SCADA Preprocessors

The following topics explain preprocessors for Supervisory Control and Data Acquisition (SCADA) protocols, and how to configure them:

Introduction to SCADA Preprocessors


Note


This section applies to Snort 2 preprocessors. For information on Snort 3 inspectors, see https://www.cisco.com/go/snort3-inspectors.


Supervisory Control and Data Acquisition (SCADA) protocols monitor, control, and acquire data from industrial, infrastructure, and facility processes such as manufacturing, production, water treatment, electric power distribution, airport and shipping systems, and so on. The Firepower System provides preprocessors for the Modbus, Distributed Network Protocol (DNP3), Common Industrial Protocol (CIP), and S7Commplus SCADA protocols that you can configure as part of your network analysis policy.

If the Modbus, DNP3, CIP, or S7Commplus preprocessor is disabled, and you enable and deploy an intrusion rule that requires one of these preprocessors, the system automatically uses the required preprocessor, with its current settings, although the preprocessor remains disabled in the web interface for the corresponding network analysis policy.

License Requirements for SCADA Preprocessors

FTD License

Threat

Classic License

Protection

Requirements and Prerequisites for SCADA Preprocessors

Model Support

Any.

Supported Domains

Any

User Roles

  • Admin

  • Intrusion Admin

The Modbus Preprocessor


Note


This section applies to Snort 2 preprocessors. For information on Snort 3 inspectors, see https://www.cisco.com/go/snort3-inspectors.


The Modbus protocol, which was first published in 1979 by Modicon, is a widely used SCADA protocol. The Modbus preprocessor detects anomalies in Modbus traffic and decodes the Modbus protocol for processing by the rules engine, which uses Modbus keywords to access certain protocol fields.

A single configuration option allows you to modify the default setting for the port that the preprocessor inspects for Modbus traffic.

Modbus Preprocessor Ports Option

Ports

Specifies the ports that the preprocessor inspects for Modbus traffic. Separate multiple ports with commas.

Configuring the Modbus Preprocessor


Note


This section applies to Snort 2 preprocessors. For information on Snort 3 inspectors, see https://www.cisco.com/go/snort3-inspectors.


You should not enable this preprocessor in a network analysis policy that you apply to traffic if your network does not contain any Modbus-enabled devices.

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.

Procedure


Step 1

Choose Policies > Access Control, then click Network Analysis Policies or Policies > Access Control > Intrusion, then click Network Analysis Policies.

Note

 
If your custom user role limits access to the first path listed here, use the second path to access the policy.

Step 2

Click Edit (edit icon) next to the policy you want to edit.

If View (View button) appears instead, the configuration belongs to an ancestor domain, or you do not have permission to modify the configuration.

Step 3

Click Settings in the navigation panel.

Step 4

If Modbus Configuration under SCADA Preprocessors is disabled, click Enabled.

Step 5

Click Edit (edit icon) next to Modbus Configuration.

Step 6

Enter a value in the Ports field.

Separate multiple values with commas.

Step 7

To save changes you made in this policy since the last policy commit, click Policy Information, then click Commit Changes.

If you leave the policy without committing changes, cached changes since the last commit are discarded if you edit a different policy.


What to do next

Modbus Preprocessor Rules

You must enable the Modbus preprocessor rules in the following table if you want these rules to generate events and, in an inline deployment, drop offending packets.

Table 1. Modbus Preprocessor Rules

Preprocessor Rule GID:SID

Description

144:1

Generates an event when the length in the Modbus header does not match the length required by the Modbus function code.

Each Modbus function has an expected format for requests and responses. If the length of the message does not match the expected format, this event is generated.

144:2

Generates an event when the Modbus protocol ID is non-zero. The protocol ID field is used for multiplexing other protocols with Modbus. Because the preprocessor does not process these other protocols, this event is generated instead.

144:3

Generates an event when the preprocessor detects a reserved Modbus function code.

The DNP3 Preprocessor


Note


This section applies to Snort 2 preprocessors. For information on Snort 3 inspectors, see https://www.cisco.com/go/snort3-inspectors.


The Distributed Network Protocol (DNP3) is a SCADA protocol that was originally developed to provide consistent communication between electrical stations. DNP3 has also become widely used in the water, waste, transportation, and many other industries.

The DNP3 preprocessor detects anomalies in DNP3 traffic and decodes the DNP3 protocol for processing by the rules engine, which uses DNP3 keywords to access certain protocol fields.

DNP3 Preprocessor Options

Ports

Enables inspection of DNP3 traffic on each specified port. You can specify a single port or a comma-separated list of ports.

Log bad CRCs

Validates the checksums contained in DNP3 link layer frames. Frames with invalid checksums are ignored.

You can enable rule 145:1 to generate events and, in an inline deployment, drop offending packets when invalid checksums are detected.

Configuring the DNP3 Preprocessor


Note


This section applies to Snort 2 preprocessors. For information on Snort 3 inspectors, see https://www.cisco.com/go/snort3-inspectors.


You should not enable this preprocessor in a network analysis policy that you apply to traffic if your network does not contain any DNP3-enabled devices.

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.

Procedure


Step 1

Choose Policies > Access Control, then click Network Analysis Policies or Policies > Access Control > Intrusion, then click Network Analysis Policies.

Note

 
If your custom user role limits access to the first path listed here, use the second path to access the policy.

Step 2

Click Edit (edit icon) next to the policy you want to edit.

If View (View button) appears instead, the configuration belongs to an ancestor domain, or you do not have permission to modify the configuration.

Step 3

Click Settings in the navigation panel.

Step 4

If DNP3 Configuration under SCADA Preprocessors is disabled, click Enabled.

Step 5

Click Edit (edit icon) next to DNP3 Configuration.

Step 6

Enter a value for Ports.

Separate multiple values with commas.

Step 7

Check or clear the Log bad CRCs check box.

Step 8

To save changes you made in this policy since the last policy commit, click Policy Information, then click Commit Changes.

If you leave the policy without committing changes, cached changes since the last commit are discarded if you edit a different policy.


What to do next

DNP3 Preprocessor Rules

You must enable the DNP3 preprocessor rules in the following table if you want these rules to generate events and, in an inline deployment, drop offending packets.

Table 2. DNP3 Preprocessor Rules

Preprocessor Rule GID:SID

Description

145:1

When Log bad CRC is enabled, generates an event when the preprocessor detects a link layer frame with an invalid checksum.

145:2

Generates an event and blocks the packet when the preprocessor detects a DNP3 link layer frame with an invalid length.

145:3

Generates an event and blocks the packet during reassembly when the preprocessor detects a transport layer segment with an invalid sequence number.

145:4

Generates an event when the DNP3 reassembly buffer is cleared before a complete fragment can be reassembled. This happens when a segment carrying the FIR flag appears after other segments have been queued.

145:5

Generates an event when the preprocessor detects a DNP3 link layer frame that uses a reserved address.

145:6

Generates an event when the preprocessor detects a DNP3 request or response that uses a reserved function code.

The CIP Preprocessor


Note


This section applies to Snort 2 preprocessors. For information on Snort 3 inspectors, see https://www.cisco.com/go/snort3-inspectors.


The Common Industrial Protocol (CIP) is a widely used application protocol that supports industrial automation applications. EtherNet/IP (ENIP) is an implementation of CIP that is used on Ethernet-based networks.

The CIP preprocessor detects CIP and ENIP traffic running on TCP or UDP and sends it to the intrusion rules engine. You can use CIP and ENIP keywords in custom intrusion rules to detect attacks in CIP and ENIP traffic. See CIP and ENIP Keywords. Additionally, you can control traffic by specifying CIP and ENIP application conditions in access control rules. See Configuring Application Conditions and Filters.

CIP Preprocessor Options

Ports

Specifies the ports to inspect for CIP and ENIP traffic. You can specify an integer from 0 to 65535. Separate multiple port numbers with commas.


Note


You must add the default CIP detection port 44818 and any other ports you list to the TCP stream Perform Stream Reassembly on Both Ports list. See TCP Stream Preprocessing Options and Creating a Custom Network Analysis Policy.


Default Unconnected Timeout (seconds)

When a CIP request message does not contain a protocol-specific timeout value and Maximum number of concurrent unconnected requests per TCP connection is reached, the system times the message for the number of seconds specified by this option. When the timer expires, the message is removed to make room for future requests. You can specify an integer from 0 to 360. When you specify 0, all traffic that does not have a protocol-specific timeout times out first.

Maximum number of concurrent unconnected requests per TCP connection

The number of concurrent requests that can go unanswered before the system closes the connection. You can specify an integer from 1 to 10000.

Maximum number of CIP connections per TCP connection

The maximum number of simultaneous CIP connections allowed by the system per TCP connection. You can specify an integer from 1 to 10000.

CIP Events

By design, application detectors detect and event viewers display the same application one time per session. A CIP session can include multiple applications in different packets, and a single CIP packet can contain multiple applications. The CIP preprocessor handles all CIP and ENIP traffic according to the corresponding intrusion rule.

The following table shows the CIP values displayed in event views.

Table 3. CIP Event Field Values

Event Field

Displayed Value

Application Protocol

CIP or ENIP

Client

CIP Client or ENIP Client

Web Application

The specific application detected, which is:

  • For access control rules that allow or monitor traffic, the last application protocol detected in the session.

    Access control rules that you configure to log connections might not generate events for specified CIP applications, and access control rules that you do not configure to log connections might generate events for CIP applications.

  • For access control rules that block traffic, the application protocol that triggered the block.

    When an access control rule blocks a list of CIP applications, event viewers display the first application that is detected.

CIP Preprocessor Rules

If you want the CIP preprocessor rules listed in the following table to generate events, you must enable them. See Setting Intrusion Rule States for information on enabling rules.

Table 4. CIP Preprocessor Rules

GID:SID

Rule Message

148:1

CIP_MALFORMED

148:2

CIP_NON_CONFORMING

148:3

CIP_CONNECTION_LIMIT

148:4

CIP_REQUEST_LIMIT

Guidelines for Configuring the CIP Preprocessor

Note the following when configuring the CIP preprocessor:

Configuring the CIP Preprocessor


Note


This section applies to Snort 2 preprocessors. For information on Snort 3 inspectors, see https://www.cisco.com/go/snort3-inspectors.


Before you begin

Procedure


Step 1

Choose Policies > Access Control, then click Network Analysis Policies or Policies > Access Control > Intrusion, then click Network Analysis Policies.

Note

 
If your custom user role limits access to the first path listed here, use the second path to access the policy.

Step 2

Click Edit (edit icon) next to the policy you want to edit.

If View (View button) appears instead, the configuration belongs to an ancestor domain, or you do not have permission to modify the configuration.

Step 3

Click Settings in the navigation panel.

Step 4

If CIP Configuration under SCADA Preprocessors is disabled, click Enabled.

Step 5

You can modify any of the options described in CIP Preprocessor Options.

Step 6

To save changes you made in this policy since the last policy commit, click Policy Information, then click Commit Changes.

If you leave the policy without committing changes, cached changes since the last commit are discarded if you edit a different policy.


What to do next

The S7Commplus Preprocessor


Note


This section applies to Snort 2 preprocessors. For information on Snort 3 inspectors, see https://www.cisco.com/go/snort3-inspectors.


The S7Commplus preprocessor detects S7Commplus traffic. You can use S7Commplus keywords in custom intrusion rules to detect attacks in S7Commplus traffic. See S7Commplus Keywords.

Configuring the S7Commplus Preprocessor


Note


This section applies to Snort 2 preprocessors. For information on Snort 3 inspectors, see https://www.cisco.com/go/snort3-inspectors.


The S7Commplus preprocessor is supported on all Firepower Threat Defense devices.

Procedure


Step 1

Choose Policies > Access Control, then click Network Analysis Policies or Policies > Access Control > Intrusion, then click Network Analysis Policies.

Note

 
If your custom user role limits access to the first path listed here, use the second path to access the policy.

Step 2

Click Edit (edit icon) next to the policy you want to edit.

If View (View button) appears instead, the configuration belongs to an ancestor domain, or you do not have permission to modify the configuration.

Step 3

Click Settings in the navigation panel.

Step 4

If S7Commplus Configuration under SCADA Preprocessors is disabled, click Enabled.

Step 5

Optionally, click Edit (edit icon) next to S7Commplus Configuration and modify s7commplus_ports to identify ports that the preprocessor inspects for S7Commplus traffic. Separate multiple ports with commas.

Step 6

To save changes you made in this policy since the last policy commit, click Policy Information, then click Commit Changes.

If you leave the policy without committing changes, cached changes since the last commit are discarded if you edit a different policy.


What to do next