cs431-cotter1 linux process synchronization tanenbaum 10.3, 2.3 linux man pthread_mutex_init, etc....
TRANSCRIPT
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Linux Process Linux Process SynchronizationSynchronization
• Tanenbaum 10.3, 2.3• Linux man pthread_mutex_init, etc.
• The Linux Programming Interface - Kerrisk• Interprocess Communications in Linux - Gray
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Overview
• Linux IPC• Signal• Alarm• Wait• Semaphore (named and unnamed)• Mutex• Pipe ( named and unnamed)• Messages• Shared Memory
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Linux IPCLinux IPC
• Kernel Synchronization– Use wait_queue for kernel process sync– Allows multiple processes to wait for a single event– Serves as basic component to build user process sync
• Process synchronization– Signal - most primitive– Semaphore– Pipes– etc.
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Figure 10-5. The signals required by POSIX.
Signals in Linux
Tanenbaum, Modern Operating Systems 3 e, (c) 2008 Prentice-Hall, Inc. All rights reserved. 0-13-6006639
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SignalsSignals
1) SIGHUP 2) SIGINT 3) SIGQUIT 4) SIGILL
5) SIGTRAP 6) SIGABRT 7) SIGEMT 8) SIGFPE
9) SIGKILL 10) SIGBUS 11) SIGSEGV 12) SIGSYS
13) SIGPIPE 14) SIGALRM 15) SIGTERM 16) SIGURG
17) SIGSTOP 18) SIGTSTP 19) SIGCONT 20) SIGCHLD
21) SIGTTIN 22) SIGTTOU 23) SIGIO 24) SIGXCPU
25) SIGXFSZ 26) SIGVTALRM 27) SIGPROF 28) SIGWINCH
29) SIGINFO 30) SIGUSR1 31) SIGUSR2
Current versions of Linux support 64 signals (real time signals added).
See: man 2 signal, man 2 sigaction man 7 signal
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Signal Handler
• Signal function can have different behavior based on the version of UNIX.
• sigaction (signal_to_catch, new_action, old_action)• struct sigaction {
void * sa_handler; // What function do we call?
sigset_t mask; // Mask of signals to block when called
int sa_flags; // Special flags to set.
};
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AlarmAlarm
• Allows user program to set an external timer (measured in seconds).
• If alarm times out, sigalrm will be sent to the calling process.
• Use: sigaction (SIGALRM, sigaction, NULL);
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Sig_alarm.cpp#include <iostream>#include <signal.h>#include <stdlib.h>#include <string.h>using namespace std;
#define MAXLINE 128static void sig_alarm(int signo);
int main () {int n;char line [MAXLINE];struct sigaction act;memset (&act, 0, sizeof(act));act.sa_handler = &sig_alarm;act.sa_flags = SA_RESTART;
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Sig_alarm.cpp
if ((sigaction(SIGALRM, &act, NULL)) < 0) {cout <<"The sigact function returned an error" <<
endl; exit (1);}alarm (5);if ( cin.getline(line, MAXLINE) < 0) {
cout << "cin returned an error" << endl;exit(1);}alarm(0);cout << line << endl;exit(0);
}
static void sig_alarm(int signo) {cout << " ### We got the alarm signal!! ###" << endl;
}
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sig_alarm.cpp Outputsig_alarm.cpp Output
[rcotter@kc-sce-450p2 cs431]$ g++ -o sigtest sig_alarm3.cpp
[rcotter@kc-sce-450p2 cs431]$ ./sigtest
This is a test
This is a test
[rcotter@kc-sce-450p2 cs431]$ ./sigtest
This is another ### We got the alarm signal!! ###
test
This is another test
[rcotter@kc-sce-450p2 cs431]$
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wait( )wait( )#include <sys/types.h>
#include <sys/wait.h>
pid_t wait (int *status);
• The wait function suspends execution of the current pro cess until a child has exited, or until a signal is deliv ered whose action is to terminate the current process or to call a signal handling function. If a child has already exited by the time of the call (a so-called "zom bie" process), the function returns immediately. Any sys tem resources used by the child are freed.
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waittest1.cwaittest1.c#include <stdio.h>#include <stdlib.h>#include <string.h>#include <unistd.h>#include <sys/types.h>#include <sys/wait.h>
int main(){
pid_t pid;int status;
printf("Forking child process...\n");if ((pid = fork()) < 0){
printf("fork failed!\n");exit(1);
}
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waittest1.cwaittest1.celse if (pid == 0) { /* child process */
sleep(5);printf("Child process is shutting down\n");exit(7);
}else { /* parent process */
if (wait (&status) != pid) {printf("Wait returned invalid pid\n");exit(1);
}if (WIFEXITED(status))
printf("Normal Termination. Exit value %2d\n",WEXITSTATUS(status));
else {printf("Abnormal termination!!!\n");exit(1);
}printf("Parent shutting down...\n");exit(0);
}}
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waittest.c outputwaittest.c output
rcotter@debian-alpha:~$ gcc -o waittest waittest1.c
rcotter@debian-alpha:~$ ./waittest
Forking child process...
Child process is shutting down
Normal Termination. Exit value 7
Parent shutting down...
rcotter@debian-alpha:~$
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SemaphoresSemaphores
• POSIX version of semaphores– #include <semaphore.h>– classic semaphore implementation
• System V version of semaphores– #include <sys/sem.h>– Enhanced version of semaphores to include
sets
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POSIX (unnamed) SemaphoresPOSIX (unnamed) Semaphores
• sem_t empty, full;
• int sem_init ((sem_t *sem, int pshared, unsigned int value));– sem_t (address of semaphore to be initialized– pshared (is semaphore shared?) SHARED, 0– initial value
• int sem_wait ((sem_t *sem));– sem_t (address of semaphore to be waited for)
• int sem_post ((sem_t *sem));– sem_t (address of semaphore to be signalled)
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Example Semaphore fragmentExample Semaphore fragmentsem_t checker;
Main Program {declare variables...sem_init(&checker, 0, 1);pthread_create(&pid1, NULL, job, NULL);pthread_create(&pid2, NULL, job, NULL);pthread_join(pid1, NULL);pthread_join(pid2, NULL);:
}job() { while (work to do..) {
sem_wait (&checker);do stuff...sem_post(&checker);do other stuff....
}}
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POSIX Named Semaphores• sem_t empty, full; • sem_t *sem_open (char *name, int oflag, [mode_t mode[, [int init_value]);– char *name (must begin with “/”)– [O_CREAT], [O_EXCL], 0 (new or existing semaphore?)– mode (if new, mod bits 0xxx)– Init_value (if new, initial value of semaphore)
• int sem_wait ((sem_t *sem));– sem_t (address of semaphore to be waited for)
• int sem_post ((sem_t *sem));– sem_t (address of semaphore to be signalled)
• int sem_close (sem_t *sem);• int sem_unlink(char *name);• int sem_getvalue (sem_t *sem, int *val);• Named semaphore has kernel persistence
– Created in /dev/shm
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Named Semaphore exampleproducer - Consumer
#define SHARED 0#define BUFSIZE 20
int terminatethreads=0;
void *Producer(void *); /* the two threads */void *Consumer(void *);
sem_t *Sempty, *Sfull, *Sflag; /* the semaphore descriptors */char sem1[] = "/semEmpty"; //The names for the semaphoreschar sem2[] = "/semFull";char sem3[] = "/semFlag";int buf[BUFSIZE]; /* shared buffer */int mycount;
static void sig_alarm(int signo);
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Named Semaphore exampleint main(int argc, char *argv[]) { int ans; time_t now; pthread_t pid, cid; time (&now); srand (now); if (signal (SIGALRM, sig_alarm) == SIG_ERR) {
cout << "The signal function returned an error" << endl;exit (1);
} //Here we set the alarm to specified seconds. alarm (atoi(argv[1])); cout << “Alarm set. Now for semaphores" << endl;
Sflag = sem_open (sem3, O_CREAT, 660, 1); Sfull = sem_open (sem2, O_CREAT, 660, 0); Sempty = sem_open (sem1, O_CREAT, 660, BUFSIZE); mycount = 0;
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Named Semaphore example cout << "main started" << endl; pthread_create(&pid, 0, Producer, NULL); pthread_create(&cid, 0, Consumer, NULL); cout << "Created both threads" << endl; pthread_join(pid, NULL); pthread_join(cid, NULL); cout << "The number of items still in the buffer is " << mycount << endl; sem_getvalue(Sfull, &ans); cout << “The value of Sfull is “ << ans << endl; sem_close(Sflag); sem_close(Sfull); sem_close(Sempty); sem_unlink(sem1); sem_unlink(sem2); sem_unlink(sem3); cout << "Main done\n" << endl; return 0;}
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Named Semaphore examplevoid *Producer(void *arg) { int produced=0; int input = 0; cout << "\nProducer created.." << endl; while(!terminatethreads) { sem_wait(Sempty); //Decrements 'empty'
produced++;input = (input + 1) % BUFSIZE;
sem_wait(Sflag); buf[input] = produced; mycount++; sem_post (Sflag);
cout << "Producing widget # " << produced << " in buffer # " << input << endl;
sem_post(Sfull);//increments full , tell consumer that it can consume nowusleep(rand () %997);
} return &buf[0];}
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Named Semaphore examplevoid *Consumer(void *arg) { int consumed= 0; cout << "\nConsumer created.." << endl; while(!terminatethreads) {
sem_wait(Sfull);consumed = (consumed + 1) % BUFSIZE;sem_wait(Sflag);mycount--;sem_post(Sflag);
cout << "Consuming widget # " << buf[consumed] << " in buffer # " << consumed << endl;sem_post(Sempty);usleep(rand () %1003);
} return &buf[0];}
static void sig_alarm(int signo) { cout << "\nWe got the Signal Alarm, Terminating the threads...\n"<< endl;
terminatethreads=1; return;}
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Figure 2-30. Some of the Pthreads calls relating to mutexes.
Mutexes in Pthreads (1)
Tanenbaum, Modern Operating Systems 3 e, (c) 2008 Prentice-Hall, Inc. All rights reserved. 0-13-6006639
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Figure 2-31. Some of the Pthreads calls relating to condition variables.
Mutexes in Pthreads (2)
Tanenbaum, Modern Operating Systems 3 e, (c) 2008 Prentice-Hall, Inc. All rights reserved. 0-13-6006639
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Figure 2-32. Using threads to solve
the producer-consumer problem.
Mutexes in Pthreads (3)
Tanenbaum, Modern Operating Systems 3 e, (c) 2008 Prentice-Hall, Inc. All rights reserved. 0-13-6006639
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Linux Interprocess Communications
• Unnamed Pipes
• Named Pipes
• Message Queues
• Shared Memory
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Unnamed pipes (pipes)Unnamed pipes (pipes)
• Allow communications between related processes.
• Unidirectional• Used from command line to link commands
– ls -l | more– cat -n myfile.cpp | lpr
• Used in programs to communicate between processes– pipetest.cpp
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Pipe CommandsPipe Commands
• popen – FILE * popen (const char* cmd, const char *
type);– type = “r”, “w”
• pclose – int pclose (FILE * stream);
• #include <stdio.h>
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Named PipesNamed Pipes
• Permanent objects
• Available to processes that can access the filespace (same system or on a shared file system)
• Processes do not have to be related.
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Named Pipes (FIFO)Named Pipes (FIFO)
• int mkfifo(const char *name, mode_t mode);– return is a file descriptor– name is the name of the pipe– mode is the permissions for the pipe (0666 = RDWR
all)
• int open(const char * name, int flags);– flags = O_RDONLY, O_WRONLY, O_RDWR
• ssize_t read(int fd, void *buf, size_t count);
• ssize_t write(int fd, void *buf, size_t count);
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Message Queues
• A “linked list of messages”• Message queue has kernel persistence
– Supports asynchronous communications.– Messages are stored in the queue, independent of the
sender (sender can close queue without losing messages).
– Receiver can retrieve messages at a later time.
• Messages have a priority– Higher priority messages are retrieved first (POSIX)– Max priority is 32768
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Message Queues
• Message Queue Capacity– (Can be set higher by root)– Max msgs: 10 /queue– Max Msg Size: 8192– Max # of Queues: 256
• Queues are created in their own virtual message queue file system (mqueue)– Can be mounted to view (and manipulate) queues– mkdir /dev/mqueue– mount –t mqueue none /dev/mqueue
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Create and/or open a msg queue
• mqd_t mq_open (qName, flags, [mode], [attributes]);– qName: Name of the queue to open / create
• Must be of the form “/qName”.
– flags: How queue will be opened/created.• O_RDONLY | O_WRONLY | O_RDWR , [O_CREAT] )
– mode: File permissions for queue:• S_IRUSR, S_IWUSR, S_IRGRP, S_IWGRP, S_IROTH, S_IWOTH
– attributes: Limits for the queue: struct mq_attr• long mq_flags: 0 | O_NONBLOCK (read queue non-blocking?)• long mq_maxmsg: max msgs in queue• long mq_msgsize: max msg size• long mq_curmsgs: How many messages are currently in queue?
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Send a message to a queue• mqd_t mq_send (queue_descr, msg, size, prior);
– Queue_descr: Like a file descriptor. Value returned from mq_open.
– Msg: a pointer to a character buffer for the message– Size: (size_t) size of message in bytes– Prior: (unsigned int) priority of message
– Returns 0 on success, -1 on error
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Receive a message from a queue
• ssize_t mq_receive (queue_descr, msg, size, prior);– Queue_descr: Like a file descriptor. Value returned from
mq_open.– Msg: a pointer to a character buffer for the message– Size: (size_t) size of buffer in bytes– Prior: (*unsigned int) priority of message read.
– Returns number of bytes read (or -1 on error)
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Get attributes of a Queue• mqd_t mq_getattr (queue_descr, *struct
mq_attr);– Queue_descr: Like a file descriptor. Value returned
from mq_open.– *struct mq_attr: Pointer to struct that will return
attributes of the opened queue• long mq_flags: 0 | O_NONBLOCK (read queue non-
blocking?)• long mq_maxmsg: max msgs in queue• long mq_msgsize: max msg size• long mq_curmsgs: How many messages are currently in
queue?
– Returns 0 on success, -1 on error
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Removing (unlinking) a queue
• Mqd_t mq_unlink ( qName);– qName: Name of queue
• Queue is removed from the message queue file system. Any messages still in the queue are lost.
• Returns 0 on success, -1 on error
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mq_send(Note: All error checking has been removed from the code
to focus on the details of message queue handling)
#include <mqueue.h> (also many other included header files…)#define NAMESIZE 25#define MSGCOUNT 5#define MSGSIZE 512using namespace std;int main (int argc, char **argv) { int lSize, bufSize, stat, i; char qName[NAMESIZE]; char ans[5]; mqd_t mqd; struct mq_attr qAtr; unsigned int prio = 3; char buf[MSGSIZE];
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mq_send - 2 strncpy(qName, "/", 2);
strncat (qName, argv[1], lSize+1);
qAtr.mq_maxmsg = MSGCOUNT;
qAtr.mq_msgsize = MSGSIZE;
mqd = mq_open(qName, O_RDWR | O_CREAT, S_IRUSR | S_IWUSR | S_IROTH | S_IWOTH, &qAtr);
do {
cout << "What message do you want to send? ";
cin.getline(buf, 80);
bufSize = strlen(buf);
cout << "What is the message priority? ";
cin >> prio;
stat = mq_send(mqd, buf, bufSize, prio);
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mq_send - 3 if (stat == 0) cout << "Send was successful" << endl; else exit(0); cout << "Send another message (yes/no)?"; cin >> ans; cin.ignore(); for (i = 0; i < 80; i++)
buf[i] = 0; }while (ans[0] =='y');
mq_close(mqd); return 0;}
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mq_recv - 1Note: Most of the error checking code has been removed to focus on
the message queue portions of the code.
#include <mqueue.h> also many other #include files…
#define NAMESIZE 25
#define MSGCOUNT 25
#define MSGSIZE 512
#define BUFSIZE 9000
using namespace std;
int main (int argc, char **argv){
int lSize, bufSize, stat, msgcount, i, j;
char qName[NAMESIZE];
mqd_t mqd; struct mq_attr qAtr;
unsigned int prio = 3;
char buf[BUFSIZE];
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mq_recv - 2 strncpy(qName, "/", 2); strncat (qName, argv[1], lSize+1); mqd = mq_open(qName, O_RDONLY); mq_getattr(mqd, &qAtr); msgcount = qAtr.mq_curmsgs; cout << "There are currently " << msgcount << " messages in queue" << endl; for (i= 0; i < msgcount; i++) { stat = mq_receive(mqd, buf, BUFSIZE, &prio); if (stat >= 0) cout << "msg: " << buf << "; Prio: " << prio << endl; else cout << "Oops! Stat = " << stat << endl; for (j = 0; j < 80; j++)
buf[j] = 0; }//end of for loop mq_close(mqd); mq_unlink(qName); //delete the message queue return 0;}
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Sample send Output[rcotter@kc-sce-450p2 msgQ]$ ./mq_send nuQMessage Queue name (/nuQ) is 4 charactersWe opened the queue!What message do you want to send? This is my first test messageWhat is the message priority? 2Send was successfulSend another message (yes/no)?yesWhat message do you want to send? This is my second test messageWhat is the message priority? 4Send was successfulSend another message (yes/no)?yesWhat message do you want to send? This is my third test messageWhat is the message priority? 1Send was successfulSend another message (yes/no)?no[rcotter@kc-sce-450p2 msgQ]$
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Sample recv Output
[rcotter@kc-sce-450p2 msgQ]$ ./mq_recv nuQFile name (/nuQ) is 4 charactersWe opened the queue!There are currently 3 messages in queuemsg: This is my second test message; Prio: 4msg: This is my first test message; Prio: 2msg: This is my third test message; Prio: 1[rcotter@kc-sce-450p2 msgQ]$
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Shared Memory
• Allows 2 or more processes to share the same main memory space– Memory can be allocated as blocks (pages) of
memory– Memory can be mapped as a file that is available in
memory to multiple processes
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Shared Memory
P1
P2
P3
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Shared Memory
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Shared Memory Usage
• Create a shared memory segment• One or more processes attach to it• Processes read and/or write to the segment.
Note that process sync is critical.• All processes detach from shared memory• One process removes (de-allocates) the
segment
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Create a Shared Memory Segment• Requires: <sys/ipc/h>, <sys/shm.h>• int shmget (key_t, int size, int shmflg);
– Key_t:• Shared memory segment number identifier (e.g. 15, 1000). Can be
used to create a new segment or ensure that an existing segment still exists.
• IPC_PRIVATE- special variable that guarantees that a new segment will be created
– Size:• Size of the memory segment. Should be a multiple of th ememory
page size (typically 4096 in Linux).
– Shmflg:• Flags that control behavior of the new segment. • IPC_CREAT, IPC_EXCL, mode bits(9)
– Return (int)• Shared memory ID – used to access or modify the shared memory
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Shared Memory Segment Limitsipcs -l
• Maximum segment size– SHMMAX 32768 kbytes
• Minimum segment size– SHMMIN 1 byte
• Total maximum # of segments– SHMMNI 4096
• Total maximum shared memory– SHMALL 8388608 kbytes
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Control Shared Memory
• int shmctl (shmid, cmd, struct shmid_ds *buf);– shmid: Shared memory identifier. (Value returned from
shmget())– cmd:
• IPC_STAT – return status information about the shared memory in buf.
• IPC_SET – modify the shared memory based on parameters in buf (can only change UID and mode bits)
• IPC_RMID – Remove (deallocate) the shared memory segment specified in shmid.
• IPC_LOCK – lock the shared memory segment in memory (don’t swap out).
• IPC_UNLOCK –release the lock on shared memory
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Attach to a Shared Memory Segment
• void * shmat (shmid, shmaddr, shmflg);– shmid: Shared memory identifier. (Value returned from shmget())
– shmaddr: Address where shared memory should attach to process.• If 0, OS picks a suitable address• If not 0 and SHM_RND flag is set, bind address will be given address,
rounded down to a page boundary• If not 0 and SHM_RND is not set, address must be a page boundary
– shmflg: • SHM_RND – round down the attach address to a page boundary• SHM_RDONLY – open for read only. Process must have read access to the
segment
– Return value: Address at which the shared memory is mapped.
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Detach from Shared Memory Segment
• int shmdt (shmaddr);– shmaddr – address at which shared memory is
attached– return 0 for success, -1 for fail
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Shared Memory Example#include <iostream>, etc…#define SHM_SIZE 2048#define ARRAYSIZE 50#define LOOPCOUNT 1000000#define PCOUNT 3
using namespace std;
int main( ) { int shmid, i, j, k, sum, *shm, *myNum;
int pid, procNum, n1, n2; int myNumbers[ARRAYSIZE]; int s[3]; //seeds for rand();
char sem1[] = “/semBlock”;sem_t *Scount;for (i = 0; i < ARRAYSIZE; i++) //Fill array with 0-49. Sum = 1225 myNumbers[i] = i;
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Shared Memory Exampleif ((shmid=shmget(IPC_PRIVATE,SHM_SIZE,IPC_CREAT|0660))< 0) {
perror("shmget fail"); return 1; } if ((shm = (int *)shmat(shmid, 0, 0)) == (int *) -1) { perror("shmat : parent"); return 2; } cout << "Shared memory is at: " << hex << shm << dec << endl; myNum = shm; // myNum now references shared mem //Now we need to copy our array of numbers into shared memory memcpy (myNum, &myNumbers, sizeof(myNumbers)); sum = 0; for (i = 0; i < ARRAYSIZE; i++) {
cout << myNum[i] << " , ";sum += myNum[i];
} cout << "\nThe sum of all values is " << sum << endl; cout << "In parent before fork, memory is: " << shm << endl; Scount = sem_open(sem1, O_CREAT, 0666, 1); sem_close (Scount);
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Shared Memory Examplefor (i = 0; i < PCOUNT; i++) {
if ((pid = fork()) < 0) //fork failed { cout << "Fork failed!!" << endl;return 2;
} else if (pid == 0) //We're in the child {
srand(s[i]); // seed the random number generatorprocNum = i;Scount = sem_open(sem1, 0);cout << "In child " << procNum << " memory is: " << shm << endl;for (j = 0; j < LOOPCOUNT; j++) {
n1 = (rand() % 50);n2 = (rand() %50);sem_wait (Scount);myNum[n1]+= 1;myNum[n2] -= 1;sem_post (Scount);
}//end of for ...sem_close(Scount);return 0; //child is done.
} //end of if pid == 0 else //We're in the parent {
cout << "We just created child " << i << " with pid " << pid << endl;}//end of for ---PCOUNT
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Shared Memory Example
//The parent now needs to wait for the children (at least 1) to finishwait(0);cout << "In parent after fork, memory is : " << shm << endl;sum = 0;for (i = 0; i < ARRAYSIZE; i++) {
cout << myNum[i] << " , ";sum += myNum[i];
}cout << "\nThe sum of the array is now " << sum << endl;cout << "\nParent removing shared memory" << endl;sem_unlink(sem1);shmdt(shm);shmctl (shmid, IPC_RMID, (struct shmid_ds *) 0);return 0;
}
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Shared Memory Example – W/ Sync
rcotter@kc-sce-450p2 shmem]$ ./sharedmem_sShared memory is at: 0xb78ed0000 , 1 , 2 , 3 , 4 , 5 , 6 , 7 , 8 , 9 , 10 , 11 , 12 , 13 , 14 , 15 , 16 , 17 , 18 , 19 , 20 , 21 , 22 , 23 , 24 , 25 , 26 , 27 , 28 , 29 , 30 , 31 , 32 , 33 , 34 , 35 , 36 , 37 , 38 , 39 , 40 , 41 , 42 , 43 , 44 , 45 , 46 , 47 , 48 , 49 ,The sum of all values is 1225In parent before fork, memory is: 0xb78ed000We just created child 0 with pid 18745In child 0 memory is: 0xb78ed000We just created child 1 with pid 18746The sum for child 0 is 1225In child 2 memory is: 0xb78ed000The sum for child 2 is 1225We just created child 2 with pid 18747In child 1 memory is: 0xb78ed000The sum for child 1 is 1225:The sum for child 2 is 1225Child 0 just did 1000000 loopsChild 18745 just terminatedThe sum for child 1 is 1225:Child 1 just did 1000000 loopsChild 18746 just terminatedThe sum for child 2 is 1225:Child 2 just did 1000000 loopsChild 18747 just terminatedIn parent after fork, memory is : 0xb78ed000167 , 425 , 83 , 320 , 162 , -387 , -120 , -236 , 712 , 548 , 136 , -391 , -82 , 561 , -362 , -115 , 555 , 7 , -169 , -492 , -459 , 113 , -58 , 19 , 130 , -581 , 266 , 36 , 524 , -272 , -393 , -119 , -65 , 24 , 495 , 367 , -315 , -225 , -146 , 515 , -173 , 321 , -91 , -60 , 69 , -111 , 6 , 468 , -56 , -326 ,The sum of the array is now 1225
Parent removing shared memory[rcotter@kc-sce-450p2 shmem]$
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Shared Memory Example – W/O Sync
[rcotter@kc-sce-450p2 shmem]$ ./sharedmemShared memory is at: 0xb77cb0000 , 1 , 2 , 3 , 4 , 5 , 6 , 7 , 8 , 9 , 10 , 11 , 12 , 13 , 14 , 15 , 16 , 17 , 18 , 19 , 20 , 21 , 22 , 23 , 24 , 25 , 26 , 27 , 28 , 29 , 30 , 31 , 32 , 33 , 34 , 35 , 36 , 37 , 38 , 39 , 40 , 41 , 42 , 43 , 44 , 45 , 46 , 47 , 48 , 49 ,The sum of all values is 1225In parent before fork, memory is: 0xb77cb000We just created child 0 with pid 18681We just created child 1 with pid 18682We just created child 2 with pid 18683In child 2 memory is: 0xb77cb000The sum for child 2 is 1225In child 0 memory is: 0xb77cb000The sum for child 0 is 1226In child 1 memory is: 0xb77cb000The sum for child 1 is 1222The sum for child 0 is 1221:Child 18681 just terminated.The sum for child 2 is 343The sum for child 1 is 343:Child 18683 just terminated.The sum for child 1 is 290:Child 18682 just terminated.In parent after fork, memory is : 0xb77cb000-204 , -443 , -85 , -339 , -178 , 390 , 101 , 232 , -717 , -548 , -116 , 384 , 102 , -533 , 365 , 123 , -537 , 52 , 217 , 497 , 485 , -101 , 100 , -4 , -99 , 619 , -216 , 6 , -500 , 316 , 432 , 152 , 98 , 29 , -433 , -333 , 368 , 289 , 187 , -461 , 232 , -257 , 152 , 130 , 4 , 175 , 30 , -386 , 121 , 392 ,The sum of the array is now 290Each process ran through 1000000 iterationsParent removing shared memory[rcotter@kc-sce-450p2 shmem]$
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SummarySummary• Several different sync mechanisms available in
Linux– Signal– Wait – Mutex– Semaphore
• Several different IPC mechanisms– Pipes– Message queues– Shared Memory
• Linux specifications consistent with POSIX
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QuestionsQuestions• What is a signal handler table? Where is it located? How is it used
by a process to handle signals sent to the process? • How do you set up a program (process) to provide customized
handling of a signal? (What code is needed to replace the default signal handler with our own signal handling routine?
• What function would a parent process use to capture the exit code of a terminated child process? If the parent process creates multiple child processes, how could it wait for one specific child process to terminate?
• If two processes want to pass information using an named pipe, what must the relationship be between those processes (no relation required, parent and child, children of the same parent, processes in the same system, etc.)
• What functions (system calls) would be needed to create and initialize a semaphore in Linux? What functions are needed to actually use the semaphore in your program?