MashupOS
Protection and communication abstractions for web browsers in MashupOS
This paper appears in SOSP '07 Proceedings of twenty-first ACM SIGOPS symposium on Operating systems principles, Pages 1-16. The audience is primarily OS researchers, as opposed to web/security researchers.
- Motivation for the work
- Authors refer to browsers as "multi-principal operating environments" where mutually distrusting web sites, as principals, interact in a single page on the client side, sharing the underlying browser resources. This is compared to PC operating environments where mutually distrusting users share host resources.
- However, the authors argue that today's browsers do not employ OS abstractions, and instead provide limited all-or-nothing trust models, and are therefore only suitable for a single-principal system. They aim to fix this with MashupOS.
- Principles of MashupOS
- Match all common trust levels
- Strike a balance between ease-of-use and security
- Easy adoption and no unintended behaviours (i.e. provide fallback mechanisms for legacy browsers)
- Principals and Resources
- In OS, the principal is a user or group. In the Web, the principal is the owner of some Web content.
- Resources:
- Memory: heap of script objects
- Persistent state: Cookies
- Display: HTML DOM
- Network communications: Ability to send and receive messages outside application.
- Existing trust relationship between content providers and integrators: All-or-nothing. Authors identify four types of content, for which they implement various abstractions
- Isolated content: Completely isolated from other sites.
- Access-controlled content: Content that is isolated but allows message-passing across domains to give mediated access.
- Open content
- Unauthorized content: Content which the integrator an directly access, but does not trust to access the integrator's resources.
- Paper puts heavy emphasis on Sandboxing and isolation
- What they implemented:
- <ServiceInstance> abstraction for isolation, fault containment, and as the unit of resource allocation and CommRequest for cross-domain communications.
- Controlled communication between service instances is allowed through the CommRequest abstraction - can be thought of as "ports". Allows separate components to talk to each other through the parent , but never directly child to child.
- Comparable to starting a new process in Linux - each is allocated its own resources
- Friv: combines properties of a and <iframe>. Acts as the display which each service instance connects to.
- <Sandbox> and <OpenSandbox> abstractions to enable the provision of unauthorized content without overtrusting it. This is also said to help in combating XSS attacks.
- <Sandbox>: Private unauthrozed content that is hosted at and belongs to the integrator.
- <Opensandbox>: May be hosted by any domain.
- <ServiceInstance> abstraction for isolation, fault containment, and as the unit of resource allocation and CommRequest for cross-domain communications.
- vop <-- Do we want to talk about
- sop <-- Do we want to talk about
- What was implemented
- Proxy server and MME filter
- What the testing was
- Running speed tests not security test , Anil said WHY ? mabey because OS conference cares about speed
- Open sandbox was not implemented
- only one service instance per friv
- Conclusions
- Mostly a theoretical paper
- But interesting
- Notes
- Do we want to show figure 2 <---- for what they did
- Do we want to show figure 3 <--- for what they did and how it works
- Mostly a theoretical paper