start multiple processes parallelly - c

I have an array of processes, and I have to implement all of them parallelly. As the number of processes depends on the size of the array, how do I carry out this question? I'm assuming I have to use fork() or threads but I am not sure how. And how do I return immediately after the process has been carried out? Thanks!

First let's get a few things straight:
fork() is on POSIX systems the system call to split one process into two. The child process will be indicated by a return code of 0, and the parent by The Pid of the child (returning immediately while the child may be created/executing/dying). Aside from that, the two are essentially identical, which means the child needs to carry out the specific sub-processing (usually by means of execve()ing) another binary), while the parent wait4()s the child. Another option is to not wait4(), but instead listen for SIGCHLD, sent when the child terminates.
Multiple threads all happen in the same process. Meaning that the sub processing is carried out by code blocks/functions in the same address space.
It's not clear from your question - so - If your array of processes is essentially an array of command lines, you use fork() and execve(), above. If it's an array of functions, use threads.

Related

Are my fork processes running parallel or executing one after another?

I am just going to post pseudo code,
but my question is I have a loop like such
for(i<n){
createfork();
if(child)
/*
Exit so I can control exact amount of forks
without children creating more children
*/
exit
}
void createfork(){
fork
//execute other methods
}
Does my fork create a process do what it is suppose to do and exit then create another process and repeat? And if so what are some ways around this, to get the processes running concurrently?
Your pseudocode is correct as written and does not need to be modified.
The processes are already executing in parallel, all six of them or however many you spawn. As written, the parent process does not wait for the children to finish before spawning more children. It calls fork(), checks if (child) (which is skipped), then immediately proceeds to the next for loop iteration and forks again.
Notably, there's no wait() call. If the parent were to call wait() or waitpid() to wait for each child to finish then that would introduce the serialism you're trying to avoid. But there is no such call, so you're good.
When a process successfully performs a POSIX fork(), that process and the new child process are initially both eligible to run. In that sense, they will run concurrently until one or the other blocks. Whether there will be any periods of time when both are executing machine instructions (on different processing units) depends at least on details of hardware capabilities, OS scheduling, the work each process is performing, and what other processes there are in the system and what they are doing.
The parent certainly does not, in general, automatically wait for the child to terminate before it proceeds with its own work (there is a family of functions to make it wait when you want that), nor does the child process automatically wait for any kind of signal from the parent. If the next thing the parent does is fork another child, then that will under many circumstances result in the parent running concurrently with both (all) children, in the sense described above.
I cannot speak to specifics of the behavior of your pseudocode, because it's pseudocode.

Forked processes order of execution

I know there's another thread with the same name, but this is actually a different question.
When a process forks multiple times, does the parent finish executing before the children? Vice versa? Concurrently?
Here's an example. Lets say I have a for loop that forks 1 parent process into 4 children. At the end of that for loop, I want the parent process to feed some data to the children via pipes. The data is written to each child process' respective stdin.
Will the parent send the data first, before any of the children execute their code? This is important, because we don't want it to start working from an invalid stdin.
The order of the execution is determined by the specific OS scheduling policy and not guaranteed by anything. In order to synchronize the processes there are special facilities for the inter-process communication (IPC) which are designed for this purpose. The mentioned pipes are one example. They make the reading process to actually wait for the other process to write it, creating a (one-way) synchronization point. The other examples would be FIFOs and sockets. For simpler tasks the wait() family of functions or signals can be used.
When a process forks multiple times, does the parent finish executing before the children? Vice versa? Concurrently? -
Concurrently and depends on the scheduler and its unpredictable.
Using pipe to pass integer values between parent and child
This link explains in detail about sharing data between parent process and child.
Since you have four child process you may need to create different individual pipes between each child process.
Each byte of data written to a pipe will be read exactly once. It isn't duplicated to every process with the read end of the pipe open.
Multiple child processes reading/writing on the same pipe
Alternatively you can try shared memory for the data transfer.
They will execute concurrently. This is basically the point of processes.
Look into mutexes or other ways to deal with concurrency.

How does fork() know when to return 0?

Take the following example:
int main(void)
{
pid_t pid;
pid = fork();
if (pid == 0)
ChildProcess();
else
ParentProcess();
}
So correct me if I am wrong, once fork() executes a child process is created. Now going by this answer fork() returns twice. That is once for the parent process and once for the child process.
Which means that two separate processes come into existence DURING the fork call and not after it ending.
Now I don't get it how it understands how to return 0 for the child process and the correct PID for the parent process.
This where it gets really confusing. This answer states that fork() works by copying the context information of the process and manually setting the return value to 0.
First am I right in saying that the return to any function is placed in a single register? Since in a single processor environment a process can call only one subroutine that returns only one value (correct me if I am wrong here).
Let's say I call a function foo() inside a routine and that function returns a value, that value will be stored in a register say BAR. Each time a function wants to return a value it will use a particular processor register. So if I am able to manually change the return value in the process block I am able to change the value returned to the function right?
So am I correct in thinking that is how fork() works?
How it works is largely irrelevant - as a developer working at a certain level (ie, coding to the UNIX APIs), you really only need to know that it works.
Having said that however, and recognising that curiosity or a need to understand at some depth is generally a good trait to have, there are any number of ways that this could be done.
First off, your contention that a function can only return one value is correct as far as it goes but you need to remember that, after the process split, there are actually two instances of the function running, one in each process. They're mostly independent of each other and can follow different code paths. The following diagram may help in understanding this:
Process 314159 | Process 271828
-------------- | --------------
runs for a bit |
calls fork |
| comes into existence
returns 271828 | returns 0
You can hopefully see there that a single instance of fork can only return one value (as per any other C function) but there are actually multiple instances running, which is why it's said to return multiple values in the documentation.
Here's one possibility on how it could work.
When the fork() function starts running, it stores the current process ID (PID).
Then, when it comes time to return, if the PID is the same as that stored, it's the parent. Otherwise it's the child. Pseudo-code follows:
def fork():
saved_pid = getpid()
# Magic here, returns PID of other process or -1 on failure.
other_pid = split_proc_into_two();
if other_pid == -1: # fork failed -> return -1
return -1
if saved_pid == getpid(): # pid same, parent -> return child PID
return other_pid
return 0 # pid changed, child, return zero
Note that there's a lot of magic in the split_proc_into_two() call and it almost certainly won't work that way at all under the covers(a). It's just to illustrate the concepts around it, which is basically:
get the original PID before the split, which will remain identical for both processes after they split.
do the split.
get the current PID after the split, which will be different in the two processes.
You may also want to take a look at this answer, it explains the fork/exec philosophy.
(a) It's almost certainly more complex than I've explained. For example, in MINIX, the call to fork ends up running in the kernel, which has access to the entire process tree.
It simply copies the parent process structure into a free slot for the child, along the lines of:
sptr = (char *) proc_addr (k1); // parent pointer
chld = (char *) proc_addr (k2); // child pointer
dptr = chld;
bytes = sizeof (struct proc); // bytes to copy
while (bytes--) // copy the structure
*dptr++ = *sptr++;
Then it makes slight modifications to the child structure to ensure it will be suitable, including the line:
chld->p_reg[RET_REG] = 0; // make sure child receives zero
So, basically identical to the scheme I posited, but using data modifications rather than code path selection to decide what to return to the caller - in other words, you'd see something like:
return rpc->p_reg[RET_REG];
at the end of fork() so that the correct value gets returned depending on whether it's the parent or child process.
In Linux fork() happens in kernel; the actual place is the _do_fork here. Simplified, the fork() system call could be something like
pid_t sys_fork() {
pid_t child = create_child_copy();
wait_for_child_to_start();
return child;
}
So in the kernel, fork() really returns once, into the parent process. However the kernel also creates the child process as a copy of the parent process; but instead of returning from an ordinary function, it would synthetically create a new kernel stack for the newly created thread of the child process; and then context-switch to that thread (and process); as the newly created process returns from the context switching function, it would make the child process' thread end up returning to user mode with 0 as the return value from fork().
Basically fork() in userland is just a thin wrapper returns the value that the kernel put onto its stack/into return register. The kernel sets up the new child process so that it returns 0 via this mechanism from its only thread; and the child pid is returned in the parent system call as any other return value from any system call such as read(2) would be.
You first need to know how multitasking works. It is not useful to understand all the details, but every process runs in some kind of a virtual machine controlled by the kernel: a process has its own memory, processor and registers, etc. There is mapping of these virtual objects onto the real ones (the magic is in the kernel), and there is some machinery that swap virtual contexts (processes) to physical machine as time pass.
Then, when the kernel forks a process (fork() is an entry to the kernel), and creates a copy of almost everything in the parent process to the child process, it is able to modify everything needed. One of these is the modification of the corresponding structures to return 0 for the child and the pid of the child in the parent from current call to fork.
Note: nether say "fork returns twice", a function call returns only once.
Just think about a cloning machine: you enter alone, but two persons exit, one is you and the other is your clone (very slightly different); while cloning the machine is able to set a name different than yours to the clone.
The fork system call creates a new process and copies a lot of state from the parent process. Things like the file descriptor table gets copied, the memory mappings and their contents, etc. That state is inside the kernel.
One of the things the kernel keeps track for every process are the values of registers this process needs to have restored at the return from a system call, trap, interrupt or context switch (most context switches happen on system calls or interrupts). Those registers are saved on a syscall/trap/interrupt and then restored when returning to userland. System calls return values by writing into that state. Which is what fork does. Parent fork gets one value, child process a different one.
Since the forked process is different from the parent process, the kernel could do anything to it. Give it any values in registers, give it any memory mappings. To actually make sure that almost everything except the return value is the same as in the parent process requires more effort.
For each running process, the kernel has a table of registers, to load back when a context switch is made. fork() is a system call; a special call that, when made, the process gets a context switch and the kernel code executing the call runs in a different (kernel) thread.
The value returned by system calls is placed in a special register (EAX in x86) that your application reads after the call. When the fork() call is made, the kernel makes a copy of the process, and in each table of registers of each process descriptor writes the appropiate value: 0, and the pid.

fork() in C; which should be parent process which should be child process

This may seem to be a dumb question but I don't really have a good understanding of fork() other than knowing that this is about multi-threading. Child process is like a thread. If a task needs to be processed via fork(), how to correctly assign tasks to parent process and child process?
Check the return value of fork. The child process will receive the value of 0. The parent will receive the value of the process id of the child.
Read Advanced Linux Programming which has an entire chapter dedicated to processes (because fork is difficult to explain);
then read documentation of fork(2); fork is not about multi-threading, but about creating processes. Threads are generally created with pthread_create(3) (which is implemented above clone(2), a Linux specific syscall). Read some pthreads tutorial to learn more about threads.
PS. fork is difficult to understand (you'll need hours of reading, some experimentation, perhaps using strace(1), till you reach the "AhAh" insight moment when you have understood it) since it returns twice on success. You need to keep its result, and you need to test the result for the three cases : <0 (failure), ==0 (child), >0 (parent). Don't forget to later call waitpid(2) (or something similar) in the parent, to avoid having zombie processes.

What is the purpose of fork()?

In many programs and man pages of Linux, I have seen code using fork(). Why do we need to use fork() and what is its purpose?
fork() is how you create new processes in Unix. When you call fork, you're creating a copy of your own process that has its own address space. This allows multiple tasks to run independently of one another as though they each had the full memory of the machine to themselves.
Here are some example usages of fork:
Your shell uses fork to run the programs you invoke from the command line.
Web servers like apache use fork to create multiple server processes, each of which handles requests in its own address space. If one dies or leaks memory, others are unaffected, so it functions as a mechanism for fault tolerance.
Google Chrome uses fork to handle each page within a separate process. This will prevent client-side code on one page from bringing your whole browser down.
fork is used to spawn processes in some parallel programs (like those written using MPI). Note this is different from using threads, which don't have their own address space and exist within a process.
Scripting languages use fork indirectly to start child processes. For example, every time you use a command like subprocess.Popen in Python, you fork a child process and read its output. This enables programs to work together.
Typical usage of fork in a shell might look something like this:
int child_process_id = fork();
if (child_process_id) {
// Fork returns a valid pid in the parent process. Parent executes this.
// wait for the child process to complete
waitpid(child_process_id, ...); // omitted extra args for brevity
// child process finished!
} else {
// Fork returns 0 in the child process. Child executes this.
// new argv array for the child process
const char *argv[] = {"arg1", "arg2", "arg3", NULL};
// now start executing some other program
exec("/path/to/a/program", argv);
}
The shell spawns a child process using exec and waits for it to complete, then continues with its own execution. Note that you don't have to use fork this way. You can always spawn off lots of child processes, as a parallel program might do, and each might run a program concurrently. Basically, any time you're creating new processes in a Unix system, you're using fork(). For the Windows equivalent, take a look at CreateProcess.
If you want more examples and a longer explanation, Wikipedia has a decent summary. And here are some slides here on how processes, threads, and concurrency work in modern operating systems.
fork() is how Unix create new processes. At the point you called fork(), your process is cloned, and two different processes continue the execution from there. One of them, the child, will have fork() return 0. The other, the parent, will have fork() return the PID (process ID) of the child.
For example, if you type the following in a shell, the shell program will call fork(), and then execute the command you passed (telnetd, in this case) in the child, while the parent will display the prompt again, as well as a message indicating the PID of the background process.
$ telnetd &
As for the reason you create new processes, that's how your operating system can do many things at the same time. It's why you can run a program and, while it is running, switch to another window and do something else.
fork() is used to create child process. When a fork() function is called, a new process will be spawned and the fork() function call will return a different value for the child and the parent.
If the return value is 0, you know you're the child process and if the return value is a number (which happens to be the child process id), you know you're the parent. (and if it's a negative number, the fork was failed and no child process was created)
http://www.yolinux.com/TUTORIALS/ForkExecProcesses.html
fork() is basically used to create a child process for the process in which you are calling this function. Whenever you call a fork(), it returns a zero for the child id.
pid=fork()
if pid==0
//this is the child process
else if pid!=0
//this is the parent process
by this you can provide different actions for the parent and the child and make use of multithreading feature.
fork() will create a new child process identical to the parent. So everything you run in the code after that will be run by both processes — very useful if you have for instance a server, and you want to handle multiple requests.
System call fork() is used to create processes. It takes no arguments and returns a process ID. The purpose of fork() is to create a new process, which becomes the child process of the caller. After a new child process is created, both processes will execute the next instruction following the fork() system call. Therefore, we have to distinguish the parent from the child. This can be done by testing the returned value of fork():
If fork() returns a negative value, the creation of a child process was unsuccessful.
fork() returns a zero to the newly created child process.
fork() returns a positive value, the process ID of the child process, to the parent. The returned process ID is of type pid_t defined in sys/types.h. Normally, the process ID is an integer. Moreover, a process can use function getpid() to retrieve the process ID assigned to this process.
Therefore, after the system call to fork(), a simple test can tell which process is the child. Please note that Unix will make an exact copy of the parent's address space and give it to the child. Therefore, the parent and child processes have separate address spaces.
Let us understand it with an example to make the above points clear. This example does not distinguish parent and the child processes.
#include <stdio.h>
#include <string.h>
#include <sys/types.h>
#define MAX_COUNT 200
#define BUF_SIZE 100
void main(void)
{
pid_t pid;
int i;
char buf[BUF_SIZE];
fork();
pid = getpid();
for (i = 1; i <= MAX_COUNT; i++) {
sprintf(buf, "This line is from pid %d, value = %d\n", pid, i);
write(1, buf, strlen(buf));
}
}
Suppose the above program executes up to the point of the call to fork().
If the call to fork() is executed successfully, Unix will make two identical copies of address spaces, one for the parent and the other for the child.
Both processes will start their execution at the next statement following the fork() call. In this case, both processes will start their execution at the assignment
pid = .....;
Both processes start their execution right after the system call fork(). Since both processes have identical but separate address spaces, those variables initialized before the fork() call have the same values in both address spaces. Since every process has its own address space, any modifications will be independent of the others. In other words, if the parent changes the value of its variable, the modification will only affect the variable in the parent process's address space. Other address spaces created by fork() calls will not be affected even though they have identical variable names.
What is the reason of using write rather than printf? It is because printf() is "buffered," meaning printf() will group the output of a process together. While buffering the output for the parent process, the child may also use printf to print out some information, which will also be buffered. As a result, since the output will not be send to screen immediately, you may not get the right order of the expected result. Worse, the output from the two processes may be mixed in strange ways. To overcome this problem, you may consider to use the "unbuffered" write.
If you run this program, you might see the following on the screen:
................
This line is from pid 3456, value 13
This line is from pid 3456, value 14
................
This line is from pid 3456, value 20
This line is from pid 4617, value 100
This line is from pid 4617, value 101
................
This line is from pid 3456, value 21
This line is from pid 3456, value 22
................
Process ID 3456 may be the one assigned to the parent or the child. Due to the fact that these processes are run concurrently, their output lines are intermixed in a rather unpredictable way. Moreover, the order of these lines are determined by the CPU scheduler. Hence, if you run this program again, you may get a totally different result.
You probably don't need to use fork in day-to-day programming if you are writing applications.
Even if you do want your program to start another program to do some task, there are other simpler interfaces which use fork behind the scenes, such as "system" in C and perl.
For example, if you wanted your application to launch another program such as bc to do some calculation for you, you might use 'system' to run it. System does a 'fork' to create a new process, then an 'exec' to turn that process into bc. Once bc completes, system returns control to your program.
You can also run other programs asynchronously, but I can't remember how.
If you are writing servers, shells, viruses or operating systems, you are more likely to want to use fork.
Multiprocessing is central to computing. For example, your IE or Firefox can create a process to download a file for you while you are still browsing the internet. Or, while you are printing out a document in a word processor, you can still look at different pages and still do some editing with it.
Fork creates new processes. Without fork you would have a unix system that could only run init.
Fork() is used to create new processes as every body has written.
Here is my code that creates processes in the form of binary tree.......It will ask to scan the number of levels upto which you want to create processes in binary tree
#include<unistd.h>
#include<fcntl.h>
#include<stdlib.h>
int main()
{
int t1,t2,p,i,n,ab;
p=getpid();
printf("enter the number of levels\n");fflush(stdout);
scanf("%d",&n);
printf("root %d\n",p);fflush(stdout);
for(i=1;i<n;i++)
{
t1=fork();
if(t1!=0)
t2=fork();
if(t1!=0 && t2!=0)
break;
printf("child pid %d parent pid %d\n",getpid(),getppid());fflush(stdout);
}
waitpid(t1,&ab,0);
waitpid(t2,&ab,0);
return 0;
}
OUTPUT
enter the number of levels
3
root 20665
child pid 20670 parent pid 20665
child pid 20669 parent pid 20665
child pid 20672 parent pid 20670
child pid 20671 parent pid 20670
child pid 20674 parent pid 20669
child pid 20673 parent pid 20669
First one needs to understand what is fork () system call. Let me explain
fork() system call creates the exact duplicate of parent process, It makes the duplicate of parent stack, heap, initialized data, uninitialized data and share the code in read-only mode with parent process.
Fork system call copies the memory on the copy-on-write basis, means child makes in virtual memory page when there is requirement of copying.
Now Purpose of fork():
Fork() can be used at the place where there is division of work like a server has to handle multiple clients, So parent has to accept the connection on regular basis, So server does fork for each client to perform read-write.
fork() is used to spawn a child process. Typically it's used in similar sorts of situations as threading, but there are differences. Unlike threads, fork() creates whole seperate processes, which means that the child and the parent while they are direct copies of each other at the point that fork() is called, they are completely seperate, neither can access the other's memory space (without going to the normal troubles you go to access another program's memory).
fork() is still used by some server applications, mostly ones that run as root on a *NIX machine that drop permissions before processing user requests. There are some other usecases still, but mostly people have moved to multithreading now.
The rationale behind fork() versus just having an exec() function to initiate a new process is explained in an answer to a similar question on the unix stack exchange.
Essentially, since fork copies the current process, all of the various possible options for a process are established by default, so the programmer does not have supply them.
In the Windows operating system, by contrast, programmers have to use the CreateProcess function which is MUCH more complicated and requires populating a multifarious structure to define the parameters of the new process.
So, to sum up, the reason for forking (versus exec'ing) is simplicity in creating new processes.
Fork() system call use to create a child process. It is exact duplicate of parent process. Fork copies stack section, heap section, data section, environment variable, command line arguments from parent.
refer: http://man7.org/linux/man-pages/man2/fork.2.html
Fork() was created as a way to create another process with shared a copy of memory state to the parent. It works the way it does because it was the most minimal change possible to get good threading capabilities in time-slicing mainframe systems that previously lacked this capability. Additionally, programs needed remarkably little modification to become multi-process, fork() could simply be added in the appropriate locations, which is rather elegant. Basically, fork() was the path of least resistance.
Originally it actually had to copy the entire parent process' memory space. With the advent of virtual memory, it has been hacked and changed to be more efficient, with copy-on-write mechanisms avoiding the need to actual copy any memory.
However, modern systems now allow the creation of actual threads, which simply share the parent process' actual heap. With modern multi-threading programming paradigms and more advanced languages, it's questionable whether fork() provides any real benefit, since fork() actually prevents processes from communicating through memory directly, and forces them to use slower message passing mechanisms.

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