Prefiltering and Prefilter Policies

About Prefiltering

Prefiltering is the first phase of access control, before the system performs more resource-intensive evaluation. Prefiltering is simple, fast, and early. Prefiltering uses limited outer-header criteria to quickly handle traffic. Compare this to subsequent evaluation, which uses inner headers and has more robust inspection capabilities.

Configure prefiltering to:

  • Improve performance— The sooner you exclude traffic that does not require inspection, the better. You can fastpath or block certain types of plaintext, passthrough tunnels based on their outer encapsulation headers, without inspecting their encapsulated connections. You can also fastpath or block any other connections that benefit from early handling.

  • Tailor deep inspection to encapsulated traffic—You can rezone certain types of tunnels, so that you can later handle their encapsulated connections using the same inspection criteria. Rezoning is necessary because after prefiltering, access control uses inner headers.

Prefiltering vs Access Control

Prefilter and access control policies both allow you to block and trust traffic, though the prefiltering "trust" functionality is called "fastpathing" because it skips more inspection. The following table explains this and other differences between prefiltering and access control, to help you decide whether to configure custom prefiltering.

If you do not configure custom prefiltering, you can only approximate—not replicate—prefilter functionality with early-placed Block and Trust rules in the access control policy.

Characteristic

Prefiltering

Access Control

For more information, see...

Primary function

Quickly fastpath or block certain types of plaintext, passthrough tunnels (see Encapsulation Conditions), or tailor subsequent inspection to their encapsulated traffic.

Fastpath or block any other connections that benefit from early handling.

Inspect and control all network traffic, using simple or complex criteria, including contextual information and deep inspection results.

About Prefiltering

Implementation

Prefilter policy.

The prefilter policy is invoked by the access control policy.

Access control policy.

The access control policy is a main configuration. In addition to invoking subpolicies, access control policies have their own rules.

About Prefilter Policies

Associating Other Policies with Access Control

Sequence within access control

First.

The system matches traffic to prefilter criteria before all other access control configurations.

Rule actions

Fewer.

You can stop further inspection (Fastpath and Block) or allow further analysis with the rest of access control (Analyze).

More.

Access control rules have a larger variety of actions, including monitoring, deep inspection, block with reset, and interactive blocking.

Tunnel and Prefilter Rule Components

Access Control Rule Actions

Bypass capability

Fastpath rule action.

Fastpathing traffic in the prefilter stage bypasses all further inspection and handling, including:

  • Security Intelligence

  • authentication requirements imposed by an identity policy

  • SSL decryption

  • access control rules

  • deep inspection of packet payloads

  • discovery

  • rate limiting

Trust rule action.

Traffic trusted by access control rules is only exempt from deep inspection and discovery.

Introduction to Access Control Rules

Rule criteria

Limited.

Rules in the prefilter policy use simple network criteria: IP address, VLAN tag, port, and protocol.

For tunnels, tunnel endpoint conditions specify the IP address of the routed interfaces of the network devices on either side of the tunnel.

Robust.

Access control rules use network criteria, but also user, application, requested URL, and other contextual information available in packet payloads.

Network conditions specify the IP address of source and destination hosts.

Tunnel vs Prefilter Rules

Rule Condition Types

IP headers used (tunnel handling)

Outermost.

Using outer headers allows you to handle entire plaintext, passthrough tunnels.

For nonencapsulated traffic, prefiltering still uses "outer" headers—which in this case are the only headers.

Innermost possible.

For a nonencrypted tunnel, access control acts on its individual encapsulated connections, not the tunnel as a whole.

Passthrough Tunnels and Access Control

Rezone encapsulated connections for further analysis

Rezones tunneled traffic.

Tunnel zones allow you to tailor subsequent inspection to prefiltered, encapsulated traffic.

Uses tunnel zones.

Access control uses the tunnel zones you assign during prefiltering.

Tunnel Zones and Prefiltering

Connection logging

Fastpathed and blocked traffic only. Allowed connections may still be logged by other configurations.

Any connection.

Other Connections You Can Log

Supported devices

Firepower Threat Defense only.

All.

Best Practices for Prefiltering

Passthrough Tunnels and Access Control

Plaintext (nonencrypted) tunnels can encapsulate multiple connections, often flowing between discontinuous networks. These tunnels are especially useful for routing custom protocols over IP networks, IPv6 traffic over IPv4 networks, and so on.

An outer encapsulation header specifies the source and destination IP addresses of the tunnel endpoints—the routed interfaces of the network devices on either side of the tunnel. Inner payload headers specify the source and destination IP addresses of the encapsulated connections' actual endpoints.

Often, network security devices handle plaintext tunnels as passthrough traffic. That is, the device is not one of the tunnel endpoints. Instead, it is deployed between the tunnel endpoints and monitors the traffic flowing between them.

Some network security devices, such as Cisco ASA firewalls running Cisco ASA Software (rather than Firepower Threat Defense), enforce security policies using outer IP headers. Even for plaintext tunnels, these devices have no control over or insight into individual encapsulated connections and their payloads.

By contrast, the Firepower System leverages access control as follows:

  • Outer header evaluation—First, prefiltering uses outer headers to handle traffic. You can block or fastpath entire plaintext, passthrough tunnels at this stage.

  • Inner header evaluation—Next, the rest of access control (and other features such as QoS) use the innermost detectable level of headers to ensure the most granular level of inspection and handling possible.

    If a passthrough tunnel is not encrypted, the system acts on its individual encapsulated connections at this stage. You must rezone a tunnel (see Tunnel Zones and Prefiltering) to act on all its encapsulated connections.

Access control has no insight into encrypted passthrough tunnels. For example, access control rules see a passthrough VPN tunnel as one connection. The system handles the entire tunnel using only the information in its outer, encapsulation header.

Best Practices for Prefiltering

Consider the following guidelines and limitations for prefiltering:

Best Practices for Fastpath Prefiltering

When you use the fastpath action in a prefilter rule, the matching traffic bypasses inspection and is simply transmitted through the device. Use this action for traffic that you can trust and that would not benefit from any of the security features available.

The following types of traffic are ideal for fastpathing. For example, you could configure the rules to fastpath any traffic from or to the IP addresses of the endpoints or servers. You can further limit the rule based on ports used.

  • Site-to-site VPN traffic that is going through the device. That is, the device is not an endpoint in the VPN topology.

  • Scanner traffic. Scanner probes can create a lot of false-positive responses from intrusion policies.

  • Voice/video.

  • Backups.

  • Management traffic (sftunnel) that traverses Firepower Threat Defense devices. Performing deep inspection on management traffic (using access control policies) can cause issues. You can prefilter based on port TCP/8305 between the management center and managed devices.

Model Requirements

Prefiltering is supported on Firepower Threat Defense devices only. Prefilter configurations have no effect on other devices.

Prefilter-like Capabilities on Non-FTD Devices

For Classic devices (7000/8000 series, ASA FirePOWER, NGIPSv):

Encapsulated Traffic Handling Best Practices

This topic discusses guidelines for the following types of encapsulated traffic:

  • Generic Routing Encapsulation (GRE)

  • Point-to-Point Protocol (PPTP)

  • IPinIP

  • IPv6inIP

  • Teredo

Devices cannot set reserved bits in the GRE packet header

Traffic is dropped if any device sets the values of bits 5 through 12 in the packet header to something other than 0 (zero) and if a signature is configured for Snort. For more information about the GRE packet header, see the introduction to RFC 1701.

How tunnels work with interfaces

Prefilter and access control policy rules are applied to all tunnel types on routed, transparent, inline-set, inline-tap, and passive interfaces.

References

For more information about the GRE and PPTP protocols, see the following:

Requirements and Prerequisites for Prefilter Policies

Model Support

FTD

Supported Domains

Any

User Roles

  • Admin

  • Access Admin

  • Network Admin

Configure Prefiltering

To perform custom prefiltering, configure and deploy prefilter policies to managed devices, as a part of access control.

Only one person should edit a policy at a time, using a single browser window. If multiple users save the same policy, the last saved changes are retained. For your convenience, the system displays information on who (if anyone) is currently editing each policy. To protect the privacy of your session, a warning appears after 30 minutes of inactivity on the policy editor. After 60 minutes, the system discards your changes.

Procedure


Step 1

Choose Policies > Access Control > Prefilter.

Step 2

Click New Policy to create a custom prefilter policy.

A new prefilter policy has no rules and a default action of Analyze all tunnel traffic. It performs no logging or tunnel rezoning. You can also Copy (copy icon) or Edit (edit icon) an existing policy.

Step 3

Configure the prefilter policy's default action and its logging options.

  • Default action—Choose a default action for supported plaintext, passthrough tunnels: Analyze all tunnel traffic (with access control) or Block all tunnel traffic.
  • Default action logging—Click Logging (logging icon) next to the default action; see Logging Connections with a Policy Default Action. You can configure default action logging for blocked tunnels only.

Step 4

Configure tunnel and prefilter rules.

In a custom prefilter policy, you can use both kinds of rule, in any order. Create rules depending on the specific type of traffic you want to match and the actions or further analysis you want to perform; see Tunnel vs Prefilter Rules.

Caution

 

Exercise caution when using tunnel rules to assign tunnel zones. Connections in rezoned tunnels may not match security zone constraints in later evaluation. For more information, see Tunnel Zones and Prefiltering.

For detailed information on configuring rule components, see Tunnel and Prefilter Rule Components and Rule Management: Common Characteristics.

Step 5

Evaluate rule order. To move a rule, click and drag or use the right-click menu to cut and paste.

Properly creating and ordering rules is a complex task, but one that is essential to building an effective deployment. If you do not plan carefully, rules can preempt other rules or contain invalid configurations. For more information, see Best Practices for Access Control Rules.

Step 6

Save the prefilter policy.

Step 7

For configurations that support tunnel zone constraints, appropriately handle rezoned tunnels.

Match connections in rezoned tunnels by using tunnel zones as source zone constraints; see Configuring Interface Conditions.

Step 8

Associate the prefilter policy with the access control policy deployed to your managed devices.

See Associating Other Policies with Access Control.

Step 9

Deploy configuration changes; see Deploy Configuration Changes.

Note

 

When you deploy a prefilter policy, its rules are not applied on the existing tunnel sessions. Hence, traffic on an existing connection is not bound by the new policy that is deployed. In addition, the policy hit count is incremented only for the first packet of a connection that matches a policy. Thus, the traffic of an existing connection that could match a policy is omitted from the hit count. To have the policy rules effectively applied, clear the existing tunnel sessions, and then deploy the policy.


About Prefilter Policies

Prefiltering is a policy-based feature. In the Firepower System, an access control policy is a main configuration that invokes subpolicies and other configurations, including a prefilter policy.

Policy Components: Rules and Default Action

In a prefilter policy, tunnel rules, prefilter rules, and a default action handle network traffic:

  • Tunnel and prefilter rules—First, rules in a prefilter policy handle traffic in the order you specify. Tunnel rules match specific tunnels only and support rezoning. Prefilter rules have a wider range of constraints and do not support rezoning. For more information, see Tunnel vs Prefilter Rules.

  • Default action (tunnels only)—If a tunnel does not match any rules, the default action handles it. The default action can block these tunnels, or continue access control on their individual encapsulated connections. You cannot rezone tunnels with the default action.

    There is no default action for nonencapsulated traffic. If a nonencapsulated connection does not match any prefilter rules, the system continues with access control.

Connection Logging

You can log connections fastpathed and blocked by the prefilter policy; see Other Connections You Can Log.

Connection events contain information on whether and how logged connections—including entire tunnels—were prefiltered. You can view this information in event views (workflows), dashboards, and reports, and use it as correlation criteria. Keep in mind that because fastpathed and blocked connections are not subject to deep inspection, associated connection events contain limited information.

Default Prefilter Policy

Every access control policy has an associated prefilter policy.

The system uses a default policy if you do not configure custom prefiltering. Initially, this system-provided policy passes all traffic to the next phase of access control. You can change the policy's default action and configure its logging options, but you cannot add rules to it or delete it.

Prefilter Policy Inheritance and Multitenancy

Access control uses a hierarchical implementation that complements multitenancy. Along with other advanced settings, you can lock a prefilter policy association, enforcing that association in all descendant access control policies. For more information, see Access Control Policy Inheritance.

In a multidomain deployment, the system displays policies created in the current domain, which you can edit. It also displays policies created in ancestor domains, which you cannot edit. To view and edit policies created in a lower domain, switch to that domain. The default prefilter policy belongs to the Global domain.

Tunnel vs Prefilter Rules

Whether you configure a tunnel or prefilter rule depends on the specific type of traffic you want to match and the actions or further analysis you want to perform.

Characteristic

Tunnel Rules

Prefilter Rules

Primary function

Quickly fastpath, block, or rezone plaintext, passthough tunnels.

Quickly fastpath or block any other connection that benefits from early handling.

Encapsulation and port/protocol criteria

Encapsulation conditions match only plaintext tunnels over selected protocols, listed in Encapsulation Conditions.

Port conditions can use a wider range of port and protocol constraints than tunnel rules; see Port and ICMP Code Conditions.

Network criteria

Tunnel endpoint conditions constrain the endpoints of the tunnels you want to handle; see Tunnel Endpoint Conditions.

Network conditions constrain the source and destination hosts in each connection; see Network Conditions.

Direction

Bidirectional or unidirectional (configurable).

Tunnel rules are bidirectional by default, so they can handle all traffic between tunnel endpoints.

Unidirectional only (nonconfigurable).

Prefilter rules match source-to-destination traffic only.

Rezone sessions for further analysis

Supported, using tunnel zones; see Tunnel Zones and Prefiltering.

Not supported.

Tunnel and Prefilter Rule Components

State (Enabled/Disabled)

By default, rules are enabled. If you disable a rule, the system does not use it and stops generating warnings and errors for that rule.

Position

Rules are numbered, starting at 1. The system matches traffic to rules in top-down order by ascending rule number. The first rule that traffic matches is the rule that handles that traffic, regardless of rule type (tunnel vs prefilter).

Action

A rule's action determines how the system handles and logs matching traffic:

  • Fastpath—Exempts matching traffic from all futher inspection and control, including access control, identity requirements, and rate limiting. Fastpathing a tunnel fastpaths all encapsulated connections.

  • Block—Blocks matching traffic without further inspection of any kind. Blocking a tunnel blocks all encapsulated connections.

  • Analyze—Allows traffic to continue to be analyzed by the rest of access control, using inner headers. If passed by access control and any related deep inspection, this traffic may also be rate limited. For tunnel rules, enables rezoning with the Assign Tunnel Zone option.

Direction (Tunnel Rules Only)

A tunnel rule's direction determines how the system source and destination criteria:

  • Match tunnels only from source (unidirectional)—Match source-to-destination traffic only. Matching traffic must originate from one of the specified source interfaces or tunnel endpoints, and leave through one of the destination interfaces or tunnel endpoints.

  • Match tunnels from source and destination (bidirectional)—Match both source-to-destination traffic and destination-to-source traffic. The effect is identical to writing two unidirectional rules, one the mirror of the other.

Prefilter rules are always unidirectional.

Assign Tunnel Zone (Tunnel Rules Only)

In a tunnel rule, assigning a tunnel zone (whether existing or created on the fly), rezones matching tunnels. Rezoning requires the Analyze action.

Rezoning a tunnel allows other configurations—such as access control rules—to recognize all the tunnel's encapsulated connections as belonging together. By using a tunnel's assigned tunnel zone as an interface constraint, you can tailor inspection to its encapsulated connections. For more information, see Tunnel Zones and Prefiltering.


Caution


Exercise caution when assigning tunnel zones. Connections in rezoned tunnels may not match security zone constraints in later evaluation. See Using Tunnel Zones for a brief walkthrough of a tunnel zone implementation, and a discussion of the implications of rezoning without explicitly handling rezoned traffic.


Conditions

Conditions specify the specific traffic the rule handles. Traffic must match all a rule's conditions to match the rule. Each condition type has its own tab in the rule editor.

You can prefilter traffic using the following outer-header constraints:

You must constrain tunnel rules by encapsulation protocol.

Logging

A rule's logging settings govern the records the system keeps of the traffic it handles.

In tunnel and prefilter rules, you can log fastpathed and blocked traffic (the Fastpath and Block actions). For traffic subject to further analysis (the Analyze action), logging in the prefilter policy is disabled, although matching connections may still be logged by other configurations. For more information, see Logging Connections with Tunnel and Prefilter Rules.

Comments

Each time you save changes to a rule you can add comments. For example, you might summarize the overall configuration for the benefit of other users, or note when you change a rule and the reason for the change.

You cannot edit or delete these comments after you save the rule.

Tunnel Zones and Prefiltering

Tunnel zones allow you to use prefiltering to tailor subsequent traffic handling to encapsulated connections.

A special mechanism is required because usually, the system handles traffic using the innermost detectable level of headers. This ensures the most granular level of inspection possible. But it also means that if a passthrough tunnel is not encrypted, the system acts on its individual encapsulated connections; see Passthrough Tunnels and Access Control.

Tunnel zones solve this problem. During the first phase of access control (prefiltering) you can use outer headers to identify certain types of plaintext, pasthrough tunnels. Then, you can rezone those tunnels by assigning a custom tunnel zone.

Rezoning a tunnel allows other configurations—such as access control rules—to recognize all the tunnel's encapsulated connections as belonging together. By using a tunnel's assigned tunnel zone as an interface constraint, you can tailor inspection to its encapsulated connections.

Despite its name, a tunnel zone is not a security zone. A tunnel zone does not represent a set of interfaces. It is more accurate to think of a tunnel zone as a tag that, in some cases, replaces the security zone associated with an encapsulated connection.


Caution


For configurations that support tunnel zone constraints, connections in rezoned tunnels do not match security zone constraints. For example, after you rezone a tunnel, access control rules can match its encapsulated connections with their newly assigned tunnel zone, but not with any original security zone.


See Using Tunnel Zones for a brief walkthough of a tunnel zone implementation, and a discussion of the implications of rezoning without explicitly handling rezoned traffic.

Configurations Supporting Tunnel Zone Constraints

Only access control rules support tunnel zone constraints.

No other configurations support tunnel zone constraints. For example, you cannot use QoS to rate limit a plaintext tunnel as a whole; you can only rate limit its individual encapsulated sessions.

Using Tunnel Zones

This example procedure summarizes how you might rezone GRE tunnels for further analysis, using tunnel zones. You can adapt the concepts described in this example to other scenarios where you need to tailor traffic inspection to connections encapsulated in plaintext, passthrough tunnels.

Consider a Firepower System deployment where your organization's internal traffic flows through the Trusted security zone. The Trusted security zone represents a set of sensing interfaces across multiple managed devices deployed in various locations. Your organization's security policy requires that you allow internal traffic after deep inspection for exploits and malware.

Internal traffic sometimes includes plaintext, passthrough, GRE tunnels between particular endpoints. Because the traffic profile of this encapsulated traffic is different from your "normal" interoffice activity—perhaps it is known and benign—you can limit inspection of certain encapsulated connections while still complying with your security policy.

In this example, after you deploy configuration changes:

  • Plaintext, passthrough, GRE-encapsulated tunnels detected in the Trusted zone have their individual encapsulated connections evaluated by one set of intrusion and file policies.

  • All other traffic in the Trusted zone is evaluated with a different set of intrusion and file policies.

You accomplish this task by rezoning GRE tunnels. Rezoning ensures that access control associates GRE-encapsulated connections with a custom tunnel zone, rather than their original Trusted security zone. Rezoning is required due to the way the Firepower System and access control handle encapsulated traffic; see Passthrough Tunnels and Access Control and Tunnel Zones and Prefiltering.

Procedure


Step 1

Configure custom intrusion and file policies that tailor deep inspection to encapsulated traffic, and another set of intrusion and file policies tailored to nonencapsulated traffic.

Step 2

Configure custom prefiltering to rezone GRE tunnels flowing through the Trusted security zone.

Create a custom prefilter policy and associate it with access control. In that custom prefilter policy, create a tunnel rule (in this example, GRE_tunnel_rezone) and a corresponding tunnel zone (GRE_tunnel). For more information, see Configure Prefiltering.

Table 1. GRE_tunnel_rezone Tunnel Rule

Rule Component

Description

Interface object condition

Match internal-only tunnels by using the Trusted security zone as both a Source Interface Object and Destination Interface Object constraint.

Tunnel endpoint condition

Specify the source and destination endpoints for the GRE tunnels used in your organization.

Tunnel rules are bidirectional by default. If you do not change the Match tunnels from... option, it does not matter which endpoints you specify as source and which as destination.

Encapsulation condition

Match GRE traffic.

Assign Tunnel Zone

Create the GRE_tunnel tunnel zone, and assign it to tunnels that match the rule.

Action

Analyze (with the rest of access control).

Step 3

Configure access control to handle connections in rezoned tunnels.

In the access control policy deployed to your managed devices, configure a rule (in this example, GRE_inspection) that handles the traffic you rezoned. For more information, see Create and Edit Access Control Rules.

Table 2. GRE_inspection Access Control Rule

Rule Component

Description

Security zone condition

Match rezoned tunnels by using the GRE_tunnel security zone as a Source Zone constraint; see Interface Conditions.

Action

Allow, with deep inspection enabled.

Choose the file and intrusion policies tailored to inspect encapsulated internal traffic.

Caution

 

If you skip this step, the rezoned connections may match any access control rule not constrained by security zone. If the rezoned connections do not match any access control rules, they are handled by the access control policy default action. Make sure this is your intent.

Step 4

Configure access control to handle nonencapsulated connections flowing through the Trusted security zone.

In the same access control policy, configure a rule (in this example, internal_default_inspection) that handles non-rezoned traffic in the Trusted security zone.

Table 3. internal_default_inspection Access Control Rule

Rule Component

Description

Security zone condition

Match non-rezoned internal-only traffic by using the Trusted security zone as both a Source Zone and Destination Zone constraint.

Action

Allow, with deep inspection enabled.

Choose the file and intrusion policies tailored to inspect nonencapsulated internal traffic.

Step 5

Evaluate the position of the new access control rules relative to preexisting rules. Change rule order if necessary.

If you place the two new access control rules next to each other, it does not matter which you place first. Because you rezoned GRE tunnels, the two rules cannot preempt each other.

Step 6

Save all changed configurations.


What to do next

Creating Tunnel Zones

Procedure


Step 1

Choose Objects > Object Management.

Step 2

Chose Tunnel Zone from the list of object types.

Step 3

Click Add Tunnel Zone.

Step 4

Enter a Name and, optionally, a Description.

Step 5

Click Save.


What to do next

  • Assign tunnel zones to plaintext, passthrough tunnels as part of custom prefiltering; see Configure Prefiltering.

Large Flow Offloads

On devices that run FXOS (such as Firepower 4100/9300 chassis), certain traffic that you configure to be fastpathed by a prefilter policy is handled by the hardware (specifically, in the NIC), not by your Firepower Threat Defense software. Offloading these connection flows results in higher throughput and lower latency, especially for data-intensive applications such as large file transfers. This feature is especially useful for data centers. This is called static flow offload.

Offloaded flows continue to receive limited stateful inspection, such as basic TCP flag and option checking. The system can selectively escalate packets to the firewall system for further processing if necessary.

Examples of applications that can benefit from offloading large flows are:

  • High Performance Computing (HPC) Research sites, where the Firepower Threat Defense device is deployed between storage and high compute stations. When one research site backs up using FTP file transfer or file sync over NFS, the large amount of data traffic affects all connections. Offloading FTP file transfer and file sync over NFS reduces the impact on other traffic.

  • High Frequency Trading (HFT), where the Firepower Threat Defense device is deployed between workstations and the Exchange, mainly for compliance purposes. Security is usually not a concern, but latency is a major concern.

The following flows can be offloaded:

  • Connections that are fastpathed by the prefilter policy.

  • Standard or 802.1Q tagged Ethernet frames only.


Important


For details, exceptions, and limitations to the above, see Flow Offload Limitations.


Use Static Flow Offload

To offload eligible traffic to hardware, create a prefilter policy rule that applies the Fastpath action. Use prefilter rules for TCP/UDP, and tunnel rules for GRE.

(Not recommended.) To disable static flow offload and as a by-product, dynamic flow-offload, use FlexConfig to run the no flow-offload enable command. After deployment, you will have to reload the device to implement the change. For information about this command, see the Cisco ASA Series Command Reference, available from https://www.cisco.com/c/en/us/support/security/asa-5500-series-next-generation-firewalls/products-command-reference-list.html.

Flow Offload Limitations

Not all flows can be offloaded. Even after offload, a flow can be removed from being offloaded under certain conditions. Following are some of the limitations:

Device Limitations

The feature is supported on the following devices:

  • Firepower 9300 running FXOS 1.1.3 or higher.

Flows that cannot be offloaded

The following types of flows cannot be offloaded.

  • Any flows that do not use IPv4 addressing, such as IPv6 addressing.

  • Flows for any protocol other than TCP, UDP, and GRE.


    Note


    PPTP GRE connections cannot be offloaded.


  • Flows on interfaces configured in passive, inline, or inline tap mode. Routed and switched interfaces are the only types supported.

  • Flows that require inspection by Snort or other inspection engines. In some cases, such as FTP, the secondary data channel can be offloaded although the control channel cannot be offloaded.

  • IPsec and TLS/DTLS VPN connections that terminate on the device.

  • Multicast flows in routed mode. They are supported in transparent mode if there are only two member interfaces in a bridge group.

  • TCP state bypass flows. You cannot configure flow offload and TCP state bypass on the same traffic.

  • Flows tagged with security groups.

  • Reverse flows that are forwarded from a different cluster node, in case of asymmetric flows in a cluster.

  • Centralized flows in a cluster, if the flow owner is not the control unit.

Additional Limitations
  • Flow offload and Dead Connection Detection (DCD) are not compatible. Do not configure DCD on connections that can be offloaded.

  • If more than one flow that matches flow offload conditions are queued to be offloaded at the same time to the same location on the hardware, only the first flow is offloaded. The other flows are processed normally. This is called a collision. Use the show flow-offload flow command in the CLI to display statistics for this situation.

  • Although offloaded flows pass through FXOS interfaces, statistics for these flows do not appear on the logical device interface. Thus, logical device interface counters and packet rates do not reflect offloaded flows.

Conditions for reversing offload

After a flow is offloaded, packets within the flow are returned to the FTD for further processing if they meet the following conditions:

  • They include TCP options other than Timestamp.

  • They are fragmented.

  • They are subject to Equal-Cost Multi-Path (ECMP) routing, and ingress packets move from one interface to another.