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I am for a long time trying to get a picture how is program memory handled under OS (I use Windows, but I guess this will be the same or very close on Linux).

So far, I know (mostly thanks to you stackoverflow users) that local variables are stored on stack. Now I also finally understand why. So thats OK.

But what I still miss is, how are stored and handled global variables. And I want to know it on assembler basis. I have my idea of how these can be handled, but I cant be sure, becouse there are many things I still dont know about that could made my idea impossible to implement.

So, my idea is, that global variables are locate at the end of the program code. After the last instruction. Why I think it could be this way? Becouse than, you would not need to waste any extra memory and CPU time. Becouse that variables and their default values would by copied into RAM by OS when executed.

Why I thing this would be possible? Becouse, if I am not wrong, on modern x86 OSes, every program gets its own adress space starting from 0. This way, compiled very easily knows adress of the global variable. becouse it know the length of the program, so it can calculate its position in its adress space.

Why I think this might be all wrong? Becouse I already thought why are local variables created on stack instead this same way. And when you would have some routines in ELF format, you have precompiled routines just with unresolved adresses for variables.

Also, in some article, I read that allocating memory using malloc expands heap. And becouse I thing of heap as the space after the program code, there would be error becouse it would grow into the stack. Otherwise stack would need to be located at the end of process adress space, but taht would be terrible waste of memory.

I tried to describe my point of view as much as I could, so I hope you can understand where I made some mistakes, and help me to fill knowledge I am missing. Thanks.

share|improve this question
en.wikipedia.org/wiki/Data_segment –  msw Aug 26 '10 at 21:21
Trying to understand things is great, but with such granularity you'll never see the end of it. Where are globals allocated and why they're there isn't even on the assembly level anymore, as the OS might just map that wherever it finds it convenient to. In short, you never will have control over that. –  zneak Aug 26 '10 at 21:28
Besides, several of your assumptions are incorrect and your picture is way too narrow. You still miss the notion of virtual memory, and you're not gonna go far understanding how stuff as close to the metal works if you don't know that. –  zneak Aug 26 '10 at 21:32
Well, but I thing I have virtual memory right. Actually I know Hw side of thing relativelly well. About virtual memory, on x86-i386 its achived mostly by paging, when MMU translated adress space requests by table it hold in special in-CPU cache. This cache is actually first cache ever introduced in x86 architecture, in 80386 CPU. And when you want to go even further, I know how to build simple calculator from stand-alone logical gates. So I thing that i know HW side well. Not great, but well. –  B.Gen.Jack.O.Neill Aug 26 '10 at 21:55

2 Answers 2

up vote 5 down vote accepted

The memory usage of a program is not a function of the language in which that program is written. You can write code that uses a ton of memory in C#, you can do the same in C.

That said, I will try to address some of what you're asking:

how are stored and handled global variables

They are given memory addresses. When you use a global, the compiler just uses that known address. (What, did you expect a complex answer?)

that global variables are locate at the end of the program code

On some architectures that may be the case, but it need not be. On Windows (using the Portable Executable file format) they are not in any way related, and may be mapped to completely different arbitrary locations. In fact, most likely this is not the case on more recent architectures, which discourage placing code where data lives (for security purposes -- you don't want a buffer overrun to be allowed to overwrite your program code)

if I am not wrong, on modern x86 OSes, every program gets its own adress space starting from 0

You are not wrong in theory, but you are wrong in fact. Even if linkers could really do this, few would, simply because 0 is used as the null constant. Usually however, the issue is that there are dynamic libraries, or other items that consume pieces of your process' address space, well before your code is actually loaded. (For example, a reference to the file where your code is located, or a block of memory which contains the command line passed to your program)

I read that allocating memory using malloc expands heap

Well, you're assuming that there is only one heap. On Windows at least, each DLL usually has it's own heap, and you can create heaps on the fly/at will. The way heaps are classically explained in Computer Science courses are usually assuming a system where there is no base operating system or virtual memory in play.

You are confusing memory with address space here for modern processors. Address locations of things often have very little to do with where they are physically stored. The Wikipedia article on Virtual Memory might make things make a bit more sense for you. Good luck!


the PE exe file actually has informations about global variables that can be distinguished from other data

Not exactly. The PE file format has a section where static data is stored, and that region of the file is memory mapped. The code knows where in that big chunk where the specific globals you're looking for are.

That Os actualy maps them to lets say "best" space available

Modern processors use a flat memory model. It's just as easy to access any one address as it is to access any other.

I always thought that compiled code is no further changed by OS at runtime

It isn't (well, for the most part, the reasons it might change are a whole can of worms in and of themselves). To access the global, the code itself needs to know the base address at which it is loaded. It can calculate where the data block of the PE file is loaded from that, for the most part. That said, compilers are free to put globals pretty much anywhere; the fact that the PE spec has a place for initialized data does not mean the compiler has to use it (MingGW, for example, I believe does not use that area).

First, does .exe contains information about stack size needed?

Yes, there are settings controlling both the reserved size of the stack as well as the committed size of the stack. Because Stack Overflows can be handled safely on Windows, usually the stack is only 1 MB; on *nix machines it's usually 8MB or more.

And is stack size limited?

Not as far as I am aware. That said; there are of course practical limitations. First and foremost, address space reserved for the stack will not be usable for anything other than the stack. There are also large portions of the address space that are reserved by the Kernel for various uses; not to mention the actual code and data on which your program operates. If you are using more than 1MB of stack, you should consider using a heap allocated stack for your data, and switch to an iterative solution, or seriously rethink how your program operates. 1MB of stack is much much more than is commonly used.

And second, is there any article you now about, that contains this informations, and/or informations what does PE format contauns are how is this coded to be seen when disassembling .exe file

You can read the PE Spec: http://www.microsoft.com/whdc/system/platform/firmware/pecoff.mspx

On modern systems, you can essentially forget about knowing exactly where code segments and data are located both physically and virtually. The Processor does not care or enforce anything like this, so there is no reason any operating system or program is forced to use any sort of memory organization. In particular, the concept of a Heap in Windows is much different than what is typically taught in Computer Science courses. In Windows (and other modern OSs), the heap is nothing more than a bunch of memory dolled out by the OS. The location, however, of that memory is completely variable. Ask for the OS for one block, you might get it at 0x00005556, and you might get the next block at 0xFFFF890. There's no reason for a distinction because the processor underneath simply does not care.

share|improve this answer
+1, good answer! I'd like to add that stack-memory is also allocated per-thread/process basis. It also doesn't grow, only the current stack-pointer moves. So essentially stack space is just a part of the heap that most likely will be prefetched into the cache since local variables on the stack are more commonly used. A reason to know about stack-stored variables can be to know when to move them into registers(if compiler allows you) to avoid load-hit-stores. –  Simon Aug 26 '10 at 21:33
Very nice answer, thanks. Can I ask further? So some problems I thought about are solved that the PE exe file actually has informations about global variables that can be distinguished from other data? That Os actualy maps them to lets say "best" space available? And than links the correct adress to the program? I always thought that compiled code is no further changed by OS at runtime. So you are basically telling me that OS links .exe files on startup to solve global variables? I thought that OS just creates new VAS, loads code into it and run it, and code must be done right way.... –  B.Gen.Jack.O.Neill Aug 26 '10 at 22:01
You completely ruined my idea of how it works. I want to have your level of knowledge. If I may ask 2 more things, please, I have no one to ask. First, does .exe contains information about stack size needed? And is stack size limited? And second, is there any article you now about, that contains this informations, and/or informations what does PE format contauns are how is this coded to be seen when disassembling .exe file? Thanks. –  B.Gen.Jack.O.Neill Aug 26 '10 at 22:06
Program code (and data) tends to be loaded at a fixed address (but there are system that support PIE - Position Independent Executables to enable more ASLR - a security feature). On the other hand, library code (and data) tends to be loaded by the dynamic linker at some free address (but some systems have rebased or prelinked libraries to avoid fixups at program startup). –  ninjalj Aug 26 '10 at 22:14
About stack size, the OS may have some configurable maximum for the stack size, and it grows the stack automatically when needed until it reaches that maximum. OTOH, systems without MMU use physical memory for the stack, so they cannot grow the stack on demand, and need the stack size on the executable (see for example the BFLT executable format). –  ninjalj Aug 26 '10 at 22:17

On a typical virtual memory modern system, the address space of a program is typically composed of the following sections:

  • Code: Marked as read only. Doesn't usually start at 0, but at some higher address. You don't want anything on address 0 or near there, think of null pointers.
  • Read only data: usually just after code, since it is read only.
  • Read/write data: usually after rodata, but starts on a new page, since it has to be read/write.
  • BSS (unitialized static variables): usually after data. The contents of this section don't come from the executable file, the executable file just tells the size and the loader initializes it with zeros.
  • Heap: usually after bss, on Unix can be expanded by calling brk()/sbrk().
  • Stack: usually starts on some high memory area, far from the heap, and grows downwards.

From the memory management point of view, these are grouped into code (code + rodata), data (data + bss + heap) and stack segments.

Dynamic libraries have their own code and data segments, and there are other sections used by the dynamic linker (GOT, PLT, ...), debuggers, ...

share|improve this answer
Except there is usually more than one heap (at least one per dynamic library). Oh, and brk()/sbrk() are POSIX specific; the equivalent Windows function is VirtualAlloc. –  Billy ONeal Aug 26 '10 at 22:57

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