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I've recently heard a few people say that in Linux, it is almost always better to use processes instead of threads, since Linux is very efficient in handling processes, and because there are so many problems (such as locking) associated with threads. However, I am suspicious, because it seems like threads could give a pretty big performance gain in some situations.

So my question is, when faced with a situation that threads and processes could both handle pretty well, should I use processes or threads? For example, if I were writing a web server, should I use processes or threads (or a combination)?

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Is there a difference with Linux 2.4? –  mouviciel Apr 30 '09 at 15:40
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The difference between processes and threads under Linux 2.4 is that threads share more parts of their state (address space, file handles etc) than processes, which usually don't. The NPTL under Linux 2.6 makes this a bit clearer by giving them "thread groups" which are a bit like "processes" in win32 and Solaris. –  MarkR Apr 30 '09 at 20:34
    
Yes, NPTL is nice: it makes things like kill, exec, etc. work as you would expect in a threaded program (the old LinuxThreads behaviors make sense given the implementation, but were icky). OTOH a "thread group" is just a collection of "threads", and doesn't really take up resources itself, so it's a ton lighter-weight than a NT or Solaris process. –  ephemient Apr 30 '09 at 21:48
    
httpd.apache.org/docs/2.0/mod/worker.html is the default for apache webserver. its a multi process multi thread configuration. –  neal aise Jun 27 '10 at 1:29
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12 Answers

Linux uses a 1-1 threading model, with (to the kernel) no distinction between processes and threads -- everything is simply a runnable task. *

On Linux, the system call clone clones a task, with a configurable level of sharing, among which are:

  • CLONE_FILES: share the same file descriptor table (instead of creating a copy)
  • CLONE_PARENT: don't set up a parent-child relationship between the new task and the old (otherwise, child's getppid() = parent's getpid())
  • CLONE_VM: share the same memory space (instead of creating a COW copy)

fork() calls clone(least sharing) and pthread_create() calls clone(most sharing). **

forking costs a tiny bit more than pthread_createing because of copying tables and creating COW mappings for memory, but the Linux kernel developers have tried (and succeeded) at minimizing those costs.

Switching between tasks, if they share the same memory space and various tables, will be a tiny bit cheaper than if they aren't shared, because the data may already be loaded in cache. However, switching tasks is still very fast even if nothing is shared -- this is something else that Linux kernel developers try to ensure (and succeed at ensuring).

In fact, if you are on a multi-processor system, not sharing may actually be beneficial to performance: if each task is running on a different processor, synchronizing shared memory is expensive.


* Simplified. CLONE_THREAD causes signals delivery to be shared (which needs CLONE_SIGHAND, which shares the signal handler table).

** Simplified. There exist both SYS_fork and SYS_clone syscalls, but in the kernel, the sys_fork and sys_clone are both very thin wrappers around the same do_fork function, which itself is a thin wrapper around copy_process. Yes, the terms process, thread, and task are used rather interchangeably in the Linux kernel...

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I think we are missing 1 point. If you make multiple process for your web server, then you have to write another process to open the socket and pass 'work' to different threads. Threading offers a single process multiple threads, clean design. In many situations thread is just natural and in other situation a new process is just natural. When the problem falls in a gray area the other trade offs as explained by ephemient becomes important. –  Saurabh Feb 6 '12 at 7:05
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@Saurabh Not really. You can easily socket, bind, listen, fork, and then have multiple processes accept connections on the same listening socket. A process can stop accepting if it's busy, and the kernel will route incoming connections to another process (if nobody is listening, kernel will queue or drop, depending on listen backlog). You don't have much more control over work distribution than that, but usually that's good enough! –  ephemient Mar 26 '12 at 21:36
    
"the data may already be loaded in cache" - what cache exactly? –  naxa Jun 15 '13 at 15:23
    
Naxa, the cache that's being referred to is the page table cache. COW ensures that initially the two threads will share the same memory - ie, each thread will point to the same physical place in memory for it's program data. This means the kernel hasn't had to perform any swapping/paging as the data is already there, probably already loaded into main memory. –  Lawrence Jones Apr 25 at 16:32
    
There is one thing which I do not understand from this answer: If threads and processes are the same to linux, how and when do we achieve shared resources for the threads? –  Bloodcount Jun 18 at 12:35
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Linux (and indeed Unix) gives you a third option.

Option 1 - processes

Create a standalone executable which handles some part (or all parts) of your application, and invoke it separately for each process, e.g. the program runs copies of itself to delegate tasks to.

Option 2 - threads

Create a standalone executable which starts up with a single thread and create additional threads to do some tasks

Option 3 - fork

Only available under Linux/Unix, this is a bit different. A forked process really is its own process with its own address space - there is nothing that the child can do (normally) to affect its parent's or siblings address space (unlike a thread) - so you get added robustness.

However, the memory pages are not copied, they are copy-on-write, so less memory is usually used than you might imagine.

Consider a web server program which consists of two steps:

  1. Read configuration and runtime data
  2. Serve page requests

If you used threads, step 1 would be done once, and step 2 done in multiple threads. If you used "traditional" processes, steps 1 and 2 would need to be repeated for each process, and the memory to store the configuration and runtime data duplicated. If you used fork(), then you can do step 1 once, and then fork(), leaving the runtime data and configuration in memory, untouched, not copied.

So there are really three choices.

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@Qwertie forking is not that cool, it breaks lots of libraries in subtle ways (if you use them in the parent process). It creates unexpected behaviour which confuses even experienced programmers. –  MarkR Jan 21 '12 at 12:32
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@MarkR could you give some examples or a link of how forking breaks library and creates unexpected behavior? –  Shurane Oct 31 '12 at 19:52
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If a process forks with an open mysql connection, bad things happen, as the socket is shared between two processes. Even if only one process uses the connection, the other stops it from being closed. –  MarkR Nov 2 '12 at 11:35
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That depends on a lot of factors. Processes are more heavy-weight than threads, and have a higher startup and shutdown cost. Interprocess communication (IPC) is also harder and slower than interthread communication.

Conversely, processes are safer and more secure than threads, because each process runs in its own virtual address space. If one process crashes or has a buffer overrun, it does not affect any other process at all, whereas if a thread crashes, it takes down all of the other threads in the process, and if a thread has a buffer overrun, it opens up a security hole in all of the threads.

So, if your application's modules can run mostly independently with little communication, you should probably use processes if you can afford the startup and shutdown costs. The performance hit of IPC will be minimal, and you'll be slightly safer against bugs and security holes. If you need every bit of performance you can get or have a lot of shared data (such as complex data structures), go with threads.

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Adam's answer would serve well as an executive briefing. For more detail, MarkR and ephemient provide good explanations. A very detailed explanation with examples may be found at cs.cf.ac.uk/Dave/C/node29.html but it does appear to be a bit dated in parts. –  CyberFonic Jan 6 '10 at 0:07
    
CyberFonic's is true for Windows. As ephemient says under Linux processes aren't heavier. And under Linux all the mechanisms available for communication between threads (futex's,shared memory, pipes, IPC) is also available for processes and run at the same speed. –  Russell Stuart Apr 4 at 3:26
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Others have discussed the considerations.

Perhaps the important difference is that in Windows processes are heavy and expensive compared to threads, and in Linux the difference is much smaller, so the equation balances at a different point.

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Once upon a time there was Unix and in this good old Unix there was lots of overhead for processes, so what some clever people did was to create threads, which would share the same address space with the parent process and they only needed a reduced context switch, which would make the context switch more efficient.

In a contemporary Linux (2.6.x) there is not much difference in performance between a context switch of a process compared to a thread (only the MMU stuff is additional for the thread). There is the issue with the shared address space, which means that a faulty pointer in a thread can corrupt memory of the parent process or another thread within the same address space.

A process is protected by the MMU, so a faulty pointer will just cause a signal 11 and no corruption.

I would in general use processes (not much context switch overhead in Linux, but memory protection due to MMU), but pthreads if I would need a real-time scheduler class, which is a different cup of tea all together.

Why do you think threads are have such a big performance gain on Linux? Do you have any data for this, or is it just a myth?

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Yes, I do have some data. I ran a test that creates 100,000 processes and a test that creates 100,000 threads. The thread version ran about 9x faster (17.38 seconds for processes, 1.93 for threads). Now this does only test creation time, but for short-lived tasks, creation time can be key. –  user17918 May 19 '09 at 15:37
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@user17918 - Is it possible for you to share the code used by you to calculate above mentioned timings .. –  codingfreak Mar 30 '11 at 12:57
    
one big different, with processes the kernel create page table for every process and theads use only one page tables, so i think is normal the threads are faster then processes –  c4f4t0r Dec 10 '13 at 13:41
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The decision between thread/process depends a little bit on what you will be using it to. One of the benefits with a process is that it has a PID and can be killed without also terminating the parent.

For a real world example of a web server, apache 1.3 used to only support multiple processes, but in in 2.0 they added an abstraction so that you can swtch between either. Comments seems to agree that processes are more robust but threads can give a little bit better performance (except for windows where performance for processes sucks and you only want to use threads).

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For some programs that benefit from concurrency, the decision whether to use processes or threads can be difficult. Here are some guidelines to help you decide which concurrency model best suits your program:

1> All threads in a program must run the same executable. A child process, on the other hand, may run a different executable by calling an exec function.

2> An errant thread can harm other threads in the same process because threads share the same virtual memory space and other resources. For instance, a wild memory write through an uninitialized pointer in one thread can corrupt memory visible to another thread.

3> An errant process, on the other hand, cannot do so because each process has a copy of the program's memory space.

4> Copying memory for a new process adds an additional performance overhead relative to creating a new thread. However, the copy is performed only when the memory is changed, so the penalty is minimal if the child process only reads memory.

5> Threads should be used for programs that need fine-grained parallelism. For example, if a problem can be broken into multiple, nearly identical tasks, threads may be a good choice. Processes should be used for programs that need coarser parallelism.

6> Sharing data among threads is trivial because threads share the same memory. (However, great care must be taken to avoid race conditions, as described previously.) Sharing data among processes requires the use of IPC mechanisms. This can be more cumbersome but makes multiple processes less likely to suffer from concurrency bugs.

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I'd have to agree with what you've been hearing. When we benchmark our cluster (xhpl and such), we always get significantly better performance with processes over threads. </anecdote>

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How tightly coupled are your tasks?

If they can live independently of each other, then use processes. If they rely on each other, then use threads. That way you can kill and restart a bad process without interfering with the operation of the other tasks.

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To complicate matters further, there is such a thing as thread-local storage, and Unix shared memory.

Thread-local storage allows each thread to have a separate instance of global objects. The only time I've used it was when constructing an emulation environment on linux/windows, for application code that ran in an RTOS. In the RTOS each task was a process with it's own address space, in the emulation environment, each task was a thread (with a shared address space). By using TLS for things like singletons, we were able to have a separate instance for each thread, just like under the 'real' RTOS environment.

Shared memory can (obviously) give you the performance benefits of having multiple processes access the same memory, but at the cost/risk of having to synchronize the processes properly. One way to do that is have one process create a data structure in shared memory, and then send a handle to that structure via traditional inter-process communication (like a named pipe).

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I used thread-local storage for a some statistics gathering, the last time I was writing a threaded networks program: each thread wrote to its own counters, no locks needed, and only when messaged would each thread combine its stats into the global totals. But yeah, TLS is not very commonly used or necessary. Shared memory, on the other hand... in addition to efficiently sending data, you can also share POSIX semaphores between processes by placing them in shared memory. It's pretty amazing. –  ephemient Apr 30 '09 at 21:57
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For most cases i would prefer processes over threads. threads can be useful when you have a relatively smaller task (process overhead >> time taken by each divided task unit) and there is a need of memory sharing between them. Think a large array. Also (offtopic), note that if your CPU utilization is 100 percent or close to it, there is going to be no benefit out of multithreading or processing. (in fact it will worsen)

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If you need to share resources, you really should use threads.

Also consider the fact that context switches between threads are much less expensive than context switches between processes.

I see no reason to explicitly go with separate processes unless you have a good reason to do so (security, proven performance tests, etc...)

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I do have the rep to edit, but I don't quite agree. Context switches between processes on Linux is almost as cheap as context switches between threads. –  ephemient Apr 30 '09 at 15:44
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