Notice the source and destination IP addresses in the IP packet. What is the destination IP address?
What is the source IP address?
Destination IP address: __________Source IP address: __________
The answer will vary. In this example, the destination is 192.168.1.19 and the source is 192.168.1.1.
What happened to the roles of source and destination for the VM and default gateway?
The VM and the default gateway have reversed their roles in DNS query and response packets.
d. In the UDP segment, the role of the port numbers has also reversed. The destination port number is 39964. Port number 39964 is the same port that was generated by the VM when the DNS query was sent to the DNS server. Your VM listens for a DNS response on this port.
The source port number is 53. The DNS server listens for a DNS query on port 53 and then sends a DNS response with a source port number of 53 back to the originator of the DNS query.
When the DNS response is expanded, notice the resolved IP addresses for www.google.com in the Answers section.
What are the benefits of using UDP instead of TCP as a transport protocol for DNS?
UDP as a transport protocol provides quick session establishment, quick response, minimal overhead, no need for retries, segment reassembly, and acknowledgment of received packets.