About DHCP and DDNS Services
The following topics describe the DHCP server, DHCP relay agent, and DDNS update.
About the DHCPv4 Server
DHCP provides network configuration parameters, such as IP addresses, to DHCP clients. The Firepower Threat Defense device can provide a DHCP server to DHCP clients attached to Firepower Threat Defense device interfaces. The DHCP server provides network configuration parameters directly to DHCP clients.
An IPv4 DHCP client uses a broadcast rather than a multicast address to reach the server. The DHCP client listens for messages on UDP port 68; the DHCP server listens for messages on UDP port 67.
The DHCP server for IPv6 is not supported; you can, however, enable DHCP relay for IPv6 traffic.
DHCP provides a framework for passing configuration information to hosts on a TCP/IP network. The configuration parameters are carried in tagged items that are stored in the Options field of the DHCP message and the data are also called options. Vendor information is also stored in Options, and all of the vendor information extensions can be used as DHCP options.
For example, Cisco IP Phones download their configuration from a TFTP server. When a Cisco IP Phone starts, if it does not have both the IP address and TFTP server IP address preconfigured, it sends a request with option 150 or 66 to the DHCP server to obtain this information.
DHCP option 150 provides the IP addresses of a list of TFTP servers.
DHCP option 66 gives the IP address or the hostname of a single TFTP server.
DHCP option 3 sets the default route.
A single request might include both options 150 and 66. In this case, the ASA DHCP server provides values for both options in the response if they are already configured on the ASA.
You can use advanced DHCP options to provide DNS, WINS, and domain name parameters to DHCP clients; DHCP option 15 is used for the DNS domain suffix.You can also use the DHCP automatic configuration setting to obtain these values or define them manually. When you use more than one method to define this information, it is passed to DHCP clients in the following sequence:
Manually configured settings.
Advanced DHCP options settings.
DHCP automatic configuration settings.
For example, you can manually define the domain name that you want the DHCP clients to receive and then enable DHCP automatic configuration. Although DHCP automatic configuration discovers the domain together with the DNS and WINS servers, the manually defined domain name is passed to DHCP clients with the discovered DNS and WINS server names, because the domain name discovered by the DHCP automatic configuration process is superseded by the manually defined domain name.
About the DHCP Relay Agent
You can configure a DHCP relay agent to forward DHCP requests received on an interface to one or more DHCP servers. DHCP clients use UDP broadcasts to send their initial DHCPDISCOVER messages because they do not have information about the network to which they are attached. If the client is on a network segment that does not include a server, UDP broadcasts normally are not forwarded by the Firepower Threat Defense device because it does not forward broadcast traffic. The DHCP relay agent lets you configure the interface of the Firepower Threat Defense device that is receiving the broadcasts to forward DHCP requests to a DHCP server on another interface.
DDNS update integrates DNS with DHCP. The two protocols are complementary: DHCP centralizes and automates IP address allocation; DDNS update automatically records the association between assigned addresses and hostnames at predefined intervals. DDNS allows frequently changing address-hostname associations to be updated frequently. Mobile hosts, for example, can then move freely on a network without user or administrator intervention. DDNS provides the necessary dynamic update and synchronization of the name-to-address mapping and address-to-name mapping on the DNS server.
The DDNS name and address mapping is held on the DHCP server in two resource records (RRs): the A RR includes the name-to-IP address mapping, while the PTR RR maps addresses to names. Of the two methods for performing DDNS updates—the IETF standard defined by RFC 2136 and a generic HTTP method—the Firepower Threat Defense device supports the IETF method.
DDNS is not supported on the BVI or bridge group member interfaces.
DDNS Update Configurations
The two most common DDNS update configurations are the following:
The DHCP client updates the A RR, while the DHCP server updates the PTR RR.
The DHCP server updates both the A RR and PTR RR.
In general, the DHCP server maintains DNS PTR RRs on behalf of clients. Clients may be configured to perform all desired DNS updates. The server may be configured to honor these updates or not. The DHCP server must know the fully qualified domain name (FQDN) of the client to update the PTR RR. The client provides an FQDN to the server using a DHCP option called Client FQDN.
UDP Packet Size
DDNS allows DNS requesters to advertise the size of their UDP packets and facilitates the transfer of packets larger than 512 octets. When a DNS server receives a request over UDP, it identifies the size of the UDP packet from the OPT RR and scales its response to contain as many resource records as are allowed in the maximum UDP packet size specified by the requester. The size of the DNS packets can be up to 4096 bytes for BIND or 1280 bytes for the Windows 2003 DNS Server.