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Title: Task Control: Signals and Alarms Chapter 7 and 8


1
Task ControlSignals and AlarmsChapter 7 and 8
  • B. Ramamurthy

2
Multi-tasking
  • How to create multiple tasks? Ex Xinu create()
  • How to control them?
  • ready()
  • resched()
  • How to synchronize them? How to communicate among
    them?
  • XINU semaphores, send and receive messages
  • How to (software) interrupt a process? signals

3
Examples
  • Consider g myProg.c
  • You want to kill this process after you started
    the compilation..hit cntrl-C
  • Consider execution of a program called badprog
  • gtbadprog
  • It core dumps .. What happened? The error in the
    program results in a signal to kernel to stop and
    dump the offending code
  • Consider kill p ltpidgt
  • Kill issues a termination signal to the process
    identified by the pid

4
Linux Processes
  • Similar to XINU Procs.
  • Lets understand how to create a linux process and
    control it.
  • Chapter 7 and 8 of text book.
  • Chapter 7 multi-tasking
  • Chapter 8 Task communication and synchronization

5
Process creation
  • Four common events that lead to a process
    creation are
  • 1) When a new batch-job is presented for
    execution.
  • 2) When an interactive user logs in / system
    initialization.
  • 3) When OS needs to perform an operation (usually
    IO) on behalf of a user process, concurrently
    with that process.
  • 4) To exploit parallelism an user process can
    spawn a number of processes.

6
Termination of a process
  • Normal completion, time limit exceeded, memory
    unavailable
  • Bounds violation, protection error, arithmetic
    error, invalid instruction
  • IO failure, Operator intervention, parent
    termination, parent request, killed by another
    process
  • A number of other conditions are possible.
  • Segmentation fault usually happens when you try
    write/read into/from a non-existent
    array/structure/object component. Or access a
    pointer to a dynamic data before creating it.
    (new etc.)
  • Bus error Related to function call and return.
    You have messed up the stack where the return
    address or parameters are stored.

7
Process control
  • Process creation in unix is by means of the
    system call fork().
  • OS in response to a fork() call
  • Allocate slot in the process table for new
    process.
  • Assigns unique pid to the new process..
  • Makes a copy of the process image, except for the
    shared memory.
  • both child and parent are executing the same code
    following fork()
  • Move child process to Ready queue.
  • it returns pid of the child to the parent, and a
    zero value to the child.

8
Process control (contd.)
  • All the above are done in the kernel mode in the
    process context. When the kernel completes these
    it does one of the following as a part of the
    dispatcher
  • Stay in the parent process. Control returns to
    the user mode at the point of the fork call of
    the parent.
  • Transfer control to the child process. The child
    process begins executing at the same point in the
    code as the parent, at the return from the fork
    call.
  • Transfer control another process leaving both
    parent and child in the Ready state.

9
Process Creation (contd.)
  • Parent process create children processes, which,
    in turn create other processes, forming a tree of
    processes
  • Generally, process identified and managed via a
    process identifier (pid)
  • Resource sharing
  • Parent and children share all resources
  • Children share subset of parents resources
  • Parent and child share no resources
  • Execution
  • Parent and children execute concurrently
  • Parent waits until children terminate

10
Process Termination
  • Process executes last statement and asks the
    operating system to delete it (exit)
  • Output data from child to parent (via wait)
  • Process resources are deallocated by operating
    system
  • Parent may terminate execution of children
    processes (abort)
  • Child has exceeded allocated resources
  • Task assigned to child is no longer required
  • If parent is exiting
  • Some operating system do not allow child to
    continue if its parent terminates
  • All children terminated - cascading termination

11
Task State Diagram
Task admitted
Ready
New
Resources allocated
Dispatched cpu allocated
Event occurred
Task exit
Blocked
Run
Waiting for event
12
Resources Critical Resources
  • Shared resources need mutual exclusion
  • Tasks cooperating to complete a job
  • Tasks contending to access a resource
  • Tasks synchronizing
  • Critical resources and critical region
  • A important synchronization and mutual exclusion
    primitive / resource is semaphore

13
Critical sections and Semaphores
  • When multiples tasks are executing there may be
    sections where only one task could execute at a
    given time critical region or critical section
  • There may be resources which can be accessed only
    be one of the processes critical resource
  • Semaphores can be used to ensure mutual exclusion
    to critical sections and critical resources

14
Semaphores
  • See semaphore.h of xinu

15
Semaphores in exinu
  • include ltkernel.hgt
  • include ltqueue.hgt /lt queue.h must define
    of sem queues /
  • / Semaphore state definitions /
  • define SFREE 0x01 /lt this semaphore is
    free /
  • define SUSED 0x02 /lt this semaphore is
    used /
  • / type definition of "semaphore" /
  • typedef ulong semaphore
  • / Semaphore table entry /
  • struct sentry
  • char state /lt the state SFREE
    or SUSED /
  • short count /lt count for this
    semaphore /
  • queue queue /lt requires q.h.
    /

16
Semaphores in exinu (contd.)
  • extern struct sentry semtab
  • /
  • isbadsem - check validity of reqested
    semaphore id and state
  • _at_param s id number to test NSEM is declared
    to be 100 in kernel.h
  • A system typically has a predetermined
    limited number of semaphores
  • /
  • define isbadsem(s) (((ushort)(s) gt NSEM)
    (SFREE semtabs.state))
  • / Semaphore function declarations /
  • syscall wait(semaphore)
  • syscall signal(semaphore)
  • syscall signaln(semaphore, short)
  • semaphore newsem(short)
  • syscall freesem(semaphore)
  • syscall scount(semaphore)

17
Definition of Semaphores functions
  • static semaphore allocsem(void)
  • /
  • newsem - allocate and initialize a new
    semaphore.
  • _at_param count - number of resources available
    without waiting.
  • example count 1 for mutual exclusion lock
  • _at_return new semaphore id on success, SYSERR on
    failure
  • /
  • semaphore newsem(short count)
  • irqmask ps
  • semaphore sem
  • ps disable() /
    disable interrupts /
  • sem allocsem() /
    request new semaphore /
  • if ( sem ! SYSERR count gt 0 ) /
    safety check /
  • semtabsem.count count
    / initialize count /
  • restore(ps)
    / restore interrupts /
  • return sem
    / return semaphore id /

18
Semaphore newsem contd.
  • /
  • allocsem - allocate an unused semaphore and
    return its index.
  • Scan the global semaphore table for a free
    entry, mark the entry
  • used, and return the new semaphore
  • _at_return available semaphore id on success,
    SYSERR on failure
  • /
  • static semaphore allocsem(void)
  • int i 0
  • while(i lt NSEM) /
    loop through semaphore table /
  • /
    to find SFREE semaphore /
  • if( semtabi.state SFREE )
  • semtabi.state SUSED
  • return i
  • i
  • return SYSERR

19
Semaphore wait()
  • /
  • wait - make current process wait on a
    semaphore
  • _at_param sem semaphore for which to wait
  • _at_return OK on success, SYSERR on failure
  • /
  • syscall wait(semaphore sem)
  • irqmask ps
  • struct sentry psem
  • pcb ppcb
  • ps disable() / disable
    interrupts /
  • if ( isbadsem(sem) ) / safety
    check /
  • restore(ps)
  • return SYSERR
  • ppcb proctabcurrpid / retrieve
    pcb from process table /
  • psem semtabsem / retrieve
    semaphore entry /
  • if( --(psem-gtcount) lt 0 ) / if
    requested resource is unavailable /

20
Semaphore wait()
  • ppcb-gtsem sem / record semaphore id in pcb /
  • enqueue(currpid, psem-gtqueue)
  • resched() / place
    in wait queue and reschedule /
  • restore(ps) / restore
    interrupts /
  • return OK

21
Semaphore signal()
  • /signal - signal a semaphore, releasing one
    waiting process, and block
  • _at_param sem id of semaphore to signal
  • _at_return OK on success, SYSERR on failure
  • /
  • syscall signal(semaphore sem)
  • irqmask ps
  • register struct sentry psem
  • ps disable() / disable
    interrupts /
  • if ( isbadsem(sem) ) / safety
    check /
  • restore(ps)
  • return SYSERR
  • psem semtabsem /
    retrieve semaphore entry /
  • if ( (psem-gtcount) lt 0 ) / release
    one process from wait queue /
  • ready(dequeue(psem-gtqueue),
    RESCHED_YES)
  • restore(ps) / restore
    interrupts /

22
Semaphore usage
  • Problem 1
  • Create 3 tasks that each sleep for a random time
    and update a counter.
  • Counter is the critical resources shared among
    the processes.
  • Only one task can update the counter at a time so
    that counter value is correct.
  • Problem 2
  • Create 3 tasks task 1 updates the counter by 1
    and then signal task 2 that updates the counter
    by 2 and then signals task 3 to update the
    counter by 3.

23
Problem 1
  • include lt..gt
  • //declare semaphore
  • semaphore mutex1 newsem(1)
  • int counter 0
  • //declare functions proc1,proc1, proc3
  • ready(create((void )proc1, INITSTK, INITPRIO,
    PROC1",, 2, 0, NULL), RESCHED_NO)
  • ready(create((void )proc2, INITSTK, INITPRIO,
    PROC2",, 2, 0, NULL), RESCHED_NO)
  • ready(create((void )proc3, INITSTK, INITPRIO,
    PROC3",, 2, 0, NULL), RESCHED_NO)

24
Problem 1 multi-tasks
  • void proc1()
  • while (1)
  • sleep (rand()10)
  • wait(mutex1)
  • counter
  • signal(mutex1)
  • void proc2()
  • while (1)
  • sleep (rand()10)
  • wait(mutex1)
  • counter
  • signal(mutex1)
  • //similarly proc3

25
Problem 1
Task 1
Task 2
Counter1
Task 3
26
Problem 2
  • semaphore synch12 newsem(0)
  • semaphore synch23 newsem(0)
  • semaphore synch31 newsem(0)
  • ready(create((void )proc1, INITSTK, INITPRIO,
    PROC1",, 2, 0, NULL), RESCHED_NO)
  • ready(create((void )proc2, INITSTK, INITPRIO,
    PROC2",, 2, 0, NULL), RESCHED_NO)
  • ready(create((void )proc3, INITSTK, INITPRIO,
    PROC3",, 2, 0, NULL), RESCHED_NO)
  • signal(synch31)

27
Task flow
28
Signals
  • Signals provide a simple method for transmitting
    software interrupts to UNIX process
  • Signals cannot carry information directly, which
    limits their usefulness as an general
    inter-process communication mechanism
  • However each type of signal is given a mnemonic
    name Ex SIGINT
  • See signal.h for others
  • SIGHUP, SIGINT, SIGILL, SIGTRAP, SIGFPE, SIGKILL
  • SIGALRM (sent by kernel to a process after an
    alarm timer has expired)
  • SIGTERM
  • signal (signal id, function) simply arms the
    signal

29
Intercept Signals
Task1
Task2
Two essential parameters are destination process
identifier and the signal code number kill
(pid, signal) Signals are a useful way of
handling intermittent data arrivals or rare
error conditions.
30
Handling Signals
  • Look at the examples
  • Catching SIGALRM
  • Ignoring SIGALRM
  • sigtest.c
  • sigHandler.c
  • pingpong.c
  • See /usr/include/sys/iso/signal_iso.h for signal
    numbers

31
Signals and Alarms
  • include ltsignal.hgt
  • unsigned int alarm( unsigned int seconds )
  • alarm(a) will start a timer for a secsonds and
    will interrupt the calling process after a secs.
  • time(t) will get you current time in the
    variable t declared as time_t t
  • ctime(t) will convert time to ascii format
  • Alarm has a sigaction function that is set for
    configuring the alarm handler etc.
  • sigaction(SIGALRM, act, oldact) the third
    paramter is for old action configuration

32
Sample programs
  • Starting new tasks in linux page 165
  • Programs in pages 174-180 on signals and alarms
  • See demos directory for first
  • See page 175 for the second program
  • See page 178 for the third program

33
Pingpong
Parent
PSIG 43
Child
CSIG 42
34
Observe in pingpong.c
  • pause() indefinite
  • sleep() sleep is random/finite time
  • While loop
  • Signal handlers
  • Re-arming of the signals

35
Volatile (from code reading last lecture)
  • A variable should be declared volatile whenever
    its value could change unexpectedly. In practice,
    only three types of variables could change
  • Memory-mapped peripheral registers
  • Global variables modified by an interrupt service
    routine
  • Global variables within a multi-threaded
    application
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