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I'm a bit confused what happened in the following code:

const int e = 2;

int* w = ( int* ) &e;          // (1) cast to remove const-ness
*w = 5;                        // (2)

cout << *w << endl;            // (3) outputs 5
cout << e << endl;             // (4) outputs 2

cout << "w = " << w << endl;   // (5) w points to the address of e
cout << "&e = " << &e << endl;

In (1), w points to the address of e. In (2), that value was changed to 5. However, when the values of *w and e were displayed, their values are different. But if you print value of w pointer and &e, they have the same value/address.

How come e still contained 2, even if it was changed to 5? Were they stored in a separate location? Or a temporary? But how come the value pointed by w is still the address of e?

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You are in undefined behaviour land - anything can happen. – anon Mar 24 '10 at 14:48
My mind is too tired to see what is happening, but you can use const_cast for this. If you asked just to understand what is happening, you can disregard this comment. – erelender Mar 24 '10 at 14:49
@erelender: You could use const_cast for this but it wouldn't make the behaviour any less undefined. – Charles Bailey Mar 24 '10 at 14:58
up vote 14 down vote accepted

As I said in my comment, once you modified the const value you are in undefined behaviour land, so it doesn't make much sense to talk about what is happening. But what the hell..

cout << *w << endl;            // (3) outputs 5
cout << e << endl;             // (4) outputs 2

At a guess, *w is being evaluated at runtime, but e is being treated as a compile time constant

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Maybe... other possibility is that the compiler noticed "*w=5" just before and inserted 5 in the first line instead of *w – jpalecek Mar 24 '10 at 14:55
I agree. A const int initialized in scope will be a compile time constant. – Zan Lynx Mar 24 '10 at 14:57
Does this mean that there's just no use casting a const variable to a non-const pointer, since modifying through that pointer results to undefined behavior? – jasonline Mar 24 '10 at 15:02
Pretty much, the whole point of const is that you don't modify the value... you should never, ever cast away const. – Peter Alexander Mar 24 '10 at 15:05
I agree with Neil, for a longer explanation const X c = v, where X is a enum or integral type, and v is an integral constant expression (i.e. const int v = 5;) defines a constant c that can be used as an integral constant expression itself. That means that the compiler can inline the value when compiling any use of c, which is what is most probably happening. The UB is that modifying that constant through a const_cast (the C style cast there is a const_cast) may do anything or nothing at all, including killing the application. In this particular case it is modifying the value. – David Rodríguez - dribeas Mar 24 '10 at 15:14

I suspect that you're tripping up the compiler. It doesn't expect you to play dirty tricks with e, so when it sees the line:

cout << e << endl;

It simply inserts the value 2 instead of looking for the actual value. You can verify (or disprove) this by looking at the disassembly of your program.

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+1 for spelunking in assembly – Ben Zotto Mar 24 '10 at 14:53

I'm guessing that the compiler has optimised the value output. It sees that e is const (so, it can't change -- in theory) and changes cout << e << endl; to cout << 2 << endl;. However, e still has to exist because it's used by w, so w correctly takes its address and modifies its value, but you don't see that in the cout.

Moral of the story -- only declare things const when you actually want to be const. Casting away constness is not a good idea.

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I guess the compiler uses the constness to optimizes out the variable and insert a fixed value into the code.

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The only thing I can think of is the compiler has some how optimised the code in such a way that any references to e are replaced with a value of 2 even though it assigns memory for e

so in effect (affect?) the line at comment (4) is 'optimized' to be

cout << "2" << endln;
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