Exactprep CISSP Questions

Monitoring of a control should occur at a rate concurrent with the volatility of the security control when implementing Information Security Continuous Monitoring (ISCM) solutions. ISCM is a process that involves maintaining the ongoing awareness of the security status, events, and activities of a system or network, by collecting, analyzing, and reporting the security data and information, using various methods and tools. ISCM can provide several benefits, such as:

• Improving the security and risk management of the system or network by identifying and addressing the security weaknesses and gaps
• Enhancing the security and decision making of the system or network by providing the evidence and information for the security analysis, evaluation, and reporting
• Increasing the security and improvement of the system or network by providing the feedback and input for the security response, remediation, and optimization
• Facilitating the compliance and alignment of the system or network with the internal or external requirements and standards

A security control is a measure or mechanism that is implemented to protect the system or network from the security threats or risks, by preventing, detecting, or correcting the security incidents or impacts. A security control can have various types, such as administrative, technical, or physical, and various attributes, such as preventive, detective, or corrective. A security control can also have different levels of volatility, which is the degree or frequency of change or variation of the security control, due to various factors, such as the security requirements, the threat landscape, or the system or network environment.

Monitoring of a control should occur at a rate concurrent with the volatility of the security control when implementing ISCM solutions, because it can ensure that the ISCM solutions can capture and reflect the current and accurate state and performance of the security control, and can identify and report any issues or risks that might affect the security control. Monitoring of a control at a rate concurrent with the volatility of the security control can also help to optimize the ISCM resources and efforts, by allocating them according to the priority and urgency of the security control.

The other options are not the correct frequencies for monitoring of a control when implementing ISCM solutions, but rather incorrect or unrealistic frequencies that might cause problems or inefficiencies for the ISCM solutions. Continuously without exception for all security controls is an incorrect frequency for monitoring of a control when implementing ISCM solutions, because it is not feasible or necessary to monitor all security controls at the same and constant rate, regardless of their volatility or importance. Continuously monitoring all security controls without exception might cause the ISCM solutions to consume excessive or wasteful resources and efforts, and might overwhelm or overload the ISCM solutions with too much or irrelevant data and information. Before and after each change of the control is an incorrect frequency for monitoring of a control when implementing ISCM solutions, because it is not sufficient or timely to monitor the security control only when there is a change of the security control, and not during the normal operation of the security control. Monitoring the security control only before and after each change might cause the ISCM solutions to miss or ignore the security status, events, and activities that occur between the changes of the security control, and might delay or hinder the ISCM solutions from detecting and responding to the security issues or incidents that affect the security control. Only during system implementation and decommissioning is an incorrect frequency for monitoring of a control when implementing ISCM solutions, because it is not appropriate or effective to monitor the security control only during the initial or final stages of the system or network lifecycle, and not during the operational or maintenance stages of the system or network lifecycle. Monitoring the security control only during system implementation and decommissioning might cause the ISCM solutions to neglect or overlook the security status, events, and activities that occur during the regular or ongoing operation of the system or network, and might prevent or limit the ISCM solutions from improving and optimizing the security control.

The configuration management and control task of the certification and accreditation process is incorporated in the system acquisition and development phase of the System Development Life Cycle (SDLC). The SDLC is a process that involves planning, designing, developing, testing, deploying, operating, and maintaining a system, using various models and methodologies, such as waterfall, spiral, agile, or DevSecOps. The SDLC can be divided into several phases, each with its own objectives and activities, such as:

• System initiation: This phase involves defining the scope, purpose, and objectives of the system, identifying the stakeholders and their needs and expectations, and establishing the project plan and budget.
• System acquisition and development: This phase involves designing the architecture and components of the system, selecting and procuring the hardware and software resources, developing and coding the system functionality and features, and integrating and testing the system modules and interfaces.
• System implementation: This phase involves deploying and installing the system to the production environment, migrating and converting the data and applications from the legacy system, training and educating the users and staff on the system operation and maintenance, and evaluating and validating the system performance and effectiveness.
• System operations and maintenance: This phase involves operating and monitoring the system functionality and availability, maintaining and updating the system hardware and software, resolving and troubleshooting any issues or problems, and enhancing and optimizing the system features and capabilities.

The certification and accreditation process is a process that involves assessing and verifying the security and compliance of a system, and authorizing and approving the system operation and maintenance, using various standards and frameworks, such as NIST SP 800-37 or ISO/IEC 27001. The certification and accreditation process can be divided into several tasks, each with its own objectives and activities, such as:

• Security categorization: This task involves determining the security level and impact of the system and its data, based on the confidentiality, integrity, and availability criteria, and applying the appropriate security controls and measures.
• Security planning: This task involves defining the security objectives and requirements of the system, identifying the roles and responsibilities of the security stakeholders, and developing and documenting the security plan and policy.
• Security implementation: This task involves implementing and enforcing the security controls and measures for the system, according to the security plan and policy, and ensuring the security functionality and compatibility of the system.
• Security assessment: This task involves evaluating and testing the security effectiveness and compliance of the system, using various techniques and tools, such as audits, reviews, scans, or penetration tests, and identifying and reporting any security weaknesses or gaps.
• Security authorization: This task involves reviewing and approving the security assessment results and recommendations, and granting or denying the authorization for the system operation and maintenance, based on the risk and impact analysis and the security objectives and requirements.
• Security monitoring: This task involves monitoring and updating the security status and activities of the system, using various methods and tools, such as logs, alerts, or reports, and addressing and resolving any security issues or changes.

The configuration management and control task of the certification and accreditation process is incorporated in the system acquisition and development phase of the SDLC, because it can ensure that the system design and development are consistent and compliant with the security objectives and requirements, and that the system changes are controlled and documented. Configuration management and control is a process that involves establishing and maintaining the baseline and the inventory of the system components and resources, such as hardware, software, data, or documentation, and tracking and recording any modifications or updates to the system components and resources, using various techniques and tools, such as version control, change control, or configuration audits. Configuration management and control can provide several benefits, such as:

• Improving the quality and security of the system design and development by identifying and addressing any errors or inconsistencies
• Enhancing the performance and efficiency of the system design and development by optimizing the use and allocation of the system components and resources
• Increasing the compliance and alignment of the system design and development with the security objectives and requirements by applying and enforcing the security controls and measures
• Facilitating the monitoring and improvement of the system design and development by providing the evidence and information for the security assessment and authorization

The other options are not the phases of the SDLC that incorporate the configuration management and control task of the certification and accreditation process, but rather phases that involve other tasks of the certification and accreditation process. System operations and maintenance is a phase of the SDLC that incorporates the security monitoring task of the certification and accreditation process, because it can ensure that the system operation and maintenance are consistent and compliant with the security objectives and requirements, and that the system security is updated and improved. System initiation is a phase of the SDLC that incorporates the security categorization and security planning tasks of the certification and accreditation process, because it can ensure that the system scope and objectives are defined and aligned with the security objectives and requirements, and that the security plan and policy are developed and documented. System implementation is a phase of the SDLC that incorporates the security assessment and security authorization tasks of the certification and accreditation process, because it can ensure that the system deployment and installation are evaluated and verified for the security effectiveness and compliance, and that the system operation and maintenance are authorized and approved based on the risk and impact analysis and the security objectives and requirements.

The primary risk with using open source software in a commercial software construction is license agreements requiring release of modified code. Open source software is software that uses publicly available source code, which can be seen, modified, and distributed by anyone. Open source software has some advantages, such as being affordable and flexible, but it also has some disadvantages, such as being potentially insecure or unsupported.

One of the main disadvantages of using open source software in a commercial software construction is the license agreements that govern the use and distribution of the open source software. License agreements are legal contracts that specify the rights and obligations of the parties involved in the software, such as the original authors, the developers, and the users. License agreements can vary in terms of their terms and conditions, such as the scope, the duration, or the fees of the software.

Some of the common types of license agreements for open source software are:

• Permissive licenses: license agreements that allow the developers and users to freely use, modify, and distribute the open source software, with minimal or no restrictions. Examples of permissive licenses are the MIT License, the Apache License, or the BSD License.
• Copyleft licenses: license agreements that require the developers and users to share and distribute the open source software and any modifications or derivatives of it, under the same or compatible license terms and conditions. Examples of copyleft licenses are the GNU General Public License (GPL), the GNU Lesser General Public License (LGPL), or the Mozilla Public License (MPL).
• Mixed licenses: license agreements that combine the elements of permissive and copyleft licenses, and may apply different license terms and conditions to different parts or components of the open source software. Examples of mixed licenses are the Eclipse Public License (EPL), the Common Development and Distribution License (CDDL), or the GNU Affero General Public License (AGPL).

The primary risk with using open source software in a commercial software construction is license agreements requiring release of modified code, which are usually associated with copyleft licenses. This means that if a commercial software construction uses or incorporates open source software that is licensed under a copyleft license, then it must also release its own source code and any modifications or derivatives of it, under the same or compatible copyleft license. This can pose a significant risk for the commercial software construction, as it may lose its competitive advantage, intellectual property, or revenue, by disclosing its source code and allowing others to use, modify, or distribute it.

The other options are not the primary risks with using open source software in a commercial software construction, but rather secondary or minor risks that may or may not apply to the open source software. Lack of software documentation is a secondary risk with using open source software in a commercial software construction, as it may affect the quality, usability, or maintainability of the open source software, but it does not necessarily affect the rights or obligations of the commercial software construction. Expiration of the license agreement is a minor risk with using open source software in a commercial software construction, as it may affect the availability or continuity of the open source software, but it is unlikely to happen, as most open source software licenses are perpetual or indefinite. Costs associated with support of the software is a secondary risk with using open source software in a commercial software construction, as it may affect the reliability, security, or performance of the open source software, but it can be mitigated or avoided by choosing the open source software that has adequate or alternative support options.

The most probable security feature of Java preventing the program from operating as intended is least privilege. Least privilege is a principle that states that a subject (such as a user, a process, or a program) should only have the minimum amount of access or permissions that are necessary to perform its function or task. Least privilege can help to reduce the attack surface and the potential damage of a system or network, by limiting the exposure and impact of a subject in case of a compromise or misuse.

Java implements the principle of least privilege through its security model, which consists of several components, such as:

• The Java Virtual Machine (JVM): a software layer that executes the Java bytecode and provides an abstraction from the underlying hardware and operating system. The JVM enforces the security rules and restrictions on the Java programs, such as the memory protection, the bytecode verification, and the exception handling.
• The Java Security Manager: a class that defines and controls the security policy and permissions for the Java programs. The Java Security Manager can be configured and customized by the system administrator or the user, and can grant or deny the access or actions of the Java programs, such as the file I/O, the network communication, or the system properties.
• The Java Security Policy: a file that specifies the security permissions for the Java programs, based on the code source and the code signer. The Java Security Policy can be defined and modified by the system administrator or the user, and can assign different levels of permissions to different Java programs, such as the trusted or the untrusted ones.
• The Java Security Sandbox: a mechanism that isolates and restricts the Java programs that are downloaded or executed from untrusted sources, such as the web or the network. The Java Security Sandbox applies the default or the minimal security permissions to the untrusted Java programs, and prevents them from accessing or modifying the local resources or data, such as the files, the databases, or the registry.

In this question, the Java program is being developed to read a file from computer A and write it to computer B, using a third computer C. This means that the Java program needs to have the permissions to perform the file I/O and the network communication operations, which are considered as sensitive or risky actions by the Java security model. However, if the Java program is running on computer C with the default or the minimal security permissions, such as in the Java Security Sandbox, then it will not be able to perform these operations, and the program will not work as expected. Therefore, the most probable security feature of Java preventing the program from operating as intended is least privilege, which limits the access or permissions of the Java program based on its source, signer, or policy.

The other options are not the security features of Java preventing the program from operating as intended, but rather concepts or techniques that are related to security in general or in other contexts. Privilege escalation is a technique that allows a subject to gain higher or unauthorized access or permissions than what it is supposed to have, by exploiting a vulnerability or a flaw in a system or network. Privilege escalation can help an attacker to perform malicious actions or to access sensitive resources or data, by bypassing the security controls or restrictions. Defense in depth is a concept that states that a system or network should have multiple layers or levels of security, to provide redundancy and resilience in case of a breach or an attack. Defense in depth can help to protect a system or network from various threats and risks, by using different types of security measures and controls, such as the physical, the technical, or the administrative ones. Privilege bracketing is a technique that allows a subject to temporarily elevate or lower its access or permissions, to perform a specific function or task, and then return to its original or normal level. Privilege bracketing can help to reduce the exposure and impact of a subject, by minimizing the time and scope of its higher or lower access or permissions.