I have always followed the concept that multithreading can only be implemented on multiple processors system where there are more than one processor to be assigned to each thread and each thread can be executed simultaneously. There is no scheduling in this case as each of the thread has separate resources all dedicated to it. But I recently read it somewhere that I can do multithreading on single processor system as well. Is it correct? and if yes then what is the difference between single processor and multiple processor systems?

  • 14
    Yes, and putting it simply, perceived vs. actual concurrency.
    – WhozCraig
    Apr 20, 2013 at 5:29
  • 11
    If it weren't possible, then Windows 95 was a mass hallucination. (If you count multiprocessing as multithreading, then the original unix was also a mass hallucination.) Apr 20, 2013 at 16:19
  • [link] (qnx.com/developers/docs/qnxcar2/…) pictures more powerful than words
    – LinconFive
    May 15, 2020 at 2:03

6 Answers 6


I recently read it somewhere that I can do multithreading on single processor system as well. Is it correct? and if yes then what is the difference between single processor and multiple processor systems?

Yes you can do multithreading on a single processor system.

In multi-processor system , multiple threads execute , simultaneously on different cores. Eg- If there are two threads and two cores , then each thread would run on individual core.

In a single-processor system, multiple threads execute , one after the other or wait until one thread finishes or is preempted by the OS , depending on the thread priority and the OS policy.But the running threads , gives an illusion that they run simultaneous , relative to the required application response time of the User space application.

Time Comparison(Example):

if two threads take 10us each to execute, then on a 2 processor system , the net time take is 10us

if two threads take 10us each to execute, then on a 1 processor system , the net time take is 20us

  • 14
    Chrome runs tabs in processes, not threads. The claim that threads improve stability is wrong. It's not possible for one thread to crash and leave the rest running. Since all threads of a process share a common address space, they are all potentially affected by any one thread clobbering memory. Moreover, involuntary termination caused by a thread "crashing" terminates the whole process, not just a single thread. Apr 20, 2013 at 5:54
  • 3
    @R.. Ok i've removed the controversial part....maybe i haven't read enough to back up and justify stability of threads... Apr 20, 2013 at 6:01
  • The only way I can see an argument that threads "improve stability" is by simplifying code and making errors less likely. It's a lot easier to write synchronous logic that runs in its own thread than asynchronous, event-driven state-machine logic, and this could translate into safer, more-stable programs. However threads don't give you any safety if one of them invokes UB. Apr 20, 2013 at 6:04
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    I think BarathBushan's answer is hepful and people should avoid down voting it :(
    – Ayse
    Apr 20, 2013 at 6:22

Of course it can be done on a single-processor system, and in fact it's much easier that way. It works the same way as running multiple processes -- the kernel, via a timer interrupt or other similar mechanism, suspends one, saving its machine state, and replacing that by the previously-saved state of another -- the only difference being that two threads of the same process share the same virtual memory space, making the task-switch much more efficient.

Multi-threading on multi-processor systems is actually much more difficult, since you have issues of simultaneous access to memory from multiple cpus/cores, and all the nasty memory synchronization issues that arise out of that.

  • 4
    No, you must be misreading that because the statement as you paraphrased it is definitely wrong. Apr 20, 2013 at 12:37
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    ⁺¹ for the «timer interrupt». Whole Internet holds no mention of how exactly the switch is done in hardware; I assumed it is some kind of timer, but even the Wikipedia is silent.
    – Hi-Angel
    Mar 10, 2016 at 13:48
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    if 2 threads running on one processor...isn't there need of synchronization?
    – user2156081
    Dec 24, 2016 at 20:23
  • Got the answer from @Barath post.
    – user2156081
    Dec 24, 2016 at 20:27
  • hi @R.. GitHub STOP HELPING ICE "the kernel, via a timer interrupt or other similar mechanism, suspends one, saving its machine state, and replacing that by the previously-saved state of another" is it what is known as "time-slicing/context switch"? thanks
    – user19481364
    Nov 3, 2022 at 15:30

You can have more than four active threads on a quad core system. There is scheduling, unless you can guarantee that processes won't try to create more threads than there are processors.

Yes, you can have multiple threads on a single-core computer.

The difference between single processor and multi-processor systems is that a multi-processor system can indeed do more than one thing at a time. It can do N things at a time, where N is the number of processor cores. A single-processor core can only do one thing at a time. As WhozCraig said in his comment, it's the difference between actual and perceived concurrency.

  • Thank you so much, I got the basic idea now how things are done
    – Ayse
    Apr 20, 2013 at 5:45

Yes, you totally can. Ages ago (Win 95?) we went from Cooperative Multitasking to Multithreading, because someone always screwed up the cooperative part. Every programm on your computer has at least one thread. Possibly more. And the CPU keep just switching between those all those threads like mad a few million times per second. If none of them has anything to do, it might even go idle for some time.

Multicore systems only mean that two or more of those threads might run in paralell.

However, it brings you a lot less to do so. All you can do with Multithreading on a Single Core machine is simulate Multitasking.

Mulitasking is enough to prevent the GUI thread from locking up because of a longrunning operation. However it is generally complicated to implement, unless you have some help from the Compiler or Langauge (like C# async...await). As a result, many GUI programmer just used Multithreading and Invoking to fake multitasking. If that code runs on single or multiple core does not mater for this.

Most importantly, Multitasking is NOT suited for CPU bound operations. But 95% of all Async problems are not CPU bound. They are Network or Disk Bound. On a singlecore computer, Multithreading also does not help with CPU bound stuff. If you got two threads that both need 100% CPU time (same programm or different one) but only one core to run them on, the CPU will just have to switch between running both at 49% and use the remaining 2% for all those other threads that only do a little bit.

Finally only very few problems can actually be Multithreaded. Just try to multithread the Fibonacci Sequence (one thread for each pair) without making it slower, more memory demanding and more complex.

tl;dr; You need Multithreading and a Multicore computer for CPU bound problems. Most async problems are not CPU bound. Multitasking is way enough. And you can totally multitask using threads, even on a single core machine.


Here's a very simplified example. It's actually a prototype for a program I'm building. It's a implementation of cooperative multitasking in a single thread.

main simply sets the quit flag to false, and populates an array of function pointers (the tasks), and then calls loop.

loop uses setjmp to set a return point for a non-local jump (a jump out of the function back to a previous location in the execution) and then proceeds to call the first task (function).

Each task ends with yield(). That is, none of the task functions actually return. Not only do they not contain a return; statement (which would be fine since they are void functions, ie. procedures), but they wouldn't reach the return even if it was there because yield jumps back to the setjmp call, this time yielding a 1 to the if statement in loop. The statement controlled by the if statement selects a different task before re-entering the while loop.

So each task function runs multiple times, yielding to the dispatcher (the if(setjmp... statement) which selects a new task to run.

#include <stdio.h> 
#include <setjmp.h> 

jmp_buf dispatch; 
int ntasks; 
void (*task[10])(void); 
int quit; 

void yield(void) { 
    longjmp(dispatch, 1); 

void loop() { 
    static int i = 0; 
        i = (i+1) % ntasks; 

int acc = 0; 

void a(void) { 
    if (acc > 10) quit = 1; 
void b(void) { 
    acc *= 2; 
void c(void) { 
    acc += 1; 

int main() { 
    quit = 0; 
    ntasks = 3; 
    task[0] = a; 
    task[1] = b; 
    task[2] = c; 
    return 0; 

The difference between this example and a single-processor multitasking computer system is the real processor supports interrupting a task in the middle of execution and resuming it later from the same spot. This isn't really possible in a C simulation with tasks as single functions. However, the tasks could be composed of a sequence of C functions which each yield to the dispatcher (an array of function pointers, maybe, or a linked-list).

  • 1
    Can you please add some form of description or comment to explain exactly what this is supposed to be showing and doing? Thank you.
    – Deanna
    Apr 26, 2013 at 12:52
  • Edited with some explanation. (I can add more if needed.) Apr 26, 2013 at 13:10
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    It doesn't look like there's any way to return from a yield(), so each thread has to complete before it calls yield. So there's no way to have more than one live thread at a time and no way to switch between them. So you could make things much simpler by just having the tasks return (instead of calling yield) and not use setjmp/longjmp at all.
    – Chris Dodd
    Sep 20, 2013 at 1:07

In a multithreaded process on a single processor, the processor can switch execution resources between threads, resulting in concurrent execution. Concurrency indicates that more than one thread is making progress, but the threads are not actually running simultaneously. The switching between threads happens quickly enough that the threads might appear to run simultaneously.

In the same multithreaded process in a shared-memory multiprocessor environment, each thread in the process can run concurrently on a separate processor, resulting in parallel execution, which is true simultaneous execution. When the number of threads in a process is less than or equal to the number of processors available, the operating system's thread support system ensures that each thread runs on a different processor. For example, in a matrix multiplication that is programmed with four threads, and runs on a system that has two dual-core processors, each software thread can run simultaneously on the four processor cores to compute a row of the result at the same time.

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