- 1. Introduction
- 2. Installing OpenSCAP
- 3. Displaying information about SCAP content
- 4. Scanning
- 5. Remediating system
- 6. Tailoring
- 7. Scanning with Script Check Engine (SCE)
- 8. Validating SCAP Content
- 9. Generating reports, guides and scripts
- 10. Details on SCAP conformance
- 11. List of accepted environment variables
- 12. Using external or remote resources
- 13. Practical Examples
- 13.1. Auditing System Settings with SCAP Security Guide
- 13.2. Auditing Security Vulnerabilities of Red Hat Products
- 13.3. How to Evaluate PCI-DSS on RHEL7
- 13.4. How to Evaluate DISA STIG
- 13.5. How to Evaluate United States Government Configuration Baseline (USGCB)
- 13.6. How to Evaluate Third-Party Guidances
- 13.7. How to check that patches are up-to-date on Red Hat Enterprise Linux 6 or 7
- 14. Scanning remote and virtual machines or containers
- 15. Scanning and remediating the system at boot time
- 16. Frequently Asked Questions (FAQs)
This documentation provides information about OpenSCAP and its most common operations. With OpenSCAP, you can check security configuration settings of a system, and examine the system for signs of a compromise by using rules based on standards and specifications.
OpenSCAP uses SCAP which is a line of specifications maintained by the NIST. SCAP was created to provide a standardized approach for maintaining system security. New specifications are governed by NIST’s SCAP Release cycle in order to provide a consistent and repeatable revision workflow. OpenSCAP mainly processes the XCCDF which is a standard way of expressing a checklist content and defines security checklists. It also combines with other specifications such as CPE, CCE and OVAL to create a SCAP-expressed checklist that can be processed by SCAP-validated products. For more information about the SCAP please refer to SCAP Standards.
OpenSCAP supports SCAP 1.3 and is backward compatible with SCAP 1.2, SCAP 1.1 and SCAP 1.0. No special treatment is required to import and process earlier versions of the SCAP content.
If you want to perform configuration or vulnerability scans of a local system then the following must be available:
-
A tool (
oscap
or SCAP Workbench) -
SCAP content (SCAP source data stream, XCCDF, OVAL…)
The oscap
tool is a part of the OpenSCAP project. If you’re
interested in a graphical alternative to this tool please visit
SCAP Workbench page.
We will use the SCAP Security Guide project to provide us the SCAP content. It provides security policies written in a form of SCAP documents covering many areas of security compliance, and it implements security guidances recommended by respected authorities, namely PCI DSS, STIG, and USGCB.
You can also generate your own SCAP content if you have an understanding of at least XCCDF or OVAL. XCCDF content is also frequently published online under open source licenses, and you can customize this content to suit your needs instead. SCAP Workbench is a great tool to do the customization.
You can either build OpenSCAP from source code or you can use an existing build for your Linux distribution.
For instructions about building from source code, please refer to OpenSCAP Developer Manual.
To install OpenSCAP on Red Hat Enterprise Linux 8 and newer, on CentOS 8 and newer or on Fedora use the following command:
# dnf install openscap-scanner
To install OpenSCAP on Red Hat Enterprise Linux 7 or CentOS 7 or older use the following command:
# yum install openscap-scanner
To install OpenSCAP on Debian or Ubuntu use the following command:
# apt install libopenscap8
After the installation is completed you can start using the oscap
command line
tool.
To display the version of OpenSCAP, supported specifications, built-in CPE names, and supported OVAL objects, type the following command:
$ oscap --version
To perform any task with OpenSCAP you also need to have security policies in SCAP format. We call them SCAP content. There are many providers of SCAP content.
In this document we will use SCAP content provided by SCAP Security Guide
(SSG). Many Linux distributions ship it in the scap-security-guide
package.
To install scap-security-guide
on Red Hat Enterprise Linux 8 and newer, on
CentOS 8 and newer or on Fedora use the following command:
# yum install scap-security-guide
To install scap-security-guide
on Red Hat Enterprise Linux 7 or CentOS 7 or
older use the following command:
# yum install scap-security-guide
The SCAP content will be installed in the /usr/share/xml/scap/ssg/content/
directory.
On other platforms, you can download the upstream release from GitHub.
When the SCAP content is installed on your system, oscap
can
process the content by specifying the file path to the content.
You can also use any other SCAP content with OpenSCAP.
Information about an SCAP file can be displayed using the oscap info
command.
The most common SCAP file type is an SCAP source data stream. In the following
example, we will display information about SCAP source data stream
/usr/share/xml/scap/ssg/content/ssg-rhel8-ds.xml
from the
scap-security-guide
package.
$ oscap info /usr/share/xml/scap/ssg/content/ssg-rhel8-ds.xml Document type: Source Data Stream Imported: 2021-01-12T04:50:11 Stream: scap_org.open-scap_datastream_from_xccdf_ssg-rhel8-xccdf-1.2.xml Generated: (null) Version: 1.3 Checklists: Ref-Id: scap_org.open-scap_cref_ssg-rhel8-xccdf-1.2.xml Status: draft Generated: 2021-01-12 Resolved: true Profiles: Title: CIS Red Hat Enterprise Linux 8 Benchmark Id: xccdf_org.ssgproject.content_profile_cis Title: Unclassified Information in Non-federal Information Systems and Organizations (NIST 800-171) Id: xccdf_org.ssgproject.content_profile_cui Title: Australian Cyber Security Centre (ACSC) Essential Eight Id: xccdf_org.ssgproject.content_profile_e8 Title: Health Insurance Portability and Accountability Act (HIPAA) Id: xccdf_org.ssgproject.content_profile_hipaa Title: PCI-DSS v3.2.1 Control Baseline for Red Hat Enterprise Linux 8 Id: xccdf_org.ssgproject.content_profile_pci-dss Title: [DRAFT] DISA STIG for Red Hat Enterprise Linux 8 Id: xccdf_org.ssgproject.content_profile_stig Title: Protection Profile for General Purpose Operating Systems Id: xccdf_org.ssgproject.content_profile_ospp Referenced check files: ssg-rhel8-oval.xml system: http://oval.mitre.org/XMLSchema/oval-definitions-5 ssg-rhel8-ocil.xml system: http://scap.nist.gov/schema/ocil/2 security-data-oval-com.redhat.rhsa-RHEL8.xml system: http://oval.mitre.org/XMLSchema/oval-definitions-5 Checks: Ref-Id: scap_org.open-scap_cref_ssg-rhel8-oval.xml Ref-Id: scap_org.open-scap_cref_ssg-rhel8-ocil.xml Ref-Id: scap_org.open-scap_cref_ssg-rhel8-cpe-oval.xml Ref-Id: scap_org.open-scap_cref_security-data-oval-com.redhat.rhsa-RHEL8.xml Dictionaries: Ref-Id: scap_org.open-scap_cref_ssg-rhel8-cpe-dictionary.xml
-
Document type describes what format the file is in. Common types include XCCDF, OVAL, source data stream and result data stream.
-
Imported is the date the file was imported for use with OpenSCAP. Since OpenSCAP uses the local filesystem and has no proprietary database format the imported date is the same as file modification date.
-
Stream is the data stream ID.
-
Version is the version of the SCAP standard.
-
Checklists lists available checklists incorporated in the data stream that you can use for the
--benchmark-id
command line attribute withoscap xccdf eval
. Also each checklist has the detailed information printed. -
Status is the XCCDF Benchmark status. Common values include "accepted", "draft", "deprecated" and "incomplete". Please refer to the XCCDF specification for details.
-
Generated date is the date the file was created or generated. This date is shown for XCCDF files and Checklists and is sourced from the XCCDF Status element.
-
Profiles lists available profiles, their titles and IDs that you can use for the
--profile
command line attribute. -
Checks and Dictionaries lists OVAL checks components and CPE dictionaries components in the given data stream.
To display more detailed information about a profile including the profile
description, use the --profile
option followed by the profile ID.
$ oscap info --profile xccdf_org.ssgproject.content_profile_ospp /usr/share/xml/scap/ssg/content/ssg-rhel8-ds.xml
The oscap info
command is also helpful with other SCAP file types such as
SCAP result data stream (ARF) files.
OpenSCAP can display the evaluation start and end dates when given ARF file.
In this example, we will display information about the ARF file arf.xml
.
$ oscap info arf.xml Document type: Result Data Stream Imported: 2021-02-11T11:04:51 Asset: asset0 ARF report: xccdf1 Report request: collection1 Result ID: xccdf_org.open-scap_testresult_xccdf_org.ssgproject.content_profile_ospp Source benchmark: /usr/share/xml/scap/ssg/content/ssg-fedora-ds.xml Source profile: xccdf_org.ssgproject.content_profile_ospp Evaluation started: 2021-02-11T11:03:06+01:00 Evaluation finished: 2021-02-11T11:04:51+01:00 Platform CPEs: cpe:/o:fedoraproject:fedora:25 cpe:/o:fedoraproject:fedora:26 cpe:/o:fedoraproject:fedora:27
The main goal of OpenSCAP is to perform configuration and vulnerability scans of a local system. OpenSCAP is able to evaluate SCAP source data streams, XCCDF benchmarks and OVAL definitions and generate the appropriate results.
SCAP content can be provided either in a single file (as an SCAP source data stream), or as multiple separate XML files.
Commonly, all required input files are bundled together in an SCAP source data
stream. Scanning using an SCAP source data stream can be performed by the
oscap xccdf eval
command, with some additional parameters available.
The basic syntax of the oscap xccdf eval
command is the following:
# oscap xccdf eval --profile PROFILE_ID --results-arf ARF_FILE --report REPORT_FILE SOURCE_DATA_STREAM_FILE
Where:
-
PROFILE_ID
is the ID of an XCCDF profile -
ARF_FILE
is the file path where the results in SCAP results data stream format (ARF) will be generated -
REPORT_FILE
is the file path where a report in HTML format will be generated -
SOURCE_DATA_STREAM_FILE
is the file path of the evaluated SCAP source data stream
For example, to evaluate the xccdf_org.ssgproject.content_profile_ospp
profile
from the /usr/share/xml/scap/ssg/content/ssg-rhel8-ds.xml
SCAP source
data stream run this command:
# oscap xccdf eval --profile xccdf_org.ssgproject.content_profile_ospp --results-arf results.xml --report report.html /usr/share/xml/scap/ssg/content/ssg-rhel8-ds.xml
The progress and results will be shown in the terminal. Full results are
generated in results.xml
as an SCAP result data stream. Detailed results can
be found in the HTML report report.html
.
$ firefox report.html
Tip
|
Instead of the complete profile ID you can provide only a suffix of the
profile ID. For example, instead of --profile
xccdf_org.ssgproject.content_profile_ospp you can use just --profile ospp .
|
To evaluate a specific XCCDF benchmark that is part of a specific SCAP source data stream, use the following command:
$ oscap xccdf eval --datastream-id DS_ID --xccdf-id CREF --results-arf ARF_FILE SOURCE_DATA_STREAM_FILE
Where:
-
DS_ID
is the ID of<ds:data-stream>
element to be evaluated -
XCCDF_ID
is ID of the<ds:component-ref>
element pointing to the desired XCCDF document -
ARF_FILE
is a file containing the scan results in a form of an SCAP result data stream -
SOURCE_DATA_STREAM_FILE
is the SCAP source data stream file
Note
|
If you omit --datastream-id on the command line, the first data
stream from the collection will be used. If you omit --xccdf-id , the
first component from the checklists element will be used. If you omit
both, the first data stream that has a component in the checklists
element will be used - the first component in its checklists element
will be used.
|
To evaluate a specific XCCDF benchmark that is part of an SCAP source data stream use the following options:
$ oscap xccdf eval --benchmark-id BENCHMARK_ID --results-arf ARF_XML SOURCE_DATA_STREAM_FILE
Where:
-
SOURCE_DATA_STREAM_FILE
is a file representing the SCAP source data stream -
BENCHMARK_ID
is the value of the "id" attribute of<xccdf:Benchmark>
containing component -
ARF_FILE
is a file containing the scan results in a form of an SCAP result data stream
The SCAP document can have a form of a single OVAL file (an OVAL Definition
file). The oscap
tool processes the OVAL Definition file during evaluation of
OVAL definitions. It collects system information, evaluates it and generates an
OVAL Result file. The result of evaluation of each OVAL definition is printed to
standard output stream. The following examples describe the most common
scenarios involving an OVAL Definition file.
To evaluate OVAL definitions within the given OVAL Definition file the
oscap oval eval
command can be used. Its basic form is the following:
$ oscap oval eval --results RESULTS_FILE OVAL_FILE
Where:
-
OVAL_FILE
is the OVAL Definition file -
RESULTS_FILE
is the path where OVAL Results file will be stored
It’s possible to select and evaluate one particular definition
within the given OVAL Definition file using --id
option:
$ oscap oval eval --id oval:rhel:def:1000 --results oval-results.xml oval.xml
Where the OVAL definition being evaluated has ID oval:rhel:def:1000
,
oval.xml
is the OVAL Definition file and oval-results.xml
is the
OVAL Result file.
To evaluate all definitions from the OVAL component that are part of a particular data stream component within a SCAP source data stream, run the following command:
$ oscap oval eval --datastream-id ds.xml --oval-id xccdf.xml --results oval-results.xml scap-ds.xml
Where ds.xml
is the ID of a specific data stream, xccdf.xml
is an XCCDF file
specifying the OVAL component, oval-results.xml
is the OVAL Result file, and
scap-ds.xml
is the SCAP source data stream collection.
When the SCAP content is represented by multiple XML files, the OVAL Definition file can be distributed along with the XCCDF file. In such a situation, OVAL Definitions may depend on variables that are exported from the XCCDF file during the scan, and separate evaluation of the OVAL definition(s) would produce misleading results. Therefore, any external variables has to be exported to a special file that is used during the OVAL definitions evaluation. The following commands are examples of this scenario:
$ oscap xccdf export-oval-variables \ --profile united_states_government_configuration_baseline \ usgcb-rhel5desktop-xccdf.xml
$ oscap oval eval \ --variables usgcb-rhel5desktop-oval.xml-0.variables-0.xml \ --results usgcb-results-oval.xml usgcb-rhel5desktop-oval.xml
Where united_states_government_configuration_baseline represents a profile in the XCCDF document, usgcb-rhel5desktop-xccdf.xml is a file specifying the XCCDF document, usgcb-rhel5desktop-oval.xml is the OVAL Definition file, usgcb-rhel5desktop-oval.xml-0.variables-0.xml is the file containing exported variables from the XCCDF file, and usgcb-results-oval.xml is the the OVAL Result file.
An OVAL directives file can be used to control whether results should be "thin" or "full". This file can be loaded by OpenSCAP using --directives <file> option.
Example of an OVAL directive file which enables thin results instead of full results:
<?xml version="1.0" encoding="UTF-8"?> <oval_directives xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xmlns:oval="http://oval.mitre.org/XMLSchema/oval-common-5" xmlns:oval-res="http://oval.mitre.org/XMLSchema/oval-results-5" xmlns="http://oval.mitre.org/XMLSchema/oval-directives-5" xsi:schemaLocation="http://oval.mitre.org/XMLSchema/oval-results-5 oval-results-schema.xsd http://oval.mitre.org/XMLSchema/oval-common-5 oval-common-schema.xsd http://oval.mitre.org/XMLSchema/oval-directives-5 oval-directives-schema.xsd"> <generator> <oval:product_name>OpenSCAP</oval:product_name> <!-- make sure the OVAL version matches your input --> <oval:schema_version>5.8</oval:schema_version> <oval:timestamp>2017-02-04T00:00:00</oval:timestamp> </generator> <directives include_source_definitions="true"> <oval-res:definition_true reported="true" content="thin"/> <oval-res:definition_false reported="true" content="thin"/> <oval-res:definition_unknown reported="true" content="thin"/> <oval-res:definition_error reported="true" content="thin"/> <oval-res:definition_not_evaluated reported="true" content="thin"/> <oval-res:definition_not_applicable reported="true" content="thin"/> </directives> </oval_directives>
If your use-case requires thin OVAL results you most likely also want
to omit system characteristics. You can use the --without-syschar
option to that effect.
Usage of OVAL directives file when scanning a plain OVAL file:
$ oscap oval eval --directives directives.xml --without-syschar --results oval-results.xml oval.xml
Usage of OVAL directives file when scanning OVAL component from a source data stream:
$ oscap oval eval --directives directives.xml --without-syschar --datastream-id ds.xml --oval-id oval.xml --results oval-results.xml scap-ds.xml
It is not always clear which OVAL file will be used when multiple files are distributed. In case you are evaluating an XCCDF file you can use:
$ oscap info ssg-rhel7-xccdf.xml Document type: XCCDF Checklist Checklist version: 1.1 Imported: 2017-01-20T14:20:43 Status: draft Generated: 2017-01-19 Resolved: true Profiles: standard pci-dss C2S rht-ccp common stig-rhel7-workstation-upstream stig-rhel7-server-gui-upstream stig-rhel7-server-upstream stig-rhevh-upstream ospp-rhel7-server nist-cl-il-al cjis-rhel7-server docker-host nist-800-171-cui Referenced check files: ssg-rhel7-oval.xml system: http://oval.mitre.org/XMLSchema/oval-definitions-5 ssg-rhel7-ocil.xml system: http://scap.nist.gov/schema/ocil/2 https://www.redhat.com/security/data/oval/com.redhat.rhsa-RHEL7.xml.bz2 system: http://oval.mitre.org/XMLSchema/oval-definitions-5
In the output you can see all referenced check files. In this case we see
that ssg-rhel7-oval.xml
is referenced. To see contents of this file you
can open it in a text editor.
You can use oscap info
with source data stream files as well. Source
data stream will often reference OVAL files that are bundled in it.
It is also possible to extract OVAL files from source data stream using
oscap ds sds-split
.
$ oscap ds sds-split ssg-rhel7-ds.xml extracted/ $ ls -1 extracted/ scap_org.open-scap_cref_output--ssg-rhel7-cpe-dictionary.xml scap_org.open-scap_cref_ssg-rhel7-xccdf-1.2.xml ssg-rhel7-cpe-oval.xml ssg-rhel7-ocil.xml ssg-rhel7-oval.xml
After splitting the source data stream you can inspect OVAL and XCCDF files individually using a text editor. Keep in mind that this is only an example and file names depend on contents of the source data stream you are splitting and that you can also inspect XCCDF and OVAL content directly in a source data stream or a result data stream.
When evaluating an XCCDF benchmark, oscap
usually processes an XCCDF
file, an OVAL file and the CPE dictionary. It performs system
analysis and produces XCCDF results based on this analysis. The results
of the scan do not have to be saved in a separate file but can be
attached to the XCCDF file. The evaluation result of each XCCDF rule
within an XCCDF checklist is printed to standard output stream. The CVE
and CCE identifiers associated with the rules are printed as well. The
following is a sample output for a single XCCDF rule:
Title Verify permissions on 'group' file Rule usgcb-rhel5desktop-rule-2.2.3.1.j Ident CCE-3967-7 Result pass
The meaning of results is defined by XCCDF Specification. This table lists the possible results of a single rule:
Result | Description | Example Situation |
---|---|---|
pass |
The target system or system component satisfied all the conditions of the rule. |
|
fail |
The target system or system component did not satisfy all the conditions of the rule. |
|
error |
The checking engine could not complete the evaluation, therefore the status of the target’s compliance with the rule is not certain. |
OpenSCAP was run with insufficient privileges and could not gather all of the necessary information. |
unknown |
The testing tool encountered some problem and the result is unknown. |
OpenSCAP was unable to interpret the output of the checking engine (the output has no meaning to OpenSCAP). |
notapplicable |
The rule was not applicable to the target of the test. |
The rule might have been specific to a different version of the target OS, or it might have been a test against a platform feature that was not installed. |
notchecked |
The rule was not evaluated by the checking engine. This status is designed for rules that have no <xccdf:check> elements or that correspond to an unsupported checking system. It may also correspond to a status returned by a checking engine if the checking engine does not support the indicated check code. |
The rule does not reference any OVAL check. |
notselected |
The rule was not selected in the benchmark. OpenSCAP does not display rules that were not selected. |
The rule exists in the benchmark, but is not a part of selected profile. |
informational |
The rule was checked, but the output from the checking engine is simply information for auditors or administrators; it is not a compliance category. This status value is designed for rules whose main purpose is to extract information from the target rather than test the target. |
|
fixed |
The rule had initially evaluated to "fail", but was then fixed by automated remediation and therefore it now evaluates as "pass". |
The CPE dictionary is used to determine whether the content is applicable on the target platform or not. Any content that is not applicable will result in each relevant XCCDF rule being evaluated to "notapplicable".
The following examples show the most common scenarios of XCCDF benchmark evaluation:
-
To evaluate a specific profile in an XCCDF file run this command:
$ oscap xccdf eval --profile Desktop --results xccdf-results.xml --cpe cpe-dictionary.xml scap-xccdf.xml
Where scap-xccdf.xml
is the XCCDF document, Desktop
is the selected
profile from the XCCDF document, xccdf-results.xml
is a file storing
the scan results, and cpe-dictionary.xml
is the CPE dictionary.
-
You can additionally add
--rule
option to the above command to evaluate a specific rule:
$ oscap xccdf eval --profile Desktop --rule ensure_gpgcheck_globally_activated --results xccdf-results.xml --cpe cpe-dictionary.xml scap-xccdf.xml
Where ensure_gpgcheck_globally_activated
is the only rule from the Desktop
profile which will be evaluated.
The --rule
option can be used multiple times to evaluate multiple rules at once.
-
You can skip some rules by using the
--skip-rule
option.
In the examples above we are generating XCCDF result files using the --results
command-line argument. You can use --results-arf
to generate an SCAP result
data stream (also called ARF - Asset Reporting Format) XML instead.
$ oscap xccdf eval --benchmark-id benchmark_id --results-arf arf-results.xml scap-ds.xml
DISA STIG Viewer is a graphical user interface (GUI) application that enables easy viewing of SCAP-formatted Security Technical Implementation Guides (STIGs). For more information on DISA STIG Viewer see the SRG / STIG Tools website.
OpenSCAP can generate results compatible with STIG Viewer even when evaluating
SCAP content that uses different rule IDs than the official DISA STIG format,
for example, content from the scap-security-guide
package or third-party
content.
To produce results compatible with STIG Viewer, each rule in an SCAP source data
stream must contain a reference to a STIG Rule ID, and the value of the href
attribute must be either
http://iase.disa.mil/stigs/Pages/stig-viewing-guidance.aspx
or
https://public.cyber.mil/stigs/srg-stig-tools/
.
For example:
<Rule id="rpm_verify_permissions"> ... <reference href="https://public.cyber.mil/stigs/srg-stig-tools/">SV-86473r2_rule</reference> ... </Rule>
In the following example, we use the
/usr/share/xml/scap/ssg/content/ssg-rhel7-ds.xml
file provided by the
scap-security-guide
RPM package. This data stream file meets both
prerequisites for rules.
1) Scan your system using the oscap
command with the --stig-viewer
option.
$ oscap xccdf eval --profile xccdf_org.ssgproject.content_profile_stig --stig-viewer results-stig.xml /usr/share/xml/scap/ssg/content/ssg-rhel7-ds.xml
2) Download a STIG file of your choice, for example, from the
STIGs Document Library, and extract
it. The version of the STIG must conform to the version of the
xccdf_org.ssgproject.content_profile_stig
profile.
3) In STIG Viewer, click on File
and then on Import STIG
. Then, select the
STIG in STIGs
panel on the left side. Click on Checklists
and then on
Create Checklists - Check Marked STIG(s)
.
4) Import the OpenSCAP scan results by clicking on Import
and then on XCCDF
Results File
. Locate the results-stig.xml
file obtained in step 1. STIG
Viewer shows the results subsequently.
Note
|
The --stig-viewer option serves for evaluating an SCAP source data stream
other than a STIG provided by DISA, for example, scap-security-guide content
and loading the generated file in STIG Viewer into a checklist created from a
STIG by DISA. When evaluating a STIG provided by DISA using oscap , use the
--results option instead. Similarly, when creating checklists based on
scap-security-guide content in STIG Viewer and evaluating
scap-security-guide by oscap, use --results instead of --stig-viewer .
|
OpenSCAP allows one to automatically remediate systems that have been found in a
non-compliant state. For system remediation the rules in SCAP content need to
have a remediation script attached. For example, the SCAP source data streams in
the scap-security-guide
package contain rules with remediation fix scripts.
System remediation consists of the following steps:
-
The
oscap
command performs a regular XCCDF evaluation. -
An assessment of the results is performed by evaluating the OVAL definitions. Each rule that has failed is marked as a candidate for remediation.
-
The
oscap
program searches for an appropriate<xccdf:fix>
element, resolves it, prepares the environment, and executes the fix script. -
Any output of the fix script is captured by
oscap
and stored within the<xccdf:rule-result>
element. The return value of the fix script is stored as well. -
Whenever
oscap
executes a fix script, it immediately evaluates the OVAL definition again (to verify that the fix script has been applied correctly). During this second run, if the OVAL evaluation returns success, the result of the rule is fixed, otherwise it is an error. -
Detailed results of the remediation are stored in an output XCCDF file. It contains two
<xccdf:TestResult>
elements. The first<xccdf:TestResult>
element represents the scan prior to the remediation. The second<xccdf:TestResult>
is derived from the first one and contains remediation results.
There are three modes of operation of oscap
with regard to remediation:
online, offline, and review.
The remediation scripts can be executed at the time of scanning. Evaluation and remediation are performed as a part of a single command.
To enable remediation during scanning, use the oscap xccdf eval
command with
the --remediate
command-line option.
In this example we will execute remediation during evaluation of the OSPP profile:
# oscap xccdf eval --remediate --profile xccdf_org.ssgproject.content_profile_ospp --results-arf results.xml /usr/share/xml/scap/ssg/content/ssg-rhel8-ds.xml
The output of this command consists of two sections. The first section shows the result of the scan prior to the remediation, and the second section shows the result of the scan after applying the remediation. The second part can contain only fixed and error results. The fixed result indicates that the scan performed after the remediation passed. The error result indicates that even after applying the remediation, the evaluation still does not pass.
This feature allows you to postpone fix execution.
In first step, the system is only evaluated, and the results are stored in the
<xccdf:TestResult>
element in an XCCDF results file.
In the second step, oscap
executes the fix scripts and verifies the result. It
is safe to store the results into the input file, no data will be lost. During
offline remediation, a new <xccdf:TestResult>
element is created that is based
on the input one and inherits all the data. The newly created
<xccdf:TestResult>
differs only in the <xccdf:rule-result>
elements that
have failed. For those, remediation is executed.
For example:
# oscap xccdf eval --profile xccdf_org.ssgproject.content_profile_ospp --results results.xml /usr/share/xml/scap/ssg/content/ssg-rhel8-ds.xml
# oscap xccdf remediate --results remediation-results.xml results.xml
The review mode allows users to store remediation instructions to a file for further review. The remediation content is not executed during this operation. To generate remediation instructions in the form of a shell script, run:
-
Run a scan and generate XCCDF results file using the
--results
option.# oscap xccdf eval --profile xccdf_org.ssgproject.content_profile_ospp --results results.xml /usr/share/xml/scap/ssg/content/ssg-rhel8-ds.xml
-
Obtain the results ID.
$ oscap info results.xml
-
Generate the fix based on the scan results.
# oscap xccdf generate fix --fix-type bash --output my-remediation-script.sh --result-id xccdf_org.open-scap_testresult_xccdf_org.ssgproject.content_profile_ospp results.xml
This section describes tailoring of content using a tailoring file. Tailoring allows you to change behavior of SCAP content without its direct modification.
Tailoring files can be easily created using SCAP Workbench which is a GUI application.
On the command line, tailoring files can be created using the autotailor
tool.
This tool is a part of the openscap-utils
package.
The basic syntax is:
$ autotailor \ --select RULE_ID --unselect RULE_ID --var-value VAR=VALUE \ --output TAILORING_FILE --new_profile_id NEW_PROFILE_ID DS_FILENAME BASE_PROFILE_ID
Where:
-
--select RULE_ID
adds a rule withRULE_ID
. This argument can be added multiple times if needed. -
--unselect RULE_ID
adds a rule withRULE_ID
. This argument can be added multiple times if needed. -
--var-value VAR=VALUE
specifies modification of the XCCDF value in the form<varname>=<value>
-
TAILORING_FILE
is a path to the file that will be created -
NEW_PROFILE_ID
is the ID of the customized profile -
DS_FILENAME
is the path to SCAP source data stream that is tailored -
BASE_PROFILE_ID
is the original profile that we want to customize
The script creates a new file with a new profile with ID in a form BASE_PROFILE_ID_customized
.
In the following example, we will create a customized profile with ID custom
based on the OSPP profile from the SCAP Security Guide for Red Hat Enterprise Linux 8 (located in /usr/share/xml/scap/ssg/content/ssg-rhel8-ds.xml
which is provided by the scap-security-guide
RPM package) which will remove the rule service_usbguard_enabled
and save it as a XCCDF Tailoring file into /tmp/tailoring.xml
.
$ autotailor --unselect service_usbguard_enabled --output /tmp/tailoring.xml \ --new-profile-id custom /usr/share/xml/scap/ssg/content/ssg-rhel8-ds.xml ospp
For more details about other options of the autotailor
program please read the autotailor(8)
man page or run autotailor --help
.
-
List profiles in the tailoring file
$ oscap info ssg-rhel8-ds-tailoring.xml Document type: XCCDF Tailoring Imported: 2016-08-31T11:08:16 Benchmark Hint: /usr/share/xml/scap/ssg/content/ssg-rhel8-ds.xml Profiles: xccdf_org.ssgproject.content_profile_C2S_customized
-
Run a scan. The command evaluates tailored data stream by
ssg-rhel8-ds-tailoring.xml
tailoring file. XCCDF results can be found inresults.xml
file.$ oscap xccdf eval \ --profile xccdf_org.ssgproject.content_profile_C2S_customized \ --tailoring-file ssg-rhel8-ds-tailoring.xml \ --results results.xml /usr/share/xml/scap/ssg/content/ssg-rhel8-ds.xml
Warning
|
Use the ID of the customized profile (from the tailoring file), do not use the ID of the original profile. |
Instead of external tailoring file, you can also use tailoring component integrated to data stream.
$ oscap info simple-ds.xml Document type: Source Data Stream Imported: 2016-02-02T14:06:14 Stream: scap_org.open-scap_datastream_from_xccdf_simple-xccdf.xml Generated: (null) Version: 1.2 Checklists: Ref-Id: scap_org.open-scap_cref_simple-xccdf.xml Status: incomplete Resolved: false Profiles: xccdf_org.open-scap_profile_override Referenced check files: simple-oval.xml system: http://oval.mitre.org/XMLSchema/oval-definitions-5 Ref-Id: scap_org.open-scap_cref_simple-tailoring.xml Benchmark Hint: (null) Profiles: xccdf_org.open-scap_profile_default xccdf_org.open-scap_profile_unselecting xccdf_org.open-scap_profile_override Checks: Ref-Id: scap_org.open-scap_cref_simple-oval.xml No dictionaries.
To choose tailoring component scap_org.open-scap_cref_simple-tailoring.xml
,
the command below can be used.
$ oscap xccdf eval \ --tailoring-id scap_org.open-scap_cref_simple-tailoring.xml \ --profile xccdf_org.open-scap_profile_default \ --results results.xml simple-ds.xml
The command above evaluates content using tailoring component
scap_org.open-scap_cref_simple-tailoring.xml
from source data stream. Scan
results are stored in results.xml
file.
The Script Check Engine (SCE) is an alternative check engine for XCCDF checklist evaluation. SCE allows you to call shell scripts out of the XCCDF document. This approach might be suitable for various use cases, mostly when OVAL checks are not required. More information about SCE usage is available on this page: Using SCE.
Warning
|
SCE is not part of any SCAP specification. |
The oscap
tool can be used to validate the security content
against standard SCAP XML schemas. The validation results are printed to the
standard error stream (stderr). The general syntax of the validation command
is the following:
$ oscap module validate [module_options_and_arguments] FILE
where FILE
is the full path to the file being validated. As a module
you
can use:
-
xccdf,
-
oval,
-
cpe or
-
cve.
The only exception is the data stream module (ds), which uses the sds-validate operation instead of validate. So for example, it would be like:
$ oscap ds sds-validate scap-ds.xml
Note
|
Note that all SCAP components within the given data stream are validated automatically and none of the components is specified separately. |
There is an extra Schematron-based validation enabled when you validate OVAL or XCCDF specification. This validation method is slower but it provides deeper analysis.
Run one of the following commands to validate an OVAL or XCCDF document without Schematron checks:
$ oscap xccdf validate --skip-schematron xccdf-file.xml
$ oscap oval validate --skip-schematron oval-file.xml
The results of validation are printed to standard error stream (stderr).
Note
|
Please note that for the rest of oscap functionality, unless you specify
--skip-validation (--skip-valid), validation will automatically occur before
files are used. Therefore, you do not need to explicitly validate a data stream
before use. Though it will not include the Schematron-based validation step.
|
When evaluating a digitally signed SCAP source data stream OpenSCAP validates the digital signature of the data stream. The signature validation is performed automatically while loading the file. Data streams with invalid signatures would be rejected and would not be evaluated. OpenSCAP uses XML Security Library with OpenSSL backend to validate the digital signature.
The signature validation only checks that the datastream hasn’t been altered
since its latest signature. OpenSCAP doesn’t address trustworthiness of
certificates or public keys that are part of the KeyInfo
signature element and
that are used to verify the signature. You should verify those keys yourself to
prevent evaluation of datastreams that have been modified and signed by bad
actors.
The signature validation can be skipped by adding the
--skip-signature-validation
option to the oscap xccdf eval
command.
Also, signature validation can be enforced (effectively rendering all unsigned
data streams invalid) with the --enforce-signature
option to the oscap xccdf eval
command.
Another useful features of oscap
is the ability to generate documents in a
human-readable HTML format. This feature is used to generate security guides and
checklists, which serve as a source of information, as well as guidance for
secure system configuration. The results of system scans can also be transformed
to well-readable result reports. Moreover, remediation scripts and Ansible
playbooks can be generated if the SCAP content contains these data.
The general command syntax is the following:
oscap module generate sub-module [specific_module/sub-module_options_and_arguments] file
Where module is either xccdf
or oval
, sub-module
is a type of
the generated document, and file represents an XCCDF or OVAL file. A sub-module
can be either report
, guide
, custom
or fix
. Please see
man oscap
for more details.
To generate a HTML guide from an SCAP source data stream or an XCCDF file use the oscap xccdf generate guide
command.
Generating a guide with profile checklist (see an example):
$ oscap xccdf generate guide --profile xccdf_org.ssgproject.content_profile_ospp /usr/share/xml/scap/ssg/content/ssg-rhel8-ds.xml > guide.html
To generate HTML scan reports after scan from the scan results in ARF or XCCDF
format the oscap xccdf generate report
command can be used.
Generating the HTML report with information about checks (see an example):
$ oscap xccdf generate report arf.xml > report.html
Tip
|
The HTML report can be generated also during scan by adding the --report
option to the oscap xccdf eval command.
|
To generate a bash remediation script from an XCCDF profile, use the oscap
xccdf generate fix
command. OpenSCAP will extract remediation scripts for all
rules in the given profile to a file.
For example, to generate a bash remediation script for RHEL 8 OSPP profile, run:
$ oscap xccdf generate fix --profile ospp /usr/share/xml/scap/ssg/content/ssg-rhel8-ds.xml > fix.sh
The output contains fixes for all rules in the given profile including those rules that would pass. It’s because system isn’t scanned during this command. If you want to generate remediation only for the failed rules based on scan results, refer to Reviewing remediations.
Similar to generating bash scripts, OpenSCAP is able to extract Ansible tasks
associated with XCCDF rules and generate an Ansible Playbook that can be used to
configure the operating system according to the given profile. To generate
Anisble Playbook use the oscap xccdf generate fix
command with --fix-type
ansible
option.
For example, to generate Ansible Playbook from RHEL 8 OSPP profile, run:
$ oscap xccdf generate fix --profile ospp --fix-type ansible /usr/share/xml/scap/ssg/content/ssg-rhel8-ds.xml > playbook.yml
The generated Ansible Playbook is generated from an OpenSCAP profile without preliminary evaluation. It attempts to fix every selected rule, even if the system is already compliant. The output contains fixes for all rules in the given profile including those rules that would pass. It’s because system isn’t scanned during this command. If you want to generate remediation only for the failed rules based on scan results, refer to Reviewing remediations.
OpenSCAP can also create a remediation in form of Image Builder (OSBuild) Blueprint. This remeditaion is intendeded to be used as a bootstrap for image creation and usually it will contain only essential elements of the configuration, elements that would be hard or impossible to change after the image is created, like partitioning or set of installed packages.
It is recommended to combine this type of remediation with other types, executed on the running system.
For example, to generate a blueprint remediation for RHEL 8 OSPP profile, run:
$ oscap xccdf generate fix --profile ospp --fix-type blueprint /usr/share/xml/scap/ssg/content/ssg-rhel8-ds.xml > blueprint.toml
Most XCCDF content uses the OVAL check engine. This is when OVAL
Definitions are being evaluated in order to assess a system. Complete
information of an evaluation is recorded in OVAL Results files, as
defined by the OVAL specification. By examining these files it’s
possible check what definitions were used for the evaluation and why the
results are as they are. Please note these files are not generated
unless --oval-results
is used.
Some content may use alternative check engines, for example the SCE check engine.
Results of rules with a check that requires a check engine not supported by OpenSCAP will be reported as notchecked. Check contents are not read or interpreted in any way unless the check system is known and supported. Following is an evaluation output of an XCCDF with unknown check system:
$ oscap xccdf eval sds-datastream.xml Title Check group file contents Rule xccdf_org.example_rule_system_authcontent-group Result notchecked Title Check password file contents Rule xccdf_org.example_rule_system_authcontent-passwd Result notchecked Title Check shadow file contents Rule xccdf_org.example_rule_system_authcontent-shadow Result notchecked ...
Note
|
The notchecked result is also reported for rules that have no check implemented. notchecked means that there was no check in that particular rule that could be evaluated. |
Each XCCDF Rule can have <xccdf:ident>
elements inside. These elements
allow the content creator to reference various external identifiers like
CVE, CCE, CPE and others.
When scanning, oscap
outputs identifiers of scanned rules regardless of
their results. For example:
Title Ensure Repodata Signature Checking is Not Disabled For Any Repos Rule rule-2.1.2.3.6.a Result pass Title Verify user who owns 'shadow' file Rule rule-2.2.3.1.a Ident CCE-3918-0 Result pass Title Verify group who owns 'shadow' file Rule rule-2.2.3.1.b Ident CCE-3988-3 Result pass
All identifiers (if any) are printed to stdout for each rule. Since standard output doesn’t allow for compact identifier metadata to be displayed, only the identifiers themselves are displayed there.
Identifiers are also part of the HTML report output. If the identifier is a CVE you can click it to display its metadata from the official NVD database (requires internet connection). OpenSCAP doesn’t provide metadata for other types of identifiers.
Another place where these identifiers can be found are machine-readable SCAP
result data stream (ARF) files. This file can be generated during the scan by
adding --results-arf
option.
$ oscap xccdf eval \ --profile xccdf_org.ssgproject.content_profile_common \ --fetch-remote-resources --results-arf results.xml \ /usr/share/xml/scap/ssg/content/ssg-rhel6-ds.xml
Result data stream file results.xml
contains these identifiers in <xccdf:rule-result>
elements.
<rule-result idref="xccdf_org.ssgproject.content_rule_partition_for_tmp" time="2017-01-20T14:30:18" severity="low" weight="1.000000"> <result>pass</result> <ident system="https://nvd.nist.gov/cce/index.cfm">CCE-27173-4</ident> <check system="http://oval.mitre.org/XMLSchema/oval-definitions-5"> <check-content-ref name="oval:ssg-partition_for_tmp:def:1" href="#oval0"/> </check> </rule-result>
Since OpenSCAP 1.2.9 you can use the Group-By feature of HTML report to get an overview of results based on their identifiers and references.
The HTML report can also be used to look-up Rules by their identifiers. You can type the identifier (e.g.: CCE-27173-4) in the search box in the HTML report and only rules with this identifier will be shown. This can be used for any type of XCCDF identifier or reference. You can also click on the rule title to show more details and see all its identifiers, including the identifier you looked for. This relies heavily on SCAP content quality, if the identifiers are not present in the source content they will not be available in the HTML report.
If you want to map two identifiers — e.g.: map CCE identifier to NIST 800-53 identifier — you need to look-up the CCE ID in the HTML report through the search box using the first identifier. And then, by grouping by NIST SP 800-53 ID, you can see all NIST 800-53 IDs related to the searched CCE ID.
OpenSCAP does not provide any static or product bundled CCE data. Thus it has no way of displaying the last generated, updated and officially published dates of static or product bundled CCE data because the dates are not defined.
XCCDF rules in the content may target only specific platforms and hold
no meaning on other platforms. Such an XCCDF rule contains an
<xccdf:platform>`
element in its body. This element references a CPE
name or CPE2 platform (defined using <cpe2:platform-specification>
)
that could be defined in a CPE dictionary file or a CPE language file
or it can also be embedded directly in the XCCDF document.
An XCCDF rule can contain multiple <xccdf:platform>
elements. It is
deemed applicable if at least one of the listed platforms is applicable.
If an XCCDF rule contains no <xccdf:platform>
elements it is considered
always applicable.
If the CPE name or CPE2 platform is defined in an external file, use the
--cpe
option and oscap
auto-detects format of the file. The following
command is an example of the XCCDF content evaluation using CPE name
from an external file:
$ oscap xccdf eval --results xccdf-results.xml --cpe external-cpe-file.xml xccdf-file.xml
Where xccdf-file.xml
is the XCCDF document, xccdf-results.xml
is a file
containing the scan results, and external-cpe-file.xml
is the CPE
dictionary or a language file.
If you are evaluating a source data stream, oscap
automatically
registers all CPEs contained within the data stream. No extra steps have
to be taken. You can also register an additional external CPE file, as
shown by the command below:
$ oscap xccdf eval --datastream-id ds.xml --xccdf-id xccdf.xml --results xccdf-results.xml --cpe additional-external-cpe.xml scap-ds.xml
Where scap-ds.xml
is a file representing the SCAP data stream
collection, ds.xml
is the particular data stream, xccdf.xml
is the
XCCDF document, xccdf-results.xml
is a file containing the scan
results, and additional-external-cpe.xml
is the additional CPE
dictionary or language file.
The oscap
tool will use an OVAL file attached to the CPE dictionary to
determine applicability of any CPE name in the dictionary.
Apart from the instructions above, no extra steps have to be taken for
content using <cpe:fact-ref>
or <cpe2:fact-ref>
. See the following
sections for details on resolving.
When a CPE name or language model platform is referenced via
<xccdf:platform>
elements, resolution happens in the following order:
-
Look into embedded CPE2 language model if name is found and applicable deem it applicable
-
If not found or not applicable, look into external CPE2 language models (order of registration)
-
If not found or not applicable, look into embedded CPE dictionary
-
If not found or not applicable, look into external CPE dictionaries (order of registration)
If the CPE name is not found in any of the sources, it is deemed not applicable. If it is found in any of the sources but not applicable, we look for it elsewhere.
CPE name referenced from within fact-ref
is resolved in the following
order:
-
Look into embedded CPE dictionary, if name is found and applicable deem it applicable
-
If not found or not applicable, look into external CPE dictionaries (order of registration)
Apart from the external CPE Dictionaries, oscap
comes with an inbuilt
CPE Dictionary. The built-in CPE Dictionary contains only a few products
(sub-set of Official CPE Dictionary) and it
is used as a fall-back option when there is no other CPE source found.
The list of inbuilt CPE names can be found in the output of
$ oscap --version
The built-in CPE dictionary will be deprecated in OpenSCAP 1.4.0.
This section describes advanced concepts of OVAL Variables and their
implementation in oscap
. The SCAP specification allows for an OVAL
variable to have multiple values during a single assessment run. There
are two variable modes which can be combined:
-
Multival — A variable is assigned with multiple values at the same time. As an example, consider a variable which refers to preferred permission of a given file, that may take multiple values like: '600', '400'. The evaluation tries to match each (or all) and then outputs a single OVAL Definition result.
-
Multiset — A variable is assigned with a different value (or multival) for different evaluations. This is known as a variable_instance. As an example consider an OVAL definition which checks that a package given by a variable is not installed. For the first evaluation of the definition, the variable can be assigned with 'telnet-server' value, for second time the variable can be assigned with 'tftp-server' value. Therefore both evaluations may output different results. Thus, the OVAL Results file may contain multiple results for the same definition, these are distinguished by variable_instance attribute.
These two concepts are a source of confusion for both the content authors and the result consumers. On one hand, the first concept is well supported by the standard and the OVAL Variable file format. It allows multiple <value> elements for each <variable> element. On the other hand, the second concept is not supported by an OVAL Variable schema which prevents fully automated evaluation of the multisets (unless you use XCCDF to bridge that gap).
Tip
|
oscap supports both variable modes as described below.
|
First we need to understand how a single value can be bound to a variable in the OVAL checking engine. There are three ways to do this:
1) OVAL Variables File — The values of external variables can be
defined in an external file. Such a file is called an OVAL Variable File
and can be recognized by using the following command: oscap info
file.xml
. The OVAL Variables file can be passed to the evaluation by
--variables
argument such as:
$ oscap oval eval \ --variables usgcb-rhel5desktop-oval.xml-0.variables-0.xml \ --results usgcb-results-oval.xml \ usgcb-rhel5desktop-oval.xml
2) XCCDF Bindings — The values of external variables can be given from
an XCCDF file. In the XCCDF file within each <xccdf:check>
element,
there might be <xccdf:check-export>
elements. These elements allow
transition of <xccdf:value>
elements to <oval:variables>
elements. The
following command allows users to export variable bindings from XCCDF to
an OVAL Variables file:
$ oscap xccdf export-oval-variables --profile united_states_government_configuration_baseline usgcb-rhel5desktop-xccdf.xml
3) Values within an OVAL Definition File — Variables' values defined
directly in the OVAL definitions file <constant_variable>
and
<local_variable>
elements.
With oscap
, there are two possible ways how two or more values can be
specified for a variable used by one OVAL definition. The approach you choose
depends on what mode you want to use, multival or multiset.
The oscap
handles multiple OVAL values seamlessly. Users don’t need to do
anything differently than for a normal scan.
The command below demonstrates evaluation of an SCAP source data stream, which
may include multiset, multival, or both concepts combined, or none of them.
$ oscap xccdf eval --profile my_baseline --results-arf scap-arf.xml --cpe additional-external-cpe.xml scap-ds.xml
Multival can pass multiple values to a single OVAL definition evaluation. This can be accomplished by all three ways as described in previous section.
1) OVAL Variables file — This option is straight forward. The file
format (XSD schema) allows for multiple <value>
elements within each
<variable>
element.
<variable id="oval:com.example.www:var:1" datatype="string" comment="Unknown"> <value>600</value> <value>400</value> </variable>
2) XCCDF Bindings — Use multiple <xccdf:check-export>
referring to the
very same OVAL variable binding with multiple different XCCDF values.
<check system="http://oval.mitre.org/XMLSchema/oval-definitions-5"> <check-export value-id="xccdf_com.example.www_value_1" export-name="oval:com.example.www:var:1"/> <check-export value-id="xccdf_com.example.www_value_2" export-name="oval:com.example.www:var:1"/> <check-content-ref href="my-test-oval.xml" name="oval:com.example.www:def:1"/> </check>
3) Values within OVAL Definitions file — This is similar to using a
Variables file, there are multiple <value>
elements allowed within
<constant_variable>
or <local_variable>
elements.
Multiset allows for the very same OVAL definition to be evaluated multiple times using different values assigned to the variables for each evaluation. In OpenSCAP, this is only possible by option (2) XCCDF Bindings. The following XCCDF snippet evaluates twice the very same OVAL Definition, each time it binds a different value to the OVAL variable.
<Rule id="xccdf_moc.elpmaxe.www_rule_1" selected="true"> <check system="http://oval.mitre.org/XMLSchema/oval-definitions-5"> <check-export value-id="xccdf_moc.elpmaxe.www_value_1" export-name="oval:com.example.www:var:1"/> <check-content-ref href="my-test-oval.xml" name="oval:com.example.www:def:1"/> </check> </Rule> <Rule id="xccdf_moc.elpmaxe.www_rule_2" selected="true"> <check system="http://oval.mitre.org/XMLSchema/oval-definitions-5"> <check-export value-id="xccdf_moc.elpmaxe.www_value_2" export-name="oval:com.example.www:var:1"/> <check-content-ref href="my-test-oval.xml" name="oval:com.example.www:def:1"/> </check> </Rule>
After the evaluation, the OVAL results file will contain multiple result-definitions and multiple result-tests and multiple collected-objects. The elements of the same id will be differentiated by the value of the variable_instance attribute. Each of the definitions/tests/object might have a different result of evaluation. The following snippet of OVAL results file illustrates output of a multiset evaluation.
<tests> <test test_id="oval:com.example.www:tst:1" version="1" check="at least one" result="true" variable_instance="1"> <tested_item item_id="1117551" result="true"/> <tested_variable variable_id="oval:com.example.www:var:1">600</tested_variable> </test> <test test_id="oval:com.example.www:tst:1" version="1" check="at least one" result="false" variable_instance="2"> <tested_item item_id="1117551" result="false"/> <tested_variable variable_id="oval:com.example.www:var:1">400</tested_variable> </test> </tests>
Normally, each XCCDF rule references to a single check with a specified name.
However, if @name
attribute of xccdf:check-content-ref
of a given rule is omitted,
multiple checks can be executed to evaluate the rule.
This is common for security_patches_up_to_date
check.
By default, only a single result is produced for an XCCDF rule in such case, and the
result is computed from all results of checks in the referenced location.
In case user wants to see separate results for each check (one xccdf:check-result
element
in results document for each check evaluated), then multi-check
attribute
of xccdf:check
element must be set to true.
<Rule id="xccdf_org.nist-testsuite.content_rule_security_patches_up_to_date" selected="false" weight="10.0"> <title xml:lang="en-US">Security Patches Up-To-Date</title> <description xml:lang="en-US">All known security patches have been installed.</description> <requires idref="xccdf_org.nist-testsuite.content_group_CM-6"/> <requires idref="xccdf_org.nist-testsuite.content_group_SI-2"/> <check system="http://oval.mitre.org/XMLSchema/oval-definitions-5" multi-check="true"> <check-content-ref href="r1100-scap11-win_rhel-patches.xml"/> </check> </Rule>
In XCCDF specification older than 1.2, the multi-check
element is not defined,
which means that only a single result is always produced.
To produce separate results for each check from the content older than XCCDF version 1.2,
you need to convert it first into XCCDF 1.2 using the following command:
$ xsltproc --stringparam reverse_DNS com.example.www /usr/share/openscap/xsl/xccdf_1.1_to_1.2.xsl xccdf.xml > xccdf-1.2.xml
And then patch the content using a text editor, adding multi-check
as
shown in the example Rule snippet above.
To create a source data stream from the patched content, the following command can be used:
$ oscap ds sds-compose xccdf-1.2.xml source_ds.xml
If the original XCCDF file referenced a custom CPE dictionary, you also have to inject the CPE dictionary into the source data stream in order to create a valid source data stream. To add a CPE dictionary component into your data stream in place, use this command:
$ oscap ds sds-add cpe_dictionary.xml source_ds.xml
Now the source_ds.xml
data stream can be evaluated as usual.
OpenSCAP identifies SWID tags using OVAL inventory class definitions that are part of an SCAP source data stream or a standalone OVAL Definition file.
It supports the following 3 methods of SWID tags detection:
-
One or more
cpe2-dict:check
elements that reference an OVAL inventory class definition that searches for the presence of a matching SWID tag. -
A
cpe:check-fact-ref
element that references an OVAL inventory class definition that searches for the presence of a matching SWID tag. -
An OVAL definition that references another OVAL inventory class definition using the
oval-def:extend_definition
element where the extended definition searches for the presence of a matching SWID tag.
The oscap
command handles the SWID tag detection transparently. The detection
algorithm is using OVAL’s xmlfilecontent
test. The OVAL inventory class definitions can be
evaluated in a standard way, i.e. by using the oscap oval eval
for a
standalone OVAL Definition file or oscap xccdf eval
for definitions that are
part of an SCAP source data stream.
For example, the following command can be used to evaluate an SCAP source data stream that contains OVAL inventory class definitions that search for the presence of a matching SWID tag (referenced XML files can be obtained from the SCAP 1.3 validation test suite).
$ oscap xccdf eval --results-arf arf.xml --profile xccdf_gov.nist.validation_profile_r2850-rhel r2850-rhel-datastream.xml
As another example, the following command can be used to evaluate a standalone OVAL Definition file that contains OVAL inventory class definitions that search for the presence of a matching SWID tag:
$ oscap oval eval --results results.xml r2860-rhel-oval.xml
10.8.1. Excluding non-local filesystems using the recurse_file_system="local" attribute of a FileBehaviors entity
The scanner loosely follows the OVAL’s idea behind this attribute to behave like
the coreutils utility df (df -l
). This is the list of filesystems, that are
not considered local by the scanner:
-
proc, sysfs
-
afs
-
ceph
-
cifs
-
smb3, smbfs
-
sshfs
-
ncpfs, ncp
-
nfs, nfs4
-
gfs, gfs2
-
glusterfs
-
gpfs
-
pvfs2
-
ocfs2
-
lustre
-
davfs
-
OSCAP_CHECK_ENGINE_PLUGIN_DIR
- Defines path to a directory that contains plug-in libraries implementing additonal check engines, eg. SCE. -
OSCAP_CONTAINER_VARS
- Additional environment variables read by environmentvariable58_probe. The variables are separated by\n
. It is used byoscap-podman
andoscap-docker
scripts during container scanning. -
OSCAP_EVALUATION_TARGET
- Change value of target factsurn:xccdf:fact:identifier
andurn:xccdf:fact:asset:identifier:ein
in XCCDF results. Used during offline scanning to pass the name of the target system. -
OSCAP_FULL_VALIDATION
- If set, XML schema validation will be performed in every step of SCAP content processing. -
OSCAP_OVAL_COMMAND_OPTIONS
- Additional command line options foroscap oval
module. The value of this environment variable is appended to the actual command line options ofoscap
command. -
OSCAP_PCRE_EXEC_RECURSION_LIMIT
- Set recursion limit of regular expression matching usingpcre_exec
function. -
OSCAP_PROBE_ROOT
- Path to a directory which contains mounted filesystem to be evaluated. Used for offline scanning. -
SEXP_VALIDATE_DISABLE
- If set,oscap
will not validate SEXP expressions during its execution. -
SOURCE_DATE_EPOCH
- Timestamp in seconds since epoch. This timestamp will be used instead of the current time to populatetimestamp
attributes in SCAP source data streams created byoscap ds sds-compose
sub-module. This is used for reproducible builds of data streams. -
OSCAP_PROBE_MEMORY_USAGE_RATIO
- maximum memory usage ratio (used/total) for OpenSCAP probes, default: 0.1
Also, OpenSCAP uses libcurl
library which also can be configured using environment variables. See the list of libcurl environment variables.
Some SCAP content references external resources. For example SCAP Security Guide uses external OVAL file to check that the system is up to date and has no known security vulnerabilities. However, other content can use external resources for other purposes.
When you are evaluating SCAP content with external resources the oscap
tool
will warn you:
$ oscap xccdf eval \ --profile xccdf_org.ssgproject.content_profile_common \ /usr/share/xml/scap/ssg/content/ssg-rhel7-ds.xml WARNING: This content points out to the remote resources. Use `--fetch-remote-resources' option to download them. WARNING: Skipping https://www.redhat.com/security/data/oval/com.redhat.rhsa-RHEL7.xml.bz2 file which is referenced from XCCDF content
By default the oscap
tool will not blindly download and execute remote content.
If you trust your local content and the remote content it references, you can use
the --fetch-remote-resources
option to automatically download it using the
oscap
tool.
$ oscap xccdf eval \ --fetch-remote-resources \ --profile xccdf_org.ssgproject.content_profile_common \ /usr/share/xml/scap/ssg/content/ssg-rhel7-ds.xml Downloading: https://www.redhat.com/security/data/oval/com.redhat.rhsa-RHEL7.xml.bz2 ... ok Title Ensure /var/log Located On Separate Partition Rule xccdf_org.ssgproject.content_rule_partition_for_var_log ...
On systems that don’t have a direct internet access or if the user doesn’t want OpenSCAP to connect to the network it’s possible to download the remote content using other tools, save it to a directory and then pass it to OpenSCAP as a file.
To do that, use --local-files
instead of --fetch-remote-resources
as argument of the oscap
command.
In place of the remote data stream component OpenSCAP will attempt to use a file whose file name is equal to name
attribute of the uri
element within the catalog
element within the component-ref
element representing a checklist in the data stream if such file exists.
In the following example, the ssg-rhel8-ds.xml
is an SCAP source datastream.
It needs some checks from a remote component. The remote component’s component-ref
ID is scap_org.open-scap_cref_security-data-oval-com.redhat.rhsa-RHEL8.xml
and the component-ref
is pointing to https://www.redhat.com/security/data/oval/com.redhat.rhsa-RHEL8.xml
.
The checks from the remote component are used in the only checklist in the data stream.
The component-ref
of the checklist component contains a catalog
where one of the uri
elements maps the remote component’s component-ref
ID in the uri
attribute to the actual name security-data-oval-com.redhat.rhsa-RHEL8.xml
which is the value of the name
attribute.
Therefore, we can download the remote data from https://www.redhat.com/security/data/oval/com.redhat.rhsa-RHEL8.xml
and save it as security-data-oval-com.redhat.rhsa-RHEL8.xml
to some directory.
Then, we execute oscap
with --local-files
and provide a path to the directory where it’s located.
It will pick the file and use it instead of the remote data and it won’t connect to the network.
$ mkdir ~/scap-files $ wget -O ~/scap-files/security-data-oval-com.redhat.rhsa-RHEL8.xml https://www.redhat.com/security/data/oval/com.redhat.rhsa-RHEL8.xml ... $ oscap xccdf eval --local-files ~/scap-files --profile ospp ssg-rhel8-ds.xml
This section demonstrates practical usage of certain security content provided for Red Hat products.
These practical examples show usage of industry standard checklists that were validated by NIST.
The SSG project contains guidance for settings of Red Hat Enterprise Linux 7.
1) Install the SSG
$ sudo yum install -y scap-security-guide
2) To inspect the security content use the oscap info
module:
$ oscap info /usr/share/xml/scap/ssg/rhel7/ssg-rhel7-ds.xml
The output of this command contains available configuration profiles. To audit
your system settings choose the
xccdf_org.ssgproject.content_profile_rht-ccp
profile and run the
evaluation command . For example, the The following command is used to assess
the given system against a draft SCAP profile for Red Hat Certified Cloud
Providers:
$ oscap xccdf eval \ --profile xccdf_org.ssgproject.content_profile_rht-ccp \ --results ssg-rhel7-xccdf-result.xml \ --report ssg-rhel7-report.html \ /usr/share/xml/scap/ssg/rhel7/ssg-rhel7-ds.xml
The Red Hat Security Response Team provides OVAL definitions for all vulnerabilities (identified by CVE name) that affect Red Hat Enterprise Linux 3, 4, 5, 6, 7 and 8. This enable users to perform a vulnerability scan and diagnose whether system is vulnerable or not. The data is provided in three ways — OVAL file, OVAL + XCCDF and an SCAP source data stream.
1) Download the content
$ wget https://www.redhat.com/security/data/metrics/com.redhat.rhsa-all.xccdf.xml $ wget https://www.redhat.com/security/data/oval/com.redhat.rhsa-all.xml
2) Run the scan
$ oscap xccdf eval --results results.xml --report report.html com.redhat.rhsa-all.xccdf.xml
This is the sample output. It reports that Red Hat Security Advisory (RHSA-2013:0911) was issued but update was not applied so a system is affected by multiple CVEs (CVE-2013-1935, CVE-2013-1943, CVE-2013-2017)
Title RHSA-2013:0911: kernel security, bug fix, and enhancement update (Important) Rule oval-com.redhat.rhsa-def-20130911 Ident CVE-2013-1935 Ident CVE-2013-1943 Ident CVE-2013-2017 Result fail
Human readable report report.html is generated, as well as "machine" readable report results.xml. Both files hold information about vulnerability status of scanned system. They map RHSA to CVEs and report what security advisories are not applied to the scanned system. CVE identifiers are linked with National Vulnerability Databases where additional information like CVE description, CVSS score, CVSS vector, etc. are stored.
1) Download the content
$ wget https://www.redhat.com/security/data/oval/com.redhat.rhsa-all.xml
2) Run the scan
$ oscap oval eval --results results.xml --report report.html com.redhat.rhsa-all.xml
This is the sample output. It reports that Red Hat Security Advisory (RHSA-2013:0911) was issued but update was not applied. Notice that the standard output is different from the XCCDF + OVAL output.
Definition oval:com.redhat.rhsa:def:20130911: true
As in case of XCCDF+OVAL, human readable report report.html, and "machine" readable report results.xml are generated. Look of report.html is different to the one generated when XCCDF checklist is used as a basis for the scan, the information in it again holds information about vulnerability status of scanned system, and mapping of RHSA to CVEs. CVE identifiers are linked with Red Hat database where additional information like CVE description, CVSS score, CVSS vector etc. are stored.
The Source data stream use-case is very similar to OVAL+XCCDF. The only difference is that you don’t have to download two separate files.
1) Download the content
$ wget https://www.redhat.com/security/data/metrics/ds/com.redhat.rhsa-all.ds.xml
2) Run the scan
$ oscap xccdf eval --results results.xml --report report.html com.redhat.rhsa-all.ds.xml
The files we used above cover multiple Red Hat products. If you only want to scan one product - for example a specific version of Red Hat Enterprise Linux - we advise to download a smaller specialized file covering just this one version. Using a smaller file will utilitize less bandwidth and make the evaluation quicker.
For example for Red Hat Enterprise Linux 7 the plain OVAL file is located at:
$ wget https://www.redhat.com/security/data/oval/Red_Hat_Enterprise_Linux_7.xml
You can get a list of all the plain OVAL files by visiting https://www.redhat.com/security/data/oval/v2/
The list of available data stream files is available at https://www.redhat.com/security/data/metrics/ds/v2/
Note
|
Note that these OVAL definitions are designed to only cover software and updates released by Red Hat. You need to provide additional definitions in order to detect the patch status of third-party software. |
To find out more information about this project, see https://www.redhat.com/security/data/metrics/.
This section describes how to evaluate the Payment Card Industry Data Security Standard (PCI-DSS) on Red Hat Enterprise Linux 7.
1) Install SSG which provides the PCI-DSS SCAP content
$ sudo yum install -y scap-security-guide
2) Verify that the PCI-DSS profile is present
$ oscap info /usr/share/xml/scap/ssg/content/ssg-rhel7-ds.xml
3) Evaluate the PCI-DSS content
$ oscap xccdf eval \ --results results.xml \ --profile xccdf_org.ssgproject.content_profile_pci-dss \ /usr/share/xml/scap/ssg/content/ssg-rhel7-ds.xml
4) Generate report readable in a web browser.
$ oscap xccdf generate report --output report.html results.xml
This section describes how to evaluate the Defense Information Systems Agency (DISA) Security Technical Implementation Guide (STIG) on Red Hat Eneterprise Linux 7.
-
Download the DISA STIG content.
$ wget https://dl.dod.cyber.mil/wp-content/uploads/stigs/zip/U_RHEL_7_V3R2_STIG_SCAP_1-2_Benchmark.zip
-
Unpack the content.
$ unzip U_RHEL_7_V3R2_STIG_SCAP_1-2_Benchmark.zip
-
Display a list of available profiles.
$ oscap info U_RHEL_7_V3R2_STIG_SCAP_1-2_Benchmark.xml
-
Evaluate your favorite profile, for example MAC-1_Public, and write ARF results into the results.xml file.
# oscap xccdf eval \ --profile xccdf_mil.disa.stig_profile_MAC-1_Public \ --results-arf results.xml \ --report report.html \ U_RHEL_7_V3R2_STIG_SCAP_1-2_Benchmark.xml
If you are interested in DISA STIG content for other systems please refer to DoD Cyber Exchange.
Note
|
NIST offers no official USGCB for RHEL6 as of September 2014 but you can acquire the content from the SSG project. |
The USGCB content for represents Tier IV Checklist for Red Hat Enterprise Linux 5 (as defined by NIST Special Publication 800-70).
Warning
|
Proper evaluation of the USGCB document requires OpenSCAP version 0.9.1 or later. |
After ensuring that version of OpenSCAP on your system is sufficient, perform the following tasks:
1) Download the USGCB content.
$ wget http://usgcb.nist.gov/usgcb/content/scap/USGCB-rhel5desktop-1.2.5.0.zip
2) Unpack the USGCB content.
$ unzip USGCB-rhel5desktop-1.2.5.0.zip
3) Run evaluation of the USGCB content.
$ oscap xccdf eval \ --profile united_states_government_configuration_baseline \ --cpe usgcb-rhel5desktop-cpe-dictionary.xml \ --oval-results \ --fetch-remote-resources \ --results results.xml \ usgcb-rhel5desktop-xccdf.xml
4) Generate a scan report that is readable in a web browser.
$ oscap xccdf generate report --output report.html results.xml
Additional reports can be generated from detailed OVAL result files. Scanner outputs OVAL results files in the current directory, for each OVAL file on input there is one output. In case of USGCB, there is one OVAL file distributed along the XCCDF, another one which is downloaded from Red Hat Repository. The latter contains CVE information for each evaluated definition.
$ oscap oval generate report --output oval-report-1.html usgcb-rhel5desktop-oval.xml.result.xml $ oscap oval generate report --output oval-report-2.html http%3A%2F%2Fwww.redhat.com%2Fsecurity%2Fdata%2Foval%2Fcom.redhat.rhsa-all.xml.result.xml
If you’re interested in runing evaluation of the USGCB on a remote machine using a GUI please see: Evaluate Remote Machine for USGCB Compliance with SCAP Workbench tutorial.
The SCAP content repository hosted at National Vulnerability Database (NVD) can be searched for publicly available guidances for a given product. For example, as per 2013/05/11 there are two Tier III checklists for Red Hat Enterprise Linux 5. Analogously, the MITRE Corp. hosts repository of OVAL content for various platforms, sorted by versions and classes.
Likewise the USGCB, any downloaded guidance can be evaluated by OpenSCAP.
-
Examplary evaluation of DoD Consensus Security Configuration Checklist for Red Hat Enterprise Linux 5 (2.0)
$ wget http://nvd.nist.gov/ncp/DoD-RHEL5-desktop.zip $ unzip DoD-RHEL5-desktop.zip $ oscap xccdf eval \ --profile DOD_baseline_1.0.0.1 \ --cpe dcb-rhel5_cpe-dictionary.xml \ --results result.xml \ --oval-results \ dcb-rhel5_xccdf.xml
-
Examplary evaluation of Red Hat 5 STIG Benchmark (Version 1, Release 12)
$ wget http://iasecontent.disa.mil/stigs/zip/July2015/U_RedHat_5_V1R12_STIG_SCAP_1-1_Benchmark.zip $ unzip U_RedHat_5_V1R12_STIG_SCAP_1-1_Benchmark.zip $ oscap xccdf eval \ --profile MAC-2_Public \ --cpe U_RedHat_5_V1R12_STIG_SCAP_1-1_Benchmark-cpe-dictionary.xml \ --results result.xml \ --oval-results \ U_RedHat_5_V1R12_STIG_SCAP_1-1_Benchmark-xccdf.xml
Furthermore, any individual file from the archive can be inspected using
the oscap info
command line option. The oscap program does not have
the concept of importing SCAP files, therefore it can process any SCAP
files available on the filesystem. That is possible because the SCAP
standard files are native file formats of the OpenSCAP.
This section describes how to check that software patches are up-to-date using external OVAL content.
1) Install the SSG
$ sudo yum install -y scap-security-guide
2a) Evaluate common profile for RHEL 6
$ oscap xccdf eval \ --profile xccdf_org.ssgproject.content_profile_common \ --fetch-remote-resources \ --results-arf results.xml \ /usr/share/xml/scap/ssg/content/ssg-rhel6-ds.xml
2b) Evaluate common profile for RHEL 7
$ oscap xccdf eval \ --profile xccdf_org.ssgproject.content_profile_common \ --fetch-remote-resources \ --results-arf results.xml \ /usr/share/xml/scap/ssg/content/ssg-rhel7-ds.xml
This command evaluates common profile for Red Hat Enterprise Linux 6 or 7. Part of
the profile is a rule to check that patches are up-to-date. To evaluate the rule
correctly, oscap tool needs to download an up-to-date OVAL file from Red Hat servers. This can be
allowed using --fetch-remote-resources
option. Result of this scan will be saved
in results.xml
using ARF format.
Apart from the oscap
command, OpenSCAP provides also other utilities for
special purposes. Those utilities use oscap
under the hood, but they
enable users to perform advanced tasks in a single command.
This manual gives a quick overview of and shows basic usage of these tools.
Each of the tools have its own manual page that gives more detailed information.
To install these tools install the openscap-utils
package.
# dnf install openscap-utils
The oscap-ssh
command is a simple tool for scanning remote machines with
OpenSCAP over network and collecting results.
The tool uses SSH connection to copy the SCAP content to a remote machine, then it runs an evaluation of the target system and downloads the results back. The remote machine needs to have OpenSCAP installed.
The tool can evaluate source data streams and OVAL files.
Usage of the tool mimics usage and options of oscap
tool.
In the following example, we will scan a remote Fedora server located on IP address 192.168.1.13 that listens for SSH connections on port 22. The server will be scanned for compliance with the Common Profile for General-Purpose Fedora Systems provided by SCAP Security Guide. HTML report is written out as report.html on the local machine.
$ oscap-ssh [email protected] 22 xccdf eval \ --profile xccdf_org.ssgproject.content_profile_common \ --report report.html \ /usr/share/xml/scap/ssg/content/ssg-fedora-ds.xml
The oscap-podman
tool can be used to scan Linux containers and container images.
Usage of the tool mimics usage and options of oscap
tool.
Note
|
oscap-podman is available only on Fedora and Red Hat Enterprise Linux 8
or newer. On other systems use oscap-docker instead.
|
-
Get the ID of a container or a container image, for example:
# podman images REPOSITORY TAG IMAGE ID CREATED SIZE registry.access.redhat.com/ubi8 latest 3269c37eae33 2 months ago 208 MB
-
Evaluate the SCAP content, for example:
# oscap-podman 3269c37eae33 xccdf eval --report report.html --profile ospp /usr/share/xml/scap/ssg/content/ssg-rhel8-ds.xml
Note that the oscap-podman
command requires root privileges.
The oscap-docker
is used to scan Docker containers and images. It can
assess vulnerabilities in the container or image and check their compliance
with security policies. Usage of the tool mimics usage and options
of oscap
tool.
Note
|
oscap-docker isn’t available on Fedora and on Red Hat Enterprise Linux 8
or newer. On other systems use oscap-podman instead.
|
The oscap-docker
tool uses a technique called offline scanning.
That means that the filesystem of the container is mounted to a directory
on the host. The mounted filesystem is read-only. OpenSCAP then assess
the container from the host. Therefore no agent is installed
in the container and container is not touched or changed in any way.
In the first example, we will perform a vulnerability assessment of an Docker image of Red Hat Enterprise Linux 7 (named rhel7). The command will attach docker image, determine OS variant/version, download CVE stream applicable to the given image and finally it will evaluate the image for vulnerabilities. CVE stream is a list of vulnerabilities in SCAP format and is downloaded directly from Red Hat. HTML report is written out as report.html on the local machine.
$ oscap-docker image-cve rhel7 --report report.html
In the second example, we will check the same rhel7 image for compliance with a security policy specified in an XCCDF checklist.
$ oscap-docker image rhel7 xccdf eval --report report.html xccdf.xml
To scan running containers, commands are very similar, just replace "image-cve" with "container-cve" and "image" with "container".
OpenSCAP provides a simple tool to evaluate virtual machines called oscap-vm
.
The tool can scan given virtual machine directly from the virtualisation host.
Usage of the tool mimics usage and options of oscap
tool.
Similarly to oscap-docker
, this utility also uses offline scanning,
so it doesn’t install anything in the guest, doesn’t require OpenSCAP
installed in the guest and it doesn’t create or change anything in the
guest’s filesystem.
A very simple script oscap-chroot
can be used to perform
an offline scan of a filesystem that is mounted at arbitrary path.
It can be used for scanning of custom objects that are not supported
by oscap-docker
or oscap-vm
, like containers in other
formats than Docker.
Again, usage of the tool mimics usage and options of oscap
tool.
OpenSCAP can scan and remediate the system at boot time using systemd’s system-update.target
.
The oscap-remediate.service
is expecting the /system-update
symlink (universal trigger for all services in system-update’s requires list) which points to a file with base name oscap-remediate-offline.conf.sh
.
The file itself could be located anywhere, but it should be accessible at boot time. This configuration file is essentially a Bash script with a set of environment variables, loaded with source
by the service.
Upon the start the service will immediately remove the symlink to prevent invocation loop but it won’t touch the configuration file itself. A helper tool, oscap-remediate-offline
, can be used to bootstrap the configuration and prime the /system-update
symlink, but its flexibility is limited and in general it should only be used for debugging.
Warning
|
The oscap-remediate-offline tool should not be considered as a stable API for priming the service. The only API of the service is the configuration file and the /system-update symlink pointing to it.
|
Configuration variables:
# Mandatory ----------------------------- # The path to the data stream file OSCAP_REMEDIATE_DS=/some/data_stream.xml # The ID of the profile to use OSCAP_REMEDIATE_PROFILE_ID=some_profile # Optional ------------------------------ # Data stream, XCCDF or Benchmark IDs # Benchmark ID and DS + XCCDF IDs pair are mutually # exclusive. DS + XCCDF IDs will take precedence OSCAP_REMEDIATE_DATASTREAM_ID=some_ds_id OSCAP_REMEDIATE_XCCDF_ID=some_xccdf_id OSCAP_REMEDIATE_BENCHMARK_ID=some_bench_id # Tailoring file and tailoring component ID OSCAP_REMEDIATE_TAILORING=/some/tailoring.xml OSCAP_REMEDIATE_TAILORING_ID=tailoring_id # Where to write ARF result and HTML report # No defaults, they won't be generated if # they are not requested explicitly OSCAP_REMEDIATE_ARF_RESULT=/some/arf_res.xml OSCAP_REMEDIATE_HTML_REPORT=/some/report.html # Log file name and verbosity OSCAP_REMEDIATE_VERBOSE_LOG=/var/some_verbose.log # Optional even if OSCAP_REMEDIATE_VERBOSE_LOG is provided (default: INFO) OSCAP_REMEDIATE_VERBOSE_LEVEL=INFO
Why do I get "notchecked" results when I use e.g. STIG checklist?
The downloaded guidance contains rule descriptions, but it doesn’t contain OVAL checks which could be used for evaluation by OpenSCAP. You can find guidances with implemented OVAL checks and also with remediations at ComplianceAsCode project, which contains wide range of profiles.
I try to apply a tailoring file, but OpenSCAP still evaluates rules that I have unselected. How can I enforce my changes of the profile?
Make sure that you provide the ID of the customized profile in --profile
option instead of the ID of the original profile.
If you created the tailoring file using SCAP Workbench, you were prompted to choose the ID of the customized profile. You can display the ID of the customized profile by running oscap info <your_tailoring_file>
. By default, the ID of the customized profile ends with _customized
suffix.
My SCAP source data stream contains rule security_patches_up_to_date
which needs to download some data from the internet to work.
But I’m in an air gapped environment so it can’t download it.
Can I download it separately and pass it to oscap?
Yes, it’s possible, you can download the file on other computer that is connected to the internet and then copy the file to the system where you run oscap
.
Instead of the --fetch-remote-resources
option you will use the --local-files
option.
For more information, please refer to section Using external or remote resources.