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C Programs Preprocessor commands –#ifdef –#include –#define Type and macro definitions Variable and function declarations Exactly one main function Function.

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Presentation on theme: "C Programs Preprocessor commands –#ifdef –#include –#define Type and macro definitions Variable and function declarations Exactly one main function Function."— Presentation transcript:

1 C Programs Preprocessor commands –#ifdef –#include –#define Type and macro definitions Variable and function declarations Exactly one main function Function calls and other executable statements Have a.c extension

2 C Header Files Have a.h extension Usually contain only : –macro –type definitions –defined constants –function declarations Include header files with the #include preprocessor command

3 Process Instance of a program in execution Each instance has its own address space and execution state Has a process ID and a state The OS manages memory allocated to the process Process has a flow of control called a thread Heavyweight process

4 Variable Lifetimes Process variables that remain in effect for the lifetime of the process are allocated to static storage Process variables that are automatically created when execution enters a block and are destroyed when execution leaves the block are allocated to automatic storage

5 Threads When a program executes, the pc determines which process instruction is executed next The resulting stream of instructions are called a thread of execution

6 Multiple Threads A natural extension is to have multiple threads within the same process Each thread can be an independent task to complete the process executed in parallel Each thread is an abstract data type that has its own: –execution stack –pc value –register set –state Threads have low overhead and are frequently called lightweight processes.

7 Program Layout Command Line Arguments and Environment Variables Stack   Heap Un-initialized static data Initialized static data Program text  argc, argv, environment  Activation records for function calls (return address, parameters, saved registers, automatic variables)  allocations from malloc family

8 Activation Record Allocated at top of process stack Holds execution context (data) of a function call Removed from stack at end of function call Contains: –return address –stack management information –parameters –automatic variables

9 Static Variable Example Version 1: int myarray[5000] = {1,2,3,4}; void main(int argc, char *argv[]) { myarray[0] = 3; } Version 2: int myarray[5000]; void main(int argc, char *argv[]) { myarray[0] = 3; Do an ls –l after compiling both versions. If integer is 4 bytes, version 1 executable is roughly 20,000 bytes larger.

10 Static Variables and Thread Safe Static variables can make a program unsafe for threaded execution. Readdir uses a static variable to hold return values. This strategy is also used for client/server stubs when marshaling/un-marshaling arguments for remote procedure calls. Therefore, avoid static variables in a threaded environment wherever possible.

11 Safe Functions Thread-Safe – Can be invoked concurrently or by multiple threads. Async-Signal-Safe – Can be called without restriction from a signal handler. These terms replace the older notion of reentrant function.

12 Function Errors Many functions return –1 on error and set external parameter errno to appropriate error code Include errno.h in order to access the symbolic names associated with errno Use errno only immediately after an error is generated

13 close Example SYNOPSIS #include int close(int filedes); POSIX Returns 0 if successful or –1 if unsuccessful and sets errno errnocause EBADF EINTR fildes is not valid close was interrupted by a signal

14 perror Outputs message string to standard error followed by the error message from the last system or library call that produced an error Place perror immediately after the occurrence of an error SYNOPSIS #include void perror(const char *s) POSIX:CX

15 close Example with perror #include int filedes; if (close(filedes) == –1) perror (“Failed to close the file”);

16 perror Example #include #include #include #include int fd; void main(void) { int fd; if ((fd = open("my.file", O_RDONLY)) == -1) perror("Unsuccessful open of my.file"); }

17 errno Test errno only if a function call returns an error errno can be set to various values depending on the function it is used with For example, when used with the function open, the value EAGAIN indicates the file is locked

18 perror/errno Example #include #include #include #include #include int fd; void main(void) { int fd; while (((fd = open("my.file", O_RDONLY)) == -1) && (errno == EAGAIN)) ; if (fd == -1) perror("Unsuccessful open of my.file"); }

19 strerror Use strerror instead of perror to format a message that contains variable values The message output depends on the value of errno

20 strerror Example #include … void main(int argc, char *argv[]) { int fd; if ((fd = open(argv[1], O_RDONLY)) == -1) fprintf(stderr, "Could not open file %s: %s\n", argv[1], strerror(errno)); }

21 Suggestions Make use of return values Do not exit early from functions – use error value from function instead Make functions general but usable (conflict?) Do not assume buffer sizes Use standard system defined limits rather than arbitrary constants Don’t re-invent the wheel Don’t modify input parameters unless necessary Don’t use static (global) variables if automatic (local) variables will do just as well Be sure to free memory allocated by malloc Consider recursive calls to functions Analyze consequences of interrupts Careful plan the termination of each program component

22 argv array for mine –c 10 2.0 Argv[] [0] [1] [2] [3] [4]NULL ‘m’‘i’‘n’‘e’‘/0’ ‘-’‘c’‘/0’ ‘1’‘0’‘/0’ ‘2’‘.’‘0’‘/0’

23 makeargv, first half #include … /* * Make argv array (*arvp) for tokens in s which are separated by * delimiters. Return -1 on error or the number of tokens otherwise. */ int makeargv(char *s, char *delimiters, char ***argvp) { char *t; char *snew; int numtokens; int i; /* snew is real start of string after skipping leading delimiters */ snew = s + strspn(s, delimiters); /* create space for a copy of snew in t */ if ((t = calloc(strlen(snew) + 1, sizeof(char))) == NULL) { *argvp = NULL; numtokens = -1; }

24 makeargv, second half } else { /* count the number of tokens in snew */ strcpy(t, snew); if (strtok(t, delimiters) == NULL) numtokens = 0; else for (numtokens = 1; strtok(NULL, delimiters) != NULL; numtokens++); /* create an argument array to contain ptrs to tokens */ if ((*argvp = calloc(numtokens + 1, sizeof(char *))) == NULL) { free(t); numtokens = -1; } else { /* insert pointers to tokens into the array */ if (numtokens > 0) { strcpy(t, snew); **argvp = strtok(t, delimiters); for (i = 1; i < numtokens + 1; i++) *((*argvp) + i) = strtok(NULL, delimiters); } else { **argvp = NULL; free(t); } } } return numtokens

25 argtest /* Program 1.1 */ #include #include int makeargv(char *s, char *delimiters, char ***argvp); void main(int argc, char *argv[]) { char **myargv; char delim[] = " \t"; int i; int numtokens; if (argc != 2) { fprintf(stderr, "Usage: %s string\n", argv[0]); exit(1); } if ((numtokens = makeargv(argv[1], delim, &myargv)) < 0) { fprintf(stderr, "Could not construct argument array for %s\n", argv[1]); exit(1); } else { printf("The argument array contains:\n"); for (i = 0; i < numtokens; i++) printf("[%d]:%s\n", i, myargv[i]); } exit(0); }

26 makeargv data structures ‘m’‘i’‘n’‘e’‘\0’‘-’‘c’‘\0’‘1’‘0’‘\0’‘2’‘.’‘0’‘\0’ NULL argvp t

27 strtok strtok is not thread safe: strtok(NULL, delimiters); strtok_r IS thread safe. It has a user-provided parameter that stores the position of the next call to strtok_r.

28 Thread Safe Functions A function is “thread safe” if it can be safely invoked by multiple threads

29 Show History listlib.h listlib.c keeplog.c keeploglib.c

30 Async-Signal Safe Functions A function is async-signal safe if that function can be called without restriction from a signal handler

31 read Not reentrant because error information is returned in external variable errno. If read returns –1, errno is set to the appropriate error.

32 Solutions to read Problem Have the read function return the error value as a function value Have the read function return the error value as a parameter. Implement errno as local to each thread (instead of as a global variable). Implement errno as a macro that invokes a function to get errno for the currently running thread. Change read so that it invokes a signal on error.

33 Process Termination Normal or abnormal. Cancel pending timers and signals Release virtual memory resources Release other process-held system resources such as locks Close open files

34 Zombies If a parent process is not waiting for a child when it finishes, the child cannot be terminated by its parent. We call these child processes zombies. Orphaned child processes become zombies when they terminate. System init process (process whose ID is 1) gets rid of orphaned zombies.

35 Normal Termination Return from main. Call to C function exit or atexit Call to _exit or _Exit system call. (note that C function exit calls user- defined exit handlers that usually provides extra cleanup before calling on _exit or _Exit).

36 exit and _exit Take an integer parameter status that indicates the status of the program. 0 normal termination. Programmer defined non-zero indicates error. At exit C function installs user-defined exit handler. Last-installed, first executed.

37 exit, _Exit, _exit Synopsis SYNOPSIS #include void exit (int status); void _Exit (int status);ISO C SYNOPSIS #include void _exit (int status);POSIX

38 atexit Synopsis SYNOPSIS #include <stdlib.h. int atexit (void (*func)(void));ISO C atexit installs a user-defined exit handler. If successful, atexit returns 0 and executes the handler function. If unsuccessful, atexit returns a non-zero value

39 Abnormal Termination Call abort. Process a signal that causes termination.

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