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I read in this presentation page 42:


- no stack overflows

How is this possible? and/or how does Go works to avoid this?

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5 Answers 5

up vote 14 down vote accepted

It's a feature called "segmented stacks": every goroutine has its own stack, allocated on the heap.

In the simplest case, programming language implementations use a single stack per process/address space, commonly managed with special processor instructions called push and pop (or something like that) and implemented as a dynamic array of stack frames starting at a fixed address (commonly, the top of virtual memory).

That is (or used to be) fast, but is not particularly safe. It causes trouble when lots of code is executing concurrently in the same address space (threads). Now each needs its own stack. But then, all the stacks (except perhaps one) must be fixed-size, lest they overlap with each other or with the heap.

Any programming language that uses a stack can, however, also be implemented by managing the stack in a different way: by using a list data structure or similar that holds the stack frames, but is actually allocated on the heap. There's no stack overflow until the heap is filled.

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Each thread has it's own stack, so "It causes trouble when lots of code is executing concurrently in the same address space (threads)." cannot be true. – dan_waterworth Nov 19 '10 at 16:39
A lot of this is incorrect, Go still uses the push/pop instructions (well, actually they don't but neither does GCC [mov off(%esp)]), it just sets the stack and stack base registers to a heap allocated stack. – cthom06 Nov 19 '10 at 16:42
@poolie: stack overflow exceptions are a pain in C or C++. It forces you to manually create iterative versions of recursive functions, or like CLang did in the last two weeks move the execution to a separate thread... and that is if you can foresee the issue. In order to circumvent this, many people will simply set a large stack (where I work it's 8MB per thread), but this still involve tuning and guesswork. Not having to worry about the stack size adds safety (not security). – Matthieu M. Nov 22 '10 at 10:16
Based on the comments here, this answer needs a bit more. Segmented stacks are more than just heap allocated. The Go runtime ensures that the stack is large enough (see runtime·morestack) at the beginning of a function, and if it isn't, it allocates more space for the stack (if there isn't enough memory, it panics). – cthom06 Nov 22 '10 at 13:09
I understand the benefit, I'm just not convinced that's what they meant by "stack overflow" in this context. Incidentally, the benefit is somewhat diluted on 64-bit machines where there is such an abundance of address space to hold widely-spaced stacks: give them each 4GB and be happy. (Obviously not all machines are 64 bit.) – poolie Nov 22 '10 at 20:58

I think what they are referring to here is that access to arrays is always checked against the actual length of the array, thus disabling one of the most common ways by which C programs crash accidentally or are crashed maliciously.

For example:

package main

func main() {
    var a [10]int

    for i:= 0; i < 100; i++ {
        a[i] = i

will panic with a runtime error when it tries to update the non-existent 11th element of the array. C would scribble over the heap, and probably also crash but in an uncontrolled way. Every array knows its length. In some cases there will be scope for the compiler to optimize out the checks if it can prove they are not necessary. (Or a sufficiently smart compiler could perhaps statically detect a problem in this function.)

Many of the other answers are talking about the memory layout of the stack but this is really not relevant: you can have heap overflow attacks too.

Basically Go's pointers should always be typesafe, with arrays and other types, unless you specifically use the unsafe package.

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I think you're confusing buffer overflows and stack overflows. You're correct though. – cthom06 Nov 22 '10 at 13:05
What you describe is bounds checking, it has nothing to do with the stack overflows the OP asked about. Pascal does this too, but it is (in typical implementations) vulnerable to stack overflows. – larsmans Nov 22 '10 at 13:14
I can't work out if the comment there is talking about a stack buffer overrun, or a stack overflow. If I was describing the key features of Go (for an audience that knows C), I would certainly mention checked arrays before I mentioned nearly-unlimited-size stacks. On the other hand this mention is in a section about concurrency, so perhaps they do mean you can add threads without giving them small stacks. – poolie Nov 22 '10 at 21:03

it uses a segmented stack. Which basically means it uses a linked list instead of a fixed size array as it's stack. When it runs out of space it makes the stack a little bigger.


Here is some more information:

The reason this is so great is not because it'll never overflow (that's a nice side-effect), it's that you can create threads with a really small memory footprint, meaning you can have lots of them.

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Links please... – Matt Joiner Nov 19 '10 at 16:45
@Matt, how's that? – dan_waterworth Nov 19 '10 at 16:59

I don't think they can "totally" avoid stack overflows. They provide a way to prevent the most typical programming-related errors to produce a stack overflow.

When the memory finishes there is no way to prevent a stack overflow.

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but anyone that writes a program that overflows a heap based stack is doing it wrong. – dan_waterworth Nov 19 '10 at 16:43
and that is 90 % of people out there, that's why the designers of go tried to prevent this – fabrizioM Nov 19 '10 at 16:46
90% of people will overflow a heap based stack (one like go's)? – dan_waterworth Nov 19 '10 at 17:01
You can't really, by definition, over a heap-based segmented stack. A stack overflow is stack_growth->*collision*<-heap_growth. With segmented stacks its just out of memory. (and still not an overflow in Go, the allocator panics instead) – cthom06 Nov 19 '10 at 19:57
For the C language, the stack default size is 1 to 8 MB, this is usually much less than any computer memory. In fact it may forces you to avoid recursion, when recursion is the simplest solution. – Muhammad Annaqeeb Nov 20 '14 at 12:58

Even C can do it with a few constraints that basically affect the compiler.

It is an impressive feat of engineering but not of language design.

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Links please... – Matt Joiner Nov 19 '10 at 16:43
I don't have any. I basically invented the technique. With a bit of assembly and a bit of imagination you can too. It's not that hard. – Joshua Nov 19 '10 at 17:24
Set the esp to somewhere in the heap? – Matt Joiner Nov 20 '10 at 23:00

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