Non problem
The expression (int*)2000
is used in several places. You take an arbitrary integer and convert it to a pointer type. This is allowed according to C11 standard, section 6.3.2.3:
- An integer may be converted to any pointer type. Except as previously specified, the result is implementation-defined, might not
be correctly aligned, might not point to an entity of the referenced
type, and might be a trap representation
So you are sure to get a pointer, but you have no guarantee that it is valid.
Potential problem
Then you take a first risk, because you convert a pointer type to a plain integer:
int y = (int*)2000;
We've already seen that the casted expression (int*)2000
is a pointer type. According to the C standard, in the section 6.3.2.3 about pointer conversions:
- Any pointer type may be converted to an integer type. Except as previously specified, the result is implementation-defined. If the
result cannot be represented in the integer type, the behavior is
undefined. The result need not be in the range of values of any
integer type.
So there is a risk of undefined behavior. This means that it could potentially crash or stop the program with a fatal error. But if your output shows the value of 2000, this means that the result can be represented in the integer type and everything's fine, at least with your specific compiler (it's not a universal guarantee: another compiler could make this crash, even if the risk is low).
Most probable problem
When you uncomment your final statement, you have a very dangerous expression in it:
*((int*)2000)
You dereference a pointer that you have obtained by conversion. However, we have seen above, that the pointer (int*)2000
might be invalid. Unfortunately, the C standard, section 6.5.3.2 is very clear about the risks:
- (...) If an invalid value has been assigned to the pointer, the behavior of the unary * operator is undefined.
And here it certainly is: on most modern computers, the operating system assigns a virtual memory address space to a process. The operating system then keeps track of the valid address ranges and the invalid one. In addition, some OS security mechanism make the relevant address location of your code random, so to avoid hacking exploits, which could make use of fixed addresses. So if your pointer would not point to a valid address (most probable situation here), there is a big chance that the operating catches an invalid memory access, which triggers a fatal error.
Another frequent situation would be an alignment issue: modern CPUs have alignment constraints for integers. For example, an integer cannot start on an odd address, because it would be a problem for the CPU to load it fast into its register. Alignment problems also cause crashes.
But all this are only potential examples of undefined behavior. Another case, could be that everything seems to work fine, despite the invalid pointer. It's just that a garbage integer value would be printed.
Conclusion
Code can be perfectly valid, but nevertheless result in perfectly undefined behavior. So, whenever you want to dereference a pointer, first think: can you be sure that it's always valid ?
2000
? What makes you think it's even a valid address?*((int*)2000)
is dereferencing an invalid address: you get segv when evaluating the argumentsint y = (int*)2000
is likeint y = 2000
with more warnings.fflush(stdout);
before the crash line, and the first output will occur. User programs cannot readmemory that does not belong to them at will, as that would be a memory segmentation violation. Hence the segfault you are most likely receiving.*((int*)2000)
.