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  1. DZone
  2. Software Design and Architecture
  3. Security
  4. Deno Security: Building Trustworthy Applications

Deno Security: Building Trustworthy Applications

Deno's design philosophy prioritizes security, making it an ideal choice for building secure, reliable, and trustworthy applications.

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Josephine Eskaline Joyce user avatar
Josephine Eskaline Joyce
DZone Core CORE ·
Joseph Jude user avatar
Joseph Jude
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Mar. 28, 24 · Tutorial
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In the world of modern web development, security is paramount. With the rise of sophisticated cyber threats, developers need robust tools and frameworks to build secure applications. Deno, a secure runtime for JavaScript and TypeScript, has emerged as a promising solution for developers looking to enhance the security of their applications.

Deno was created by Ryan Dahl, the original creator of Node.js, with a focus on addressing some of the security issues present in Node.js. Deno comes with several built-in security features that make it a compelling choice for developers concerned about application security. This guide will explore some of the key security features of Deno and how they can help you build trustworthy applications.

Deno’s "Secure by Default" Features

Deno achieves "Secure by Default" through several key design choices and built-in features:

  • No file, network, or environment access by default: Unlike Node.js, which grants access to the file system, network, and environment variables by default, Deno restricts these permissions unless explicitly granted. This reduces the attack surface of applications running in Deno.
  • Explicit permissions: Deno requires explicit permissions for accessing files, networks, and other resources, which are granted through command-line flags or configuration files. This helps developers understand and control the permissions their applications have.
  • Built-in security features: Deno includes several built-in security features, such as a secure runtime environment (using V8 and Rust), automatic updates, and a dependency inspector to identify potentially unsafe dependencies.
  • Secure standard library: Deno provides a secure standard library for common tasks, such as file I/O, networking, and cryptography, which is designed with security best practices in mind.
  • Sandboxed execution: Deno uses V8's built-in sandboxing features to isolate the execution of JavaScript and TypeScript code, preventing it from accessing sensitive resources or interfering with other applications.
  • No access to critical system resources: Deno does not have access to critical system resources, such as the registry (Windows) or keychain (macOS), further reducing the risk of security vulnerabilities.

Overall, Deno's "Secure by Default" approach aims to provide developers with a safer environment for building applications, helping to mitigate common security risks associated with JavaScript and TypeScript development.

Comparison of “Secure by Default” With Node.js

Deno takes a more proactive approach to security by restricting access to resources by default and requiring explicit permissions for access. It also includes built-in security features and a secure standard library, making it more secure by default compared to Node.js.

Feature
Deno
Node.js

File access

Denied by default, requires explicit permission

Allowed by default

Network access

Denied by default, requires explicit permission

Allowed by default

Environment access

Denied by default, requires explicit permission

Allowed by default

Permissions system

Uses command-line flags or configuration files

Requires setting environment variables

Built-in security

Includes built-in security features

Lacks comprehensive built-in security

Standard library

Secure standard library

Standard library with potential vulnerabilities

Sandboxed execution

Uses V8's sandboxing features

Lacks built-in sandboxing features

Access to resources

Restricted access to critical system resources

May have access to critical system resources


Permission Model

Deno's permission model is central to its "Secure by Default" approach. Here's how it works:

  • No implicit permissions: In Deno, access to resources like the file system, network, and environment variables is denied by default. This means that even if a script tries to access these resources, it will be blocked unless the user explicitly grants permission.
  • Explicit permission requests: When a Deno script attempts to access a resource that requires permission, such as reading a file or making a network request, Deno will throw an error indicating that permission is required. The script must then be run again with the appropriate command-line flag (--allow-read, --allow-net, etc.) to grant the necessary permission.
  • Fine-grained permissions: Deno's permission system is designed to be fine-grained, allowing developers to grant specific permissions for different operations. For example, a script might be granted permission to read files but not write them, or to access a specific network address but not others.
  • Scoped permissions: Permissions in Deno are scoped to the script's URL. This means that if a script is granted permission to access a resource, it can only access that specific resource and not others. This helps prevent scripts from accessing resources they shouldn't have access to.
  • Permissions prompt: When a script requests permission for the first time, Deno will prompt the user to grant or deny permission. This helps ensure that the user is aware of the permissions being requested and can make an informed decision about whether to grant them.

Overall, Deno's permission model is designed to give developers fine-grained control over the resources their scripts can access, while also ensuring that access is only granted when explicitly requested and authorized by the user. This helps prevent unauthorized access to sensitive resources and contributes to Deno's "Secure by Default" approach.

Sandboxing

Sandboxing in Deno helps achieve "secure by default" by isolating the execution of JavaScript and TypeScript code within a restricted environment. This isolation prevents code from accessing sensitive resources or interfering with other applications, enhancing the security of the runtime. Here's how sandboxing helps in Deno:

  • Isolation: Sandboxing in Deno uses V8's built-in sandboxing features to create a secure environment for executing code. This isolation ensures that code running in Deno cannot access resources outside of its sandbox, such as the file system or network, without explicit permission.
  • Prevention of malicious behavior: By isolating code in a sandbox, Deno can prevent malicious code from causing harm to the system or other applications. Even if a piece of code is compromised, it is limited in its ability to access sensitive resources or perform malicious actions.
  • Enhanced security: Sandboxing helps enhance the overall security of Deno by reducing the attack surface available to potential attackers. It adds an additional layer of protection against common security vulnerabilities, such as arbitrary code execution or privilege escalation.
  • Controlled access to resources: Sandboxing allows Deno to control access to resources by requiring explicit permissions for certain actions. This helps ensure that applications only access resources they are authorized to access, reducing the risk of unauthorized access.

Overall, sandboxing plays a crucial role in Deno's "secure by default" approach by providing a secure environment for executing code and preventing malicious behavior. It helps enhance the security of applications running in Deno by limiting their access to resources and reducing the impact of potential security vulnerabilities.

Secure Runtime APIs

Deno's secure runtime APIs provide a robust foundation for building secure applications by default. With features such as sandboxed execution, explicit permission requests, and controlled access to critical resources, Deno ensures that applications run in a secure environment. Sandboxed execution isolates code, preventing it from accessing sensitive resources or interfering with other applications. Deno's permission model requires explicit permission requests for accessing resources like the file system, network, and environment variables, reducing the risk of unintended or malicious access. Additionally, Deno's secure runtime APIs do not have access to critical system resources, further enhancing security. Overall, Deno's secure runtime APIs help developers build secure applications from the ground up, making security a core part of the development process. 

Implement Secure Runtime APIs

Implementing secure runtime APIs in Deno involves using Deno's built-in features and following best practices for secure coding. Here's how you can implement secure-by-default behavior in Deno with examples:

  • Explicitly request permissions: Use Deno's permission model to explicitly request access to resources. For example, to read from a file, you would use the --allow-read flag:
TypeScript
 
const file = await Deno.open("example.txt"); 

// Read from the file... 

Deno.close(file.rid);


  • Avoid insecure features: Instead of using Node.js-style child_process for executing shell commands, use Deno's Deno.run API, which is designed to be more secure:
TypeScript
 
const process = Deno.run({ 

cmd: ["echo", "Hello, Deno!"], 

}); 
await process.status(); 


  • Enable secure flag for import maps: When using import maps, ensure the secure flag is enabled to restrict imports to HTTPS URLs only:
JSON
 
{ 
  "imports": { 
    "example": "https://example.com/module.ts" 
  }, 
  "secure": true 
} 

  • Use HTTPS for network requests: Always use HTTPS for network requests. Deno's fetch API supports HTTPS by default:
TypeScript
 
const response = await fetch("https://example.com/data.json"); 

const data = await response.json(); 


  • Update dependencies regularly: Use Deno's built-in security audits to identify and update dependencies with known vulnerabilities: 
Shell
 
deno audit 


  • Enable secure runtime features: Take advantage of Deno's secure runtime features, such as automatic updates and dependency inspection, to enhance the security of your application.
  • Implement secure coding practices: Follow secure coding practices, such as input validation and proper error handling, to minimize security risks in your code. 

Managing Dependencies To Reduce Security Risks

To reduce security risks associated with dependencies, consider the following recommendations:

  • Regularly update dependencies: Regularly update your dependencies to the latest versions, as newer versions often include security patches and bug fixes. Use tools like deno audit to identify and update dependencies with known vulnerabilities.
  • Use semantic versioning: Follow semantic versioning (SemVer) for your dependencies and specify version ranges carefully in your deps.ts file to ensure that you receive bug fixes and security patches without breaking changes.
  • Limit dependency scope: Only include dependencies that are necessary for your project's functionality. Avoid including unnecessary or unused dependencies, as they can introduce additional security risks.
  • Use import maps: Use import maps to explicitly specify the mapping between module specifiers and URLs. This helps prevent the use of malicious or insecure dependencies by controlling which dependencies are used in your application.
  • Check dependency health: Regularly check the health of your dependencies using tools like `deno doctor` or third-party services. Look for dependencies with known vulnerabilities or that are no longer actively maintained.
  • Use dependency analysis tools: Use dependency analysis tools to identify and remove unused dependencies, as well as to detect and fix vulnerabilities in your dependencies.
  • Review third-party code: When using third-party dependencies, review the source code and documentation to ensure that they meet your security standards. Consider using dependencies from reputable sources or well-known developers.
  • Monitor for security vulnerabilities: Monitor security advisories and mailing lists for your dependencies to stay informed about potential security vulnerabilities. Consider using automated tools to monitor for vulnerabilities in your dependencies.
  • Consider security frameworks: Consider using security frameworks and libraries that provide additional security features, such as input validation, authentication, and encryption, to enhance the security of your application.
  • Implement secure coding practices: Follow secure coding practices to minimize security risks in your code, such as input validation, proper error handling, and using secure algorithms for cryptography.

Secure Coding Best Practices

Secure coding practices in Deno are similar to those in other programming languages but are adapted to Deno's unique features and security model. Here are some best practices for secure coding in Deno:

  • Use explicit permissions: Always use explicit permissions when accessing resources like the file system, network, or environment variables. Use the --allow-read, --allow-write, --allow-net, and other flags to grant permissions only when necessary.
  • Avoid using unsafe APIs: Deno provides secure alternatives to some Node.js APIs that are considered unsafe, such as the child_process module. Use Deno's secure APIs instead.
  • Sanitize input: Always sanitize user input to prevent attacks like SQL injection, XSS, and command injection. Use libraries like std/encoding/html to encode HTML entities and prevent XSS attacks.
  • Use HTTPS: Always use HTTPS for network communication to ensure data integrity and confidentiality. Deno's fetch API supports HTTPS by default.
  • Validate dependencies: Regularly audit and update your dependencies to ensure they are secure. Use Deno's built-in audit tools to identify and mitigate vulnerabilities in your dependencies.
  • Use secure standard library: Deno's standard library (std) provides secure implementations of common functionality. Use these modules instead of relying on third-party libraries with potential vulnerabilities.
  • Avoid eval: Avoid using eval or similar functions, as they can introduce security vulnerabilities by executing arbitrary code. Use alternative approaches, such as functions and modules, to achieve the desired functionality.
  • Minimize dependencies: Minimize the number of dependencies in your project to reduce the attack surface. Only include dependencies that are necessary for your application's functionality.
  • Regularly update Deno: Keep Deno up to date with the latest security patches and updates to mitigate potential vulnerabilities in the runtime.
  • Enable secure flags: When using import maps, enable the secure flag to restrict imports to HTTPS URLs only, preventing potential security risks associated with HTTP imports.

Conclusion

Deno's design philosophy, which emphasizes security and simplicity, makes it an ideal choice for developers looking to build secure applications. Deno's permission model and sandboxing features ensure that applications have access only to the resources they need, reducing the risk of unauthorized access and data breaches. Additionally, Deno's secure runtime APIs provide developers with tools to implement encryption, authentication, and other security measures effectively.

By leveraging Deno's security features, developers can build applications that are not only secure but also reliable and trustworthy. Deno's emphasis on security from the ground up helps developers mitigate common security risks and build applications that users can trust. As we continue to rely more on digital technologies, the importance of building trustworthy applications cannot be overstated, and Deno provides developers with the tools they need to meet this challenge head-on.

applications security Node.js

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