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Unix programming Term:2008-2009 III B.Tech II semester Unit-V II PPT Slides

Unix programming Term:2008-2009 III B.Tech II semester Unit-V II PPT Slides Text Books : (1)unix the ultimate guide by Sumitabha Das (2)Advanced programming in Unix environment by Stevens . INDEX UNIT-V II PPT SLIDES.

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Unix programming Term:2008-2009 III B.Tech II semester Unit-V II PPT Slides

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  1. Unix programming Term:2008-2009 III B.TechII semester Unit-V II PPT Slides Text Books: (1)unix the ultimate guide by Sumitabha Das (2)Advanced programming in Unix environment by Stevens

  2. INDEX UNIT-V II PPT SLIDES • Srl. No. Module as per Session planner Lecture No. PPT Slide No. • data management: management of memory L1 1-2 • malloc ,free ,realloc ,calloc L2 3-9 • 3. file locking L3 10-17 • 4. create locks files ,locking regions L4 18-31 • 5. use of read/write locking L5 32-45 • 6. competing locks, other commands L6 46-50 • 7. Deadlocks L8 • 9. Revision

  3. Memory management • ANSI C specifies three functions for memory allocation: 1.malloc: which allocates a specified number of bytes of memory. The initial value of the memory is indeterminate. 2.calloc:which allocates space for a specified number of objects of a specified size. The space is initialized to all 0 bits. 3. realloc:which increases or decreases the size of a previously allocated area.

  4. #include <stdlib.h> void *malloc (size_t size); void *calloc (size_t nobj, size_t size); void *realloc (void *ptr, size_t newsize); All three return: non-null pointer if OK, NULL on error. void free(void *ptr); • The function free causes the space pointed to by ptr to be deallocated.

  5. Record Locking: • Record locking is used to describe the ability of a process to prevent other processes from modifying a region of a file while the first process is reading or modifying that portion of the file. • It is byte-range locking, since it is a range of a file (possibly the entire file) that is locked.

  6. fcntl Record Locking: #include <fcntl.h> int fcntl(int filedes, int cmd, ... /* struct flock *flockptr */ ); Returns: depends on cmd if OK, -1 on error. Here cmd is F_GETLK, F_SETLK, or F_SETLKW. Flockptr is a pointer to an flock structure.

  7. struct flock { short l_type; off_t l_start; short l_whence; off_t l_len; pid_t l_pid; }; • The type of lock desired: F_RDLCK (a shared read lock), F_WRLCK (an exclusive write lock), or F_UNLCK (unlocking a region). • The starting byte offset of the region being locked or unlocked (l_start and l_whence).

  8. The size of the region in bytes (l_len). • The ID (l_pid) of the process holding the lock that can block the current process (returned by F_GETLK only). Rules about the specification of the region to be locked or unlocked: • Locks can start and extend beyond the current end of file, but cannot start or extend before the beginning of the file. • If l_len is 0, it means that the lock extends to the largest possible offset of the file. This allows us to lock a region starting anywhere in the file, up through and including any data that is appended to the file

  9. To lock the entire file, we set l_start and l_whence to point to the beginning of the file and specify a length (l_len) of 0. Types of locks: 1.Shared lock: read locks are shard locks. Any no.of process can have read lock on the same object at a time. 2. Exclusive lock : Write locks are exclusive locks. When one process puts write lock on the object, no other read lock or write lock is allowed on the same object.

  10. Commands for the fcntl function: F_GETLK: Determine whether the lock described by flockptr is blocked by some other lock. F_SETLK: Set the lock described by flockptr. F_SETLKW: This command is a blocking version of F_SETLK. If the requested read lock or write lock cannot be granted because another process currently has some part of the requested region locked, the calling process is put to sleep.

  11. Function to lock or unlock a region of a file: #include <fcntl.h> int lock_reg (int fd, int cmd, int type, off_t offset, int whence, off_t len) { struct flock lock; lock.l_type = type; lock.l_start = offset; lock.l_whence = whence; lock.l_len = len; return(fcntl( fd, cmd, &lock)); }

  12. Implied Inheritance and Release of Locks: • Locks are associated with a process and a file. when a process terminates, all its locks are released. whenever a descriptor is closed, any locks on the file referenced by that descriptor for that process are released. • Locks are never inherited by the child across a fork.

  13. Place a write lock on an entire file: #include <unistd.h> #include <fcntl.h> int lockfile (int fd) { struct flock fl; fl.l_type = F_WRLCK; fl.l_start = 0; fl.l_whence = SEEK_SET; fl.l_len = 0; return(fcntl(fd, F_SETLK, &fl)); }

  14. Advisory locking: In Unix, advisory locking is done with flock() and lockf() commands. Both fcntl and flock offer advisory locking. Advisory locking is locking that requires the cooperation of participating processes. advisory locking is sometimes called unenforced locking.

  15. Mandatory locking: • Is the kernel enforced file locking, as opposed to the more usual cooperative file locking used to guarantee sequential access to files among processes. • A file is marked as a candidate for mandatory locking by setting the group-id bit in its file mode but removing the group-execute bit. • Mandatory locks can only be applied via the fcntl()/lockf() locking interface.

  16. If a process has locked a region of a file with a mandatory read lock, then other processes are permitted to read from that region. If any of these processes attempts to write to the region it will block until the lock is released. • If a process has locked a region of a file with a mandatory write lock, all attempts to read or write to that region block until the lock is released.

  17. Advisory versus Mandatory Locking • Mandatory locking only protects those portions of a file that are locked. Other portions of the file that are not locked may be accessed according to normal UNIX system file permissions. • Advisory locking is more efficient because a record lock check does not have to be performed for every I/O request.

  18. Deadlock: • Deadlock occurs when two processes are each waiting for a resource that the other has locked. • When a deadlock is detected, the kernel has to choose one process to receive the error return. L8.1

  19. Example of deadlock detection: #include <fcntl.h> static void lockabyte (const char *name, int fd, off_t offset) { if (writew_lock (fd, offset, SEEK_SET, 1) < 0) err_sys("%s: writew_lock error", name); printf("%s: got the lock, byte %ld\n", name, offset); } int main(void) { int fd; pid_t pid; if ((fd = creat("templock", FILE_MODE)) < 0) err_sys("creat error"); L8.2

  20. if (write(fd, "ab", 2) != 2) err_sys("write error"); TELL_WAIT(); if ((pid = fork()) < 0) { err_sys("fork error"); } else if (pid == 0) lockabyte("child", fd, 0); TELL_PARENT( getppid()); WAIT_PARENT(); lockabyte("child", fd, 1); } L8.3

  21. else { lockabyte("parent", fd, 1); TELL_CHILD(pid); WAIT_CHILD(); lockabyte("parent", fd, 0); } exit(0); } L8.4

  22. The child locks byte 0 and the parent locks byte 1. Then each tries to lock the other's already locked byte. We use the parentchild synchronization routines TELL_xxx and WAIT_xxx so that each process can wait for the other to obtain its lock. $ ./a.out parent: got the lock, byte 1 child: got the lock, byte 0 child: writew_lock error: Resource deadlock avoided parent: got the lock, byte 0

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