Applies To:
Show VersionsBIG-IP AAM
- 13.1.5, 13.1.4, 13.1.3, 13.1.1, 13.1.0
BIG-IP APM
- 13.1.5, 13.1.4, 13.1.3, 13.1.1, 13.1.0
BIG-IP Link Controller
- 13.1.5, 13.1.4, 13.1.3, 13.1.1, 13.1.0
BIG-IP Analytics
- 13.1.5, 13.1.4, 13.1.3, 13.1.1, 13.1.0
BIG-IP LTM
- 13.1.5, 13.1.4, 13.1.3, 13.1.1, 13.1.0
BIG-IP AFM
- 13.1.5, 13.1.4, 13.1.3, 13.1.1, 13.1.0
BIG-IP PEM
- 13.1.5, 13.1.4, 13.1.3, 13.1.1, 13.1.0
BIG-IP DNS
- 13.1.5, 13.1.4, 13.1.3, 13.1.1, 13.1.0
BIG-IP ASM
- 13.1.5, 13.1.4, 13.1.3, 13.1.1, 13.1.0
Overview: Mitigating Denial of Service and other attacks
The BIG-IP® system contains several features that provide you with the ability to create a configuration that contributes to the security of your network. In particular, the BIG-IP system is in a unique position to mitigate some types of Denial of Service (DoS) attacks that try to consume system resources in order to deny service to the intended recipients.
The following features of the BIG-IP system help it resist many types of DoS attacks:
- The BIG-IP kernel has a mechanism built in to protect against SYN Flood attacks by limiting simultaneous connections, and tearing down connections that have unacknowledged SYN/ACK packets after some time period as passed. (A SYN/ACK packet is a packet that is sent as part of the TCP three-way handshake).
- BIG-IP system can handle tens of thousands of Layer 4 (L4) connections per second. It would take a very determined attack to affect either the BIG-IP system itself, or the site, if sufficient server resources and bandwidth are available.
- SYN floods, or Denial of Service (DoS) attacks, can consume all available memory. The BIG-IP system supports a large amount of memory to help it resist DoS attacks.
Denial of Service attacks and iRules
You can create BIG-IP® iRules® to filter out malicious DoS attacks. After you identify a particular attack, you can write an iRule that discards packets containing the elements that identify the packet as malicious.
iRules for Code Red attacks
The BIG-IP® system is able to filter out the Code Red attack by using an iRule to send the HTTP request to a dummy pool.
when HTTP_REQUEST { if {string tolower [HTTP::uri] contains "default.ida" } { discard } else { pool RealServerPool }
iRules for Nimda attacks
The Nimda worm is designed to attack systems and applications based on the Microsoft® Windows® operating system.
when HTTP_REQUEST { set uri [string tolower [HTTP::uri]] if { ($uri contains "cmd.exe") or ($uri contains "root.exe") or ($uri contains "admin.dll") } { discard } else { pool ServerPool } }
Common Denial of Service attacks
You might want to know how the BIG-IP® system reacts to certain common attacks that are designed to deny service by breaking the service or the network devices. The following information lists the most common attacks, along with how the BIG-IP system functionality handles the attack.
Attack type | Description | Mitigation |
---|---|---|
SYN flood | A SYN flood is an attack against a system for the purpose of exhausting that system's resources. An attacker launching a SYN flood against a target system attempts to occupy all available resources used to establish TCP connections by sending multiple SYN segments containing incorrect IP addresses. Note that the term SYN refers to a type of connection state that occurs during establishment of a TCP/IP connection. More specifically, a SYN flood is designed to fill up a SYN queue. A SYN queue is a set of connections stored in the connection table in the SYN-RECEIVED state, as part of the standard three-way TCP handshake. A SYN queue can hold a specified maximum number of connections in the SYN-RECEIVED state. Connections in the SYN-RECEIVED state are considered to be half-open and waiting for an acknowledgment from the client. When a SYN flood causes the maximum number of allowed connections in the SYN-RECEIVED state to be reached, the SYN queue is said to be full, thus preventing the target system from establishing other legitimate connections. A full SYN queue therefore results in partially-open TCP connections to IP addresses that either do not exist or are unreachable. In these cases, the connections must reach their timeout before the server can continue fulfilling other requests. | The BIG-IP system includes a feature designed to alleviate SYN flooding. Known as SYN Check™, this feature sends information about the flow, in the form of cookies, to the requesting client, so that the system does not need to keep the SYN-RECEIVED state that is normally stored in the connection table for the initiated session. Because the SYN-RECEIVED state is not kept for a connection, the SYN queue cannot be exhausted, and normal TCP communication can continue. The SYN Check feature complements the existing adaptive reaper feature in the BIG-IP system. While the adaptive reaper handles established connection flooding, SYN Check prevents connection flooding altogether. That is, while the adaptive reaper must work overtime to flush connections, the SYN Check feature prevents the SYN queue from becoming full, thus allowing the target system to continue to establish TCP connections. |
ICMP flood (Smurf) | The ICMP flood, sometimes referred to as a Smurf attack, is an attack based on a method of making a remote network send ICMP Echo replies to a single host. In this attack, a single packet from the attacker goes to an unprotected network's broadcast address. Typically, this causes every machine on that network to answer with a packet sent to the target. The BIG-IP system is hardened against these attacks because it answers only a limited number of ICMP requests per second, and then drops the rest. On the network inside the BIG-IP system, the BIG-IP system ignores directed subnet broadcasts, and does not respond to the broadcast ICMP Echo that a Smurf attacker uses to initiate an attack. | You do not need to make any changes to the BIG-IP system configuration for this type of attack. |
UDP flood | The UDP flood attack is most commonly a distributed Denial of Service attack (DDoS), where multiple remote systems are sending a large flood of UDP packets to the target. The BIG-IP system handles these attacks similarly to the way it handles a SYN flood. If the port is not listening, the BIG-IP system drops the packets. If the port is listening, the reaper removes the false connections. | Setting the UDP idle session timeout to between 5 and 10 seconds reaps these connections quickly without impacting users with slow connections. However, with UDP this might still leave too many open connections, and your situation might require a setting of between 2 and 5 seconds. |
UDP fragment | The UDP fragment attack is based on forcing the system to reassemble huge amounts of UDP data sent as fragmented packets. The goal of this attack is to consume system resources to the point where the system fails. The BIG-IP system does not reassemble these packets, it sends them on to the server if they are for an open UDP service. If these packets are sent with the initial packet opening the connection correctly, then the connection is sent to the back-end server. If the initial packet is not the first packet of the stream, the entire stream is dropped. | You do not need to make any changes to the BIG-IP system configuration for this type of attack. |
Ping of Death | The Ping of Death attack is an attack with ICMP echo packets that are larger than 65535 bytes. As this is the maximum allowed ICMP packet size, this can crash systems that attempt to reassemble the packet. The BIG-IP system is hardened against this type of attack. However, if the attack is against a virtual server with the Any IP feature enabled, then these packets are sent on to the server. It is important that you apply the latest updates to your servers. | You do not need to make any changes to the BIG-IP system configuration for this type of attack. |
Land | A Land attack is a SYN packet sent with the source address and port the same as the destination address and port. The BIG-IP system is hardened to resist this attack. The BIG-IP system connection table matches existing connections so that a spoof of this sort is not passed on to the servers. Connections to the BIG-IP system are checked and dropped if spoofed in this manner. | You do not need to make any changes to the BIG-IP system configuration for this type of attack. |
Teardrop | A Teardrop attack is carried out by a program that sends IP fragments to a machine connected to the Internet or a network. The Teardrop attack exploits an overlapping IP fragment problem present in some common operating systems. The problem causes the TCP/IP fragmentation re-assembly code to improperly handle overlapping IP fragments. The BIG-IP system handles these attacks by correctly checking frame alignment and discarding improperly aligned fragments. | You do not need to make any changes to the BIG-IP system configuration for this type of attack. |
Data | The BIG-IP system can also offer protection from data attacks to the servers behind the BIG-IP system. The BIG-IP system acts as a port-deny device, preventing many common exploits by simply not passing the attack through to the server. | You do not need to make any changes to the BIG-IP system configuration for this type of attack. |
WinNuke | The WinNuke attack exploits the way certain common operating systems handle data sent to the NetBIOS ports. NetBIOS ports are 135, 136, 137 and 138, using TCP or UDP. The BIG-IP system denies these ports by default. | On the BIG-IP system, do not open these ports unless you are sure your servers have been updated against this attack. |
Sub 7 | The Sub 7 attack is a Trojan horse that is designed to run on certain common operating systems. This Trojan horse makes it possible the system to be controlled remotely. This Trojan horse listens on port 27374 by default. The BIG-IP system does not allow connections to this port from the outside, so a compromised server cannot be controlled remotely. | Do not open high ports (ports higher than 1024) without explicit knowledge of what applications will be running on these ports. |
Back Orifice | A Back Orifice attack is a Trojan horse that is designed to run on certain common operating systems. This Trojan horse makes it possible the system to be controlled remotely. This Trojan horse listens on UDP port 31337 by default. The BIG-IP system does not allow connections to this port from the outside, so a compromised server cannot be controlled remotely. | Do not open high ports (ports higher than 1024) without explicit knowledge of what will be running on these ports |
Task summary
There are several tasks you can perform to mitigate Denial of Service attacks.
Task list
Configuring adaptive reaping
This procedure configures adaptive reaping. The adaptive connection reaper closes idle connections when memory usage on the BIG-IP system increases. This feature makes it possible for the BIG-IP system to aggressively reap connections when the system memory utilization reaches the low-water mark, and to stop establishing new connections when the system memory utilization reaches the high-water mark percentage.
Blocking DoS attack
When aggressive mode is activated on the BIG-IP system, the event is marked in the /var/log/ltm file with messages similar to these examples:
tmm tmm[PID]: 011e0002:4: sweeper_update: aggressive mode activated. (117504/138240 pages)
tmm tmm[PID]: 011e0002:4: sweeper_update: aggressive mode deactivated. (117503/138240 pages)
Setting the TCP and UDP connection timers
- On the Main tab, click .
- From the Protocol menu, choose TCP or UDP.
- Click the name of the profile type you want to configure.
- Set the Idle Timeout setting to 60.
- Click Update.
Applying a rate class to a virtual server
Calculating connection limits on the main virtual server
Connection Limit = Approximate Amount of RAM in KB * 0.8.
256,000 * 0.8 = 204800
Setting connection limits on the main virtual server
Adjusting the SYN Check threshold
- On the Main tab, click .
- From the Local Traffic menu, choose General.
- In the SYN Check Activation Threshold field, type the number of connections that you want to define for the threshold.
- Click Update.