Silberschatz et al.: Ch. 1,2.

Welcome Lecture: [Slides] [Handouts]
Overview Lecture: [Slides] [Handouts]

History of operating system development. Role of an operating system. Evolution of hardware and operating systems. Course structure and plan.

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Homework 1: [PDF]

Silberschatz et al.: Ch. 8.
Bonwick: The Slab Allocator: An Object-Caching Kernel Memory Allocator

Memory Management Lecture: [Slides] [Handouts]

Rubber, roads, and operating systems. Allocation strategies for main memory. The problem of fragmentation. Overlays and placement algorithms for fixed partitions. Dynamic partitioning strategies. External fragmentation. The Buddy System. Swapping and relocation. Segmentation vs. position independent code.

Address translation, page tables, and paging. Implementations of page tables (hierarchical, hashed). TLBs and the performance impact of memory hierarchies. Memory protection and multilevel paging mechanisms. Complications of page sharing and need for inverted page tables.

The address space as a resource: understanding the proper relationship between actors, processes, and address spaces.

Silberschatz et al.: Ch. 9.

Virtual Memory Lecture: [Slides] [Handouts]

Making something out of nothing: revisiting the swapping concept. Demand paging vs. prefetching. Page faults and architecture support for paging. Performance implications of memory hierarchies. Page replacement policies and ageing strategies (FIFO, LRU, Stack algorithms). Working sets and the problem of shared pages. Second chance algorithms. Page buffering and why clean frames are better than free frames. Frame allocation policies and the recurring problem of ad hoc policy in monolithic systems. Pinning. Thrashing. Variable page sizes.

Project 1: The Slab Allocator. [PDF]
Assigned February 5.

Silberschatz et al.: Ch. 3, 4, 5.
Mercer et al.: Processor Capacity Reserves: Operating System Support for Multimedia Applications

Process Control Lecture: [Slides] [Handouts]

Programs in motion: processes, threads, and actors. Process states, queueing, and context switching. Thread models (user vs. system). Scheduling strategies and preemption. Multilevel schedulers. Fairness. The problem of ad hoc policy.

Silberschatz et al.: Ch. 6.

Process Synchronization Lecture: [Slides] [Handouts]

The problem with unrestricted concurrency. Race conditions and critical sections. Software meachanisms. The Bakery Algorithm. Hardware mechanisms: atomic instructions, disabling interrupts. Operating system mechanisms: semaphores. The producer/consumer problem. The readers/writers problem. Care and feeding of philosophers. Monitors and condition variables.

Silberschatz et al.: Ch. 7.

Deadlocks Lecture: [Slides] [Handouts]

Definition of deadlock. Railroads in Indianna. Conditions for deadlock. Resource allocation graphs. Methods for prevention, avoidance, and detection. Safe states. The Bankers Algorithm. An integrated solution.

Project 1 due this week

Silberschatz et al.: Ch. 10, 11.

File Systems Lecture: [Slides] [Handouts]

Definition of a ``file'' and purpose of a file system. Files and file attributes. Conventional file protection mechanisms. Why they do not work. Operations on files. Files as a generic interface for I/O channels. Access methods for files.

Directories and directory organization. Operations on directories. Single level, two level, and multilevel directories. Acyclic graph directories. General graph directories. Protection.

File sharing and consistency semantics. File system components and the architecture of a file system. File allocation policies and storage management strategies. Linked vs. hierarchical file structures. Log structured file systems.

Silberschatz et al.: Ch. 11, 12.
Ruemmler and Wilkes: An Introduction to Disk Drive Modeling

File Systems II, Disk Management Lecture: [Slides] [Handouts]

Free space management. Directories as a type of file. Consistency and the problem of directory updates. Why general directory graphs are a bad idea. Backup and recovery. Block (buffer) caching. Ram disks. Placement, interleaving, and update ordering. Disk drive mechanics and performance. Interleaving and disk scheduling.

Project 2: To be assigned

Silberschatz et al.: Ch. 14, 15.
Lampson: Protection

Protection and Security Lecture: [Slides] [Handouts]

Domains of protection. Domain structure. Domain implementation in UNIX. The Lampson Access Matrix. Access Control Lists (ACLs) and Capabilities. The Safety Problem. The confinement problem. Why users are not subjects. Enforceable vs. political security policies.

Silberschatz et al.: Ch. 16,17.
Golub et al.: UNIX as an Application Program
Bershad and Chen: The Impact of Operating System Structure on Memory System Performance
Hartig et al.: The Performance of Microkernel-Based Systems

Other Kernels Lecture: [Slides] [Handouts]

Questions of operating system structure. Encapsulation of function, and design of kernel substrates for encapsulation rather than feature set. The argument for microkernels. Core mechanisms of a microkernel, advantages, and disadvantages.

Project 2: Part 1 due this week

Virtual Machines Lecture [Slides] [Handouts]

TBA

TBA

Response to exam review questions (if any) or advanced topic discussion.

Project 2: Due this week.