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Recently, I was asked in an interview, why would you have a smaller stack when the available memory has no limit? Why would you have it in 1KB range even when you might have 4GB physical memory? Is this a standard design practice?

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Yes, because having really, really deep recursion is an antipattern. :-P –  Chris Jester-Young Sep 23 '11 at 5:05

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The smaller your stacks, the more of them you can have. A 1kB stack is pretty useless, as I can't think of an architecture that has pages that small. A more typical size is 128kB-1MB.

Since each thread has its own stack, the number of stacks you can have is an upper limit on the number of threads you can have. Some people complain about the fact that they can't create more than 2000 threads in a standard 2GB address space of a 32-bit Windows process, so it's not surprising that some people would want even smaller stacks to allow even more threads.

Also, consider that if a stack has to be completely reserved ahead of time, it is carving a chunk out of your address space that can't be returned until the stack isn't used anymore (i.e. the thread exits). That chunk of reserved address space then limits the size of a contiguous allocation you can make.

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Thanks @Gabe, that explains it very well. I never thought in terms of threads or allocation ahead of time, without need for a it. –  Gaurav Sinha Sep 23 '11 at 5:31
    
Confused on the last part... is using up 4 KiB of contiguous virtual address space really that different from 1 MiB of contiguous space, when you have so many gigabytes anyway? –  Mehrdad Sep 23 '11 at 5:33
    
@Mehrdad: Consider the situation where you create 1000 threads and then all exit but the last one. Assume a 2GB address space where stacks are allocated contiguously. If you had 1MB stacks, your address space is partitioned into two 1GB segments. If you had 4kB stacks, your address space is partitioned into a 4MB segment and a 1.996GB segment. –  Gabe Sep 23 '11 at 5:47
    
@Gabe: Oooh, you mean in the same process... sorry I was thinking of multiple processes, my bad. –  Mehrdad Sep 23 '11 at 5:51
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Those "some people" who want 2000 threads in a process are doing something deeply, deeply wrong. Imagine having 2000 motorbikes but only four riders, and the riders stop their bike, run to the next one, drive it for a few metres, stop, run to the next one... Not an efficient way to solve a problem. When we have thousand-processor machines then it makes sense to have a couple thousand threads, but not before. –  Eric Lippert Sep 24 '11 at 14:41

The other answers are good; I just thought I'd point out an important misunderstanding inherent in the question. How much physical memory you have is completely irrelevant. Having more physical memory is just an optimization; it prevents having to use disk as storage. The precious resource consumed by a stack is address space, not physical memory. The bits of the stack that aren't being used right now are not even going to reside in physical memory; they'll be paged out to disk. But as soon as they are committed, they are consuming virtual address space.

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Thanks for your help. –  Sandeep Sep 25 '11 at 4:21

I don't know the "real" answer, but my guess is:

  • It's committed on-demand.

  • Do you really need it?

If the system uses 1 MiB for a stack, then a typical system with 1024 threads would be using 1 GiB of memory for (mostly) nothing... which may not be what you want, especially since you don't really need it.

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Thanks @Mehrdad –  Gaurav Sinha Sep 23 '11 at 5:34

One reason is, even though memory is huge these days, it is still not unlimited. A 32-bit process is normally limited to 4GB of address space (yes, you can use PAE to increase that, but that requires support from the OS and a return to a segmented memory model.) Each thread uses up some of that memory for its stack, and if a stack is megabytes in size -- whether it's paged in or not -- it's taking up a significant part of the app's address space.

The smaller the stack, the more threads you can squeeze into the app, and the more memory you have available for everything else. Ideally, you want a stack just large enough to handle all possible control flows through the thread, but small enough that you don't have wasted address space.

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Thanks @cHao, got it :) –  Gaurav Sinha Sep 23 '11 at 5:35

There are two things here. First, the limit on the stack size will put the limit on number of processes/threads in the system. And then too, the limit is not because of the size of physical memory but because of the limit on addressable virtual memory. Secondly, rarely processes/threads need more stack size then that, and if they do, they can ask for it (libraries handle this seamlessly). So, when starting a new process/thread, it makes sense to give them a small stack space.

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Other answers here already mention the core concept, that the most significant consumed resource of a stack is address space (since its implementation requires chunks of contiguous address space) and that the default space consumed on windows for each thread is not insignificant.

However the full story is extremely nuanced (and can and will change over time) over many layers and levels.

This article by Mark Russinovich as part of his "Pushing the limits of Windows" series goes into extremely detailed levels of analysis. The work is in no way an introductory article though, and most people would not consider it the sort of thing that would be expected to be known in a job interview unless perhaps you were interviewing for a job in that particular field.

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Thanks for the articles link, looks like an interesting read. –  Gaurav Sinha Sep 28 '11 at 6:45

Maybe because everytime you call a function the OS has to allocate memory to be the stack of that function. Because functions can chain, several function calls will incur more stack allocations. A large default stack size, like 4GiB, would be impractical. But that's just my guess...

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