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Can anyone explain the difference between a fork and a thread?

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You use a fork to eat, and a thread to sew. :p – kennytm Mar 20 '10 at 12:55
well, you can stick two pieces of cloth together with a fork and it will hold for some time, but if you want something more durable, you must stitch it with a thread. (just kidding, take it easy :-)) – Eli Bendersky Mar 20 '10 at 12:55

5 Answers 5

up vote 43 down vote accepted

A fork gives you a brand new process, which is a copy of the current process, with the same code segments. As the memory image changes (typically this is due to different behaviour of the two processes) you get a separation of the memory images (Copy On Write), however the executable code remains the same. Tasks do not share memory unless they use some Inter Process Communication (IPC) primitive.

In contrast a thread is another execution thread of the same task. One task can have multiple threads, and the task memory object are shared among threads, therefore shared data must be accessed through some primitive and synchronization objects (like mutexes, condition variables and semaphores) that allow you to avoid data corruption.

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You probably want to refer to "copy of the current process" as a child process. – verwerfe Mar 20 '10 at 13:25
The text segment however is often shared (virtually) and even data segment can be copy-on-write. – Xepoch Feb 29 '12 at 19:27


Fork is nothing but a new process that looks exactly like the old or the parent process but still it is a different process with different process ID and having it’s own memory. Parent process creates a separate address space for child. Both parent and child process possess the same code segment, but execute independently from each other.

The simplest example of forking is when you run a command on shell in unix/linux. Each time a user issues a command, the shell forks a child process and the task is done.

When a fork system call is issued, a copy of all the pages corresponding to the parent process is created, loaded into a separate memory location by the OS for the child process, but in certain cases, this is not needed. Like in ‘exec’ system calls, there is not need to copy the parent process pages, as execv replaces the address space of the parent process itself.

Few things to note about forking are:

  • The child process will be having it’s own unique process ID.
  • The child process shall have it’s own copy of parent’s file descriptor.
  • File locks set by parent process shall not be inherited by child process.
  • Any semaphores that are open in the parent process shall also be open in the child process.
  • Child process shall have it’s own copy of message queue descriptors of the parents.
  • Child will have it’s own address space and memory.


Threads are Light Weight Processes (LWPs). Traditionally, a thread is just a CPU (and some other minimal state) state with the process containing the remains (data, stack, I/O, signals). Threads require less overhead than “forking” or spawning a new process because the system does not initialize a new system virtual memory space and environment for the process. While most effective on a multiprocessor system where the process flow can be scheduled to run on another processor thus gaining speed through parallel or distributed processing, gains are also found on uniprocessor systems which exploit latency in I/O and other system functions which may halt process execution.

  • Threads in the same process share:
  • Process instructions
  • Most data
  • open files (descriptors)
  • signals and signal handlers
  • current working directory
  • User and group id

More details can be found here.

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Dacav's answer is excellent, I just wanted to add that not all threading models give you true multi-processing.

For example, Ruby's default threading implementation doesn't use true OS / kernel threads. Instead it mimics having multiple threads by switching between the Thread objects within a single kernel thread / process.

This is important on multiprocessor / multi-core systems, because these types of lightweight threads can only run on a single core - you don't get much in the way of performance boost from having multiple threads.

The other place this makes a difference is when one thread blocks (waiting on I/O or calling a driver's IOCTL), all Threads block.

This isn't very common nowadays - most threading implementations use kernel threads which don't suffer from these issues - but its worth mentioining for completeness.

By contrast, fork gives you another process which is runnable simultaneously on another physical CPU while the original process is executing. Some people find IPC more suitable for their app, others prefer threading.

Good luck and have fun! Multi-threading is both challenging and rewarding.

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+1 for hitting a nerve: "not all threading give you true multiprocessing" – Dacav Mar 20 '10 at 15:53

Threads are functions run in parallel, fork is a new process with parents inheritance. Threads are good to execute a task in parallel, while forks are independent process, that also are running simultaneously. Threads have race conditions and there controls semaphores and locks or mutexes, pipes can both be used in fork and thread.

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  1. Threads share the address space of the process that created it; processes have their own address space.
  2. Threads have direct access to the data segment of its process; processes have their own copy of the data segment of the parent process.
  3. Threads can directly communicate with other threads of its process; processes must use interprocess communication to communicate with sibling processes.
  4. Threads have almost no overhead; processes have considerable overhead.
  5. New threads are easily created; new processes require duplication of the parent process.
  6. Threads can exercise considerable control over threads of the same process; processes can only exercise control over child processes.
  7. Changes to the main thread (cancellation, priority change, etc.) may affect the behavior of the other threads of the process; changes to the parent process does not affect child processes
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