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OPERATING SYSTEMS DESIGN AND IMPLEMENTATION Third Edition ANDREW S. TANENBAUM ALBERT S. WOODHULL

Yan hao (Wilson) Wu wwu@uwc.ac.za University of the Western Cape Computer Science Department. OPERATING SYSTEMS DESIGN AND IMPLEMENTATION Third Edition ANDREW S. TANENBAUM ALBERT S. WOODHULL. The Process Model (1). Figure 2-1 (a) Multiprogramming of four programs. The Process Model (2).

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OPERATING SYSTEMS DESIGN AND IMPLEMENTATION Third Edition ANDREW S. TANENBAUM ALBERT S. WOODHULL

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  1. Yan hao (Wilson) Wu wwu@uwc.ac.za University of the Western Cape Computer Science Department OPERATING SYSTEMSDESIGN AND IMPLEMENTATIONThird EditionANDREW S. TANENBAUMALBERT S. WOODHULL

  2. The Process Model (1) Figure 2-1 (a) Multiprogramming of four programs.

  3. The Process Model (2) Figure 2-1 (b) Conceptual model of four independent, sequential processes.

  4. The Process Model (3) Figure 2-1 (c) Only one program is active at any instant.

  5. Process Creation Principal events that cause processes to be created: 1. System initialization. 2. Execution of a process creation system call by a running process. 3. A user request to create a new process. 4. Initiation of a batch job.

  6. Process Termination Conditions that cause a process to terminate: 1. Normal exit (voluntary). 2. Error exit (voluntary). 3. Fatal error (involuntary). 4. Killed by another process (involuntary).

  7. Process States (1) Possible process states: 1. Running (actually using the CPU at that instant). 2. Ready (runnable; temporarily stopped to let another process run). 3. Blocked (unable to run until some external event happens).

  8. Process States (2) Figure 2-2A process can be in running, blocked, or ready state. Transitions between these states are as shown.

  9. Process States (3) Figure 2-3The lowest layer of a process-structured operating system handles interrupts and scheduling. Above that layer are sequential processes.

  10. Implementation of Processes Kernel Process management File management Registers Program counter Program status word Stack pointer Process state Current scheduling priority Maximum scheduling priority Scheduling ticks left Quantum size CPU time used Message queue pointers Pending signal bits Various flag bits Process name Pointer to text segment Pointer to data segment Pointer to bss segment Exit status Signal status Process ID Parent process Process group Children’s CPU time Real UID Effective UID Real GID Effective GID File info for sharing text Bitmaps for signals Various flag bits Process name UMASK mask Root directory Working directory File descriptions Real id Effective UID Real GID Effective GID Controlling tty Save area for read/write System call parameters Various flag bits Figure 2-4. Some of the fields of the MINIX 3 process table. The fields are distributed over the kernel, the process manager, and the file system.

  11. Interrupts Figure 2-5Skeleton of what the lowest level of the operating system does when an interrupt occurs.

  12. Threads vs. Processes Creation of a new process using fork is expensive (time & memory). A thread (sometimes called a lightweight process) does not require lots of memory or startup time.

  13. Thread (1) Figure 2-6(a) Three processes each with one thread.

  14. Threads (2) Figure 2-7. The first column lists some items shared by all threads in a process. The second one lists some items private to each thread.

  15. Threads (3) Figure 2-6 (b) One process with three threads.

  16. Race Conditions Definition: Where two or more processes are reading or writing some shared data and the final result depends on who runs precisely when, are called race condition Figure 2-8Two processes want to access shared memory at the same time.

  17. DANGER! DANGER! DANGER! Sharing global variables is dangerous – two threads may attempt to modify the same variable at the same time. Just because you don't see a problem when running your code doesn't mean it can't and won't happen!!!!

  18. Critical Sections Necessary to avoid race conditions: No process running outside its critical region may block other processes. (not busy then in) No two processes may be simultaneously inside their critical regions. (busy then wait) No process should have to wait forever to enter its critical region. (wait only limited time) No assumptions may be made about speeds or the number of CPUs. (give up CPU while waiting)

  19. Mutual Exclusion with Busy Waiting Figure 2-9 Mutual exclusion using critical regions.

  20. Strict Alternation Figure 2-10.A proposed solution to the critical region problem. (a) Process 0. (b) Process 1. In both cases, be sure to note the semicolons terminating the while statements.

  21. Peterson’s Solution (1) Figure 2-11Peterson’s solution for achieving mutual exclusion.

  22. Peterson’s Solution (2) Figure 2-11Peterson’s solution for achieving mutual exclusion.

  23. The TSL Instruction Figure 2-12.Entering and leaving a critical region using the TSL instruction.

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