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Given a program of :

int main()
{

    short myVariableName1;  // stores from -32768 to +32767
    short int myVariableName2;  // stores from -32768 to +32767
    signed short myVariableName3;  // stores from -32768 to +32767
    signed short int myVariableName4;  // stores from -32768 to +32767
    unsigned short myVariableName5;  // stores from 0 to +65535
    unsigned short int myVariableName6;  // stores from 0 to +65535

    int myVariableName7;  // stores from -32768 to +32767
    signed int myVariableName8;  // stores from -32768 to +32767
    unsigned int myVariableName9;  // stores from 0 to +65535

    long     myVariableName10;  // stores from -2147483648 to +2147483647
    long     int myVariableName11;  // stores from -2147483648 to +2147483647
    signed   long myVariableName12;  // stores from -2147483648 to +2147483647
    signed   long int myVariableName13;  // stores from -2147483648 to +2147483647
    unsigned long myVariableName14;  // stores from 0 to +4294967295
    unsigned long int myVariableName15;  // stores from 0 to +4294967295
    cout << "Hello World!" << endl;
    cout << myVariableName1 << endl;
    cout << myVariableName2 << endl;
    cout << myVariableName3 << endl;
    cout << myVariableName4 << endl;
    cout << myVariableName5 << endl;
    cout << myVariableName6 << endl;
    cout << myVariableName7 << endl;
    cout << myVariableName8 << endl;
    cout << myVariableName9 << endl;
    cout << myVariableName10 << endl;
    cout << myVariableName11 << endl;
    cout << myVariableName12 << endl;
    cout << myVariableName13 << endl;
    cout << myVariableName14 << endl;
    cout << myVariableName15 << endl;
    cin.get();

    return 0;
}

Printing out the unassigned variables will print whatever was stored in that memory location previously. What I've noticed is that across multiple consecutive executions the printed values are not changing - which tells me that the locations in memory are the same each time they execute.

I'm just curious as to how this is determined, why this is so.

share|improve this question
    
you are running debug or release mode? –  Naveen Oct 12 '12 at 16:59
3  
"I'm just curious as to how this is determined" - The values are indeterminate. That means that they are not determined. –  Robᵩ Oct 12 '12 at 17:03

5 Answers 5

up vote 3 down vote accepted

Those variables live on the stack. The execution of your program looks to be deterministic, so every time you run it the same things happen. It's not choosing the same address necessarily (many runtimes these days make use of Address Space Randomization techniques to ensure that the stack addresses are not the same between runs), but the relative addresses on the stack contain the same data every time.

share|improve this answer
    
Firstly thank you.second how is it possible that randomized locations contain the same data? –  Wjdavis5 Oct 15 '12 at 4:08
1  
You still seem confused. Memory is wiped to zero before being mapped, there is no "existing contents" to the memory when a process starts running. You see non-zero data in those bytes because your program (though not your code per se) put them there. And it's the same every time because your program does the same thing every time. –  Andy Ross Oct 15 '12 at 4:12
    
If I attached an assembly debugger then I should be able to see those memory locations set to those values? –  Wjdavis5 Oct 15 '12 at 12:36
1  
Yes, but it will be difficult. Dynamically linked linux programs actually start execution in ld.so and run a significant amount of code before calling _start (which calls main). You'd need to do some research about setting breakpoints there, I don't know how off hand. –  Andy Ross Oct 15 '12 at 15:26

They're all stack based. Probably the startup code has already used those locations, so you're getting whatever it left in them.

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+1 especially as when one uses cout there is some initialization ongoing to build all those static objects. –  Matthieu M. Oct 12 '12 at 17:46
    
Thanks! So by that theory changing the order they are initialized in should yield the same results a long as the sizeof is the same? –  Wjdavis5 Oct 15 '12 at 4:11

They can be anything don't rely on them to be anything specific.
Technically, the values are Indeterminate.

Note that using an Indeterminate value results in Undefined Behavior.

share|improve this answer
1  
This is confusing things more than helping. Your use of "indeterminate" and "undefined" refers to the C language specification. The poster has a real machine, with real values stored in real memory. The question was why those values are the same between runs. Saying they are "undefined" without reference to what you mean (clearly the memory contents are real and quite well defined!) doesn't answer the question. –  Andy Ross Oct 13 '12 at 0:33
    
@AndyRoss: The real machine, with real values stored in real memory doesn't make the behavior deterministic in any possible way.The behavior is Undefined as per the Standard and that is the only correct explanation. –  Alok Save Oct 13 '12 at 8:00
    
A real machine's behavior is not deterministic? I think you're confused about how computers work, and I'm certain you're confused about my criticism. It's fine to argue a design point based on a language standard. But that's not what the question was about. –  Andy Ross Oct 14 '12 at 2:11

The behaviour is not defined as "whatever was stored in that memory location previously", but it is rather not defined at all. There is no guarantee to what will happen.

My best guess is that your operation system is using virtual memory (as most modern OS do), thus giving you the same memory addresses every time.

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Why the downvote? did i note anything incorrect? –  user1708860 Oct 12 '12 at 17:04
    
The fact that the address in memory is the same does not explain why the content at that address would be the same. –  Matthieu M. Oct 12 '12 at 17:43
    
The virtual memory bit isn't relevant to memory mapping address choices. In fact it's increasingly common for mappings to be semi-randomized at runtime. But the addresses aren't the issue anyway -- the symptom the OP is seeing is that the contents of the memory are the same between runs, not the addresses. Memory content is never retained from one process to another in a modern OS. –  Andy Ross Oct 12 '12 at 18:37

Unlike humans, computers are deterministic.

Usually a good idea to use the compiler options to pick up when reading a variable that has not been given a value.

So the OS picks up the code and does exactly the same thing ever time. Hence the same result.

But if you start fiddling with the code the executable will be different. As you have not been specific you get a different result the next time around.

So in summary just use all the features of the compiler to help you spot this error and get into the habit of giving the variables values before using that variable.

share|improve this answer
    
I actually did this on purpose and after executing several times noticed the values were not changing. Being so I was curious as to how the memory address were being assigned to the variables. Thanks for the help! –  Wjdavis5 Oct 12 '12 at 17:11

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